CN116087819A

CN116087819A - Power supply current monitoring device for foil producing machine

Info

Publication number: CN116087819A
Application number: CN202310011276.9A
Authority: CN
Inventors: 杨锋; 陈艺锋; 王斌; 陈赞锋; 任明明; 刘辉; 邵管民; 吴伟峰; 李乐乐; 荆鸿飞; 王肖展
Original assignee: Lingbao Baoxin Electronic Technology Co Ltd
Current assignee: Lingbao Baoxin Electronic Technology Co Ltd
Priority date: 2023-01-05
Filing date: 2023-01-05
Publication date: 2023-05-09
Anticipated expiration: 2043-01-05
Also published as: CN116087819B

Abstract

The invention discloses a power supply current monitoring device of a foil forming machine, which relates to the technical field of foil forming machine accessories and comprises an electrolytic tank, a high-frequency power supply, a conductive bar and a current monitoring component, wherein the current monitoring component is arranged on the outer side of the conductive bar, and a plurality of groups of conductive bars and current monitoring components are arranged. According to the invention, the conductive bars and the current monitoring components are arranged, so that current transmission between the high-frequency power supply and the electrolytic tank can be realized, the current monitoring components are arranged on the outer side of the conductive bars in a surrounding manner, the conductive bars can monitor the current in the current transmission process, and the monitoring information is transmitted to the data display device on the outer side of the electrolytic tank, so that current monitoring in the foil producing work process is realized, the current monitoring components, the conductive bars and the high-frequency power supply are in one-to-one correspondence, and therefore, simultaneous monitoring of multiple paths of power supplies can be realized, and further, the high-frequency power supply supplied by a foil producing machine can be regulated in time by workers.

Description

Power supply current monitoring device for foil producing machine

Technical Field

The invention relates to the technical field of accessories of foil producing machines, in particular to a power supply current monitoring device of a foil producing machine.

Background

The electrolytic copper foil is obtained by supplying electricity to an electrolytic cell of the foil producing machine and electrodepositing the electrolytic copper foil on the surface of a cathode roller through electrochemical reaction, the electrolytic copper foil production process has extremely high precision, extremely harsh requirements standard is arranged on the thickness and the surface density of the copper foil, the size of the running current directly determines the specification and the unit weight standard of the copper foil, therefore, the process stability of the electrolytic copper foil directly depends on whether the running current of the foil producing machine is stable, the on-line current monitoring of the foil producing machine is an essential important work in the electrolytic copper foil production process, the precision requirement is extremely high, the on-line current monitoring of the current foil producing machine is realized by setting the running total current through a touch panel of the foil producing machine, then scientifically distributing the total current to Hall corresponding to four power supply cabinets through a control main board, feeding back the actual running current to the control main board through Hall corresponding to each power supply cabinet, the on-line monitoring instrument can realize on-line detection, the indoor temperature and humidity can be known through a temperature detection device, and the functions are more diversified.

However, the current monitoring device for monitoring the electrolytic copper foil has certain defects, is easy to be interfered by magnetic force or electric power, and because the electrolytic tank needs to be powered by a plurality of groups of battery modules and the battery modules need to be continuously powered, the current monitoring device needs to be in a state of long-term working, once the current monitoring device breaks down, the current monitoring device needs to be disassembled and maintained, and the current detection assembly device is not convenient to disassemble and maintain due to the adoption of a fixed mounting mode. Therefore, it is necessary to invent a power supply current monitoring device for foil production to solve the above problems.

Disclosure of Invention

The invention aims to provide a power supply current monitoring device for a foil forming machine, which is used for solving the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a raw foil power supply power current monitoring device, includes electrolysis trough, high frequency power supply, conducting bar and current monitoring component, the current monitoring component sets up in the outside of conducting bar, conducting bar and current monitoring component all are provided with the multiunit, multiunit conducting bar and current monitoring component all set up between electrolysis trough and high frequency power supply;

the electric conduction bar comprises an electric conduction plate, one end of the electric conduction plate is provided with an electric conduction copper sheet, the other end of the electric conduction plate is provided with a line concentration plate, a cavity is formed in the electric conduction plate, a plurality of extension pipes are fixedly arranged in the cavity, a regulating motor is arranged in each extension pipe, and a plurality of radiating fins with inclined structures are rotatably arranged in each extension pipe;

the current monitoring assembly comprises a lower shell and an upper shell, the conducting plate is located between the lower shell and the upper shell, an LED light source is fixedly arranged at one side bottom end of the lower shell, an analyzer is fixedly arranged at one end, close to the LED light source, of the lower surface of the lower shell, and a polarizer is fixedly arranged at one end of the LED light source.

