CN114498409A - Intelligent heat dissipation control system based on power distribution - Google Patents

Abstract

The invention discloses an intelligent heat dissipation control system based on power distribution, which comprises a distribution box and an intelligent control system, a wire assembly is fixedly arranged above the inner wall of the distribution box, a line controller is fixedly arranged on the right side below the inner wall of the distribution box, the circuit is provided with a controller, a left pipeline is connected with a heat dissipation cavity, a distribution box is fixedly arranged in the middle of the inner wall of the distribution box, a motor is fixedly arranged on the left side of the inner wall of the heat dissipation cavity, a heat dissipation blade is fixedly arranged at the output end of the motor, a control mechanism is fixedly installed in the middle of the output end of the motor, four wire conduits are fixedly installed on the inner wall of the wiring box, the four wire conduits are all connected with a heat dissipation cavity pipeline, cooling pipes are fixedly installed on the outer sides of the four wire conduits, the cooling pipes are connected with the control mechanism pipeline, the device has solved the problem that can't intellectuality at present to the conductor cooling after total conductor cooling and distribution.

Description

Intelligent heat dissipation control system based on power distribution

Technical Field

The invention belongs to the technical field of electric power heat dissipation, and particularly relates to an intelligent heat dissipation control system based on electric power distribution.

Background

Along with the continuous propulsion of electric power heat dissipation technology, make the conductor heat up when the electron flows to need carry out the work of dispelling the heat to the conductor, and most intelligent heat dissipation control system can only dispel the heat cooling work to the high temperature that the total conductor produced, thereby the output of electric current is guaranteed to the electric current need with the voltage rising when distributing, the voltage rising then can produce secondary high temperature, need dispel the heat to the conductor of distribution again, prior art can't cool off the conductor after the distribution, lead to the circuit to damage.

The conductor after total conductor and current distribution can not be accurately controlled by temperature and cooled according to the temperature of the total conductor in the prior art, the conductor is influenced by temperature during transmission, the temperature rises, the resistance becomes large, and the conductor becomes small. This phenomenon becomes an urgent problem to be solved by those skilled in the art.

Disclosure of Invention

The invention aims to solve the problems in the prior art by aiming at an intelligent heat dissipation control system based on power distribution of the conventional material collecting device.

In order to solve the technical problems, the invention provides the following technical scheme: the utility model provides an intelligent heat dissipation control system based on power distribution, includes block terminal and intelligent control system, its characterized in that: a wire assembly is fixedly arranged above the inner wall of the distribution box, a line controller is fixedly arranged on the right side below the inner wall of the distribution box, the circuit is provided with a controller, a left pipeline is connected with a heat dissipation cavity, a distribution box is fixedly arranged in the middle of the inner wall of the distribution box, a motor is fixedly arranged on the left side of the inner wall of the heat dissipation cavity, a heat dissipation blade is fixedly arranged at the output end of the motor, a control mechanism is fixedly arranged in the middle of the output end of the motor, four wire conduits are fixedly arranged on the inner wall of the wiring box, the four wire conduits are all connected with a heat dissipation cavity pipeline, cooling pipes are fixedly arranged on the outer sides of the four wire conduits, the cooling pipe is connected with a control mechanism pipeline, the inner wall of the heat dissipation cavity is provided with a temperature sensing module, the temperature sensing module is used for sensing the temperature generated by the conductor when the current passes through the heat dissipation cavity, and the cooling pipe is connected with an external water source pipeline.

