CN113543548A - Ultrahigh current monitoring and processing system - Google Patents

Abstract

The invention relates to the technical field of current monitoring, and discloses an ultrahigh current monitoring and processing device which comprises an elastic mechanism, wherein a movable plate is arranged in the elastic mechanism, an elastic band penetrates through the top side wall of the movable plate, a movable ring penetrates through the side wall of the elastic band, a compression spring penetrates through the middle part of the top side wall of the movable plate, the top end of the compression spring is connected with an elastic spring, and the bottom end of the elastic spring is connected with a rolling mechanism. The bottom through the spring drives the lateral wall rotation of movable ball, the rotatory roll of lateral wall department that the bottom lateral wall department of movable ball drove the hemisphere shell, the lateral wall department area that the lateral wall of hemisphere shell is in the movable block rotates, the lateral wall of movable block is promoted to and is close to with laminating each other between the lateral wall according to the briquetting, the movable block with press scraping between the lateral wall of briquetting and press, make the sound wave disperse away from between the lateral wall of movable block and according to the briquetting, can weaken the strength of sound wave, avoid the sound wave to lead to the fact the interference excessively by force.

Description

Ultrahigh current monitoring and processing system

Technical Field

The invention relates to the technical field of current monitoring, in particular to an ultrahigh current monitoring and processing system.

Background

In the flowing process of ultrahigh current, if the temperature characteristics of elements are poor, the current detection precision is low, the sensor is very susceptible to drift, the current containing direct current components is difficult to measure under the influence of point drift, the current flowing in the measuring coil needs to eliminate the influence of factors such as external interference factors, noise generated in the induction process and the like, the sound wave pressure is easy to be applied to the periphery of the outer side of the coil, and when the noise is too large, the side wall of the coil shakes, so that the measurement error is increased.

Disclosure of Invention

In order to solve the above problems, the present invention provides the following technical solutions: an ultrahigh current monitoring and processing device comprises an elastic mechanism, wherein the elastic mechanism comprises a movable plate inside, the top side wall of the movable plate is connected with an elastic belt in a penetrating way, the side wall of the elastic belt is connected with a movable ring in a penetrating way, the middle part of the top side wall of the movable plate is connected with a compression spring in a penetrating way, the top end of the compression spring is connected with an elastic spring in a penetrating way, the bottom end of the elastic spring is connected with a rolling mechanism in a penetrating way, the bottom end of the springing mechanism is connected with a movable block through the side wall, the side wall of the movable block is connected with a pressing block through the side wall, the bottom end of the movable block is connected with a laminated body through the side wall, the side wall of the laminated body is connected with a pressing mechanism through the side wall, the top end of the pressing mechanism is movably connected with a rotating mechanism, the bottom through connection of the lamination body has a movable section of thick bamboo, and the bottom through connection of a movable section of thick bamboo has the stack mechanism, and the lateral wall department through connection of stack mechanism has the elasticity basin.

Preferably, the inside of folding the pressure mechanism includes the hose, and the lateral wall department swing joint of hose has the fan of folding, and the lateral wall department through connection of folding the fan has the slide bar, and the lateral wall department through connection of folding the fan has branch, and the lateral wall department through connection of branch has the filter screen, and the outer end through connection of filter screen has the movable sleeve, and the outer end lateral wall department sliding connection of filter screen has the slide, the lateral wall department through connection of slide bar has the soft colloid.

Preferably, the inside of pushing down the mechanism includes the connecting axle, and the bottom through connection of connecting axle has the pipeline, and the bottom fixedly connected with connecting pipe of pipeline, the inside bottom through and sliding connection of connecting pipe have the angle frame.

Preferably, the rolling mechanism comprises a movable ball inside, and a hemispherical shell is connected to the side wall of the movable ball in a penetrating manner.

Preferably, the rotating mechanism comprises a connecting ring, a movable rod is connected to the side wall of the connecting ring in a penetrating manner, and a sliding shaft is connected to the side wall of the connecting ring in a penetrating manner.

Preferably, the top end of the elastic band is connected to the side wall of the compression spring in a penetrating manner, and the compression spring can be dragged to shake in the swinging process of the side wall of the elastic band.

Preferably, the lateral wall of hemisphere shell roll and connect in the outer end lateral wall department of movable block, and the lateral wall of hemisphere shell can promote when rotatory to strike between the lateral wall of movable block and the lateral wall of pressing the piece.

Preferably, the soft colloid is connected to the side wall of the sliding plate in a sliding manner at one end far away from the sliding rod, and when the position of the sliding plate is changed, the soft colloid can be used for driving the sliding rod to move.

