CN114025533B

CN114025533B - Artificial intelligence device and method for simulating brain learning knowledge based on computer

Info

Publication number: CN114025533B
Application number: CN202111250522.3A
Authority: CN
Inventors: 李先锋; 周丽萍
Original assignee: Yancheng Institute of Technology
Current assignee: Yancheng Lingxiang Software Co ltd
Priority date: 2021-10-26
Filing date: 2021-10-26
Publication date: 2023-06-09
Anticipated expiration: 2041-10-26
Also published as: CN114025533A

Abstract

The invention discloses an artificial intelligent device based on computer simulation brain learning knowledge, which comprises a base, wherein a driving mechanism is fixedly arranged on the base, a moving mechanism is arranged on the base, a shell is welded on the base, supporting legs are welded on the base, components are fixedly arranged on the supporting legs, the shell is connected with a shell cover through screws, a heat dissipation mechanism is arranged on the shell cover, a wind scooper is sleeved in the shell in a sliding manner, a vent hole is formed in the base, the components are connected with a socket through a wire, a socket is fixedly sleeved in the shell, a connecting belt is fixedly connected on the shell, a plug is arranged at the tail end of the connecting belt, and the plug is sleeved in the socket. The invention relates to an artificial intelligence device and method based on computer simulation brain learning knowledge, which has the characteristics of high stability after the device moves and uniform heat dissipation on components.

Description

Artificial intelligence device and method for simulating brain learning knowledge based on computer

Technical Field

The invention belongs to the technical field of computers, and particularly relates to an artificial intelligence device and method based on computer simulation of brain learning knowledge.

Background

Artificial intelligence, also known as smart machine, machine intelligence, refers to the intelligence exhibited by machines made by humans. Artificial intelligence generally refers to the technology of presenting human intelligence through a common computer program. The word also indicates whether and how to study the implementation of such intelligent systems. The core problems of artificial intelligence include constructing reasoning, knowledge, planning, learning, communication, perception, moving objects, using tools, and the ability to manipulate machinery, etc., that can be even super-tall to humans. Thus, artificial intelligence simulates the knowledge of human brain learning as a necessary basis for artificial intelligence development. Current artificial intelligence learning is to obtain massive information from a network on a computer basis. In the prior art, an artificial intelligence device based on computer simulation brain study knowledge is when using, and stability is relatively poor after the device wholly removes, simultaneously, and the device is inside components and parts operation in-process, and it is great to produce the heat, and uneven meeting of dispelling the heat to components and parts leads to components and parts local difference in temperature too big, and then leads to the life low during playing. Accordingly, improvements in the art are needed.

The invention comprises the following steps:

the invention aims to solve the problems, and provides an artificial intelligence device and an artificial intelligence method based on computer simulation brain learning knowledge, which solve the problems in the background art.

In order to solve the problems, the invention provides a technical scheme that:

the utility model provides an artificial intelligence device based on computer simulation brain study knowledge, includes the base, fixedly mounted has actuating mechanism on the base, be provided with moving mechanism on the base, the welding has the casing on the base, the welding has the stabilizer blade on the base, fixedly mounted has components and parts on the stabilizer blade, there is the cap on the casing through the screw connection, be provided with heat dissipation mechanism on the cap, sliding sleeve has cup jointed the wind scooper in the casing, the venthole has been seted up on the base, be connected with the socket through the wire on the components and parts, the fixed socket that has cup jointed in the casing, fixedly connected with connecting band on the casing, the end of connecting band is provided with the jam, cup joint the jam in the socket.

The driving mechanism comprises a motor, a rotating shaft, square blocks, rolling wheels, square holes, baffles, limiting pins, connecting ropes and connecting rings, wherein the motor is fixedly arranged on the base, the rotating shaft of the motor is rotationally connected with the base, the square blocks are welded at the tail ends of the rotating shaft, the rolling wheels are sleeved on the outer sides of the square blocks in a sliding mode, the square holes are formed in the rolling wheels, the square blocks are sleeved on the rolling wheels in a sliding mode, the baffles are contacted with the rotating shaft, the connecting ropes are arranged on the outer sides of the rolling wheels, and the supporting rods are fixedly connected with the tail ends of the connecting ropes;

the heat dissipation mechanism comprises an air pump, an air inlet pipe, an air outlet cover, a convex edge, semicircular blocks, connecting rods, supporting shafts and fan blades, wherein the air pump and the shell cover are fixedly installed, the air inlet pipe and the shell cover of the air pump are sleeved in a sliding mode, the outer side of the air inlet pipe is rotationally connected with the air outlet cover, the convex edge is arranged on the air inlet pipe, the semicircular blocks are welded on the convex edge and are in contact with the air outlet cover, the connecting rods are welded on the air outlet cover, the supporting shafts are welded at the tail ends of the connecting rods, and the fan blades are arranged on the supporting shafts.

