CN217588306U - Simulation sand table of electric power net rack structure optimal design - Google Patents

Abstract

The utility model discloses a simulation sand table of power grid network frame structure optimization design, which comprises a first shell, a first bearing, a driving mechanism, a first adjusting mechanism, a second shell, a first sand table, a second sand table, a fixed frame, a first gear, a second bearing, a second adjusting mechanism, a telescopic plate, a guide mechanism and an operation box; this simulation sand table of electric power net rack structure optimal design through setting up guide cylinder and guide bar, because of sliding connection has the guide bar in the guide cylinder, the guide cylinder can carry on spacingly to the guide bar for the guide bar can not take place to rock when the motion, and the expansion plate of being connected with the guide bar can be steady in vertical direction moves.

Description

Simulation sand table of electric power net rack structure optimal design

Technical Field

The utility model belongs to the technical field of electric power, concretely relates to electric power network spatial grid structure optimal design's simulation sand table.

Background

The power grid structure refers to the overall arrangement of each power plant, substation and switch station in the power grid, and connect their connection mode of voltage power lines at different levels, and power grid spatial grid structure optimal design usually relies on the simulation sand table to go on, can effectively practice thrift the cost, but the simulation sand table of current power grid spatial grid structure optimal design is the structure of show stand form usually, and the volume is great, is not convenient for carry and use, consequently needs a power grid spatial grid structure optimal design's that has regulatory function simulation sand table to solve above-mentioned problem.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the simulation sand table of current power grid spatial grid structure optimal design and be the structure of show stand form usually, the problem that the volume is great and be not convenient for carry and use has provided a power grid spatial grid structure optimal design's simulation sand table.

The technical scheme of the utility model is that: a simulation sand table for optimized design of a power grid structure comprises a first shell, a first bearing, a driving mechanism, a first adjusting mechanism, a second shell, a first sand table, a second sand table, a fixing frame, a first gear, a second bearing, a second adjusting mechanism, a telescopic plate, a guide mechanism and an operation box;

the first bearing is clamped on the inner wall of one side of the first shell; an output shaft at one side of the driving mechanism is connected with one end of the first adjusting mechanism; the other end of the first adjusting mechanism is fixedly connected with the inner wall of the second shell; the second shell is arranged in the first shell in a sliding manner; a first sand table is fixedly connected in the first shell; a second sand table is arranged in the second shell; the second sand table is connected in the first sand table in a sliding manner; one side of the inner wall of the first shell is fixedly connected with the front and the back of the driving mechanism through two fixing frames respectively; the first gear is arranged in the first bearing and meshed with the second gear; the second adjusting mechanism is clamped on the second gear and arranged in the second bearing, and an output shaft on the other side of the driving mechanism is connected with the first gear; the second bearing is clamped on the lower surface of the inner wall of the operation box; one side of the operation box is fixedly connected with the outer wall of one side of the first shell; the bottom end of the second adjusting mechanism is provided with a telescopic plate; the upper surface of the expansion plate is provided with two guide mechanisms; the guide mechanism is arranged on one side of the second shell.

Further, the simulation sand table also comprises a first magnet; the upper surface of first casing and second casing all the joint has first magnet.

Furthermore, the simulation sand table also comprises a cover plate and a second magnet; the front and the back of first casing all are articulated with the inner wall of two apron respectively through two hinges, and the outer wall joint of apron has two second magnets.

Further, the simulation sand table also comprises a third bearing; a third bearing is arranged on the outer surface of the first adjusting mechanism; the lower surface of the third bearing is fixedly connected with the lower surface of the inner wall of the first shell.

Furthermore, the simulation sand table also comprises a storage battery and a motor; the storage battery and the motor are both arranged in the first shell; the motor is connected to the driving mechanism.

Furthermore, the simulation sand table also comprises a power switch, an ascending button and a telescopic button; the power switch, the ascending button and the telescopic button are all arranged on the outer wall of the operation box.