An ultrahigh current monitoring and processing system is divided into two modules of temperature sensing and sound wave transmission;

the temperature sensing also comprises input voltage and current signals, current transmission control, a temperature controller and an overload protector;

the sound wave transmission comprises sound wave vibration, dispersion, elimination, frequency division processing, segmented sampling, recording, data response, detection and analysis and a variable frequency inductor;

the switch power connection control also comprises an access current detector, a power supply is started, a circuit wire connection point is checked, a shell switch is touched, and the switch is switched on and off;

vibration of sound waves: after various external sounding bodies send out sound, sound waves are formed along with the propagation of substances in the air, and energy is formed along with the increase of the strength of the sound waves to influence the movement of the coil;

touching the shell switch: the sound waves form energy and can collide with the side wall of the shell, and when the shell shakes, the switch shakes to be opened;

switching on and off of the organ: when the lateral wall of the mechanism shakes, the opening and closing modes can be switched, so that gaps can exist at intervals;

dispersing and eliminating: when the switch at the gap is closed and opened, airflow is formed, and when sound waves pass through the gap, the sound waves are absorbed along with the closing of the shell, so that the sound waves are weakened;

switching on the current detector: electrical equipment such as winding coils of cables and the like can be interfered by the outside, and the risk of short circuit or skin breaking and electric leakage occurs, so that the condition needs to be detected in time to avoid causing the use safety of other equipment;

and (3) turning on a power supply: after the power supply is turned on, the connection point of the circuit needs to be determined to be firmly connected;

detection of a circuit wire connection point: whether the skin is broken or not and whether the looseness condition occurs at the connecting point or not are checked at the connecting point of the circuit wire;

input voltage, current signal: signals of current and voltage are input into the monitor, model data of each voltage and current are different, the same model is determined, and detection is convenient;

frequency division processing: separating the sound signals of different frequency bands into several groups, and respectively sending the signals to the corresponding frequency bands for processing;

segmented sampling and recording: the signal data collected in the front are sampled in several groups in a layering way, and are recorded and compared;

data response, detection analysis: comparing and analyzing the data, comparing tests, and adjusting equipment;

frequency conversion inductor: the frequency mode of the working power supply of the motor is changed to control the control equipment of the alternating current motor;

overload protector: when the intensity of the sound wave is too large, after one part of the sound wave is dissipated, the other part of the sound wave is weakened and then is transmitted downwards, and the overload protector can limit the intensity of the sound wave;

and (3) current transfer control: when the constant frequency switch is changed and the power of current output is increased, the size of the constant frequency needs to be changed, so that the output imbalance is avoided;

a temperature controller: the current continuously passes through the coil, and when the temperature can't give off fast, the in-process that the power grow diminishes can make the temperature rise, needs timely control to avoid temperature unbalance to cause the short circuit.

Connecting a current detector, starting a power supply to enable the current to be detected, simultaneously checking whether connection points between circuit wires are firmly connected, inputting voltage and current signals to enable the voltage and current signals to be the same as the current between adjacent equipment, controlling current transmission, detecting the temperature through a temperature controller, and limiting by an overload protector when the temperature exceeds the standard;

the shell switch can be touched when the sound wave vibrates, so that the switch is opened after being touched, the residual wave is subjected to frequency division processing through the circuit after dispersion and elimination, the frequency division processing is carried out for times, sampling and recording are carried out, the detected data result is analyzed, the detected sound wave is subjected to sectional type induction through the variable frequency inductor, and results with different frequencies are generated.

Advantageous effects

Compared with the prior art, the invention provides an ultrahigh current monitoring and processing system, which has the following beneficial effects:

1. this super high current monitoring processing system, lateral wall department through compression spring's lateral wall drive spring rotates, the bottom of spring drives the lateral wall rotation of movable ball, the rotatory roll of lateral wall department that the end lateral wall department of movable ball drove the hemisphere shell, the lateral wall department that the lateral wall of hemisphere shell is in the movable block takes the rotation, the lateral wall of movable block is promoted to and is close to with laminating each other between the lateral wall according to the briquetting, the movable block with scrape the pressure between the lateral wall according to the briquetting, make the sound wave disperse away from between the lateral wall of movable block and according to the briquetting, the strength of weakable sound wave, avoid the sound wave to cause the interference excessively.