Preferably, one end of the conductive copper sheet is fixedly arranged at the output end of the high-frequency power supply, the line concentration plate is of a T-shaped structure, and one end of the line concentration plate is fixedly arranged at the input end of the electrolytic tank;

the utility model discloses a motor vehicle, including lower casing, upper casing, inlet tube, rubber circle, vent, rubber circle, inlet tube, lower casing and the one end that is close to each other of upper casing are all fixed to be provided with the inlet tube, and the inlet tube sets up to semi-circular structure, the one end of inlet tube is fixed to be provided with semi-circular structure's rubber circle, be provided with a plurality of vents on the rubber circle.

Preferably, the analyzer and the polarizer are both arranged in the lower shell, one end of the inner side wall of the lower shell, which is far away from the analyzer, and the top ends of the two sides of the upper shell are both provided with reflecting plates, the reflecting plates are of an inclined structure, and the inclination angle of the reflecting plates is 45 degrees.

Preferably, two adjacent radiating fins are distributed in a staggered mode, a plurality of radiating grooves are formed in two sides of the cavity in a penetrating mode, and the radiating grooves correspond to the extension tubes.

Preferably, the middle part of one end that the inside of lower casing and last casing kept away from each other all is provided with the light pipe, the both ends of light pipe all are provided with lens, the outside of light pipe is provided with the mounting panel, be provided with the mounting bracket between light pipe and the mounting panel.

Preferably, the middle parts of the ends of the lower shell and the upper shell, which are far away from each other, are respectively provided with a square groove in a penetrating way, and the middle parts of the inner walls of the two sides of the square grooves are provided with positioning grooves;

the utility model discloses a socket, including the mounting panel, the slot has all been seted up at the both ends middle part of mounting panel, the inside of slot is provided with the inserted block, and the lower surface one end of inserted block sets up to the inclined plane, the one end of inserted block passes through the tank bottom swing joint of spring and slot, the fixed lug that is provided with in upper surface one end of inserted block, logical groove has been seted up in the top inner wall of slot, and lug and logical groove through connection.

Preferably, the fixed frame that is provided with is all fixed on the both sides top of inferior valve, the both sides bottom of going up the casing is all fixed to be provided with the fixture block, the bottom mounting of fixture block is provided with the elastic block, the lateral wall bottom of elastic block sets up to the inclined plane, and elastic block and fixed frame through connection.

Preferably, a signal processor is arranged below the lower shell, a photoelectric sensor is arranged on the signal processor, the photoelectric sensor is positioned between the analyzer and the signal processor, a data display instrument is arranged on the outer side wall of the electrolytic cell, and the signal output end of the signal processor is connected with the signal input end of the data display instrument.

Preferably, the output end of the regulating motor is connected with the rotating shaft of the radiating fin, the outer end of the regulating motor is wrapped with a rubber insulating sleeve, and the regulating motor is electrically connected with the signal processor.

Preferably, the two ends of the conductive plate are provided with wire pressing heads, and the conductive copper sheet and the wire collecting plate are connected with the wire pressing heads through bolts.

The invention has the technical effects and advantages that:

1. according to the invention, the current monitoring in the working process of the foil producing machine is realized by arranging the conducting bars and the current monitoring components, the conducting bars and the high-frequency power supply are in one-to-one correspondence, so that the simultaneous monitoring of multiple paths of power supplies can be realized, and the high-frequency power supply supplied by the foil producing machine can be adjusted in time by a worker conveniently;

2. according to the invention, the current monitoring assembly is arranged, and the current monitoring assembly monitors the current on the conducting bar by detecting the polarization amplitude of light, so that the external disordered electromagnetic interference can be effectively avoided, the monitoring precision can be ensured, and when the current monitoring assembly fails, the upper shell and the lower shell can be separated to realize quick disassembly, thereby facilitating the later maintenance;

3. through setting up the cavity in the inside of current conducting plate, extension tube, regulation and control motor and the cooperation of radiating fin in the cavity can promote and control the radiating effect of current conducting plate to can avoid on the current conducting plate long-term through the electric current and the too high polarization of heat to light influences, further promoted the monitoring accuracy of device.