Further, the first adjusting mechanism comprises a threaded barrel and a threaded rod; one end of the threaded cylinder is fixedly connected with an output shaft at one side of the driving mechanism; one end of the threaded rod is sleeved in the threaded cylinder, and the other end of the threaded rod is fixedly connected with the inner wall of the second shell; the threaded barrel is arranged in the third bearing.

Further, the second adjusting mechanism comprises a screw rod cylinder and a screw rod; the screw rod barrel is clamped on the second gear and is arranged in the second bearing; one end of the screw rod is sleeved in the screw rod cylinder, and the other end of the screw rod is fixedly connected with the upper surface of the expansion plate.

Further, the guide mechanism comprises a guide cylinder and a guide rod; one side of the guide cylinder is fixedly connected with the outer wall of the second shell; one end of the guide rod is slidably sleeved in the guide cylinder; the bottom of guide bar is fixedly connected with the upper surface of expansion plate.

The utility model has the advantages that:

(1) This simulation sand table of electric power net rack structure optimal design is through setting up actuating mechanism, first gear, the second gear, a screw section of thick bamboo, the threaded rod, lead screw and a lead screw section of thick bamboo, when needs carry this sand table, control actuating mechanism reversal, the second casing slides in first casing, make the second casing drive the second sand table and remove in first sand table, this sand table size reduction on the horizontal direction drives the expansion plate rebound simultaneously, make this sand table size reduction on vertical direction, the storage space of this sand table has been reduced, it transports to it to have made things convenient for the staff, control actuating mechanism corotation, the second casing moves the expansion plate rebound left in first casing, make the size of this sand table increase in vertical direction, make this sand table can adjust its size according to actual conditions, the adaptability of this sand table has been improved, make the staff can be convenient use this sand table.

(2) This simulation sand table of electric power net rack structure optimal design is through setting up first magnet, second magnet and apron, when the right flank of second casing and the left surface contact of second casing, rotate two apron, the apron drives the first magnet contact that second magnet corresponds with it, and two apron contacts, the apron, protective structure that first casing and second casing mutually supported and constitute can block the inside simulation article of sand table, make this simulation article be difficult for dropping the damage, the normal life of this sand table has been guaranteed.

(3) This simulation sand table of electric power net rack structure optimal design through setting up guide cylinder and guide bar, because of sliding connection has the guide bar in the guide cylinder, the guide cylinder can carry on spacingly to the guide bar for the guide bar can not take place to rock when the motion, and the expansion plate of being connected with the guide bar can be steady in vertical direction moves.

Drawings

FIG. 1 is a schematic structural diagram of a simulated sand table;

FIG. 2 is a schematic cross-sectional view of a first shell of a simulated sand table in a front perspective;

FIG. 3 is a schematic cross-sectional view of a simulation sand table console box in a front perspective;

FIG. 4 is a schematic cross-sectional view of a second shell of the simulated sand table for showing a left-side perspective;

in the figure: 1. a first housing; 2. a first bearing; 3. a drive mechanism; 4. a first adjustment mechanism; 41. a threaded barrel; 42. a threaded rod; 5. a second housing; 6. a first sand table; 7. a second sand table; 8. a fixed mount; 9. a first gear; 10. a second gear; 11. a second bearing; 12. a second adjustment mechanism; 121. a screw barrel; 122. a screw rod; 13. a retractable plate; 14. a guide mechanism; 151. a power switch; 152. a raise button; 153. a telescopic button; 141. a guide cylinder; 142. a guide bar; 15. an operation box; 16. a first magnet; 17. a cover plate; 18. a second magnet; 19. and a third bearing.

Detailed Description

The embodiments of the present invention will be further described with reference to the accompanying drawings.