2. This super high current monitoring processing system, top lateral wall through a movable cylinder can the lapse to the top lateral wall department of hose, expand around the outside bottom of hose, the lateral wall department that promotes the elasticity basin outwards struts, the top lateral wall circle footpath of elasticity basin is greater than the circle footpath size of bottom, consequently, the inside wall department of elasticity basin receives the extrusion of hose can glide down, the lateral wall of elasticity basin is open and closed state, when the lateral wall of elasticity basin is flexible inside and outside, the lateral wall that can laminate the hose reciprocates, it flows with higher speed to drive the air current, can be with the temperature discharge partly at top, avoid circuit temperature to rise the influence numerical value change and measure inaccurate formation error.

3. This super high current monitoring processing system, the lateral wall bottom of folding the fan is pushed when upwards sliding through the lateral wall of elasticity basin, the lateral wall of folding the fan upwards draws in, the lateral wall of slide upwards slides in the lateral wall department of filter screen, can push away the lateral wall of movable sleeve to the lateral wall department of filter screen, the lateral wall of movable sleeve is pushed away to the top, make the whole slight bottom to the movable sleeve of lateral wall of folding the fan support and be close to, the lateral wall of movable sleeve is slowly lifted up, can slow down the shake that the device appears at reciprocating process and the speed of influence current.

4. This super high current monitoring processing system, through analyzing two big modules to temperature and sound wave, detect it in a period after the coil at the electric current, the temperature just reaches certain height, weakens the temperature, can avoid burning out the circuit in later stage, and the lateral wall of sound wave is in the back that weakens, can appear the afterwave, carries out the detection in later stage and absorbs, avoids influencing the electric current speed.

Drawings

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

FIG. 2 is a schematic view showing the connection between the internal related structures of the pressing mechanism and the rotating mechanism according to the present invention;

FIG. 3 is a schematic view of the connection of the internal relevant structures of the laminating mechanism according to the present invention;

FIG. 4 is a schematic diagram of the ultra-high current monitoring and processing system of the present invention.

In the figure: 1. a spring mechanism; 111. a movable plate; 112. a compression spring; 113. a movable ring; 114. an elastic band; 115. a spring; 2. a movable block; 201. a pressing block; 3. a rolling mechanism; 311. a movable ball; 312. a hemispherical shell; 4. a laminate; 5. a rotating mechanism; 511. a connecting ring; 512. a movable rod; 513. a sliding shaft; 6. a pressing mechanism; 611. a connecting shaft; 612. a pipeline; 613. a connecting pipe; 614. a corner bracket; 7. a movable barrel; 8. a laminating mechanism; 811. a hose; 812. a slide bar; 813. folding the fan; 814. a strut; 815. filtering with a screen; 816. a movable sleeve; 817. a soft gel; 818. a slide plate; 9. an elastic basin.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. 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.

The first embodiment is as follows:

referring to fig. 1, an ultrahigh current monitoring and processing device includes an elastic mechanism 1, the elastic mechanism 1 includes a movable plate 111 therein, the top side wall of the movable plate 111 is connected with an elastic band 114 in a penetrating manner, the side wall of the elastic band 114 is connected with a movable ring 113 in a penetrating manner, the middle portion of the top side wall of the movable plate 111 is connected with a compression spring 112 in a penetrating manner, the top end of the compression spring 112 is connected with an elastic spring 115 in a penetrating manner, the bottom end of the elastic spring 115 is connected with a rolling mechanism 3 in a penetrating manner, the rolling mechanism 3 includes a movable ball 311 therein, the side wall of the movable ball 311 is connected with a hemispherical shell 312 in a penetrating manner, the bottom side wall of the elastic mechanism 1 is connected with a movable block 2 in a penetrating manner, the side wall of the movable block 2 is connected with a pressing block 201 in a penetrating manner, the bottom end of the movable block 2 is connected with a laminated body 4 in a penetrating manner, the side wall of the laminated body 4 is connected with a pressing mechanism 6 in a penetrating manner, the top end of the pressing mechanism 6 is movably connected with a rotating mechanism 5, the bottom end of the laminated body 4 is connected with a movable cylinder 7 in a penetrating way, the bottom end of the movable cylinder 7 is connected with a laminating mechanism 8 in a penetrating way, and the outer side wall of the laminating mechanism 8 is connected with an elastic basin 9 in a penetrating way.

The top end of the elastic band 114 is connected to the side wall of the compression spring 112 in a penetrating manner, and the compression spring 112 can be pulled to shake in the swinging process of the side wall of the elastic band 114.

The side wall of the hemispherical shell 312 is connected to the outer end side wall of the movable block 2 in a rolling manner, and when the side wall of the hemispherical shell 312 rotates, the side wall of the movable block 2 and the side wall of the pressing block 201 can be pushed to collide with each other.

