CN113056152B - Analysis storage platform based on big data of Internet of things - Google Patents

Abstract

The invention discloses an analysis and storage platform based on big data of the Internet of Things, which comprises several storage modules connected by lines and a carrier for carrying the storage modules. The carrier comprises a casing and a plurality of storage modules arranged inside the casing. The cavity and the supporting mechanism slidably arranged inside the receiving cavity for supporting the storage module. The invention only needs to control the rotation of the screw to drive the internal thread slider to move back and forth, so that the wire rope located at one end of the internal thread slider can be releasable, and the wire rope located at the other end of the internal thread slider can stretch the wire rope and slide out of the storage cavity in the supporting mechanism. After the inside, place the flipping strip on the top sub-supporting component in a horizontal state, and pull the flipping strip on the bottom sub-supporting component to a horizontal state. Similarly, when the supporting mechanism slides into the The inversion bar of the top sub-support assembly is pulled to a vertical state, and the inversion bar located on the bottom sub-support assembly is placed in a vertical state.

Description

An analysis and storage platform based on IoT big data

technical field

The invention relates to the technical field of big data, in particular to an analysis and storage platform based on the big data of the Internet of Things.

Background technique

Today's society is a rapidly developing society, with advanced technology, information flow, more and more communication between people, and more and more convenient life. The Internet of Things is the product of this high-tech era. The concept of the Internet of Things, its definition Yes: through information sensing equipment such as radio frequency identification (RFID), infrared sensors, global positioning systems, laser scanners, etc., according to the agreed protocol, connect any item through the Internet of Things domain name for information exchange and communication to achieve intelligent A network concept that identifies, locates, tracks, monitors and manages. With the advent of the Internet of Things, the development of big data is driven. Big data refers to huge data sets collected from many sources in multiple forms, often with Real-time, in the case of business-to-business sales, this data may be obtained from social networks, e-commerce sites, customer visit records, and many other sources, and these data are not the normal data set of a company's customer relationship management database, big data It has also attracted more and more people's attention. Due to the huge amount of Internet data, difficult acquisition, relatively low unit value, and almost all unstructured data such as text, the cloud storage system for big data uses big data. The management and operation mechanism of the analytical storage platform guarantees the high reliability of the services provided, and on the other hand, it aggregates the storage resources contributed by all participating users.

The existing large-scale storage platform has many storage modules inside, and the storage modules are placed inside the shells. When maintenance personnel repair a certain module, they need to take out the corresponding module, which is very inconvenient to operate, and when taking out It is also necessary to remove its line, which is very cumbersome and affects the maintenance time.

SUMMARY OF THE INVENTION

The purpose of the present invention is to provide an analysis and storage platform based on the big data of the Internet of Things to solve the problems raised in the above background art.

In order to achieve the above purpose, the present invention provides the following technical solution: an analysis and storage platform based on the big data of the Internet of Things, comprising a plurality of storage modules connected by lines and a carrier for carrying the storage modules, the carrier comprises a casing, a set of a plurality of storage cavities inside the housing and a supporting mechanism slidably arranged inside the storage cavity for supporting the storage module;

The supporting mechanism includes a main supporting component slidably arranged inside the receiving cavity and two sets of secondary supporting components arranged on the top and bottom of the main supporting component, and the main supporting component includes a sliding arrangement in the middle of the receiving cavity. A sliding seat, a connecting column vertically arranged on the front of the sliding seat, and a main supporting plate horizontally arranged at one end of the connecting column away from the sliding seat, wherein the connecting column is provided with a cavity inside, and two sets of the secondary supporting components They are respectively located on both sides of the connecting column, and the secondary support assembly includes a fixed shaft fixedly arranged between the sliding seat and the main bearing support plate, a turning bar rotatably arranged on the fixed shaft, and a turning shaft that is evenly arranged along the length of the turning bar through the turning shaft. The secondary support plate on the front side of the inversion bar, wherein a transmission cavity is arranged inside the inversion bar, and the supporting mechanism further includes a drive assembly for controlling the forward and reverse rotation or reverse rotation and forward rotation of the two inversion bars respectively and a rotation limiting assembly used to control the synchronous rotation of the secondary support plate to always maintain a horizontal state when the flipping bar rotates, and the driving assembly is used to control the flipping bar to be in a vertical state when the support mechanism slides into the storage cavity, When the supporting mechanism slides out of the storage cavity, the control turning bar is in a horizontal state.

