CN109586523B - Carbon powder receiving device for large and medium-sized wound motor - Google Patents

Abstract

The invention discloses a carbon powder receiving device for a large and medium-sized wound motor, which structurally comprises a carbon powder interface groove, a carbon powder centralizing body, an adjusting sliding block, a carbon powder receiving machine body, an installation fixing block, a carbon powder filtering, guiding and flow controlling device, a fixing clamping seat, a carbon powder storage box and a leading-out notch, wherein the carbon powder interface groove is welded on the inner side of the carbon powder centralizing body in an embedding mode, the lower surface of the carbon powder centralizing body is connected with the upper surface of the carbon powder receiving machine body in an electric welding mode, and the adjusting sliding block is installed on the front surface of the carbon powder receiving machine body in an embedding mode and is. The invention detects the carbon powder drainage flow velocity, calculates the flow and reduces the flowing sectional area when the carbon powder is fully stored, relieves the large carbon powder flow, stores the carbon powder in the carbon powder storage box, prevents the carbon powder from being blocked by compression or leaking due to large quantity during the drainage, and simultaneously absorbs and filters impurities during the drainage to avoid the carbon powder from being influenced by the use and breaking down.

Description

Carbon powder receiving device for large and medium-sized wound motor

Technical Field

The invention relates to the field of motors, in particular to a carbon powder connecting device for a large and medium winding motor.

Background

The wound-rotor motor is one asynchronous motor, and rotates under the guide of current, and the carbon powder makes the rotor of the motor connected with current through the carbon brush to play a role. However, the conventional carbon powder receiving device of the wound motor has the following defects:

1. the carbon powder of the carbon powder receiving device is fully stored at any time in storage, and the flow of the carbon powder drainage is large when the storage box is cleaned, so that the inflowing carbon powder enters the storage box and influences the carbon powder in the storage box, and the carbon powder particles are small and difficult to see when flying, and are difficult to collect again and easy to leak.

2. The carbon powder is easy to discharge doped impurities together during collection, and the doped carbon powder is difficult to use due to the influence of the impurities.

Disclosure of Invention

The invention aims to provide a carbon powder receiving device for a large and medium-sized wound motor, aiming at solving the problems that the carbon powder of the carbon powder receiving device in the prior art is fully stored at any time during storage, the inflow carbon powder enters a storage box and influences the carbon powder in the storage box due to large flow of the drainage of the carbon powder when the storage box is cleaned, the carbon powder particles are small and difficult to see during fluttering, the secondary collection is difficult and easy to leak, the carbon powder is easy to discharge doped impurities together during collection, and the carbon powder doped with the impurities is difficult to use due to the influence of the impurities during use.

In order to achieve the purpose, the invention is realized by the following technical scheme:

a carbon powder receiving device for large and medium-sized wound motors structurally comprises a carbon powder interface groove, a carbon powder centralizing body, an adjusting sliding block, a carbon powder receiving machine body, an installing and fixing block, a carbon powder filtering and guiding flow control device, a fixing clamping seat, a carbon powder storage box and a leading-out notch, wherein the carbon powder interface groove is welded on the inner side of the carbon powder centralizing body in an embedding mode, the lower surface of the carbon powder centralizing body is connected with the upper surface of the carbon powder receiving machine body in an electric welding mode, the adjusting sliding block is installed on the front surface of the carbon powder receiving machine body in an embedding mode and is movably connected with the front surface of the carbon powder receiving machine body, the right surface of the installing and fixing block is connected with and electrically connected with the left surface of the carbon powder receiving machine body in an electric welding mode, the carbon powder filtering and guiding flow control device is welded on the, the carbon powder filtering, guiding and flow controlling device is arranged on the upper surface of a fixed clamping seat in a welding mode, a carbon powder storage box is arranged on the lower surface of the fixed clamping seat and connected in an embedding mode, a leading-out notch is formed in the right surface of the carbon powder storage box, the carbon powder filtering, guiding and flow controlling device comprises a carbon powder quality removing and filtering mechanism, a micro-pressure moving mechanism, a micro-pressure electromagnetic starting mechanism, an electric rotating transmission mechanism, a carbon powder extracting and switching mechanism, a flow speed detection and transmission mechanism, a flow path adjusting mechanism and a flow control device shell, the carbon powder quality removing and filtering mechanism is welded on the upper surface of the flow control device shell in an embedding mode, the micro-pressure moving mechanism is arranged below the carbon powder quality removing and filtering mechanism, the micro-pressure electromagnetic starting mechanism is arranged on the lower surface of the inner side of the micro-pressure moving mechanism and connected in an electric welding mode, and the left side of, the micro-pressure electromagnetic starting mechanism is electrically connected with the electric rotating transmission mechanism, the electric rotating transmission mechanism is positioned below the carbon powder extraction and switching mechanism and is movably connected, the right side of the carbon powder extraction and switching mechanism is connected with the left side of the flow rate detection and transmission mechanism in an electric welding mode, and the right side of the flow rate detection and transmission mechanism is provided with a flow path adjusting mechanism and is electrically connected.