The side wall of the compression spring 112 is in a spiral state, and has a slightly stretching process in the process of swinging by an external force, and the spiral state is close to the superposition in the pressing process, the side wall of the compression spring 112 expands to a certain extent, and the position of the side wall can be changed while the side wall of the compression spring 112 expands to a certain extent, so that the side wall of the compression spring 112 rotates, and the side wall of the compression spring 112 drives the side wall of the elastic spring 115 to rotate.

Example two:

referring to fig. 1-2, an ultrahigh current monitoring and processing device includes an elastic mechanism 1, the elastic mechanism 1 includes a movable plate 111 therein, the top wall of the movable plate 111 is connected with an elastic band 114 in a penetrating manner, the side wall of the elastic band 114 is connected with a movable ring 113 in a penetrating manner, the middle portion of the top wall of the movable plate 111 is connected with a compression spring 112 in a penetrating manner, the top end of the compression spring 112 is connected with an elastic spring 115 in a penetrating manner, the bottom end of the elastic spring 115 is connected with a rolling mechanism 3 in a penetrating manner, the bottom end of the elastic mechanism 1 is connected with a movable block 2 in a penetrating manner, the side wall of the movable block 2 is connected with a pressing block 201 in a penetrating manner, the bottom end of the movable block 2 is connected with a laminated body 4 in a penetrating manner, the side wall of the laminated body 4 is connected with a pressing mechanism 6 in a penetrating manner, the internal connecting shaft 611 of the pressing mechanism 6 includes a laminated body 612, the bottom end of the connecting shaft 611 is connected with a pipe 612, the inside bottom of connecting pipe 613 runs through and sliding connection has the corner brace 614, the top swing joint of pushing down mechanism 6 has slewing mechanism 5, slewing mechanism 5's inside includes clamping ring 511, clamping ring 511's lateral wall department through connection has movable rod 512, clamping ring 511's lateral wall department through connection has sliding shaft 513, the bottom through connection of lamination body 4 has a movable section of thick bamboo 7, the bottom through connection of movable section of thick bamboo 7 has pressure stack mechanism 8, pressure stack mechanism 8's inside includes hose 811, pressure stack mechanism 8's lateral wall department through connection has elasticity basin 9.

The connecting shaft 611 rotates to drive the side wall of the pipe 612 to rotate, the side wall of the pipe 612 is twisted downward to press the gas inside the connecting pipe 613 downward to the corner bracket 614, the inner side wall of the bottom end of the connecting pipe 613 is opened by the gas pressure, the bottom end of the corner bracket 614 is inserted into the inner bottom end of the connecting pipe 613, and the whole side wall of the pressing mechanism 6 scrapes the side wall of the laminated body 4.

Example three:

referring to fig. 1 and 3, an ultrahigh current monitoring and processing device includes an elastic mechanism 1, the elastic mechanism 1 includes a movable plate 111 therein, the top wall of the movable plate 111 is connected with an elastic band 114 in a penetrating manner, the side wall of the elastic band 114 is connected with a movable ring 113 in a penetrating manner, the middle portion of the top wall of the movable plate 111 is connected with a compression spring 112 in a penetrating manner, the top end of the compression spring 112 is connected with an elastic spring 115 in a penetrating manner, the bottom end of the elastic spring 115 is connected with a rolling mechanism 3 in a penetrating manner, the bottom end of the elastic mechanism 1 is connected with a movable block 2 in a penetrating manner, the side wall of the movable block 2 is connected with a pressing block 201 in a penetrating manner, the bottom end of the movable block 2 is connected with a laminated body 4 in a penetrating manner, the side wall of the laminated body 4 is connected with a pressing mechanism 6 in a penetrating manner, the top end of the pressing mechanism 6 is movably connected with a rotating mechanism 5, the bottom end of the laminated body 4 is connected with a movable barrel 7 in a penetrating manner, and the bottom end of the movable barrel 7 is connected with a laminating mechanism 8 in a penetrating manner, the inside of the laminating mechanism 8 comprises a hose 811, a fan folding 813 is movably connected to the side wall of the hose 811, a sliding rod 812 is connected to the side wall of the fan folding 813 in a penetrating manner, a supporting rod 814 is connected to the side wall of the fan folding 813 in a penetrating manner, a filter screen 815 is connected to the side wall of the supporting rod 814 in a penetrating manner, a movable sleeve 816 is connected to the outer end of the filter screen 815 in a penetrating manner, a sliding plate 818 is connected to the outer end side wall of the filter screen 815 in a sliding manner, a soft rubber body 817 is connected to the side wall of the sliding rod 812 in a penetrating manner, and an elastic basin 9 is connected to the outer side wall of the laminating mechanism 8 in a penetrating manner.