Preferably, the drive assembly includes a screw that is rotatably arranged inside the cavity and is perpendicular to the sliding seat, an internal thread slider that is threadedly arranged on the screw, and two guide wheels that are respectively rotatably arranged inside the cavity on both sides of the screw. One and two steel wire ropes arranged on both sides of the internally threaded slider, wherein the bottom of the internally threaded slider is provided with a fixed rod, and the bottom end of the fixed rod is slidably connected to the bottom surface of the cavity, and the two guide wheels are one They are located at both ends of the screw rod, and the connecting columns on one side of the corresponding guide wheel are provided with wire holes, and the second guide wheels are symmetrically arranged inside the wire holes. The guide wheel 1 and the guide wheel 2 on the corresponding side are extended and fixedly connected to one end of the corresponding turning bar away from the main bearing plate. Corresponding to the two guide members for guiding and limiting the wire rope and the rotating member for driving the rotation of the screw rod.

Preferably, both of the two guide members are located above the fixed shaft, and one of them is located on the side of the fixed shaft close to the connecting column, and the other is located on the side of the fixed shaft away from the connecting column. Two positioning shafts between the main bearing support plate, a roller sleeved at the middle position of the positioning shaft, an L-shaped support plate arranged horizontally and symmetrically on the side of the positioning shaft at both ends of one of the rollers, and a vertical support plate arranged on the L-shaped support The T-shaped fixing rod at one end of the plate away from the positioning shaft, and the second roller sleeved on the T-shaped fixing rod, wherein a space is formed between the two rollers 2 and the two rollers 1 for the wire rope The guide limit channel of the guide limit.

Preferably, the rotating member includes a drive rod disposed through the inside of the main support plate and fixedly connected with the screw rod, and a rotating handle disposed at the other end of the drive rod.

Preferably, the rotation limiting assembly includes a gear 1 located inside the transmission cavity and assembled on a fixed shaft, a rotating shaft rotatably arranged inside the transmission cavity on one side of the gear, a rotating shaft 1 which is transferred to the rotating shaft and is connected with the gear 1 The second gear that meshes with each other, the second rotating shaft that is arranged in the transmission cavity on the side of the first rotating shaft away from the first gear, and the third and fourth gears that are transferred to the second rotating shaft, wherein the third and second gears are mutually The rotating shaft extends to the inside of the transmission cavity and is provided with a gear 5, and a chain is arranged between the gear 4 in the transmission cavity and the two gears 5.

Preferably, a door body is provided on one side of the storage cavity, and an observation window is provided on the door body.

Preferably, a line pipe is provided on the turning bar between the two rotating shafts and the turning bar between the rotating shaft and the fixed shaft.

Compared with the prior art, the beneficial effects of the present invention are:

(1) The two sets of secondary support assemblies of the present invention are respectively located on both sides of the connecting column, and the secondary support assemblies include a fixed shaft fixedly arranged between the sliding seat and the main bearing support plate, and a turning bar rotatably arranged on the fixed shaft And the secondary support plate that evenly flips the front of the strip through the rotating shaft along the length direction of the flip strip, and is also provided with a drive assembly for controlling the two flip strips to rotate forward and reverse or reverse and forward respectively, and for When the bar rotates, it controls the synchronous rotation of the secondary support plate to keep the rotation limit component in a horizontal state. In application, when the support mechanism slides into the storage cavity, the driving component controls the turning bar to be in a vertical state, so that the storage module is in a vertical state. It is placed vertically to reduce the floor space of the storage module; after the supporting mechanism slides into the storage cavity, the turning bar is controlled to be in a vertical state through the drive assembly, so that the storage module is placed horizontally, which is convenient for maintenance and detection of the storage module, and During this process, the synchronous rotation of the secondary support plate is controlled to keep the horizontal state all the time when the turning bar rotates through the rotation limit component, and the turning storage module slides down.