As a further scheme of the invention, the carbon powder quality-removing and filtering mechanism comprises an active filtering tank, a suction attachment pipe, a sundry separation groove, a sundry pipe, a sundry storage box, a cleaning bottom box and a carbon powder flowing branch port, wherein the suction attachment pipe is arranged on the inner side of the active filtering tank and connected in an adhesion mode, the sundry separation groove is arranged in the center of the inner side of the suction attachment pipe, the sundry pipe is arranged on the left surface of the sundry storage box in an electric welding mode, the left surface of the sundry storage box is connected with the right surface of the active filtering tank in an electric welding mode, the cleaning bottom box is arranged on the inner side of the sundry storage box and connected in an attaching mode, and the carbon powder flowing branch port is arranged on the lower surface of the active filtering tank.

As a further scheme of the present invention, the micro-pressure moving mechanism includes a fixed side plate, a sealing block, a micro-pressure plate, and a spring guide rod, the inner side of the fixed side plate is provided with the spring guide rod and is connected by electric welding, the right surface of the sealing block is connected with the left surface of the micro-pressure plate by means of fitting, the micro-pressure plate is installed on the left surface of the fixed side plate by means of embedding, the spring guide rod penetrates through the upper and lower surfaces of the micro-pressure plate, the axis of the spring guide rod is perpendicular to the lower surface of the micro-pressure plate, and the right surface of the fixed side plate is provided with a carbon powder extraction switching mechanism.

As a further scheme of the invention, the micro-pressure electromagnetic starting mechanism comprises a sliding block, a micro-pressure drag hook, a positioning spring, a pulling rope, a limiting wheel driving plate, a micro-electromagnetic block, an interface electrifying module and a starting switching module, the lower surface of the sliding block is connected with the top end of the micro-pressure drag hook in an electric welding mode, the top of the positioning spring is provided with the micro-pressure drag hook, the left end of the pulling rope is arranged at the right end part of the micro-pressure drag hook in an embedded mode, the pulling rope is arranged at the outer side of the limiting wheel in a fitting mode, the other end of the pulling rope is connected with the upper surface of the driving plate in an electric welding mode, the upper surface of the driving plate is parallel to the lower surface of the micro-electromagnetic block, the micro-electromagnetic block is arranged on the lower surface of the interface power-on module in a welding mode and is electrically connected, the left surface of the starting switching module is connected and electrically connected with the right surface of the interface power-on module in a fitting mode.

As a further aspect of the present invention, the electric rotating transmission mechanism includes a protection control module, an electromagnetic field control module, a central rotor, a rotating connection flange, a transmission belt, and a rotating disc, wherein the right surface of the protection control module is provided with the electromagnetic field control module and is electrically connected to the electromagnetic field control module, the central rotor is provided on the right surface of the electromagnetic field control module and is connected in an embedded manner, the left side of the rotating connection flange is connected to the right side of the central rotor in an electric welding manner, and the axis of the rotating connection flange is installed on the same horizontal line, the inner side of the transmission belt is attached to the outer side of the rotating connection flange and is in transmission connection with the outer side of the rotating connection flange, and.

As a further aspect of the present invention, the carbon powder extraction switching mechanism includes a center pin, a switching pumping body, an extraction pipe head cover, a connection pipe, a connection buckle, and an actuation pipe, wherein the extraction pipe head cover is installed inside the fixed side plate in an embedded manner, the center pin is welded to the front surface of the switching pumping body in an embedded manner, the extraction pipe head cover is installed on the left side of the connection pipe in an electric welding manner, the connection buckle is installed on the front surface of the switching pumping body in an electric welding manner, and the left side of the actuation pipe is attached to the inside of the connection buckle in an embedded manner.