The invention further discloses that the control mechanism comprises a turntable, the turntable is fixedly connected with the outer side of the output end of the motor, a fixed rod is fixedly arranged on the outer side of the turntable, a clamping block is fixed at the outer end of the fixed rod, a friction block is fixedly arranged at the outer end of the inner wall of the fixed rod, an air pressure cavity is fixedly arranged at the bottom of the inner wall of the fixed rod, an extrusion plate is slidably connected with the inner wall of the air pressure cavity, the extrusion plate is connected with a spring at the bottom of the air pressure cavity, the upper part of the air pressure cavity is connected with an external pipeline, a one-way valve I is arranged in the pipeline, a push rod is fixedly connected with the outer end of the extrusion plate, an expansion ball is fixedly arranged at the outer end of the push rod, the expansion ball is hollow and elastic, a friction plate is fixedly arranged at the inner end of the outer wall of the push rod, the friction plate is mutually attached to the friction block, and a telescopic rod is fixedly arranged between the inner end of the push rod and the outer end of the air pressure cavity, the utility model discloses a hydraulic expansion valve, including telescopic link, expansion ball, fixed intracavity wall, extrusion pole, cooling pipe, telescopic link and external control valve pipe connection, the telescopic link is provided with check valve two with external pipe connection and in the pipeline, the atmospheric pressure chamber is provided with the pressure valve with expansion ball pipe connection and in the pipeline, motor outside fixed mounting has fixed chamber, fixed intracavity wall fixed mounting has the pressure chamber of taking out, take out pressure intracavity wall sliding connection has the stripper bar, the stripper bar outer end is the arc form, take out pressure chamber and external water source pipe connection, take out and press the chamber and be provided with the booster pump with cooling tube pipe connection and in the pipeline, the expansion ball is connected with external control valve pipe connection.

The invention further discloses that the intelligent control system comprises a data acquisition module, an intelligent conversion module and an intelligent control module, wherein the data acquisition module is electrically connected with the temperature sensing module, the intelligent conversion module is respectively electrically connected with the data acquisition module and the intelligent control module, and the intelligent control module is respectively electrically connected with the motor and the booster pump;

the data acquisition module is used for acquiring data in the temperature sensing module, the intelligent conversion module is used for converting according to the acquired data and inputting a result into the intelligent control module, and the intelligent control module is used for controlling the operation of the motor and the booster pump.

The invention further illustrates that the operation process of the intelligent control system comprises the following steps:

s1, operating the intelligent control system, electrically driving the intelligent control system to start the circuit controller, and transmitting the conductor through the pipeline and the conduit in the heat dissipation cavity;

s2, the intelligent control system electrically drives the temperature sensing module to detect the temperature generated by the conductor, inputs the data into the data acquisition module, converts the data by the intelligent conversion module, and inputs the converted data into the intelligent control module;

s3, the intelligent control module drives the motor to rotate, so that the output end of the motor drives the radiating blades to rotate, the main conductor starts to be radiated, when the temperature generated by the conductor is high, the operation enters S4, and otherwise, the operation enters S5;

s4, changing the state of the pressure valve, controlling the state of the expansion ball, performing primary water cooling work, changing the moving distance of the pushing rod under the influence of mutual friction of the friction plate and the friction block and the centrifugal force on the pushing rod, so as to control the water cooling effect, simultaneously operating the booster pump, further improving the water cooling effect, and then entering S5;

and S5, after the power is used, the intelligent control system drives the line controller to close the conductor, and the steps from S1 to S4 are repeated when the power is continuously used.

In S3, the intelligent control module operates the motor, and the motor drives the heat dissipating blades to rotate via the output end, so as to control the rotation speed of the heat dissipating blades according to the temperature generated by the main conductor, thereby controlling the air cooling effect.

In step S4, the motor rotates to drive the turntable to rotate, the turntable drives the fixing rod to rotate, the fixing rod is influenced by the temperature inside the heat dissipation cavity, the rotation speed of the motor changes, so that the centrifugal force generated by the fixing rod during rotation changes, and the state of the pressure valve changes due to the change of the centrifugal force, thereby controlling the state of the expansion ball.

In step S4, the rotation speed of the motor changes, the centrifugal force applied to the push rod changes, and the friction force between the friction plate and the friction block changes the moving distance of the push rod due to the change of the rotation speed of the motor.

In step S4, the intelligent control module operates the booster pump, and drives the booster pump to change the boosting force of water according to the temperature generated by the main conductor, so as to control the flow rate of water and further control the water cooling effect.