Preferably, the base is welded with a supporting pin, the wind scooper is provided with a supporting groove, and the supporting pin is sleeved in the supporting groove in a sliding manner.

Preferably, the baffle is slidably sleeved with a limiting pin, and the block is internally connected with the limiting pin through threads.

Preferably, a connecting ring is welded on the base, and a connecting rope is connected in the connecting ring in a sliding manner.

Preferably, the moving mechanism comprises a supporting rod, wheels, a guide rod, a stop block, steel balls and a spring, wherein the supporting rod is hinged to the base, the wheels are arranged at the tail end of the supporting rod, the guide rod is sleeved on the side wall of the base in a sliding mode, the steel balls are welded on the guide rod and are in contact with the supporting rod, the spring is arranged on the outer side of the guide rod, one end of the spring is welded with the base, and the other end of the spring is welded with the steel balls.

Preferably, a stop block is welded on the guide rod, and the stop block is in contact with the base.

The application method of the artificial intelligent device based on the computer simulation brain learning knowledge comprises the following specific steps:

step one: when the device needs to move, the motor is started, the motor starts the rotating shaft to rotate, the rotating shaft drives the square to rotate, the square drives the winding wheel to rotate, the winding wheel rotates to wind the connecting rope, the connecting rope is shortened, the supporting rod is pulled to rotate by the shortening of the connecting rope, the wheels extend out of the base, the base is lifted off the ground, and the whole device can move;

step two: the supporting rod rotates to enable the steel balls to slide on the surface of the supporting rod, the steel balls further move towards the side wall of the base, the guide rod moves towards the stop block, the spring is compressed due to the movement of the steel balls, and the supporting rod is supported by the steel balls due to the reaction force of the spring;

step three: when the device moves to a designated position, the motor drives the rotating shaft to rotate reversely, the rotating shaft drives the square to rotate reversely, the square drives the winding wheel to rotate reversely, the winding wheel rotates reversely to extend the connecting rope, meanwhile, the spring elastic action enables the steel balls to reset, the steel balls reset to enable the supporting rod to rotate, the wheels retract into the base, the base is lowered and is in ground contact, the whole device is increased in contact area with the ground, and the stability of the device is higher;

step four: the air pump is started, the air inlet pipe is started to enter the air outlet cover by the air pump, and air flow acts on the fan blades, so that the fan blades drive the supporting shaft to rotate, the supporting shaft drives the connecting rod to rotate, the connecting rod rotates to drive the air outlet cover to rotate, and the air outlet cover rotates to enable air outlet to be more uniform;

step five: the air outlet of the air outlet cover moves towards the direction of the base, the air flows to the air guide cover, the air guide cover guides the air flow, the air flow returns to cool the lower end of the component, and then the whole component is cooled uniformly.

The beneficial effects of the invention are as follows: the invention relates to an artificial intelligence device and a method based on computer simulation human brain learning knowledge, which have the characteristics of high stability after the device moves and uniform heat dissipation to components, and in specific use, compared with the traditional artificial intelligence device based on computer simulation human brain learning knowledge, the artificial intelligence device based on computer simulation human brain learning knowledge has the following two beneficial effects:

firstly, through setting up motor, pivot, reel, connecting rope, bracing piece, wheel, guide arm, spring, steel ball isotructure, rotate the reel through motor drive and carry out rolling and spring coupling to connecting rope, can make the terminal wheel of bracing piece flexible in the base for the device is whole can remove, after the device removes the assigned position, the wheel can retract the base in the machine and make base and ground contact, and then increase device whole and ground area of contact, makes device stability higher.

Secondly, through setting up structures such as air pump, intake pipe, air-out cover, flabellum, wind scooper, the intake pipe effect is taken in to the inlet pipe through the air pump start for the flabellum drives the air-out cover and rotates and make the air-out more even, and the air-out cover air-out air current blows to the wind scooper on, and the wind scooper leads the air current, makes the air current turn back and cools off the lower extreme of components and parts, and then makes components and parts overall cooling even.

Description of the drawings:

for ease of illustration, the invention is described in detail by the following detailed description and the accompanying drawings.

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is an enlarged view of the invention at A in FIG. 1;

FIG. 3 is an enlarged view of the invention at B in FIG. 1;

FIG. 4 is an enlarged view of FIG. 1 at C in accordance with the present invention;

FIG. 5 is an enlarged view of the invention at D in FIG. 1;

fig. 6 is an enlarged view of fig. 1 at E in accordance with the present invention.