As a further aspect of the present invention, the flow velocity detection transmission mechanism includes a rotation wheel, a positioning shaft, a protective housing, an electrical lead, a flow detection module, a data line, a terminal connection transmission module, and a feedback control module, wherein the positioning shaft penetrates through the rotation wheel and is in clearance fit, the rotation wheel is mounted at the lower end of the protective housing in an embedded manner, the electrical lead is mounted at the top end of the protective housing and is electrically connected, the data line is disposed at the left side of the flow detection module, the data line is mounted in the terminal connection transmission module in an embedded manner and is electrically connected, and the left surface of the feedback control module is connected with the right surface of the terminal connection transmission module in an electric welding manner.

As a further aspect of the present invention, the flow path adjusting mechanism includes an overload prevention module, a valve body of the air pump, an airflow tube, an air pressure moving plate, a movable buffer block, a return spring, and a central flow tube, the overload prevention module is installed on the left surface of the valve body of the air pump and electrically connected to the left surface of the valve body of the air pump, the airflow tube is installed on the lower surface of the valve body of the air pump in an embedded manner, the lower surface of the air pressure moving plate is connected to the upper surface of the movable buffer block in a welded manner, the return spring is installed on the lower surface of the air pressure moving plate, and the top end.

Advantageous effects of the invention

The invention relates to a carbon powder receiving device for a large and medium-sized wound motor, wherein the motor is started to operate, carbon powder enters through a carbon powder interface groove, the carbon powder drives impurities to enter an active filter box through discharging, the carbon powder continuously moves downwards unaffected at a suction attachment pipe, the impurities are adsorbed at the pipe and are stored at the inner side, when the suction attachment pipe is fully adsorbed, the impurities move to a sundry pipe through a sundry separation groove and are deposited and stored in a sundry storage box, then the impurities are discharged through a cleaning bottom box, the carbon powder at the other side moves to a micro-pressure plate and generates downward pressing force through accumulation, when the micro-pressure plate slightly moves downwards, a sliding block pushes a micro-pressure drag hook, the other end of a pull rope pulls a driving plate upwards, the driving plate slightly moves upwards and is strengthened by magnetic adsorption of a micro-electric magnetic block and continuously moves upwards to be attached to the micro-electric magnetic block, and an interface electrifying module completes connection to start a switching module to control the, the electric current of electromagnetic control field module lets central rotor rotatory, swivelling joint flange is also rotatory simultaneously, let the rolling disc clockwise rotation through the drive belt, the carbon dust receives suction and gets into the connecting pipe by extracting the tube head cover, take out the internal pressure boost promotion of pressure in the switching and follow the pipe inflow of motivating, drive rotatoryly through the swiveling wheel, calculate by flow detection module through the electric lead, it is convenient for look over to transmit to the internal roll-out of terminal connection transmission module, start the pneumatic pump valve body through feedback control module when the carbon dust is deposited to capacity, atmospheric pressure is exerted pressure to the atmospheric pressure movable plate through the air current pipe, it lets the flow path reduction of central flow tube to remove the buffer block downstream.

The carbon powder receiving device for the large and medium-sized wound motor detects the current drainage flow velocity of carbon powder, calculates the flow, reduces the flowing sectional area when the carbon powder is fully stored, relieves the large flow of the carbon powder, stores the carbon powder in the carbon powder storage box, prevents the carbon powder from being leaked due to compression blockage or large discharge amount, and simultaneously absorbs and filters impurities during discharge to avoid the carbon powder from being influenced and having faults due to use of the carbon powder.

Drawings

Other features, objects and advantages of the invention will become more apparent from a reading of the detailed description of non-limiting embodiments with reference to the attached drawings.

In the drawings:

FIG. 1 is a schematic structural diagram of a toner carrying device for a large and medium-sized wound motor according to the present invention.

FIG. 2 is a plan view of a carbon powder filtering, guiding and flow controlling device according to the present invention.

FIG. 3 is a detailed structural diagram of a carbon powder filtering, guiding and flow controlling device according to the present invention.

FIG. 4 is a detailed structural diagram of a carbon powder mass-removing and filtering mechanism according to the present invention.

Fig. 5 is a detailed structural schematic diagram of a micro-pressure electromagnetic starting mechanism of the present invention.

Fig. 6 is a detailed structural schematic diagram of a flow rate detection transmission mechanism according to the present invention.