Compared with the prior art, the invention has the following beneficial effects: according to the invention, the control mechanism and the intelligent control system are adopted, the control mechanism is driven to start rotating in the rotating process of the motor, and meanwhile, the control mechanism is intelligently controlled, so that the control mechanism injects cooling liquid into the cooling pipe through the pipeline, thus the heat dissipation of the distributed circuit is realized, and the heat dissipation effect is further improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

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

FIG. 2 is a schematic diagram of the circuit of the present invention;

FIG. 3 is a schematic diagram of the internal structure of the heat dissipation chamber of the present invention;

fig. 4 is a schematic view of the internal structure of the wiring box of the present invention;

FIG. 5 is a schematic view of the motor output end structure of the present invention;

FIG. 6 is a schematic view of the control mechanism of the present invention;

FIG. 7 is a schematic flow diagram of the intelligent control system of the present invention;

in the figure: 1. a distribution box; 2. a line controller; 3. a heat dissipation cavity; 4. a wiring box; 5. a heat-dissipating leaf; 6. a motor; 7. a conduit; 8. a cooling tube; 9. a turntable; 10. fixing the rod; 11. a friction block; 12. a pneumatic chamber; 13. a compression plate; 14. a push rod; 15. an expansion ball; 16. a friction plate; 17. a telescopic rod; 18. a fixed cavity; 19. a pressure pumping cavity; 20. an extrusion stem; 21. a booster pump; 22. a pressure valve.

Detailed Description

The present invention will be described in further non-limiting detail with reference to the following preferred embodiments and accompanying drawings. It is to be understood that the described embodiments are merely exemplary of the invention, and not restrictive of the full scope of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the present invention provides the following technical solutions: an intelligent heat dissipation control system based on electric power distribution comprises a distribution box 1 and an intelligent control system, wherein a wire assembly is fixedly installed above the inner wall of the distribution box 1, a line controller 2 is fixedly installed on the right side below the inner wall of the distribution box 1, a heat dissipation cavity 3 is connected with a left side pipeline of the line controller 2, a distribution box 4 is fixedly installed in the middle of the inner wall of the distribution box 1, a motor 6 is fixedly installed on the left side of the inner wall of the heat dissipation cavity 3, a heat dissipation blade 5 is fixedly installed at the output end of the motor 6, a control mechanism is fixedly installed in the middle of the output end of the motor 6, four conductor pipes 7 are fixedly installed on the inner wall of the distribution box 4, the four conductor pipes 7 are all connected with the heat dissipation cavity 3 through pipelines, a cooling pipe 8 is fixedly installed on the outer side of the four conductor pipes 7, the cooling pipe 8 is connected with the control mechanism through a pipeline, a temperature sensing module is arranged on the inner wall of the heat dissipation cavity 3, and is used for sensing the temperature generated by a conductor when induction current passes through the heat dissipation cavity 3, the upper cooling pipe 8 is connected with an external water source pipeline, the intelligent control system is respectively connected with an external power supply, the line controller 2, the motor 6 and the control mechanism, a circuit enters the line controller 2 through the line collection assembly, then enters the heat dissipation cavity 3 through the pipeline, finally enters the four lead pipes 7 through the pipeline to distribute electric power, an operator drives the intelligent control system to operate through the external power supply, the intelligent control system enables the line controller 2 to be started through electric drive, a conductor is transmitted out through the pipeline and the lead pipes 7 in the heat dissipation cavity 3, meanwhile, the temperature sensing module senses the temperature generated by a main conductor in the heat dissipation cavity 3 through electric drive, the rotating speed of the motor 6 is controlled to change according to the temperature, the motor 6 drives the heat dissipation blades 5 to rotate through the output end of the motor, the rotating speed of the heat dissipation blades 5 is controlled, and high-speed airflow dissipates heat inside the heat dissipation cavity 3, the effect of dissipating heat of the temperature generated by the main conductor is achieved, the heat dissipation efficiency is controlled, the control mechanism is driven to rotate in the rotating process of the motor 6, and meanwhile the control mechanism is intelligently controlled, so that the control mechanism injects cooling liquid into the cooling pipe 8 through a pipeline, heat dissipation of a distributed circuit is achieved, and the heat dissipation effect is further improved;