(2) The drive assembly of the present invention includes a screw that is rotatably arranged inside the cavity and is perpendicular to the sliding seat, an internal thread slider that is threadedly arranged on the screw, and two guides that are respectively rotatably arranged inside the cavity on both sides of the screw. The first wheel and the two steel wire ropes arranged on both sides of the inner threaded slider, wherein the bottom of the inner threaded slider is provided with a fixing rod, and the bottom end of the fixing rod is slidably connected with the bottom surface of the cavity, and the two guide wheels 1 are respectively located at the bottom of the screw. Both ends and the connecting column on one side of the corresponding guide wheel are provided with wire holes, and the second guide wheel is symmetrically arranged inside the wire hole. The second extension of the guide wheel is fixedly connected with one end of the corresponding turning strip away from the main bearing plate, and the driving assembly also includes two guides arranged between the sliding seats on both sides of the connecting column and the main bearing plate for guiding and limiting the corresponding steel wire rope. The component and the rotating component used to drive the rotation of the screw, in application, only need to control the rotation of the screw to drive the internal thread slider to move back and forth. The wire rope at the other end of the inner threaded slider can stretch the wire rope. After the supporting mechanism slides out of the storage cavity, place the flipping bar located on the top sub-supporting component in a horizontal state, and pull the flipping strip located on the bottom sub-supporting component. In the same way, when the supporting mechanism is slid into the storage cavity, pull the flipping bar located on the top sub-supporting component to a vertical state, and place the flipping strip located on the bottom sub-supporting component in a vertical position. State, simple structure, easy operation and production, easy to use.

(3) The guide member of the present invention includes two positioning shafts arranged longitudinally between the sliding seat and the main bearing plate, a roller sleeved at the middle position of the positioning shaft, and a positioning shaft arranged horizontally symmetrically at both ends of one of the rollers The L-shaped support plate on the side, the T-shaped fixed rod vertically arranged at one end of the L-shaped support plate away from the positioning shaft, and the roller 2 sleeved on the T-shaped fixed rod, wherein the distance between the two rollers A guide and limit channel for guiding and limiting the wire rope is formed between the first rollers. In application, when the wire rope is pulled horizontally, the two rollers can prevent the wire rope from moving forward and backward. When the wire rope is pulled longitudinally, the two Roller 1 can prevent the wire rope from moving in the longitudinal direction, and prevent the wire rope from shifting when the wire rope is adjusted and turned over.

(4) The rotation limiting assembly of the present invention includes a gear 1 which is located inside the transmission cavity and is assembled on a fixed shaft, a rotating shaft rotatably arranged inside the transmission cavity on one side of the gear one, and is transferred on the rotating shaft 1 and is connected with the gear 1. The second gear that meshes with each other, the second rotating shaft arranged in the transmission cavity on the side of the first rotating shaft away from the gear one, and the third and fourth gears that are transferred on the second rotating shaft, wherein the third gear and the second gear are meshed with each other, The rotating shaft extends to the inside of the transmission cavity and is provided with gear 5, and a chain is set between the gear 4 in the transmission cavity and the two gears 5. In application, when the turning bar rotates, gear 1 and gear 2 on the rotating shaft 1 They mesh with each other, so that the second gear rotates, and the rotation of the second gear drives the rotation of the gear three that meshes with it. When the third gear rotates, its rotating shaft two also rotates synchronously, and the rotation is reversed to the second gear. When the rotating shaft two rotates, Through the cooperation of gear 4, gear 5 and chain, the rotating shaft is driven to rotate synchronously, so that the synchronous rotation of the secondary bearing plate is always kept in a horizontal state, and the relative displacement between the rotating bar and the fixed shaft is used, and no external motor is required.