As shown in fig. 1, the utility model provides a simulation sand table of power grid network frame structure optimal design, including first casing 1, first bearing 2, actuating mechanism 3, first adjustment mechanism 4, second casing 5, first sand table 6, second sand table 7, mount 8, first gear 9, second gear 10, second bearing 11, second adjustment mechanism 12, expansion plate 13, guiding mechanism 14 and control box 15;

the first bearing 2 is clamped on the inner wall of one side of the first shell 1; an output shaft at one side of the driving mechanism 3 is connected with one end of the first adjusting mechanism 4; the other end of the first adjusting mechanism 4 is fixedly connected with the inner wall of the second shell 5; the second shell 5 is arranged in the first shell 1 in a sliding way; a first sand table 6 is fixedly connected in the first shell 1; a second sand table 7 is arranged in the second shell 5; the second sand table 7 is connected in the first sand table 6 in a sliding way; one side of the inner wall of the first shell 1 is respectively and fixedly connected with the front and the back of the driving mechanism 3 through two fixing frames 8; the first gear 9 is arranged in the first bearing 2, and the first gear 9 is meshed with the second gear 10; the second adjusting mechanism 12 is clamped on the second gear 10, the second adjusting mechanism 12 is arranged in the second bearing 11, and an output shaft on the other side of the driving mechanism 3 is connected with the first gear 9; the second bearing 11 is clamped on the lower surface of the inner wall of the operation box 15; one side of the operation box 15 is fixedly connected with the outer wall of one side of the first shell 1; the bottom end of the second adjusting mechanism 12 is provided with a telescopic plate 13; the upper surface of the expansion plate 13 is provided with two guide mechanisms 14; the guide mechanism 14 is provided on one side of the second housing 5.

In the embodiment of the present invention, as shown in fig. 2, the simulated sand table further includes a first magnet 16; the upper surfaces of the first shell 1 and the second shell 5 are respectively clamped with a first magnet 16.

In the embodiment of the present invention, as shown in fig. 1, the simulated sand table further includes a cover plate 17 and a second magnet 18; the front and the back of the first shell 1 are hinged to the inner walls of the two cover plates 17 through two hinges respectively, and the outer walls of the cover plates 17 are connected with two second magnets 18 in a clamped mode.

In the embodiment of the present invention, as shown in fig. 2, the simulation sand table further includes a third bearing 19; the outer surface of the first adjusting mechanism 4 is provided with a third bearing 19; the lower surface of the third bearing 19 is fixedly connected with the lower surface of the inner wall of the first housing 1.

In the embodiment of the present invention, as shown in fig. 1, the simulated sand table further includes a storage battery and a motor; the storage battery and the motor are both arranged in the first shell 1; the motor is connected to the driving mechanism 3.

In the embodiment of the present invention, as shown in fig. 1, the simulated sand table further includes a power switch 151, a raising button 152 and a stretching button 153; the power switch 151, the up button 152, and the expansion button 153 are provided on the outer wall of the operation box 15.

In the embodiment of the present invention, as shown in fig. 4, the first adjusting mechanism 4 includes a threaded cylinder 41 and a threaded rod 42; one end of the threaded cylinder 41 is fixedly connected with an output shaft at one side of the driving mechanism 3; one end of the threaded rod 42 is sleeved in the threaded cylinder 41, and the other end thereof is fixedly connected with the inner wall of the second shell 5; the threaded cylinder 41 is disposed within the third bearing 19.

In the embodiment of the present invention, as shown in fig. 3, the second adjusting mechanism 12 includes a screw cylinder 121 and a screw 122; the screw rod cylinder 121 is clamped on the second gear 10, and the screw rod cylinder 121 is arranged in the second bearing 11; one end of the screw rod 122 is sleeved in the screw rod cylinder 121, and the other end thereof is fixedly connected with the upper surface of the expansion plate 13.

In the embodiment of the present invention, as shown in fig. 2, the guiding mechanism 14 includes a guiding cylinder 141 and a guiding rod 142; one side of the guide cylinder 141 is fixedly connected with the outer wall of the second shell 5; one end of the guide rod 142 is slidably sleeved in the guide cylinder 141; the bottom end of the guide rod 142 is fixedly connected with the upper surface of the expansion plate 13.