the control mechanism comprises a rotary table 9, the rotary table 9 is fixedly connected with the outer side of the output end of the motor 6, a fixed rod 10 is fixedly installed on the outer side of the rotary table 9, a clamping block is fixed at the outer end of the fixed rod 10, a friction block 11 is fixedly installed at the outer end of the inner wall of the fixed rod 10, an air pressure cavity 12 is fixedly installed at the bottom of the inner wall of the fixed rod 10, a squeezing plate 13 is connected with the inner wall of the air pressure cavity 12 in a sliding manner, the squeezing plate 13 is connected with a spring at the bottom of the air pressure cavity 12, the upper portion of the air pressure cavity 12 is connected with an external pipeline, a one-way valve I is arranged in the pipeline, a pushing rod 14 is fixedly connected with the outer end of the squeezing plate 13, an expansion ball 15 is fixedly installed at the outer end of the pushing rod 14, the expansion ball 15 is hollow and has elasticity, a friction plate 16 is fixedly installed at the inner end of the outer wall of the pushing rod 14, the friction plate 16 is mutually attached to the friction block 11, a telescopic rod 17 is fixedly installed between the inner end of the pushing rod 14 and the outer end of the air pressure cavity 12, the telescopic rod 17 is connected with the external pipeline, and a one-way valve II is arranged in the pipeline, the telescopic rod 17 is connected with an external control valve pipeline, the air pressure cavity 12 is connected with an expansion ball 15 pipeline, a pressure valve 22 is arranged in the pipeline, a fixed cavity 18 is fixedly arranged at the outer side of the motor 6, a pressure pumping cavity 19 is fixedly arranged on the inner wall of the fixed cavity 18, an extrusion rod 20 is connected on the inner wall of the pressure pumping cavity 19 in a sliding manner, the outer end of the extrusion rod 20 is arc-shaped, the pressure pumping cavity 19 is connected with an external water source pipeline, the pressure pumping cavity 19 is connected with a cooling pipe 8 pipeline, a booster pump 21 is arranged in the pipeline, the expansion ball 15 is connected with the external controller pipeline, the intelligent control system is respectively electrically connected with the booster pump 21 and the external control valve, through the steps, the intelligent control system operates, after the main conductor generates high temperature, secondary high temperature is generated when the conductor is distributed, the conductor needs to be secondarily cooled through a conductor pipe 7, and water cooling can ensure the full cooling of the distributed conductor, the heat dissipation effect is enhanced, the motor 6 rotates to drive the turntable 9 to start to rotate, the turntable 9 drives the fixed rod 10 to rotate and is influenced by the temperature in the heat dissipation cavity 3, the rotating speed of the motor 6 is changed, so that the centrifugal force generated when the fixed rod 10 rotates is changed, when the temperature is higher, the rotating speed of the motor 6 is high, the generated centrifugal force is high, the pushing rod 14 starts to move outwards under the action of the high centrifugal force, the friction plate 16 and the friction block 11 rub against each other to control the moving speed of the pushing rod 14, the phenomenon that the heat dissipation adjustment function fails when the pushing rod 14 reaches a limit position once is avoided, the pushing rod 14 pulls the extrusion plate 13 to move outwards along the inner wall of the air pressure cavity 12 after being subjected to the high centrifugal force, the spring is deformed under the stress, the air outside the air pressure cavity 12 enters the inner side of the pressure valve 22 through a pipeline until the pressure bearing limit of the pressure valve 22 is reached, and the pressure valve 22 is opened, at this time, gas enters the expansion ball 15 through the pipeline, the expansion ball 15 is inflated after being filled with gas, so that in the rotating process of the turntable 9, the expansion ball 15 can initially contact with the extrusion rod 20, meanwhile, the expansion rod 17 is pulled to extend in the outward moving process of the push rod 14, the expansion rod 17 draws gas from the outside, the one-way valve controls the gas to only enter the expansion rod 17 from the outside, the supporting effect on the push rod 14 is realized, the extrusion force insufficiency caused by the mutual acting force when the push rod 14 drives the expansion ball 15 to move outward to extrude the extrusion rod 20 is avoided, the subsequent cooling effect is prevented from being influenced, the extrusion rod 20 slides outward along the inner wall of the pressure pumping cavity 19 after being extruded, the spring is deformed under force, after the turntable 9 rotates to drive the expansion ball 15 to be separated from the extrusion rod 20, the spring in the pressure pumping cavity 19 generates the reaction force to push the extrusion rod 20 to reset, water is drawn from the outside through the pipeline to enter the pressure pumping cavity 19, when the expansion ball 15 contacts the extrusion rod 20 again, water is extruded through the pipeline and passes through the booster pump 21, the booster pump 21 is controlled to boost the water according to the temperature, thereby the flow rate of the water is controlled, the heat dissipation effect is further improved, the water enters the cooling pipe 8 through the pipeline, the water cooling work is carried out on the line in the conduit 7, the circuit is further cooled, the water entering the cooling pipe 8 is discharged to the outside again through the pipeline, when the temperature is lower, the rotating speed of the motor 6 is small, the generated centrifugal force is small, at this time, the pushing rod 14 cannot move due to the mutual friction force of the friction block 11 and the friction plate 16 after the pushing rod 14 receives the small centrifugal force, the extrusion plate 13 cannot move, the external control valve controls the gas in the expansion rod 17 to discharge to reset the expansion rod 17, the external controller controls the gas in the expansion ball 15 to discharge to reset the expansion ball 15, at this time, the pressure valve 22 cannot reach the pressure bearing limit to be closed, stopping the contact of the extrusion rod 20 and stopping the water cooling operation, wherein the temperature generated by the conductor is low and does not need to be cooled, so that the energy consumption is reduced, the influence on the output of the conductor caused by continuous cooling operation is prevented, and the follow-up abnormal use of electric power is avoided;