(5) Line pipes are arranged on the flipping strip between the two rotating shafts and the flipping strip between the rotating shaft and the fixed shaft, which is convenient to protect the lines between the storage modules during application. When it rotates around the rotation axis, the line is drawn out from the place close to the rotation axis, and the line will not be pulled during the overturning process.

Description of drawings

Fig. 1 is the front view structure schematic diagram of the present invention;

Fig. 2 is the top-view structure schematic diagram of the supporting mechanism of the present invention after unfolding;

3 is a schematic structural diagram of a drive assembly of the present invention;

Figure 4 is a schematic side view of the structure of the guide member of the present invention;

Fig. 5 is the front view structural schematic diagram of the guide member of the present invention;

FIG. 6 is a schematic structural diagram of the rotation limiting assembly of the present invention.

In the figure: 1. storage module; 2. housing; 3. storage cavity; 4. supporting mechanism; 5. main supporting component; 51. sliding seat; 52. connecting column; 53. main supporting plate; 54. Cavity; 6. Secondary bearing assembly; 61. Fixed shaft; 62. Turning bar; 63. Rotating shaft; 64. Secondary bearing plate; 65. Transmission cavity; 7. Drive assembly; 71, Screw rod; 72, Internal thread Slider; 73, guide wheel one; 74, wire rope; 75, wire hole; 76, guide wheel two; 77, guide member; 771, positioning shaft; 772, roller one; 773, L-shaped support plate; 774, T Type fixing rod; 775, roller two; 776, guide limit channel; 78, rotating member; 781, driving rod; 782, rotating handle; 8, rotating limit assembly; 81, rotating shaft one; 82, gear one; 83 , gear two; 84, rotating shaft two; 85, gear three; 86, gear four; 87, gear five; 88, chain.

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only a part of the embodiments of the present invention, but not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative efforts shall fall within the protection scope of the present invention.

Please refer to FIG. 1-6, an analysis and storage platform based on big data of the Internet of Things includes several storage modules 1 connected by lines and a carrier for carrying the storage modules 1. The carrier includes a casing 2 and is arranged in the casing 2. a plurality of storage cavities 3 inside and a supporting mechanism 4 slidably arranged inside the storage cavity 3 for supporting the storage module 1;

The support mechanism 4 includes a main support assembly 5 slidably arranged inside the storage cavity 3 and two sets of secondary support assemblies 6 arranged at the top and bottom of the main support assembly 5. The main support assembly 5 includes a sliding arrangement in the storage cavity 3. The sliding seat 51 at the middle position, the connecting column 52 vertically arranged on the front of the sliding seat 51, and the main support plate 53 horizontally arranged at one end of the connecting column 52 away from the sliding seat 51, wherein the connecting column 52 is provided with a cavity 54 inside , the two sets of secondary support assemblies 6 are located on both sides of the connecting column 52 respectively. The secondary support assemblies 6 include a fixed shaft 61 fixedly arranged between the sliding seat 51 and the main bearing support plate 53, and a rotating shaft 61 arranged on the fixed shaft 61. The turning bar 62 and the sub-supporting plate 64 on the front surface of the turning bar 62 are evenly turned along the length direction of the turning bar 62 through the rotating shaft 63 , wherein a transmission cavity 65 is arranged inside the turning bar 62 , and the support mechanism 4 also includes a function for controlling two turning The bar 62 rotates forwardly and reversely or reversely and forwardly, respectively, and the drive assembly 7 and the rotation limit assembly 8 for controlling the synchronous rotation of the secondary support plate 64 to keep the horizontal state when the turning bar 62 rotates. The drive assembly 7 uses When the support mechanism 4 slides into the storage cavity 3 , the turning bar 62 is controlled to be in a vertical state, and after the support mechanism 4 slides out of the storage cavity 3 , the turning bar 62 is controlled to be in a horizontal state.