The utility model discloses a theory of operation and process do:

when the sand table needs to be carried, a worker turns on the power switch 151, the motor can be controlled to rotate through the ascending button 152 and the telescopic button 153, and the motor drives the driving mechanism, so that the worker can adjust the height and the length of the sand table as required. A worker controls the driving mechanism 3 to rotate reversely, the reversely rotating driving mechanism 3 drives the threaded cylinder 41 to rotate reversely, the reversely rotating threaded cylinder 41 drives the threaded rod 42 to move rightwards, the threaded rod 42 moving rightwards drives the second shell 5 to slide in the first shell 1, so that the second shell 5 drives the second sand table 7 to move in the first sand table 6, and the size of the sand table in the horizontal direction is small;

secondly, the driving mechanism 3 which simultaneously rotates reversely drives the first gear 9 to rotate, the rotating first gear 9 drives the second gear 10 to rotate, the second gear 10 which rotates reversely drives the screw cylinder 121 to rotate reversely, the screw cylinder 121 which rotates reversely drives the screw 122 to move upwards, the screw 122 which moves upwards drives the expansion plate 13 to move upwards, the expansion plate 13 which moves upwards drives the guide rod 142 to move upwards in the guide cylinder 141, and when the right side surface of the second shell 5 is contacted with the left side surface of the first shell 1, the sand table is adjusted to the minimum size;

finally, the driving mechanism 3 is controlled to rotate forwards, the driving mechanism 3 which rotates forwards drives the threaded rod 42 to extend inside the threaded rod 42 through the threaded cylinder 41, the extended threaded rod 42 drives the second shell 5 to move leftwards in the first shell 1, the driving mechanism 3 drives the screw rod cylinder 121 to rotate forwards through the first gear 9 and the second gear 10, the screw rod cylinder 121 which rotates forwards drives the telescopic plate 13 to move downwards through the screw rod 122, the size of the sand table is increased in the vertical direction, and the sand table is adjusted to be in a proper size.

The utility model has the advantages that:

(1) This simulation sand table of electric power net rack structure optimal design is through setting up actuating mechanism, first gear, the second gear, a screw section of thick bamboo, the threaded rod, lead screw and a lead screw section of thick bamboo, when needs carry this sand table, control actuating mechanism reversal, the second casing slides in first casing, make the second casing drive the second sand table and remove in first sand table, this sand table size reduction on the horizontal direction drives the expansion plate rebound simultaneously, make this sand table size reduction on vertical direction, the storage space of this sand table has been reduced, it transports to it to have made things convenient for the staff, control actuating mechanism corotation, the second casing moves the expansion plate rebound left in first casing, make the size of this sand table increase in vertical direction, make this sand table can adjust its size according to actual conditions, the adaptability of this sand table has been improved, make the staff can be convenient use this sand table.

(2) This simulation sand table of electric power net rack structure optimal design is through setting up first magnet, second magnet and apron, when the right flank of second casing and the left surface contact of second casing, rotate two apron, the apron drives the first magnet contact that second magnet corresponds with it, and two apron contacts, the apron, protective structure that first casing and second casing mutually supported and constitute can block the inside simulation article of sand table, make this simulation article be difficult for dropping the damage, the normal life of this sand table has been guaranteed.

(3) This simulation sand table of electric power net rack structure optimal design through setting up guide cylinder and guide bar, because of sliding connection has the guide bar in the guide cylinder, the guide cylinder can carry on spacingly to the guide bar for the guide bar can not take place to rock when the motion, and the expansion plate of being connected with the guide bar can be steady in vertical direction moves.

It will be appreciated by those of ordinary skill in the art that the embodiments described herein are intended to assist the reader in understanding the principles of the invention, and it is to be understood that the scope of the invention is not limited to such specific statements and embodiments. Those skilled in the art can make various other specific variations and combinations without departing from the spirit of the invention, which fall within the scope of the claims.