One end of the soft rubber 817, which is far away from the sliding rod 812, is slidably connected to the side wall of the sliding plate 818, and when the position of the sliding plate 818 is changed, the soft rubber 817 can drive the sliding rod 812 to move.

The side wall of the sliding plate 818 slides upwards at the outer side wall of the filter screen 815, so that the side wall of the movable sleeve 816 can be pushed to the side wall of the filter screen 815, the side wall of the movable sleeve 816 is pushed to the top end, the whole side wall of the folding fan 813 slightly supports and approaches the bottom end of the movable cylinder 7, the side wall of the movable cylinder 7 is slowly lifted, and shaking of the device in the up-and-down moving process can be relieved.

Example four:

referring to fig. 1-3, an ultrahigh current monitoring and processing device includes an elastic mechanism 1, the elastic mechanism 1 includes a movable plate 111 therein, the top wall of the movable plate 111 is connected with an elastic band 114 in a penetrating manner, the side wall of the elastic band 114 is connected with a movable ring 113 in a penetrating manner, the middle portion of the top wall of the movable plate 111 is connected with a compression spring 112 in a penetrating manner, the top end of the compression spring 112 is connected with an elastic spring 115 in a penetrating manner, the bottom end of the elastic spring 115 is connected with a rolling mechanism 3 in a penetrating manner, the rolling mechanism 3 includes a movable ball 311 therein, the side wall of the movable ball 311 is connected with a hemispherical shell 312 in a penetrating manner, the bottom end side wall of the elastic mechanism 1 is connected with a movable block 2 in a penetrating manner, the side wall of the movable block 2 is connected with a pressing block 201 in a penetrating manner, the bottom end of the movable block 2 is connected with a laminated body 4 in a penetrating manner, the side wall of the laminated body 4 is connected with a pressing mechanism 6 in a penetrating manner, the pressing mechanism 6 includes a connecting shaft 611 therein, the bottom end of the connecting shaft 611 is connected with a pipeline 612 in a penetrating manner, the bottom end of the pipeline 612 is fixedly connected with a connecting pipe 613, the bottom end inside the connecting pipe 613 is connected with an angle bracket 614 in a penetrating manner and in a sliding manner, the top end of the pressing mechanism 6 is movably connected with a rotating mechanism 5, the inside of the rotating mechanism 5 comprises a connecting ring 511, the side wall of the connecting ring 511 is connected with a movable rod 512 in a penetrating manner, the side wall of the connecting ring 511 is connected with a sliding shaft 513 in a penetrating manner, the bottom end of the laminated body 4 is connected with a movable cylinder 7 in a penetrating manner, the bottom end of the movable cylinder 7 is connected with a laminating mechanism 8 in a penetrating manner, the inside of the laminating mechanism 8 comprises a hose 811, the side wall of the hose 811 is movably connected with a laminated fan 813 in a penetrating manner, the side wall of the laminated fan 813 is connected with a sliding rod 812 in a penetrating manner, the side wall of the laminated fan 813 is connected with a supporting rod 814 in a penetrating manner, the side wall of the supporting rod 814 is connected in a penetrating manner, the outer end of the filtering net 815 is connected with a movable sleeve 816 in a penetrating manner, and a sliding plate 818 is connected with the outer end of the filtering net, the side wall of the sliding rod 812 is connected with a soft colloid 817 in a penetrating way, and the outer side wall of the laminating mechanism 8 is connected with an elastic basin 9 in a penetrating way.

The top end of the elastic band 114 is connected to the side wall of the compression spring 112 in a penetrating manner, and the compression spring 112 can be pulled to shake in the swinging process of the side wall of the elastic band 114.

The side wall of the hemispherical shell 312 is connected to the outer end side wall of the movable block 2 in a rolling manner, and when the side wall of the hemispherical shell 312 rotates, the side wall of the movable block 2 and the side wall of the pressing block 201 can be pushed to collide with each other.

One end of the soft rubber 817, which is far away from the sliding rod 812, is slidably connected to the side wall of the sliding plate 818, and when the position of the sliding plate 818 is changed, the soft rubber 817 can drive the sliding rod 812 to move.