the intelligent control system comprises a data acquisition module, an intelligent conversion module and an intelligent control module, wherein the data acquisition module is electrically connected with the temperature sensing module, the intelligent conversion module is electrically connected with the data acquisition module and the intelligent control module respectively, and the intelligent control module is electrically connected with the motor 6 and the booster pump 21 respectively;

the data acquisition module is used for acquiring data in the temperature sensing module, the intelligent conversion module is used for converting according to the acquired data and inputting the result into the intelligent control module, and the intelligent control module is used for controlling the operation of the motor 6 and the booster pump 21;

the operation process of the intelligent control system comprises the following steps:

s1, operating the intelligent control system, electrically driving the intelligent control system to enable the circuit controller 2 to be started, and transmitting the conductor out through the pipeline and the conduit 7 in the heat dissipation cavity 3;

s2, the intelligent control system electrically drives the temperature sensing module to detect the temperature generated by the conductor, inputs the data into the data acquisition module, converts the data by the intelligent conversion module, and inputs the converted data into the intelligent control module;

s3, the intelligent control module drives the motor 6 to rotate, so that the output end of the motor 6 drives the heat dissipation blade 5 to rotate, the heat dissipation work of the main conductor is started, when the temperature generated by the conductor is high, the operation enters S4, and otherwise, the operation enters S5;

s4, changing the state of the pressure valve 22, controlling the state of the expansion ball 15, performing preliminary water cooling work, and controlling the water cooling effect by changing the moving distance of the pushing rod 14 under the influence of the mutual friction of the friction plate 16 and the friction block 11 and the centrifugal force on the pushing rod 14, wherein the water cooling effect is further improved by the operation of the booster pump 21, and then entering S5;

s5, after the power is used, the intelligent control system drives the line controller 2 to close the conductor, and the steps from S1 to S4 are repeated when the power is continuously used;

in S3, intelligent control module makes motor 6 operate, and motor 6 drives radiating fin 5 through the output and rotates to according to the rotational speed of temperature control radiating fin 5 that the total conductor produced, control the air-cooled effect:

wherein V is the rotation speed of the motor 6, V_maxThe maximum speed of the motor 6, C the temperature generated by the total conductor, C_maxThe maximum temperature generated by the main conductor is higher, the rotating speed of the motor 6 is higher aiming at the higher temperature generated by the main conductor, so that the rotating speed of the heat dissipation blade 5 is higher, the temperature generated by the main conductor is higher, the heat dissipation blade 5 is rotated at a high speed to drive airflow to carry out high-intensity cooling on the main conductor, and the cooling effect is ensured;