Fig. 7 is a detailed structural diagram of a flow path adjusting mechanism according to the present invention.

In the figure: carbon powder interface tank-1, carbon powder centralizing body-2, regulating slide block-3, carbon powder receiving machine body-4, mounting fixed block-5, carbon powder filtering guiding flow control device-6, fixed clamping seat-7, carbon powder storage box-8, leading-out notch-9, carbon powder quality-removing filtering mechanism-61, micropressure moving mechanism-62, micropressure electromagnetic starting mechanism-63, electric rotating transmission mechanism-64, carbon powder extracting and switching mechanism-65, flow rate detection and transmission mechanism-66, flow path regulating mechanism-67, flow control device shell-68, active filtering box-611, suction attachment pipe-612, impurity separation tank-613, impurity pipe-614, impurity storage box-615, cleaning bottom box-616, carbon powder flow branch-617, etc, A fixed side plate-621, a sealing block-622, a micro-pressure plate-623, a spring guide rod-624, a sliding block-631, a micro-pressure draw hook-632, a positioning spring-633, a drawing rope-634, a limiting wheel-635 actuating plate-636, a micro-electromagnetic block-637, an interface energizing module-638, a starting switching module-639, a protection control module-641, an electromagnetic control field module-642, a central rotor-643, a rotary connecting flange-644, a driving belt-645, a rotary disc-646, a central pin-651, a switching pumping body-652, a pumping pipe head cover-653, a connecting pipe-654, a connecting buckle-655, a pumping pipe-656, a rotary wheel-661, a positioning shaft-662, a protective shell-663, an electric lead-664, a flow detection module-665, a sliding block-631, a micro-pressure, A data line-666, a terminal connection transmission module-667, a feedback control module-668, an overload prevention module-671, a pneumatic pump valve body-672, an air flow pipe-673, a pneumatic moving plate-674, a moving buffer block-675, a return spring-676 and a central flow pipe-677.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

As shown in fig. 1-7, the present invention provides a technical solution of a carbon powder receiving device for large and medium-sized wound motors:

a carbon powder receiving device for large and medium-sized wound motors comprises a carbon powder interface groove 1, a carbon powder centralized body 2, an adjusting sliding block 3, a carbon powder receiving machine body 4, an installation fixing block 5, a carbon powder filtering, guiding and flow controlling device 6, a fixing clamping seat 7, a carbon powder storage box 8 and a leading-out notch 9, wherein the carbon powder interface groove 1 is welded on the inner side of the carbon powder centralized body 2 in an embedding mode, the lower surface of the carbon powder centralized body 2 is connected with the upper surface of the carbon powder receiving machine body 4 in an electric welding mode, the adjusting sliding block 3 is installed on the front surface of the carbon powder receiving machine body 4 in an embedding mode and is movably connected, the right surface of the installation fixing block 5 is connected with and electrically connected with the left surface of the carbon powder receiving machine body 4 in an electric welding mode, the carbon powder filtering, guiding and flow controlling device 6 is welded on the inner side of the carbon powder receiving machine body 4 in an embedding mode, and the upper, the carbon powder filtering, guiding and flow controlling device 6 is installed on the upper surface of a fixed card seat 7 in a welding mode, a carbon powder storage box 8 is arranged on the lower surface of the fixed card seat 7 and connected in an embedding mode, a lead-out notch 9 is arranged on the right surface of the carbon powder storage box 8, the carbon powder filtering, guiding and flow controlling device 6 comprises a carbon powder quality removing and filtering mechanism 61, a micro-pressure moving mechanism 62, a micro-pressure electromagnetic starting mechanism 63, an electric rotating mechanism 64, a carbon powder extraction and switching mechanism 65, a flow rate detection and transmission mechanism 66, a flow path adjusting mechanism 67 and a flow controlling device shell 68, the carbon powder quality removing and filtering mechanism 61 is welded on the upper surface of the flow controlling device shell 68 in an embedding mode, the micro-pressure moving mechanism 62 is arranged below the carbon powder quality removing and filtering mechanism 61, the micro-pressure electromagnetic starting mechanism 63 is installed on the inner lower surface of the micro-pressure moving, the left side of the electric rotating transmission mechanism 64 is mounted on the right surface of the micro-pressure moving mechanism 62 in a fitting manner, the micro-pressure electromagnetic starting mechanism 63 is electrically connected with the electric rotating transmission mechanism 64, the electric rotating transmission mechanism 64 is positioned below and movably connected with the carbon powder extraction and transfer mechanism 65, the right side of the carbon powder extraction and transfer mechanism 65 is connected with the left side of the flow rate detection and transmission mechanism 66 in an electric welding manner, the right side of the flow rate detection and transmission mechanism 66 is provided with the flow path adjusting mechanism 67 and is electrically connected with the flow path adjusting mechanism, the carbon powder de-mass filtering mechanism 61 comprises an active filtering box 611, a suction attachment pipe 612, a sundries separation groove 613, a sundries pipe 614, a sundries storage box 615, a cleaning bottom box 616 and a carbon powder flowing branch port 617, the suction attachment pipe 612 is arranged on the inner side of the active filtering box 611 and is connected in an adhesive manner, the sundries separation groove 613 is mounted in the center, the sundries storage box 614 is arranged on the left surface of the sundries storage box 615 in an electric welding mode, the left surface of the sundries storage box 615 is connected with the right surface of the active filter box 611 in an electric welding mode, the cleaning bottom box 616 is arranged on the inner side of the sundries storage box 615 and connected in an attaching mode, the lower surface of the active filter box 611 is provided with a carbon powder flowing branch opening 617, the micro-pressure moving mechanism 62 comprises a fixed side plate 621, a sealing block 622, a micro-pressure plate 623 and a spring guide rod 624, the inner side of the fixed side plate 621 is provided with the spring guide rod 624 and connected in an electric welding mode, the right surface of the sealing block 622 is connected with the left surface of the micro-pressure plate 623 in an attaching mode, the micro-pressure plate 623 is arranged on the left surface of the fixed side plate 621 in an embedding mode, the spring guide rod 624 penetrates through the upper and lower surfaces of the micro-pressure plate 623, and the axial center, the right surface of the fixed side plate 621 is provided with a carbon powder extraction switching mechanism 65, the micro-pressure electromagnetic starting mechanism 63 comprises a sliding block 631, a micro-pressure drag hook 632, a positioning spring 633, a pulling rope 634, a limiting wheel 635 actuating plate 636, a micro-electric block 637, an interface electrifying module 638 and a starting switching module 639, the lower surface of the sliding block 631 is connected with the top end of the micro-pressure drag hook 632 in an electric welding manner, the top of the positioning spring 633 is provided with the micro-pressure drag hook 632, the left end of the pulling rope 634 is installed at the right end of the micro-pressure drag hook 632 in an embedded manner, the pulling rope 634 is installed at the outer side of the limiting wheel 635 in a fitting manner, the other end of the pulling rope 634 is connected with the upper surface of the actuating plate 636 in an electric welding manner, the upper surface of the pulling plate 636 is parallel to the lower surface of the micro-electric block 637, the micro-electric block 637 is installed at the lower surface of the interface, the left surface of the starting adapter module 639 is connected and electrically connected with the right surface of the interface power-on module 638 in a fitting manner, the electric power transmission mechanism 64 includes a protection control module 641, an electromagnetic field control module 642, a central rotor 643, a rotary connecting flange 644, a transmission belt 645 and a rotary disc 646, the right surface of the protection control module 641 is provided with the electromagnetic field control module 642 and is electrically connected, the central rotor 643 is arranged on the right surface of the electromagnetic field control module 642 and is connected in an embedding manner, the left side of the rotary connecting flange 644 is connected with the right side of the central rotor 643 in an electric welding manner and is axially installed on the same horizontal line, the inner side of the transmission belt 645 is connected and is driven with the outer side of the rotary connecting flange 644, the rotary disc 646 is connected with the transmission belt 645 in a fitting manner, and the carbon powder extraction adapter mechanism 65 includes a central pin 651, The adapter pumping body 652, the extraction tube head cover 653, the connection tube 654, the connection buckle 655, the actuation tube 656, the extraction tube head cover 653 is installed on the inner side of the fixed side plate 621 by means of embedding, the center pin 651 is welded on the front surface of the adapter pumping body 652 by means of embedding, the extraction tube head cover 653 is installed on the left side of the connection tube 654 by means of electric welding, the connection buckle 655 is installed on the front surface of the adapter pumping body 652 by means of electric welding, the actuation tube 656 left side is attached to the inner side of the connection buckle 655 by means of embedding, the flow rate detection transmission mechanism 66 comprises a rotating wheel, a positioning shaft 662, a protective shell 663, an electric lead 664, a flow detection module 665, a data line 666, a terminal connection transmission module 667, a feedback control module 668, the positioning shaft 662 runs through the rotating wheel 661 and adopts clearance fit, the rotating wheel is installed on the lower end of the 663 by means of embedding, the electrical lead 664 is installed at the top end of the protective shell 663 and is electrically connected, the left side of the flow detection module 665 is provided with a data line 666, the data line 666 is embedded in and electrically connected with the terminal connection transmission module 667, the left surface of the feedback control module 668 is electrically welded with the right surface of the terminal connection transmission module 667, the flow path adjusting mechanism 67 comprises an overload prevention module 671, a pneumatic pump valve body 672, an air flow pipe 673, a pneumatic moving plate 674, a moving buffer block 675, a return spring 676 and a central flow pipe 677, the overload prevention module 671 is installed at the left surface of the pneumatic pump valve body 672 and is electrically connected, the air flow pipe 673 is installed at the lower surface of the pneumatic pump valve body 672 in an embedded manner, the lower surface of the pneumatic moving plate 674 is connected with the upper surface of the moving buffer block 675 in a welded manner, the return spring 676 is installed at the lower surface of the pneumatic, the top end of the central flow pipe 677 is provided with a movable buffer block 675.