Example five:

as shown in fig. 4, an ultra-high current monitoring and processing system is divided into two modules, namely a temperature sensing module and a sound wave transmission module;

the temperature sensing also comprises input voltage and current signals, current transmission control, a temperature controller and an overload protector;

the sound wave transmission comprises sound wave vibration, dispersion, elimination, frequency division processing, segmented sampling, recording, data response, detection and analysis and a variable frequency inductor;

the switch power connection control also comprises an access current detector, a power supply is started, a circuit wire connection point is checked, a shell switch is touched, and the switch is switched on and off;

vibration of sound waves: after various external sounding bodies send out sound, sound waves are formed along with the propagation of substances in the air, and energy is formed along with the increase of the strength of the sound waves to influence the movement of the coil;

touching the shell switch: the sound waves form energy and can collide with the side wall of the shell, and when the shell shakes, the switch shakes to be opened;

switching on and off of the organ: when the lateral wall of the mechanism shakes, the opening and closing modes can be switched, so that gaps can exist at intervals;

dispersing and eliminating: when the switch at the gap is closed and opened, airflow is formed, and when sound waves pass through the gap, the sound waves are absorbed along with the closing of the shell, so that the sound waves are weakened;

switching on the current detector: electrical equipment such as winding coils of cables and the like can be interfered by the outside, and the risk of short circuit or skin breaking and electric leakage occurs, so that the condition needs to be detected in time to avoid causing the use safety of other equipment;

and (3) turning on a power supply: after the power supply is turned on, the connection point of the circuit needs to be determined to be firmly connected;

detection of a circuit wire connection point: whether the skin is broken or not and whether the looseness condition occurs at the connecting point or not are checked at the connecting point of the circuit wire;

input voltage, current signal: signals of current and voltage are input into the monitor, model data of each voltage and current are different, the same model is determined, and detection is convenient;

frequency division processing: separating the sound signals of different frequency bands into several groups, and respectively sending the signals to the corresponding frequency bands for processing;

segmented sampling and recording: the signal data collected in the front are sampled in several groups in a layering way, and are recorded and compared;

data response, detection analysis: comparing and analyzing the data, comparing tests, and adjusting equipment;

frequency conversion inductor: the frequency mode of the working power supply of the motor is changed to control the control equipment of the alternating current motor;

overload protector: when the intensity of the sound wave is too large, after one part of the sound wave is dissipated, the other part of the sound wave is weakened and then is transmitted downwards, and the overload protector can limit the intensity of the sound wave;

and (3) current transfer control: when the constant frequency switch is changed and the power of current output is increased, the size of the constant frequency needs to be changed, so that the output imbalance is avoided;

a temperature controller: the current continuously passes through the coil, and when the temperature can't give off fast, the in-process that the power grow diminishes can make the temperature rise, needs timely control to avoid temperature unbalance to cause the short circuit.

Connecting a current detector, starting a power supply to enable the current to be detected, simultaneously checking whether connection points between circuit wires are firmly connected, inputting voltage and current signals to enable the voltage and current signals to be the same as the current between adjacent equipment, controlling current transmission, detecting the temperature through a temperature controller, and limiting by an overload protector when the temperature exceeds the standard;

the shell switch can be touched when the sound wave vibrates, so that the switch is opened after being touched, the residual wave is subjected to frequency division processing through the circuit after dispersion and elimination, the frequency division processing is carried out for times, sampling and recording are carried out, the detected data result is analyzed, the detected sound wave is subjected to sectional type induction through the variable frequency inductor, and results with different frequencies are generated.

The working principle is as follows: when in use, as shown in fig. 1, after the top sidewall of the movable plate 111 is pressed, the top sidewall of the movable plate 111 can swing up and down, the top sidewall of the movable plate 111 and the sidewall of the movable ring 113 can knock, the sidewall of the movable ring 113 can rotate, the sidewall of the movable ring 113 drives the sidewall of the elastic band 114 to swing, the sidewall of the elastic band 114 swings up and down under the pulling force, the top end of the elastic band 114 pulls the sidewall of the compression spring 112, the sidewall of the compression spring 112 swings left and right under the force of the compression spring 112, the sidewall of the compression spring 112 is in a spiral state, and there is a slight stretching process in the swinging process under the external force, and the spiral state approaches to overlap in the pressing process, the sidewall of the compression spring 112 expands the range to a certain extent, and the sidewall of the compression spring 112 expands in a large range and simultaneously changes the position of the sidewall, the side wall of the compression spring 112 rotates, the side wall of the compression spring 112 drives the side wall of the elastic spring 115 to rotate, the bottom end of the elastic spring 115 drives the side wall of the movable ball 311 to rotate, the bottom side wall of the movable ball 311 drives the side wall of the hemispherical shell 312 to rotate, the side wall of the hemispherical shell 312 is located on the outer side wall of the movable block 2 and is driven to rotate, the side wall of the movable block 2 is pushed to be close to the side wall of the pressing block 201 in a mutually attached mode, the movable block 2 and the side wall of the pressing block 201 are scraped and pressed to form a new gap and collision, so that sound waves are dispersed from the side wall of the movable block 2 and the side wall of the pressing block 201, and the strength of the sound waves can be weakened;