In the figure: 1. a base; 2. a driving mechanism; 21. a motor; 22. a rotating shaft; 23. a square block; 24. a winding wheel; 25. square holes; 26. a baffle; 27. a limiting pin; 28. a connecting rope; 29. a connecting ring; 3. a moving mechanism; 31. a support rod; 32. a wheel; 33. a guide rod; 34. a stop block; 35. steel balls; 36. a spring; 4. a housing; 5. a support leg; 6. a component; 7. a cover; 8. a heat dissipation mechanism; 81. an air pump; 82. an air inlet pipe; 83. an air outlet cover; 84. a convex edge; 85. a semicircle block; 86. a connecting rod; 87. a support shaft; 88. a fan blade; 9. a wind scooper; 10. a support pin; 11. a support groove; 12. an air outlet hole; 13. a socket; 14. a connecting belt; 15. and (3) blocking.

The specific embodiment is as follows:

as shown in fig. 1-6, the present embodiment adopts the following technical scheme:

examples:

the utility model provides an artificial intelligence device based on computer simulation brain study knowledge, includes base 1, fixed mounting has actuating mechanism 2 on the base 1, be provided with moving mechanism 3 on the base 1, the welding has casing 4 on the base 1, the welding has stabilizer blade 5 on the base 1, fixed mounting has components and parts 6 on the stabilizer blade 5, there is cap 7 through the screw connection on the casing 4, be provided with cooling body 8 on the cap 7, sliding sleeve has cup jointed wind scooper 9 in casing 4, venthole 12 has been seted up on the base 1, be connected with socket 13 through the wire on the components and parts 6, socket 13 has been cup jointed to casing 4 internal fixation, fixedly connected with connecting band 14 on the casing 4, the end of connecting band 14 is provided with the jam 15, cup joint the jam 15 in the socket 13.

The base 1 is welded with a supporting pin 10, the wind scooper 9 is provided with a supporting groove 11, and the supporting pin 10 is sleeved in the supporting groove 11 in a sliding manner.

The driving mechanism 2 comprises a motor 21, a rotating shaft 22, a square block 23, a winding wheel 24, a square hole 25, a baffle 26, a limiting pin 27, a connecting rope 28 and a connecting ring 29, wherein the motor 21 and the base 1 are fixedly installed, the rotating shaft 22 of the motor 21 is rotationally connected with the base 1, the square block 23 is welded at the tail end of the rotating shaft 22, the winding wheel 24 is sleeved on the outer side of the square block 23 in a sliding manner, the square hole 25 is formed in the winding wheel 24, the square block 23 is sleeved on the square hole 25 in a sliding manner, the baffle 26 is contacted on the winding wheel 24, the winding wheel 24 is contacted with the rotating shaft 22, the connecting rope 28 is arranged on the outer side of the winding wheel 24, and the supporting rod 31 is fixedly connected with the tail end of the connecting rope 28.

The baffle 26 is slidably sleeved with a limiting pin 27, and the block 23 is internally connected with the limiting pin 27 through threads.

The base 1 is welded with a connecting ring 29, and a connecting rope 28 is slidably connected with the connecting ring 29.

The moving mechanism 3 comprises a supporting rod 31, wheels 32, a guide rod 33, a stop block 34, steel balls 35 and springs 36, wherein the supporting rod 31 is hinged to the base 1, the wheels 32 are arranged at the tail end of the supporting rod 31, the guide rod 33 is sleeved on the side wall of the base 1 in a sliding mode, the steel balls 35 are welded on the guide rod 33, the steel balls 35 are in contact with the supporting rod 31, the springs 36 are arranged on the outer sides of the guide rod 33, one ends of the springs 36 are welded with the base 1, and the other ends of the springs 36 are welded with the steel balls 35.

Wherein, the guide rod 33 is welded with a stop block 34, and the stop block 34 is contacted with the base 1.