Drawings

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

FIG. 2 is a schematic diagram showing the positional relationship between the current monitoring device and the conductive strip according to the present invention.

Fig. 3 is a schematic structural diagram of a current monitoring component according to the present invention.

Fig. 4 is a schematic diagram of a conductive bar structure according to the present invention.

Fig. 5 is a schematic cross-sectional view of the conductive plate structure of the present invention.

Fig. 6 is an enlarged schematic view of the structure a in fig. 5 according to the present invention.

Fig. 7 is a schematic view of the lower housing structure of the present invention.

Fig. 8 is a schematic view of the upper housing structure of the present invention.

FIG. 9 is a schematic cross-sectional view of a current monitoring assembly according to the present invention.

FIG. 10 is a cross-sectional view of a light pipe structure of the present invention.

FIG. 11 is a schematic view of the positional relationship between the light pipe and the mounting plate according to the present invention.

Fig. 12 is a schematic view of a light reflection path according to the present invention.

Fig. 13 is a schematic diagram of the positional relationship between a motor and a heat sink fin according to the present invention.

In the figure: 1. an electrolytic cell; 2. a high frequency power supply; 3. a conductive bar; 4. a current monitoring assembly; 301. a conductive plate; 302. wire pressing heads; 303. a conductive copper sheet; 304. a line concentration board; 305. a cavity; 306. an extension tube; 307. a heat radiation fin; 308. a heat sink; 309. regulating and controlling a motor; 401. a lower housing; 402. an upper housing; 403. a wire inlet pipe; 404. a rubber ring; 405. an LED light source; 406. an analyzer; 407. a polarizer; 408. a light reflecting plate; 409. a signal processor; 410. a light pipe; 411. a lens; 412. a mounting plate; 413. a mounting frame; 414. a square groove; 415. a positioning groove; 416. a slot; 417. inserting blocks; 418. a bump; 419. a through groove; 420. a fixed frame; 421. a clamping block; 422. an elastic block.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

The invention provides a power supply current monitoring device for a foil forming machine, which is shown in fig. 1 to 12, and comprises an electrolytic tank 1, a high-frequency power supply 2, a conductive bar 3 and a current monitoring component 4, wherein the current monitoring component 4 is arranged on the outer side of the conductive bar 3, the conductive bar 3 and the current monitoring component 4 are respectively provided with a plurality of groups, and the conductive bar 3 and the current monitoring component 4 are respectively arranged between the electrolytic tank 1 and the high-frequency power supply 2.

Twelve high-frequency power supplies 2, conducting bars 3 and current monitoring components 4 are arranged, three high-frequency power supplies 2, conducting bars 3 and current monitoring components 4 are arranged into one group, and the twelve high-frequency power supplies 2, conducting bars 3 and current monitoring components 4 are divided into four groups to supply power for the electrolytic tank 1.

The conductive bar 3 comprises a conductive plate 301, one end of the conductive plate 301 is provided with a conductive copper sheet 303, and the other end of the conductive plate 301 is provided with a line concentration plate 304.

Specifically, the two ends of the conductive plate 301 are provided with wire pressing heads 302, and the conductive copper sheet 303 and the wire collecting plate 304 are connected with the wire pressing heads 302 through bolts.

More specifically, one end of the conductive copper sheet 303 is fixedly disposed at the output end of the high-frequency power supply 2, the line concentration plate 304 is configured in a T-shaped structure, and one end of the line concentration plate 304 is fixedly disposed at the input end of the electrolytic cell 1.

And, cavity 305 is provided in conductive plate 301, and the inside of cavity 305 is fixed to be provided with a plurality of extension pipes 306, and the inside of extension pipe 306 rotates and is provided with a plurality of heat dissipation fins 307 of sloping structure, and two adjacent heat dissipation fins 307 are dislocation distribution, and a plurality of heat dissipation grooves 308 have all been run through to the both sides of cavity 305, and heat dissipation groove 308 corresponds with extension pipe 306.

In addition, the heat generated by the current passing through the conductive plate 301 can be transmitted to the extension pipe 306, the extension pipe 306 can transmit the heat to the radiating fins 307, and because the two ends of the extension pipe 306 are corresponding to the radiating grooves 308, the outside air can enter the extension pipe 306 through the radiating grooves 308, and the air can take away the heat on the radiating fins 307, so that the heat of the conductive plate 301 can be dissipated, and further the influence of the too high heat on the polarization of light caused by the long-term current passing through the conductive plate 301 can be avoided, and the monitoring precision of the device is further improved.