In this embodiment, as shown in Figures 2-3, in order to facilitate the adjustment of the inversion of the inversion bars of the two sets of secondary support assemblies 6, so that (when the support mechanism 4 slides into the storage cavity 3, the control inversion bar 62 is in a vertical state , so that the storage module is placed vertically, reducing the floor space of the storage module; after the supporting mechanism 4 slides into the interior of the storage cavity 3, the control overturning bar 62 is in a vertical state, so that the storage module is placed horizontally, which is convenient for maintenance and operation. Detection and storage module), adopting a simple structure, easy to manufacture drive assembly to achieve the above functions, specifically: the drive assembly 7 includes a screw rod 71 that is rotatably arranged inside the cavity 54 and is perpendicular to the sliding seat 51, and is threadedly arranged on the screw rod 71. The inner threaded slider 72, the two guide wheels 73 arranged inside the cavity 54 on both sides of the screw 71 respectively, and the two wire ropes 74 arranged on both sides of the inner threaded slider 72, wherein the inner threaded slider 72 The bottom of the screw rod is provided with a fixed rod, and the bottom end of the fixed rod is slidably connected with the bottom surface of the cavity. The wire-passing hole 75, and the inside of the wire-passing hole 75 is symmetrically provided with a guide wheel 2 76, and the end of the wire rope 74 away from the inner threaded slider 72 sequentially passes through the guide wheel 1 73 and the guide wheel 2 76 on the corresponding side to extend and turn correspondingly. One end of the bar 62 away from the main support plate 53 is fixedly connected, and the drive assembly 7 also includes two guide members arranged between the sliding seats 51 on both sides of the connecting column 52 and the main support plate 53 for guiding and limiting the corresponding steel wire rope 74 77 and the rotating member 78 for driving the rotation of the screw 71, through the above-mentioned structure, when the turning bar 62 is adjusted to turn over, it is only necessary to control the rotation of the screw 71 to drive the internal thread slider 72 to move back and forth, and when the internal thread slider 72 moves back and forth , the releasable wire rope 74 is located at one end of the wire rope, and the wire rope 74 at the other end can stretch the wire rope 74. After the supporting mechanism 4 slides out of the interior of the storage cavity 3, the flipping bar 62 located on the top sub-supporting assembly 6 is placed horizontally state, pull the flip bar located on the bottom sub-support assembly to a horizontal state, and similarly, when the support mechanism 4 slides into the interior of the storage cavity 3, pull the flip bar 62 located on the top sub-support assembly 6 to a vertical state In the straight state, place the turning bar 62 on the bottom sub-support assembly 6 in a vertical state.

In this embodiment, as shown in Figures 4-5, in order to prevent the wire rope 74 from being shifted when the overturning bar 62 is turned over, a guide member 77 that can limit the position of the front, rear, up and down is used to prevent the wire rope 74 from shifting, specifically: two The guide members 77 are all located above the fixed shaft 61 , and one of the guide members 77 is located on the side of the fixed shaft 61 close to the connecting column 52 , and the other is located on the side of the fixed shaft 61 away from the connecting column 52 . The two positioning shafts 771 between the main bearing support plates 53, the roller one 772 sleeved at the middle position of the positioning shaft 771, the L-shaped support plate 773 horizontally symmetrically arranged on the side of the positioning shaft 771 at both ends of one of the roller one 772, A T-shaped fixing rod 774 vertically arranged at one end of the L-shaped support plate 773 away from the positioning shaft 771, and a second roller 775 sleeved on the T-shaped fixing rod 774, wherein the two rollers 775 and the two rollers 1 772 A guide limiting channel 776 for guiding and limiting the wire rope 74 is formed therebetween. The above structure is adopted: when the wire rope 74 is pulled horizontally, the two rollers 775 can prevent the wire rope 74 from moving forward and backward. The two rollers 772 prevent the wire rope 74 from moving longitudinally when pulling.