Claims (9)

1. A simulation sand table with an optimized design of a power grid structure is characterized by comprising a first shell (1), a first bearing (2), a driving mechanism (3), a first adjusting mechanism (4), a second shell (5), a first sand table (6), a second sand table (7), a fixing frame (8), a first gear (9), a second gear (10), a second bearing (11), a second adjusting mechanism (12), a telescopic plate (13), a guide mechanism (14) and an operation box (15);

the first bearing (2) is clamped on the inner wall of one side of the first shell (1); an output shaft at one side of the driving mechanism (3) is connected with one end of the first adjusting mechanism (4); the other end of the first adjusting mechanism (4) is fixedly connected with the inner wall of the second shell (5); the second shell (5) is arranged in the first shell (1) in a sliding manner; a first sand table (6) is fixedly connected in the first shell (1); a second sand table (7) is arranged in the second shell (5); the second sand table (7) is connected in the first sand table (6) in a sliding manner; one side of the inner wall of the first shell (1) is fixedly connected with the front and the back of the driving mechanism (3) through two fixing frames (8) respectively; the first gear (9) is arranged in the first bearing (2), and the first gear (9) is meshed with the second gear (10); the second adjusting mechanism (12) is clamped on the second gear (10), the second adjusting mechanism (12) is arranged in the second bearing (11), and an output shaft on the other side of the driving mechanism (3) is connected with the first gear (9); the second bearing (11) is clamped on the lower surface of the inner wall of the operation box (15); one side of the operating box (15) is fixedly connected with the outer wall of one side of the first shell (1); the bottom end of the second adjusting mechanism (12) is provided with a telescopic plate (13); two guide mechanisms (14) are arranged on the upper surface of the telescopic plate (13); the guide mechanism (14) is arranged on one side of the second shell (5).

2. The grid architecture optimized design simulation sand table according to claim 1, characterized in that the simulation sand table further comprises a first magnet (16); the upper surfaces of the first shell (1) and the second shell (5) are clamped with first magnets (16).

3. The optimized design simulation sand table of the power grid network structure according to the claim 2, characterized in that the simulation sand table further comprises a cover plate (17) and a second magnet (18); the front and the back of the first shell (1) are hinged to the inner walls of the two cover plates (17) through two hinges respectively, and the outer wall of each cover plate (17) is connected with two second magnets (18) in a clamped mode.

4. The power grid fabric optimization designed simulation sand table according to claim 1, characterized in that it further comprises a third bearing (19); a third bearing (19) is arranged on the outer surface of the first adjusting mechanism (4); the lower surface of the third bearing (19) is fixedly connected with the lower surface of the inner wall of the first shell (1).

5. The optimally designed simulated sand table for the grid structure of the power grid according to claim 1, characterized in that the simulated sand table further comprises a storage battery and a motor; the storage battery and the motor are both arranged in the first shell (1); the motor is connected to the driving mechanism (3).

6. The optimized design simulation sand table of power grid network architecture according to claim 1, characterized in that the simulation sand table further comprises a power switch (151), a raising button (152) and a telescoping button (153); the power switch (151), the ascending button (152) and the telescopic button (153) are all arranged on the outer wall of the operation box (15).

7. The grid structure of power grids optimally designed simulated sand table according to claim 4, characterized in that said first adjustment mechanism (4) comprises a threaded cylinder (41) and a threaded rod (42); one end of the threaded cylinder (41) is fixedly connected with an output shaft on one side of the driving mechanism (3); one end of the threaded rod (42) is sleeved in the threaded cylinder (41), and the other end of the threaded rod is fixedly connected with the inner wall of the second shell (5); the threaded barrel (41) is arranged in a third bearing (19).

8. The optimally designed simulated sand table for grid structures of power networks according to claim 1, characterized in that said second adjustment mechanism (12) comprises a screw cylinder (121) and a screw (122); the screw rod cylinder (121) is clamped on the second gear (10) and the screw rod cylinder (121) is arranged in the second bearing (11); one end of the screw rod (122) is sleeved in the screw rod cylinder (121), and the other end of the screw rod is fixedly connected with the upper surface of the expansion plate (13).

9. The optimized designed simulated sand table for grid network architecture according to claim 1, characterized in that said guiding mechanism (14) comprises a guiding cylinder (141) and a guiding rod (142); one side of the guide cylinder (141) is fixedly connected with the outer wall of the second shell (5); one end of the guide rod (142) is slidably sleeved in the guide cylinder (141); the bottom end of the guide rod (142) is fixedly connected with the upper surface of the expansion plate (13).

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