The invention relates to a carbon powder receiving device for a large and medium-sized wound motor, which has the working principle that: when the motor is started to operate, carbon powder enters through the carbon powder interface groove 1, the carbon powder drives impurities to enter the active filter box 611 through discharging, the carbon powder continuously moves downwards without being influenced at the position of the attraction attachment pipe 612, the impurities are adsorbed at the position of the pipe and remain at the inner side, when the attraction attachment pipe 612 is fully adsorbed, the impurities move to the impurity pipe 614 through the impurity separation groove 613 and are deposited and stored in the impurity storage box 615, then the impurities are removed through the cleaning bottom box 616, when the carbon powder on the other side moves to the micro-pressure plate 623, the micro-pressure plate 623 generates downward pressing force through accumulation, when the micro-pressure plate 623 slightly moves downwards, the sliding block 631 pushes the micro-pressure drag hook 632, the other end of the pulling rope 634 is pulled upwards, the actuating plate 636 slightly moves upwards due to micro-motion, the magnetic adsorption of the micro-magnetic block 637 is strengthened, the micro-motion is continuously moved upwards to be attached to the micro-electric magnetic block 637, and simultaneously the interface energizing module 638, the current of the electromagnetic field control module 642 enables the central rotor 643 to rotate, meanwhile, the rotating connecting flange 644 also rotates, the rotating disc 646 rotates clockwise through the transmission belt 645, carbon powder is sucked and enters the connecting pipe 654 through the extracting pipe head cover 653, the carbon powder is pushed to flow in along the pipe from the actuating pipe 656 by pressurization in the switching pressure extracting body 652, the rotating wheel 661 is driven to rotate, the carbon powder is calculated through the flow detection module 665 through the electric lead 664, the carbon powder is transmitted to the terminal connecting transmission module 667 to be rotated out for being convenient to check, the pneumatic pump valve body 672 is started through the feedback control module 668 when the carbon powder is full, the pneumatic moving plate 674 is pressed through the pneumatic pipe 673 by air pressure, and the moving buffer block 675 moves downwards to enable the flow path of the central flow pipe 67.

The invention solves the problems that the carbon powder of the carbon powder receiving device in the prior art is fully stored at any time in storage, the inflow carbon powder enters a storage box and influences the carbon powder in the storage box due to the large flow of the drained carbon powder when the storage box is cleaned, the fine carbon powder particles are difficult to see when floating and difficult to collect again and easy to leak, the doped impurities are easy to be discharged together by the carbon powder in collection, and the carbon powder doped with the impurities is difficult to use due to the change caused by the influence of the impurities when in use.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (8)