In this embodiment, as shown in FIG. 3 , in order to facilitate the control of the rotation of the screw 71 and to consider production, a manually driven rotating member 78 is used, specifically: the rotating member 78 includes a fixed connection with the screw 71 disposed through the main support plate 53 The driving rod 781 and the rotating handle 782 arranged at the other end of the driving rod 781, through the above structure: only need to rotate the rotating handle 782 to drive the screw 71 through the driving rod 781, the structure is simple, easy to operate, and easy to manufacture.

In this embodiment, as shown in FIG. 6 , in order to ensure that when the flipping bar 62 rotates, the secondary support plate 64 can also rotate synchronously and always maintain a horizontal state, so as to prevent the storage module 1 from sliding down, the relative displacement between the flipping bar and the fixed shaft is used when the flipping bar rotates. , set the rotation limit assembly 8 to realize the synchronous rotation of the secondary support plate 64 and always keep it horizontal, specifically: the rotation limit assembly 8 includes a gear one 81 located inside the transmission cavity 65 and assembled on the fixed shaft 61. The rotating shaft one 82 inside the transmission cavity 65 on the 81 side, the gear two 83 which is transferred to the rotating shaft one 82 and meshes with the gear one 81, and the transmission cavity which is rotated and arranged on the side of the rotating shaft one 82 away from the gear one 81 The second rotating shaft 84 inside 65, the third gear 85 and the fourth gear 86 which are transferred on the second rotating shaft 84, wherein the third gear 85 and the second gear 83 mesh with each other, and the rotating shaft 63 extends to the inside of the transmission cavity 65. There is a gear five. 87. A chain 88 is arranged between the gear four 86 and the two gear five 87 inside the corresponding transmission cavity 65. Through the above structure, when the turning bar 62 rotates, the gear one 82 on the rotating shaft one 81 meshes with the gear two 83. , so that the second gear 83 rotates, and the rotation of the second gear 83 drives the rotation of the gear three 85 that meshes with it. When the gear three 85 rotates, its rotating shaft two 84 also rotates synchronously, and the rotation is reversed opposite to the second gear 83. When the second 84 rotates, through the cooperation of the fourth gear 86, the fifth gear 87 and the chain 88, the rotating shaft 63 is driven to rotate synchronously, so that the synchronous rotation of the secondary support plate 64 is always kept in a horizontal state.

In this embodiment, as shown in FIG. 1 , a door body is provided on one side of the storage cavity 3 , and an observation window is provided on the door body to facilitate observation of the interior of the storage cavity 3 .

In this embodiment, as shown in FIG. 2 , a line pipe is provided on the turning bar 62 between the two rotating shafts 63 and the turning bar 62 between the rotating shaft 63 and the fixed shaft 61 to facilitate the wiring between the storage modules 1 . At the same time, since the secondary support plate 64 rotates around the rotating shaft 63, the circuit is drawn out from the position close to the rotating shaft 63, and the circuit will not be pulled during the overturning process.