The heat dissipation mechanism 8 comprises an air pump 81, an air inlet pipe 82, an air outlet cover 83, a convex edge 84, a semicircular block 85, a connecting rod 86, a supporting shaft 87 and fan blades 88, wherein the air pump 81 and the shell cover 7 are fixedly installed, the air inlet pipe 82 of the air pump 81 and the shell cover 7 are in sliding sleeve joint, the air outlet cover 83 is rotationally connected to the outer side of the air inlet pipe 82, the convex edge 84 is arranged on the air inlet pipe 82, the semicircular block 85 is welded on the convex edge 84, the semicircular block 85 is in contact with the air outlet cover 83, the connecting rod 86 is welded on the air outlet cover 83, the supporting shaft 87 is welded at the tail end of the connecting rod 86, and the fan blades 88 are arranged on the supporting shaft 87.

step one: when the device needs to move, the motor 21 is started, the motor 21 starts the rotating shaft 22 to rotate, the rotating shaft 22 drives the square block 23 to rotate, the square block 23 drives the winding wheel 24 to rotate, the winding wheel 24 rotates to wind the connecting rope 28, the connecting rope 28 is shortened, the supporting rod 31 is pulled to rotate, the wheels 32 extend out of the base 1, the base 1 rises to leave the ground, and the whole device can move;

step two: the supporting rod 31 rotates to enable the steel balls 35 to slide on the surface of the supporting rod 31, so that the steel balls 35 move towards the side wall of the base 1, the steel balls 35 move to enable the guide rod 33 to move towards the stop block 34, the steel balls 35 move to enable the spring 36 to be compressed, and the reaction force of the spring 36 enables the steel balls 35 to support the supporting rod 31;

step three: when the device moves to a designated position, the motor 21 drives the rotating shaft 22 to rotate reversely, the rotating shaft 22 drives the square block 23 to rotate reversely, the square block 23 drives the winding wheel 24 to rotate reversely, the winding wheel 24 stretches the connecting rope 28, meanwhile, the spring 36 elastically acts to reset the steel balls 35, the steel balls 35 reset the supporting rods 31 to rotate, the wheels 32 are retracted into the base 1, the base 1 is lowered to be in contact with the ground, the contact area between the whole device and the ground is increased, and the stability of the device is higher;

step four: the air pump 81 is started, the air pump 81 starts the air inlet pipe 82 to enter the air outlet cover 83, the air flow acts on the fan blades 88, the fan blades 88 drive the supporting shaft 87 to rotate, the supporting shaft 87 drives the connecting rod 86 to rotate, the connecting rod 86 rotates to drive the air outlet cover 83 to rotate, and the air outlet cover 83 rotates to enable the air outlet to be more uniform;

step five: the air outlet cover 83 moves along the direction of the air outlet flow direction of the base 1, the air flows to the air guide cover 9, the air guide cover 9 guides the air flow, the lower end of the component 6 is cooled by turning back the air flow, and the whole component 6 is cooled uniformly.

While the basic principles and main features of the present invention and advantages of the present invention have been shown and described, it will be understood by those skilled in the art that the present invention is not limited by the foregoing embodiments, which are described in the foregoing specification merely illustrate the principles of the present invention, and various changes and modifications may be made therein without departing from the spirit and scope of the invention, which is defined in the appended claims and their equivalents.

Claims

1. An artificial intelligence device based on computer simulation brain study knowledge, includes base (1), its characterized in that: the novel solar energy collecting device is characterized in that a driving mechanism (2) is fixedly arranged on the base (1), a moving mechanism (3) is arranged on the base (1), a shell (4) is welded on the base (1), supporting legs (5) are welded on the base (1), components (6) are fixedly arranged on the supporting legs (5), a shell cover (7) is connected to the shell (4) through screws, a heat dissipation mechanism (8) is arranged on the shell cover (7), a wind scooper (9) is sleeved in the shell (4) in a sliding mode, a vent hole (12) is formed in the base (1), a socket (13) is connected to the components (6) through a wire, a socket (13) is fixedly sleeved in the shell (4), a connecting belt (14) is fixedly connected to the shell (4), a plug (15) is arranged at the tail end of the connecting belt (14), and a plug (15) is sleeved in the socket (13).

The driving mechanism (2) comprises a motor (21), a rotating shaft (22), a square block (23), a winding wheel (24), square holes (25), a baffle plate (26), a limiting pin (27), a connecting rope (28) and a connecting ring (29), wherein the motor (21) and the base (1) are fixedly installed, the rotating shaft (22) of the motor (21) is rotationally connected with the base (1), the square block (23) is welded at the tail end of the rotating shaft (22), the winding wheel (24) is sleeved on the outer side of the square block (23) in a sliding manner, the square holes (25) are formed in the winding wheel (24), the square block (23) is sleeved on the winding wheel (24) in a sliding manner, the baffle plate (26) is contacted with the winding wheel (24) in a contact manner, the connecting rope (28) is arranged at the outer side of the winding wheel (24), and the tail end of the connecting rope (28) is fixedly connected with a supporting rod (31);