The current monitoring assembly 4 includes a lower housing 401 and an upper housing 402, with the conductive plate 301 located between the lower housing 401 and the upper housing 402.

Specifically, the lower casing 401 and the upper casing 402 are all fixedly provided with the inlet tube 403 near one end each other, and the inlet tube 403 is set to semi-circular structure, and the one end of inlet tube 403 is fixedly provided with semi-circular structure's rubber circle 404, and is provided with a plurality of vents on the rubber circle 404, through the assistance of vent, makes the heat that the intermediate part produced of current conducting plate 301 also can discharge smoothly, has guaranteed current conducting plate 301 radiating effect.

More specifically, an LED light source 405 is fixedly disposed at the bottom end of one side of the lower housing 401, an analyzer 406 is fixedly disposed at one end of the lower surface of the lower housing 401 close to the LED light source 405, a polarizer 407 is fixedly disposed at one end of the LED light source 405, the analyzer 406 and the polarizer 407 are disposed inside the lower housing 401, a reflector 408 is disposed at one end of the inner side wall of the lower housing 401 far from the analyzer 406 and at the top ends of two sides of the upper housing 402, the reflector 408 is in an inclined structure, and the inclination angle of the reflector 408 is 45 °.

And, the LED light source 405 works to emit light, the light enters the lower shell 401 after passing through the polarizer 407, the light moves to the reflector 408 in the lower shell 401, and the reflector 408 is set to be of a 45-degree inclined structure, so that the light is reflected on the surface of the reflector 408, and the light enters the analyzer 406 after being reflected by a plurality of reflectors 408.

Meanwhile, a signal processor 409 is arranged below the lower shell 401, a photoelectric sensor is arranged on the signal processor 409, the photoelectric sensor is located between the analyzer 406 and the signal processor 409, a data display instrument is arranged on the outer side wall of the electrolytic cell 1, and the signal output end of the signal processor 409 is connected with the signal input end of the data display instrument.

When the device is used, twelve high-frequency power supplies 2 are divided into four groups, and the power is supplied to the electrolytic tank 1 through the conductive bars 3, in the process, the current monitoring assembly 4 can respectively monitor the current on the twelve conductive bars 3, and monitor data are transmitted to a data display instrument on the electrolytic tank 1 in real time, so that the stable transmission of the current during the operation of the foil producing machine is ensured.

When the current monitoring component 4 monitors the current on the conducting bar 3, the LED light source 405 works to emit light, the light enters the lower shell 401 after passing through the polarizer 407, the light moves to the reflecting plate 408 in the lower shell 401, the reflecting plate 408 is of a 45-degree inclined structure, the light reflects on the surface of the reflecting plate 408, the light enters the analyzer 406 after being reflected by the reflecting plates 408, in the process, the current on the high-frequency power supply 2 enters the electrolytic tank 1 through the conducting plates 301, the conducting plates 301 generate a magnetic field due to the passing of the current, the magnetic field can influence the light which is being reflected in the lower shell 401, so that the light is polarized, the polarization amplitude of the light is detected by the cooperation of the photoelectric sensor on the analyzer 406 and the signal processor 409, the detection data are transmitted to the signal processor 409, the signal processor 409 can process the polarization data of the light to obtain the current passing through the conducting plates 301, the signal processor 409 transmits the detection result to the data display instrument, and the data display instrument can realize the display of the current data on the plurality of groups of conducting plates 301, so that the monitoring precision of equipment is improved.

In the process of transmitting current, the heat generated by the current passing through the conductive plate 301 can be transmitted to the extension pipe 306 by the conductive plate 301, and the extension pipe 306 can transmit the heat to the radiating fins 307, because the two ends of the extension pipe 306 are corresponding to the radiating grooves 308, the outside air can enter the extension pipe 306 through the radiating grooves 308, and then the air can take away the heat on the radiating fins 307, so that the heat of the conductive plate 301 can be radiated, and further the influence of the heat too high to the polarization of light caused by the long-term current passing through the conductive plate 301 can be avoided, and the monitoring precision of the device is further improved.