as shown in fig. 1-2, when the side wall of the pressing block 201 is scraped back and forth at the inner side wall of the pressing mechanism 6, the outer end of the side wall of the pressing block 201 will scrape the side wall of the pressing mechanism 6, the inside of the pressing mechanism 6 includes a connecting shaft 611, the connecting shaft 611 will drive the side wall of the pipe 612 to rotate when rotating, the side wall of the pipe 612 will twist downward to press the gas inside the connecting pipe 613 downward to the corner bracket 614, the inner side wall at the bottom end of the connecting pipe 613 is opened by the gas pressure, the bottom end of the corner bracket 614 is inserted into the inner bottom end of the connecting pipe 613, at this time, the whole side wall of the pressing mechanism 6 will scrape the side wall of the laminated body 4, the overlapping pattern at the side wall of the laminated body 4 will be downward, at the same time, the side wall of the laminated body 4 is folded downward, the bottom end of the laminated body 4 is turned over to the inner side wall, the bottom end of the movable tube 7 will be pressed to the top side wall of the bottom after the bottom is turned over, the side wall of the top end of the movable cylinder 7 can slide downwards to the top side wall of the hose 811, the bottom end of the hose 811 expands outwards and peripherally to push the side wall of the elastic basin 9 to expand outwards, the circle diameter of the side wall of the top end of the elastic basin 9 is larger than the circle diameter of the bottom end, so that the inner side wall of the elastic basin 9 can slide downwards under the extrusion of the hose 811, the side wall of the elastic basin 9 is in an open and closed state, when the side wall of the elastic basin 9 stretches inwards and outwards, the side wall of the elastic basin 811 can be attached to move up and down to drive airflow to flow in an accelerated manner, the temperature at the top can be discharged partially, and the influence of the temperature rise of a circuit on the numerical value change is avoided;

as shown in fig. 1 and 3, as the side wall of the elastic basin 9 slides upwards, the bottom end of the side wall of the folding fan 813 is pushed, the side wall of the folding fan 813 is folded upwards, the side wall of the sliding plate 818 slides upwards at the outer side wall of the filter screen 815, and the side wall of the movable sleeve 816 can be pushed to the side wall of the filter screen 815, and as shown in fig. 1 and 3, the side wall of the movable sleeve 816 is pushed to the top end, so that the whole side wall of the folding fan 813 slightly approaches the bottom end of the movable cylinder 7, and the side wall of the movable cylinder 7 is lifted slowly, which can slow down the shaking of the device during the up-and-down movement.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. The utility model provides an ultrahigh current monitoring processing apparatus, includes snapping mechanism (1), its characterized in that: the elastic mechanism (1) comprises a movable plate (111) inside, an elastic band (114) is connected to the top side wall of the movable plate (111) in a penetrating manner, a movable ring (113) is connected to the side wall of the elastic band (114) in a penetrating manner, a compression spring (112) is connected to the middle part of the top side wall of the movable plate (111) in a penetrating manner, an elastic spring (115) is connected to the top end of the compression spring (112) in a penetrating manner, a rolling mechanism (3) is connected to the bottom end of the elastic spring (115) in a penetrating manner, a movable block (2) is connected to the bottom side wall of the elastic mechanism (1) in a penetrating manner, a pressing block (201) is connected to the side wall of the movable block (2) in a penetrating manner, a laminated body (4) is connected to the bottom end of the movable block (2) in a penetrating manner, a pressing mechanism (6) is connected to the side wall of the laminated body (4) in a penetrating manner, a rotating mechanism (5) is movably connected to the top end of the pressing mechanism (6), and a movable barrel (7) is connected to the bottom end of the laminated body (4) in a penetrating manner, the bottom end of the movable cylinder (7) is connected with a laminating mechanism (8) in a penetrating way, and the outer side wall of the laminating mechanism (8) is connected with an elastic basin (9) in a penetrating way.