the moving mechanism (3) comprises a supporting rod (31), wheels (32), a guide rod (33), a stop block (34), steel balls (35) and springs (36), wherein the supporting rod (31) is hinged to a base (1), the wheels (32) are arranged at the tail end of the supporting rod (31), the guide rod (33) is sleeved on the side wall of the base (1) in a sliding mode, the steel balls (35) are welded on the guide rod (33), the steel balls (35) are in contact with the supporting rod (31), the springs (36) are arranged on the outer sides of the guide rod (33), one ends of the springs (36) are welded with the base (1), and the other ends of the springs (36) are welded with the steel balls (35);

the utility model provides a cooling mechanism (8) is including air pump (81), intake pipe (82), air-out cover (83), chimb (84), semicircle piece (85), connecting rod (86), back shaft (87) and flabellum (88), air pump (81) and cap (7) fixed mounting, intake pipe (82) and cap (7) of air pump (81) slide and cup joint, the outside rotation of intake pipe (82) is connected with air-out cover (83), be provided with chimb (84) on intake pipe (82), the welding has semicircle piece (85) on chimb (84), semicircle piece (85) and air-out cover (83) contact, the welding has connecting rod (86) on air-out cover (83), the end welding of connecting rod (86) has back shaft (87), be provided with flabellum (88) on back shaft (87).

2. An artificial intelligence device based on computer simulated human brain learning knowledge as claimed in claim 1 wherein: the base (1) is welded with a supporting pin (10), the wind scooper (9) is provided with a supporting groove (11), and the supporting pin (10) is sleeved in the supporting groove (11) in a sliding mode.

3. An artificial intelligence device based on computer simulated human brain learning knowledge as claimed in claim 1 wherein: and the baffle (26) is internally sleeved with a limiting pin (27) in a sliding manner, and the block (23) is internally connected with the limiting pin (27) through threads.

4. An artificial intelligence device based on computer simulated human brain learning knowledge as claimed in claim 1 wherein: the base (1) is welded with a connecting ring (29), and the connecting ring (29) is connected with a connecting rope (28) in a sliding way.

5. An artificial intelligence device based on computer simulated human brain learning knowledge as claimed in claim 1 wherein: a stop block (34) is welded on the guide rod (33), and the stop block (34) is in contact with the base (1).

6. The application method of the artificial intelligent device based on the computer simulation brain learning knowledge is characterized by comprising the following steps of: the method comprises the following specific steps:

step one: when the device needs to move, the motor (21) is started, the motor (21) starts the rotating shaft (22) to rotate, the rotating shaft (22) drives the square block (23) to rotate, the square block (23) drives the winding wheel (24) to rotate, the winding wheel (24) rotates to wind the connecting rope (28), the connecting rope (28) is further shortened, the connecting rope (28) is shortened, the supporting rod (31) is pulled to rotate, the wheels (32) extend out of the base (1), the base (1) rises to leave the ground, and the whole device can move;

step two: the supporting rod (31) rotates to enable the steel balls (35) to slide on the surface of the supporting rod (31), the steel balls (35) move towards the side wall of the base (1), the steel balls (35) move to enable the guide rod (33) to move towards the stop block (34), the steel balls (35) move to enable the springs (36) to be compressed, and the reaction force of the springs (36) enables the steel balls (35) to support the supporting rod (31);

step three: when the device moves to a designated position, the motor (21) drives the rotating shaft (22) to rotate reversely, the rotating shaft (22) drives the square block (23) to rotate reversely, the square block (23) drives the winding wheel (24) to rotate reversely, the winding wheel (24) rotates reversely to enable the connecting rope (28) to extend, meanwhile, the spring (36) elastically acts to enable the steel balls (35) to reset, the steel balls (35) enable the supporting rod (31) to rotate, the wheels (32) are enabled to retract into the base (1), the base (1) is enabled to descend and contact with the ground, the whole contact area of the device and the ground is increased, and the stability of the device is enabled to be higher;

step four: the air pump (81) is started, the air pump (81) starts the air inlet pipe (82) to enter the air outlet cover (83), air flow acts on the fan blades (88), the fan blades (88) drive the supporting shaft (87) to rotate, the supporting shaft (87) drives the connecting rod (86) to rotate, the connecting rod (86) rotates to drive the air outlet cover (83) to rotate, and the air outlet cover (83) rotates to enable air to be more uniform;

step five: the air outlet cover (83) moves in the direction of the air outlet flow direction of the base (1), the air flow blows to the air guide cover (9), the air guide cover (9) guides the air flow, the lower end of the component (6) is cooled by turning back the air flow, and then the component (6) is uniformly cooled as a whole.