Example 2

Based on the above embodiment 1, although the device improves the accuracy of current monitoring on the conductive plate 301, at the same time, light is attenuated by multiple refraction, which affects the monitoring accuracy, and the conductive bar 3 or the current monitoring component 4 is damaged and needs to be replaced conveniently, so the following embodiments are proposed based on the above technical problems.

As shown in fig. 1 to 12, in the power supply current monitoring device for a foil machine, a light pipe 410 is disposed in the middle of one end of the lower housing 401 and the upper housing 402, which are far from each other, lenses 411 are disposed at both ends of the light pipe 410, and the two lenses 411 are respectively disposed as a convex lens and a concave lens, which are matched, so that the converging effect of light is improved, and thus, the light is prevented from being attenuated due to multiple refraction, the monitoring precision is improved, a mounting plate 412 is disposed at the outer side of the light pipe 410, and a mounting frame 413 is disposed between the light pipe 410 and the mounting plate 412.

Meanwhile, the middle parts of the ends of the lower shell 401 and the upper shell 402, which are far away from each other, are respectively provided with a square groove 414 in a penetrating way, and the middle parts of the inner walls of the two sides of the square groove 414 are provided with positioning grooves 415.

Further, slots 416 are formed in the middle portions of two ends of the mounting plate 412, inserting blocks 417 are arranged in the slots 416, one end of the lower surface of each inserting block 417 is provided with an inclined surface, one end of each inserting block 417 is movably connected with the bottom of each slot 416 through a spring, a lug 418 is fixedly arranged at one end of the upper surface of each inserting block 417, through slots 419 are formed in the inner walls of the top ends of the slots 416 in a penetrating mode, and the lug 418 is connected with the through slots 419 in a penetrating mode.

Further, the fixing frames 420 are fixedly arranged at the top ends of the two sides of the lower housing 401, the clamping blocks 421 are fixedly arranged at the bottom ends of the two sides of the upper housing 402, the elastic blocks 422 are fixedly arranged at the bottom ends of the clamping blocks 421, the bottom ends of the outer side walls of the elastic blocks 422 are inclined surfaces, and the elastic blocks 422 are connected with the fixing frames 420 in a penetrating manner.

When the device is used, light can enter the light pipe 410 in the process of internal reflection of the current monitoring component 4, as the lenses 411 are arranged at the two ends of the light pipe 410, and the two lenses 411 are respectively arranged as the convex lens and the concave lens which are matched, the converging effect of the light is improved, so that the light is prevented from being attenuated due to multiple refraction, and the monitoring precision is improved.

When the conductive bar 3 or the current monitoring component 4 needs to be detached and replaced, the elastic block 422 is pulled first, so that the elastic block 422 deforms until the bottom end of the elastic block 422 moves into the fixed frame 420, at the moment, the limit of the fixed frame 420 to the elastic block 422 is released, at the moment, the upper shell 402 is pulled upwards, and the upper shell 402 and the lower shell 401 can be separated, so that the conductive bar 3 or the current monitoring component 4 can be detached and replaced.

When the light pipe 410 and the lens 411 are disassembled and maintained, the protruding block 418 is pulled, so that the protruding block 418 drives the inserting block 417 to move, the inserting block 417 slides in the inserting groove 416 until one end of the inserting block 417 is separated from the positioning groove 415, at this time, the limit between the mounting plate 412 and the square groove 414 is released, and the mounting plate 412 can be taken out from the square groove 414, so that the light pipe 410 can be disassembled.

Example 3

Although the accuracy of current monitoring on the conductive plate 301 is improved based on the above embodiment 2, the following embodiments are proposed based on the above technical problems, in which the conductive plate 301 cannot dynamically adjust the heat dissipation according to the current in the conductive plate 301 when the conductive plate 301 dissipates heat through the plurality of heat dissipation fins 307, and the polarization amplitude of the light is affected by the temperature variation around the path of the light when the light is refracted.

As shown in fig. 1 to 13, in the power supply current monitoring device for a foil generator, an output end of a regulating motor 309 is connected with a rotating shaft of a radiating fin 307, a rubber insulation sleeve is wrapped at an outer end of the regulating motor 309, the regulating motor 309 is electrically connected with a signal processor 409, the regulating motor 309 can control a deflection angle of the radiating fin 307, and meanwhile, the regulating motor 309 is controlled by the signal processor 409.