Working principle: When the storage module 1 needs to be repaired, the main support plate 53 can be pulled, so that the sliding seat 51 slides inside the storage cavity 3 to move the connecting column 52 and the main support plate 53 out of the storage cavity, and the rotary handle 782 is turned. , the screw 71 is driven by the driving rod 781, thereby driving the internally threaded slider 72 to move back and forth, and when the internally threaded slider 72 moves back and forth, the releasable wire rope 74 located at one end of the internally threaded slider 72 is located at the internally threaded slider 72. The wire rope 74 at the other end can stretch the wire rope 74, place the inversion bar 62 of the sub-support assembly 6 at the top of the main supporting plate 53 in a horizontal state, and place the inversion bar 62 of the sub-support assembly 6 at the bottom of the main supporting plate 53 in a horizontal state. Pull it to a horizontal state, which is convenient for maintenance personnel to repair the storage module. During this process, the turning bar 62 rotates, and the gear 1 82 on the rotating shaft 1 81 and the gear 2 83 mesh with each other, so that the gear 2 83 rotates. The rotation of the second gear 83 drives the gear three 85 that meshes with it to rotate. When the gear three 85 rotates, the rotating shaft two 84 also rotates synchronously, and the rotation is reversed to the second gear 83. When the rotating shaft two 84 rotates, the second gear 86 rotates , gear five 87 and chain 88 cooperate to drive the rotating shaft 63 to rotate synchronously, so that the synchronous rotation of the secondary support plate 64 is always kept in a horizontal state, and when it is turned over, the set line pipe can protect the lines between the storage modules 1. , because the secondary support plate 64 rotates around the rotating shaft 63, and the line is drawn out from the place close to the rotating shaft 63, during the overturning process, the line will not be pulled. It can be understood that the wire rope 74 can pull the turning bar 62 on the top sub-support assembly 6 to a vertical state, and place the turning bar 62 on the bottom sub-support assembly 6 in a vertical state.

Although the present invention has been described in detail with reference to the foregoing embodiments, for those skilled in the art, it is still possible to modify the technical solutions described in the foregoing embodiments, or to perform equivalent replacements for some of the technical features. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention shall be included within the protection scope of the present invention.

Claims (7)

1. An analysis storage platform based on big data of the Internet of things comprises a plurality of storage modules (1) connected through lines and a carrier for bearing the storage modules (1), and is characterized in that the carrier comprises a shell (2), a plurality of containing cavities (3) arranged inside the shell (2) and a bearing mechanism (4) which is arranged inside the containing cavities (3) in a sliding mode and used for bearing the storage modules (1);

bearing mechanism (4) including the slip setting accomodate the inside main bearing subassembly (5) of chamber (3) and set up two sets of secondary bearing subassembly (6) at main bearing subassembly (5) top and bottom, main bearing subassembly (5) including the slip setting take in slide bracket (51) of chamber (3) intermediate position department, set up perpendicularly and keep away from main bearing board (53) of slide bracket (51) one end at spliced pole (52) at spliced pole (51) positive spliced pole (52) and level setting, wherein, the inside of spliced pole (52) is provided with cavity (54), and is two sets of secondary bearing subassembly (6) are located the both sides of spliced pole (52) respectively, secondary bearing subassembly (6) including fixed axle (61) of fixed setting between slide bracket (51) and main bearing board (53), rotate upset strip (62) of setting on fixed axle (61) and through axis of rotation (63) along upset strip (62) length direction even upset strip (62) Positive inferior bearing board (64), wherein, the inside of upset strip (62) sets up transmission chamber (65), bearing mechanism (4) are still including being used for controlling two upset strips (62) corotation respectively and reversal or reversal and corotation drive assembly (7) and be used for when upset strip (62) rotate control inferior bearing board (64) synchronous rotation keep the horizontality all the time rotation spacing subassembly (8), drive assembly (7) are used for accomodating chamber (3) when inside in bearing mechanism (4) slip-in, control upset strip (62) are vertical state, and when bearing mechanism (4) roll-off was accomodate chamber (3) inside, control upset strip (62) were the horizontality.