1. The utility model provides a connect carbon powder device for big-and-middle-sized wire wound motor, its structure includes carbon powder interface slot (1), the carbon powder body of concentrating (2), adjusts sliding block (3), connects carbon powder organism (4), installation fixed block (5), carbon powder filtration guide accuse and flow device (6), fixed cassette (7), carbon powder storage box (8), draws forth notch (9), its characterized in that: the carbon powder interface tank (1) is welded on the inner side of the carbon powder centralized body (2) in an embedding mode, the lower surface of the carbon powder centralized body (2) is connected with the upper surface of the carbon powder connecting machine body (4) in an electric welding mode, the adjusting sliding block (3) is installed on the front surface of the carbon powder connecting machine body (4) in an embedding mode and is movably connected with the front surface of the carbon powder connecting machine body (4), the right surface of the installing fixing block (5) is connected with the left surface of the carbon powder connecting machine body (4) in an electric welding mode and is electrically connected with the left surface of the carbon powder connecting machine body (4), the carbon powder filtering and guiding flow control device (6) is welded on the inner side of the carbon powder connecting machine body (4) in an embedding mode, the upper surface of the fixing clamp seat (7) is perpendicular to the front surface of the carbon powder connecting machine body (4), the carbon powder filtering and guiding flow control device (6) is installed on the upper surface of the fixing The right surface of the carbon powder storage box (8) is provided with a lead-out notch (9); the carbon powder filtering and guiding flow control device (6) comprises a carbon powder quality removing and filtering mechanism (61), a micro-pressure moving mechanism (62), a micro-pressure electromagnetic starting mechanism (63), an electric rotating transmission mechanism (64), a carbon powder extracting and switching mechanism (65), a flow speed detecting and transmitting mechanism (66), a flow path adjusting mechanism (67) and a flow control device shell (68), wherein the carbon powder quality removing and filtering mechanism (61) is welded on the upper surface of the flow control device shell (68) in an embedding mode, the micro-pressure moving mechanism (62) is arranged below the carbon powder quality removing and filtering mechanism (61), the micro-pressure electromagnetic starting mechanism (63) is arranged on the lower surface of the inner side of the micro-pressure moving mechanism (62) and is connected with the inner side of the micro-pressure electromagnetic starting mechanism in an electric welding mode, the left side of the electric rotating transmission mechanism (64) is arranged on the right surface of the micro-pressure moving mechanism (62) in a fitting mode, and the micro-pressure electromagnetic starting, the electric rotating transmission mechanism (64) is positioned below the carbon powder extraction and switching mechanism (65) and is movably connected with the carbon powder extraction and switching mechanism, the right side of the carbon powder extraction and switching mechanism (65) is connected with the left side of the flow rate detection and transmission mechanism (66) in an electric welding mode, and the right side of the flow rate detection and transmission mechanism (66) is provided with a flow path adjusting mechanism (67) and is electrically connected with the flow path adjusting mechanism.

2. A toner receiving device for a large and medium sized wound motor according to claim 1, wherein: the carbon powder quality-removing filtering mechanism (61) comprises an active filtering box (611), a suction attachment pipe (612), a sundries separating groove (613), a sundries pipe (614), a sundries storage box (615), a cleaning bottom box (616) and a carbon powder flowing branch opening (617), the inner side of the active filter box (611) is provided with a suction attachment pipe (612) which is connected in an adhesive way, the sundries separating groove (613) is arranged in the center of the inner side of the suction attaching pipe (612), the sundries storage box (615) is provided with a sundries pipe (614) on the left surface in an electric welding mode, the left surface of the sundries storage box (615) is connected with the right surface of the active filter box (611) in an electric welding way, the cleaning bottom box (616) is arranged at the inner side of the sundries storage box (615) and is connected in a fitting mode, the lower surface of the active filter box (611) is provided with a carbon powder flowing branch opening (617).

3. A toner receiving device for a large and medium sized wound motor according to claim 1, wherein: micropressure moving mechanism (62) including fixed curb plate (621), sealed piece (622), minute clamp plate (623), spring guide (624), the inboard of fixed curb plate (621) is equipped with spring guide (624) and is connected through the mode of electric welding, the right surface of sealed piece (622) is connected with the left surface of minute clamp plate (623) adoption laminating mode, the left surface in fixed curb plate (621) is installed in the mode of embedding in minute clamp plate (623), spring guide (624) run through in the upper and lower surface of minute clamp plate (623) and the axle center of spring guide (624) and the lower surface mutually perpendicular of minute clamp plate (623), the right surface of fixed curb plate (621) is equipped with carbon powder extraction changeover mechanism (65).