When the device is used, when the current monitoring component 4 monitors the current on the conductive strip 3, the LED light source 405 works to emit light, the light enters the lower shell 401 after passing through the polarizer 407, the light moves to the reflector 408 in the lower shell 401, the reflector 408 is of a 45-degree inclined structure, so that the light reflects on the surface of the reflector 408, the light enters the analyzer 406 after being reflected by the reflectors 408, in the process, the current on the high-frequency power supply 2 enters the electrolytic tank 1 through the conductive plate 301, the conductive plate 301 generates a magnetic field due to the passing of the current, the magnetic field can influence the light which is being reflected in the lower shell 401, so that the light is polarized, the polarization amplitude of the light is detected by the analyzer 406 and the photoelectric sensor on the signal processor 409 in a matched mode, the detection data is transmitted to the signal processor 409, the signal processor 409 can process the polarization data of the light, so as to obtain the current passing through the conductive plate 301, the signal processor 409 transmits the detection result to the data display instrument, the data on the plurality of groups of conductive plates 301 can be realized, the current data can be transmitted to the data display instrument, the conductive plates 306 can be extended to the heat sink 306 and the heat pipe 306 can be extended to the heat pipe 306 because the heat is transmitted to the heat pipe 306 and the heat pipe 306 is extended to the heat pipe 306.

When the current passing through the conductive plate 301 increases, the magnetic field generated by the current increases, so that the polarization amplitude of the light increases, and the heat generation of the conductive plate 301 increases, the control motor 309 is controlled by the signal processor 409 to operate, the deflection angle of the radiating fins 307 is increased by the operation of the control motor 309, so that the channel in the middle of the extension pipe 306 is opened, the circulation of air in the extension pipe 306 is smoother, the radiating effect of the radiating fins 307 is further improved, the conductive plate 301 maintains a stable temperature environment, the influence effect of the temperature on the current in the conductive plate 301 is reduced, and meanwhile, the refraction of the light is performed at a constant temperature, so that the light is more stable when being refracted.

When the current passing through the conductive plate 301 is reduced, the magnetic field generated by the current is weakened, so that the polarization amplitude of light is reduced, and the heat generation of the conductive plate 301 is reduced, the regulating motor 309 is operated under the control of the signal processor 409, the deflection angle of the radiating fins 307 is reduced by the operation of the regulating motor 309, so that the channel in the middle of the extension pipe 306 is reduced, the circulation of air in the extension pipe 306 is blocked, the radiating effect of the radiating fins 307 is reduced, the conductive plate 301 is kept in a stable temperature environment, the influence effect of the temperature on the current in the conductive plate 301 is reduced, the refraction of the light is simultaneously carried out at a constant temperature, the polarization amplitude of the light is more stable when the light is refracted, the dynamic regulation of the radiation of the conductive plate 301 is realized under the interaction of the signal processor 409 and the regulating motor 309, and the electrolysis of the foil generator is more stable.

And when the regulating motor 309 operates, the operation of the regulating motor 309 is not influenced by the current in the conductive plate 301 by the action of the rubber insulating sleeve at the outer end of the regulating motor 309, so that the heat dissipation control of the conductive plate 301 is more accurate.

Finally, it should be noted that: the foregoing description is only illustrative of the preferred embodiments of the present invention, and although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements or changes may be made without departing from the spirit and principles of the present invention.

Claims

1. The utility model provides a raw foil power supply power current monitoring device which is characterized in that, including electrolysis trough (1), high frequency power (2), conducting bar (3) and current monitoring component (4), current monitoring component (4) set up in the outside of conducting bar (3), conducting bar (3) and current monitoring component (4) all are provided with the multiunit, multiunit conducting bar (3) and current monitoring component (4) all set up between electrolysis trough (1) and high frequency power (2);

the electric conduction bar (3) comprises an electric conduction plate (301), one end of the electric conduction plate (301) is provided with an electric conduction copper sheet (303), the other end of the electric conduction plate (301) is provided with a line concentration plate (304), a cavity (305) is formed in the electric conduction plate (301), a plurality of extension pipes (306) are fixedly arranged in the cavity (305), a regulating motor (309) is arranged in the extension pipes (306), and a plurality of radiating fins (307) with inclined structures are rotatably arranged in the extension pipes (306);

the current monitoring assembly (4) comprises a lower shell (401) and an upper shell (402), the conducting plate (301) is located between the lower shell (401) and the upper shell (402), an LED light source (405) is fixedly arranged at one side bottom end of the lower shell (401), an analyzer (406) is fixedly arranged at one end, close to the LED light source (405), of the lower surface of the lower shell (401), and a polarizer (407) is fixedly arranged at one end of the LED light source (405).