2. The analysis and storage platform based on the big data of the Internet of things according to claim 1, characterized in that: the driving assembly (7) comprises a screw rod (71) which is rotatably arranged in the cavity (54) and is perpendicular to the sliding seat (51), an internal thread sliding block (72) which is in threaded connection with the screw rod (71), two guide wheels I (73) which are respectively rotatably arranged in the cavity (54) on the two sides of the screw rod (71) and two steel wire ropes (74) which are arranged on the two sides of the internal thread sliding block (72), wherein a fixing rod is arranged at the bottom of the internal thread sliding block (72), the bottom end of the fixing rod is in sliding connection with the bottom surface of the cavity, the two guide wheels I (73) are respectively arranged at the two ends of the screw rod (71), a wire passing hole (75) is formed in a connecting column (52) corresponding to one side of the guide wheels I (73), two guide wheels (76) are symmetrically arranged in the cavity of the wire passing hole (75), and one end, far away from the steel wire ropes (74), of the sliding block (72) sequentially extends and corresponds to the corresponding internal thread through the guide wheels I (73) and the guide wheels II (76) The overturning strip (62) is fixedly connected with one end far away from the main bearing plate (53), and the driving assembly (7) further comprises two guide members (77) which are arranged between the sliding seats (51) on the two sides of the connecting column (52) and the main bearing plate (53) and used for guiding and limiting corresponding steel wire ropes (74) and a rotating member (78) used for driving the screw rod (71) to rotate.

3. The analysis and storage platform based on the big data of the internet of things according to claim 2, characterized in that: the two guide members (77) are positioned above the fixed shaft (61), one of the guide members is positioned on one side of the fixed shaft (61) close to the connecting column (52), the other guide member is positioned on one side of the fixed shaft (61) far away from the connecting column (52), the guide member (77) comprises two positioning shafts (771) longitudinally arranged between the sliding seat (51) and the main supporting plate (53), first rollers (772) sleeved at the middle position of the positioning shafts (771), L-shaped supporting plates (773) horizontally and symmetrically arranged on the side surfaces of the positioning shafts (771) at two ends of one of the first rollers (772), T-shaped fixing rods (774) vertically arranged at one ends, far away from the positioning shafts (771), of the L-shaped supporting plates (773) and second rollers (775) sleeved on the T-shaped fixing rods (774), and a guide limiting channel (776) for guiding and limiting the steel wire rope (74) is formed between the two second rollers (775) and between the two first rollers (772).

4. The analysis and storage platform based on the big data of the internet of things according to claim 2, characterized in that: the rotating component (78) comprises a driving rod (781) which penetrates through the interior of the main bearing plate (53) and is fixedly connected with the screw rod (71), and a rotating handle (782) which is arranged at the other end of the driving rod (781).

5. The analysis and storage platform based on the big data of the Internet of things according to claim 1, characterized in that: the rotation limiting component (8) comprises a first gear (81) which is arranged inside the transmission cavity (65) and assembled on the fixed shaft (61), a first rotating shaft (82) which is arranged inside the transmission cavity (65) on one side of the first gear (81) in a rotating mode, a second gear (83) which is arranged on the first rotating shaft (82) in a rotating mode and meshed with the first gear (81), a second rotating shaft (84) which is arranged inside the transmission cavity (65) on one side, far away from the first gear (81), of the first rotating shaft (82) in a rotating mode, a third gear (85) and a fourth gear (86) which are arranged on the second rotating shaft (84) in a rotating mode, wherein the gear III (85) is meshed with the gear II (83), the rotating shaft (63) extends into the transmission cavity (65) and is provided with a gear V (87), a chain (88) is arranged between the gear four (86) corresponding to the inside of the transmission cavity (65) and the two gear five (87).

6. The analysis and storage platform based on the big data of the Internet of things according to claim 1, characterized in that: one side of the containing cavity (3) is provided with a door body, and an observation window is arranged on the door body.

7. The analysis and storage platform based on the big data of the Internet of things according to claim 1, characterized in that: and a line pipe is arranged on the overturning strip (62) between the two rotating shafts (63) and the overturning strip (62) between the rotating shaft (63) and the fixed shaft (61).

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