in S4, motor 6 rotates and drives carousel 9 and begin to rotate, and carousel 9 drives dead lever 10 and rotates, receives the inside temperature influence in heat dissipation chamber 3, and motor 6 rotational speed changes to the centrifugal force that produces when making dead lever 10 rotate changes, because the centrifugal force changes and leads to pressure valve 22 state to change, thereby controls the state of inflation ball 15:

when C is present_mid<C<C_maxNormal temperature that the bus conductor can generate: after the pushing rod 14 is subjected to a large centrifugal force, the extrusion plate 13 is pulled to move outwards along the inner wall of the air pressure cavity 12, the spring is deformed under stress, gas outside the air pressure cavity 12 is extruded and then enters the inner side of the pressure valve 22 through the pipeline until the pressure bearing limit of the pressure valve 22 is reached, the pressure valve 22 is opened, at the moment, the gas enters the expansion ball 15 through the pipeline, the expansion ball 15 is inflated after the gas is filled into the expansion ball 15, so that the rotary table 9 rotates, the expansion ball 15 can be in initial contact with the extrusion rod 20, the extrusion rod 20 slides outwards along the inner wall of the pumping cavity 19 after being extruded, the spring is deformed under stress, the rotary table 9 rotates to drive the expansion ball 15 to be separated from the extrusion rod 20, and the spring in the pumping cavity 19 generates a reaction force to push the extrusion rodThe movable extrusion rod 20 is reset, water is extracted from the outside through a pipeline and enters the pressure extraction cavity 19, the water enters the cooling pipe 8 through the pipeline, and water cooling work is performed on a line in the conduit 7, so that the contact between the expansion ball 15 and the pressure extraction cavity 19 is ensured, preliminary water cooling can be smoothly performed, the water cooling effect is increased in subsequent water cooling control, the conductor is fully cooled when passing through the conduit 7, and the use efficiency of the conductor is improved;

when C is less than or equal to C_midThe method comprises the following steps: the rotating speed of the motor 6 is low, the generated centrifugal force is low, after the pushing rod 14 is subjected to a small centrifugal force, the pushing rod 14 cannot move due to the mutual friction force between the friction block 11 and the friction plate 16, meanwhile, the extrusion plate 13 cannot move, the external control valve controls the gas in the expansion rod 17 to be discharged so as to reset the expansion rod 17, the external controller controls the gas in the expansion ball 15 to be discharged so as to reset the expansion ball 15, the pressure valve 22 cannot reach the pressure bearing limit and is closed, the extrusion rod 20 is stopped from being contacted, the water cooling operation is stopped, the temperature generated by the conductor is low, cooling is not needed, on one hand, the energy consumption is reduced, on the other hand, the conductor output is prevented from being influenced due to continuous cooling operation, and the problem that subsequent electric power cannot be normally used is avoided;

in S4, when the rotation speed of the motor 6 changes, the centrifugal force applied to the push rod 14 changes, and the friction force between the friction plate 16 and the friction block 11 causes the moving distance of the push rod 14 to change due to the change of the rotation speed of the motor 6:

when C is present_mid<C<C_maxThe method comprises the following steps:

l is the distance of outward movement of the push rod 14, L_maxFor the maximum distance that the pushing rod 14 moves outwards, the higher the temperature generated by the main conductor, the larger the distance that the pushing rod 14 moves outwards, so that the distance that the expansion ball 15 moves outwards is larger, the more the water can be pumped by the pumping cavity 19, the cooling effect on the distribution conductor is improved, sufficient cooling is ensured, the lower the temperature generated by the main conductor, the smaller the distance that the pushing rod 14 moves outwards, and at the moment, due to the lower temperature, normal operation of water cooling work is ensured, and the high of the distribution conductor can be avoidedThe intensity cooling causes the conductor to flow and be influenced, and the normal use of the electric power is ensured;

when C is less than or equal to C_midThe method comprises the following steps: the pushing rod 14 is subjected to small centrifugal force and cannot move outwards, so that the temperature generated by the main conductor is low, water cooling is not needed, the use energy consumption is reduced, meanwhile, the phenomenon that an external water source does not have enough self-cooling time due to long-time water cooling is avoided, and the subsequent influence on the water cooling effect is prevented;