4. A toner receiving device for a large and medium sized wound motor according to claim 1, wherein: the micro-pressure electromagnetic starting mechanism (63) comprises a sliding block (631), a micro-pressure drag hook (632), a positioning spring (633), a pulling rope (634), a limiting wheel (635), a driving plate (636), a micro-electromagnetic block (637), an interface electrifying module (638) and a starting switching module (639), wherein the lower surface of the sliding block (631) is connected with the top end of the micro-pressure drag hook (632) in an electric welding mode, the top of the positioning spring (633) is provided with the micro-pressure drag hook (632), the left end of the pulling rope (634) is installed at the right end of the micro-pressure drag hook (632) in an embedded mode, the pulling rope (634) is installed on the outer side of the limiting wheel (635) in a fitting mode, the other end of the pulling rope (634) is connected with the upper surface of the driving plate (636) in an electric welding mode, and the upper surface of the driving plate (636) is parallel to the lower surface of the micro-electromagnetic block (637, the micro-electromagnetic block (637) is arranged on the lower surface of the interface power-on module (638) in a welding mode and is electrically connected, and the left surface of the starting switching module (639) is connected with and electrically connected with the right surface of the interface power-on module (638) in a fitting mode.

5. A toner receiving device for a large and medium sized wound motor according to claim 1, wherein: the electric rotating transmission mechanism (64) comprises a protection control module (641), an electromagnetic field control module (642), a central rotor (643), a rotating connecting flange (644), a transmission belt (645) and a rotating disc (646), wherein the electromagnetic field control module (642) is arranged on the right surface of the protection control module (641) and is electrically connected, the central rotor (643) is arranged on the right surface of the electromagnetic field control module (642) and is connected in an embedded mode, the left side of the rotating connecting flange (644) is connected with the right side of the central rotor (643) in an electric welding mode, the axis center of the rotating connecting flange is installed on the same horizontal line, the inner side of the transmission belt (645) is attached to the outer side of the rotating connecting flange (644) in a transmission mode, and the rotating disc (646) is connected with the transmission belt (645) in an attaching mode.

6. A toner receiving device for large and medium sized wound motor according to claim 1 or 3 characterized in that: the carbon powder extraction switching mechanism (65) comprises a center pin (651), a switching pressure-relief body (652), an extraction pipe head cover (653), a connecting pipe (654), a connecting buckle (655) and a priming pipe (656), wherein the extraction pipe head cover (653) is installed on the inner side of the fixed side plate (621) in an embedded mode, the center pin (651) is welded on the front surface of the switching pressure-relief body (652) in an embedded mode, the extraction pipe head cover (653) is installed on the left side of the connecting pipe (654) in an electric welding mode, the connecting buckle (655) is installed on the front surface of the switching pressure-relief body (652) in an electric welding mode, and the left side of the priming pipe (656) is attached to the inner side of the connecting buckle (655) in an embedded mode.

7. A toner receiving device for a large and medium sized wound motor according to claim 1, wherein: the flow velocity detection transmission mechanism (66) comprises a rotating wheel (661), a positioning shaft (662), a protective shell (663), an electric lead (664), a flow detection module (665), a data line (666), a terminal connection transmission module (667) and a feedback control module (668), the positioning shaft (662) penetrates through the rotating wheel (661) and adopts clearance fit, the rotating wheel (661) is mounted at the lower end of the protective shell (663) in an embedded manner, the electric lead (664) is arranged at the top end of the protective shell (663) and is electrically connected, the left side of the flow detection module (665) is provided with a data line (666), the data line (666) is embedded in a terminal connection transmission module (667) and is electrically connected, the left surface of the feedback control module (668) is connected with the right surface of the terminal connection transmission module (667) in an electric welding mode.

8. A toner receiving device for a large and medium sized wound motor according to claim 1, wherein: the flow path adjusting mechanism (67) comprises an overload prevention module (671), a pneumatic pump valve body (672), an airflow pipe (673), a pneumatic moving plate (674), a movable buffer block (675), a return spring (676) and a central flow pipe (677), wherein the overload prevention module (671) is installed on the left surface of the pneumatic pump valve body (672) and is electrically connected with the pneumatic pump valve body, the airflow pipe (673) is installed on the lower surface of the pneumatic pump valve body (672) in an embedded mode, the lower surface of the pneumatic moving plate (674) is connected with the upper surface of the movable buffer block (675) in a welding mode, the return spring (676) is installed on the lower surface of the pneumatic moving plate (674), and the top end of the central flow pipe (677) is provided with the movable buffer block (675).

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