2. A foil-forming machine power supply current monitoring device as claimed in claim 1, characterized in that: one end of the conductive copper sheet (303) is fixedly arranged at the output end of the high-frequency power supply (2), the line concentration plate (304) is of a T-shaped structure, one end of the line concentration plate (304) is fixedly arranged at the input end of the electrolytic tank (1), and a plurality of radiating fins (307) of inclined structures are rotatably arranged in the extension tube (306);

the utility model discloses a rubber ring, including lower casing (401) and last casing (402), lower casing (401) and last casing (402) are all fixed be provided with inlet tube (403) near one end each other, and inlet tube (403) set up to semi-circular structure, the fixed rubber circle (404) that are provided with semi-circular structure of one end of inlet tube (403), be provided with a plurality of vents on rubber circle (404).

3. A foil-forming machine power supply current monitoring device as claimed in claim 2, characterized in that: the polarization analyzer is characterized in that the polarization analyzer (406) and the polarizer (407) are arranged in the lower shell (401), one end of the inner side wall of the lower shell (401) away from the polarization analyzer (406) and the top ends of two sides of the upper shell (402) are respectively provided with a reflecting plate (408), the reflecting plates (408) are of an inclined structure, and the inclination angle of the reflecting plates (408) is 45 degrees.

4. A foil-forming machine power current monitoring device as claimed in claim 3, characterized in that: two adjacent radiating fins (307) are distributed in a staggered mode, a plurality of radiating grooves (308) are formed in the two sides of the cavity (305) in a penetrating mode, and the radiating grooves (308) correspond to the extending pipes (306).

5. A foil-forming machine power current monitoring device as claimed in claim 3, characterized in that: the light guide is characterized in that light pipes (410) are arranged in the middle of one ends, far away from each other, of the inner parts of the lower shell (401) and the upper shell (402), lenses (411) are arranged at two ends of the light pipes (410), mounting plates (412) are arranged on the outer sides of the light pipes (410), and mounting frames (413) are arranged between the light pipes (410) and the mounting plates (412).

6. A foil-forming machine power supply current monitoring device as defined in claim 5, wherein: square grooves (414) are formed in the middle of one end, far away from each other, of the lower shell (401) and the upper shell (402) in a penetrating manner, and positioning grooves (415) are formed in the middle of the inner walls of two sides of the square grooves (414);

slot (416) have all been seted up at the both ends middle part of mounting panel (412), the inside of slot (416) is provided with inserted block (417), and the lower surface one end of inserted block (417) sets up to the inclined plane, the tank bottom swing joint of spring and slot (416) is passed through to the one end of inserted block (417), the fixed lug (418) that is provided with in upper surface one end of inserted block (417), logical groove (419) have been seted up in the top inner wall of slot (416), and lug (418) and logical groove (419) through connection.

7. A foil-forming machine power supply current monitoring device as claimed in claim 1, characterized in that: the utility model discloses a fixed frame (420) is fixed on both sides top of inferior valve body (401), the both sides bottom of last casing (402) is fixed and is provided with fixture block (421) all, the bottom mounting of fixture block (421) is provided with elastic block (422), the lateral wall bottom of elastic block (422) sets up to the inclined plane, and elastic block (422) and fixed frame (420) through connection.

8. The power supply current monitoring device for a foil generator of claim 4, wherein: the electrolytic cell is characterized in that a signal processor (409) is arranged below the lower shell (401), a photoelectric sensor is arranged on the signal processor (409), the photoelectric sensor is located between the analyzer (406) and the signal processor (409), a data display instrument is arranged on the outer side wall of the electrolytic cell (1), and a signal output end of the signal processor (409) is connected with a signal input end of the data display instrument.

9. The power supply current monitoring device for a foil generator of claim 8, wherein: the output end of the regulating motor (309) is connected with a rotating shaft of the radiating fin (307), the outer end of the regulating motor (309) is wrapped with a rubber insulating sleeve, and the regulating motor (309) is electrically connected with the signal processor (409).

10. A foil-forming machine power supply current monitoring device as claimed in claim 1, characterized in that: both ends of the conducting plate (301) are provided with wire pressing heads (302), and the conducting copper sheets (303) and the wire collecting plates (304) are connected with the wire pressing heads (302) through bolts.