in S4, the intelligent control module makes the booster pump 21 run, and the booster pump 21 is driven to change the water boosting strength according to the temperature generated by the main conductor, so as to control the flow rate of water and further control the water cooling effect:

when C is present_mid<C<C_maxThe method comprises the following steps:

p is the water pressurization force of the booster pump 21, P_maxFor the maximum water pressurization force of the booster pump 21, the higher the temperature generated by the main conductor is, the higher the water pressurization force of the booster pump 21 on water is, the higher the temperature of the generated distribution conductor is, the higher the pressure on water is, so that water can smoothly and quickly flow in the uppermost cooling pipe 8, all the distribution conductors are guaranteed to be cooled, and the phenomenon of insufficient cooling is avoided;

when C is less than or equal to C_midThe method comprises the following steps: at this moment, because the temperature that the total conductor produced need not to carry out water-cooling work to make booster pump 21 close, avoid booster pump 21 to continue to operate and increase the use energy consumption, thereby make block terminal 1 energy consumption relatively can be lower in the use, save the running cost.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", etc. indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description of the present invention, and do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

Finally, it should be pointed out that: the above examples are only for illustrating the technical solutions of the present invention, and are not limited thereto. Although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: it is to be understood that modifications may be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions may be made in some technical features thereof, without departing from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (8)

1. The utility model provides an intelligent heat dissipation control system based on power distribution, includes block terminal (1) and intelligent control system, its characterized in that: the cable-type heat dissipation device is characterized in that a cable assembly is fixedly mounted above the inner wall of the distribution box (1), a circuit controller (2) is fixedly mounted on the right side below the inner wall of the distribution box (1), a controller (2) is connected with a heat dissipation cavity (3) through a pipeline on the left side, a distribution box (4) is fixedly mounted in the middle of the inner wall of the distribution box (1), a motor (6) is fixedly mounted on the left side of the inner wall of the heat dissipation cavity (3), a heat dissipation blade (5) is fixedly mounted at the output end of the motor (6), a control mechanism is fixedly mounted in the middle of the output end of the motor (6), four conductor pipes (7) are fixedly mounted on the inner wall of the distribution box (4), the four conductor pipes (7) are all connected with the heat dissipation cavity (3) through a pipeline, cooling pipes (8) are fixedly mounted on the outer side of the conductor pipes (7), and the cooling pipes (8) are connected with the control mechanism through a pipeline, the inner wall of the heat dissipation cavity (3) is provided with a temperature sensing module, the temperature sensing module is used for sensing the temperature generated by the conductor when the current passes through the heat dissipation cavity (3), and the cooling pipe (8) is connected with an external water source pipeline.

2. The intelligent heat dissipation control system based on power distribution as claimed in claim 1, wherein: the control mechanism comprises a rotary table (9), the rotary table (9) is fixedly connected with the outer side of the output end of a motor (6), a fixing rod (10) is fixedly mounted on the outer side of the rotary table (9), a clamping block is fixed at the outer end of the fixing rod (10), a friction block (11) is fixedly mounted at the outer end of the inner wall of the fixing rod (10), an air pressure cavity (12) is fixedly mounted at the bottom of the inner wall of the fixing rod (10), a squeezing plate (13) is slidably connected with the inner wall of the air pressure cavity (12), the squeezing plate (13) is connected with a spring at the bottom of the air pressure cavity (12), the upper part of the air pressure cavity (12) is connected with an external pipeline, a one-way valve I is arranged in the pipeline, a pushing rod (14) is fixedly connected with the outer end of the squeezing plate (13), an expansion ball (15) is fixedly mounted at the outer end of the pushing rod (14), and the expansion ball (15) is hollow and has elasticity, the inner fixed mounting of propelling movement pole (14) outer wall has friction disc (16), friction disc (16) and clutch blocks (11) laminate each other, fixed mounting has telescopic link (17) between propelling movement pole (14) inner and atmospheric pressure chamber (12) outer end, telescopic link (17) and outside pipe connection and intraductal be provided with check valve two, telescopic link (17) and external control valve pipe connection, atmospheric pressure chamber (12) and inflation ball (15) pipe connection and intraductal be provided with pressure valve (22), motor (6) outside fixed mounting has fixed chamber (18), fixed chamber (18) inner wall fixed mounting has the pressure chamber (19) of taking out, pressure chamber (19) inner wall sliding connection has squeeze bar (20), squeeze bar (20) outer end is the arc form, pressure chamber (19) and outside water source pipe connection, pressure chamber (19) and cooling tube (8) pipe connection and intraductal be provided with booster pump (21), the expansion ball (15) is connected with an external controller pipeline.