2. The ultrahigh current monitoring and processing device according to claim 1, wherein: fold the inside of pressing mechanism (8) and include hose (811), the lateral wall department swing joint of hose (811) has folding fan (813), the lateral wall department through connection of folding fan (813) has slide bar (812), the lateral wall department through connection of folding fan (813) has branch (814), the lateral wall department through connection of branch (814) has filter screen (815), the outer end through connection of filter screen (815) has movable sleeve (816), the outer end lateral wall department sliding connection of filter screen (815) has slide plate (818), the lateral wall department through connection of slide bar (812) has soft colloid (817).

3. The ultrahigh current monitoring and processing device according to claim 1, wherein: the inside of mechanism (6) pushes down includes connecting axle (611), and the bottom through connection of connecting axle (611) has pipeline (612), and the bottom fixedly connected with connecting pipe (613) of pipeline (612), the inside bottom through and the sliding connection of connecting pipe (613) have corner brace (614).

4. The ultrahigh current monitoring and processing device according to claim 1, wherein: the rolling mechanism (3) comprises a movable ball (311), and a hemispherical shell (312) is connected to the side wall of the movable ball (311) in a penetrating manner.

5. The ultrahigh current monitoring and processing device according to claim 3, wherein: the inside of slewing mechanism (5) includes connecting ring (511), and the lateral wall department through connection of connecting ring (511) has movable rod (512), and the lateral wall department through connection of connecting ring (511) has slide shaft (513).

6. The ultrahigh current monitoring and processing device according to claim 1, wherein: the top end of the elastic band (114) is connected with the side wall of the compression spring (112) in a penetrating way.

7. The ultrahigh current monitoring and processing device according to claim 1, wherein: the side wall of the hemispherical shell (312) is connected to the side wall of the outer end of the movable block (2) in a rolling manner.

8. The ultrahigh current monitoring and processing device according to claim 2, wherein: the end of the soft colloid (817) far away from the sliding rod (812) is connected with the side wall of the sliding plate (818) in a sliding way.

9. The ultra-high current monitoring and processing system of claim 1, wherein: the system is divided into three modules of temperature sensing, sound wave transmission and switch power connection control;

the temperature sensing also comprises input voltage and current signals, current transmission control, a temperature controller and an overload protector;

the sound wave transmission comprises sound wave vibration, dispersion, elimination, frequency division processing, segmented sampling, recording, data response, detection and analysis and a variable frequency inductor;

the switch power connection control also comprises an access current detector, a power supply is started, a circuit wire connection point is checked, a shell switch is touched, and the switch is switched on and off;

vibration of sound waves: after various external sounding bodies send out sound, sound waves are formed along with the propagation of substances in the air, and energy is formed along with the increase of the strength of the sound waves to influence the movement of the coil;

touching the shell switch: the sound waves form energy and can collide with the side wall of the shell, and when the shell shakes, the switch shakes to be opened;

switching on and off of the organ: when the lateral wall of the mechanism shakes, the opening and closing modes can be switched, so that gaps can exist at intervals;

dispersing and eliminating: when the switch at the gap is closed and opened, airflow is formed, and when sound waves pass through the gap, the sound waves are absorbed along with the closing of the shell, so that the sound waves are weakened;

switching on the current detector: electrical equipment such as winding coils of cables and the like can be interfered by the outside, and the risk of short circuit or skin breaking and electric leakage occurs, so that the condition needs to be detected in time to avoid causing the use safety of other equipment;

and (3) turning on a power supply: after the power supply is turned on, the connection point of the circuit needs to be determined to be firmly connected;

detection of a circuit wire connection point: whether the skin is broken or not and whether the looseness condition occurs at the connecting point or not are checked at the connecting point of the circuit wire;

input voltage, current signal: signals of current and voltage are input into the monitor, model data of each voltage and current are different, the same model is determined, and detection is convenient;

frequency division processing: separating the sound signals of different frequency bands into several groups, and respectively sending the signals to the corresponding frequency bands for processing;

segmented sampling and recording: the signal data collected in the front are sampled in several groups in a layering way, and are recorded and compared;

data response, detection analysis: comparing and analyzing the data, comparing tests, and adjusting equipment;

frequency conversion inductor: the frequency mode of the working power supply of the motor is changed to control the control equipment of the alternating current motor;

overload protector: when the intensity of the sound wave is too large, after one part of the sound wave is dissipated, the other part of the sound wave is weakened and then is transmitted downwards, and the overload protector can limit the intensity of the sound wave;

and (3) current transfer control: when the constant frequency switch is changed and the power of current output is increased, the size of the constant frequency needs to be changed, so that the output imbalance is avoided;

a temperature controller: the current continuously passes through the coil, and when the temperature can't give off fast, the in-process that the power grow diminishes can make the temperature rise, needs timely control to avoid temperature unbalance to cause the short circuit.

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