3. The intelligent heat dissipation control system based on power distribution as claimed in claim 2, wherein: the intelligent control system comprises a data acquisition module, an intelligent conversion module and an intelligent control module, wherein the data acquisition module is electrically connected with the temperature sensing module, the intelligent conversion module is electrically connected with the data acquisition module and the intelligent control module respectively, and the intelligent control module is electrically connected with the motor (6) and the booster pump (21) respectively;

the data acquisition module is used for acquiring data in the temperature sensing module, the intelligent conversion module is used for converting according to the acquired data and inputting a result into the intelligent control module, and the intelligent control module is used for controlling the operation of the motor (6) and the booster pump (21).

4. The intelligent heat dissipation control system based on power distribution of claim 3, wherein: the operation process of the intelligent control system comprises the following steps:

s1, operating the intelligent control system, electrically driving the intelligent control system to start the line controller (2), and transmitting the conductor out through the pipeline and the conduit (7) in the heat dissipation cavity (3);

s2, the intelligent control system electrically drives the temperature sensing module to detect the temperature generated by the conductor, inputs the data into the data acquisition module, converts the data by the intelligent conversion module, and inputs the converted data into the intelligent control module;

s3, the intelligent control module drives the motor (6) to rotate, so that the output end of the motor (6) drives the heat dissipation blade (5) to rotate, the heat dissipation work of the main conductor is started, when the temperature generated by the conductor is high, the temperature enters S4, and otherwise, the temperature enters S5;

s4, changing the state of the pressure valve (22), controlling the state of the expansion ball (15), performing primary water cooling work, and controlling the water cooling effect by changing the moving distance of the pushing rod (14) under the influence of the mutual friction of the friction plate (16) and the friction block (11) and the centrifugal force on the pushing rod (14), and simultaneously operating the booster pump (21) to further improve the water cooling effect, and then entering S5;

and S5, after the power is used, the intelligent control system drives the line controller (2) to close the conductor, and the steps from S1 to S4 are repeated when the power is continuously used.

5. The intelligent heat dissipation control system based on power distribution as claimed in claim 4, wherein: in S3, the intelligent control module enables the motor (6) to operate, the motor (6) drives the radiating blades (5) to rotate through the output end, and therefore the rotating speed of the radiating blades (5) is controlled according to the temperature generated by the main conductor, and the air cooling effect is controlled.

6. The intelligent heat dissipation control system based on power distribution as claimed in claim 5, wherein: in S4, the motor (6) rotates to drive the rotary table (9) to start rotating, the rotary table (9) drives the fixing rod (10) to rotate, the fixing rod (10) is influenced by the temperature inside the heat dissipation cavity (3), the rotating speed of the motor (6) changes, therefore, the centrifugal force generated when the fixing rod (10) rotates changes, the state of the pressure valve (22) changes due to the change of the centrifugal force, and the state of the expansion ball (15) is controlled.

7. The intelligent heat dissipation control system based on power distribution as claimed in claim 6, wherein: in the S4, the rotating speed of the motor (6) changes, the centrifugal force applied to the pushing rod (14) changes, and the friction force between the friction plate (16) and the friction block (11) enables the moving distance of the pushing rod (14) to change due to the rotating speed change of the motor (6).

8. The intelligent heat dissipation control system based on power distribution as claimed in claim 7, wherein: in S4, the intelligent control module enables the booster pump (21) to operate, and the booster pump (21) is driven to change the water boosting force according to the temperature generated by the main conductor, so that the flow rate of water is controlled, and the water cooling effect is further controlled.

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