CN114670356A

CN114670356A - Power envelope curve apparatus for producing that carries out material mixing through rotatory stirring

Info

Publication number: CN114670356A
Application number: CN202210304410.XA
Authority: CN
Inventors: 林文树; 乔元朝; 林文禄; 曹卫明
Original assignee: Tianchang Fuda Electronic Technology Co ltd
Current assignee: Tianchang Fuda Electronic Technology Co ltd
Priority date: 2022-03-26
Filing date: 2022-03-26
Publication date: 2022-06-28

Abstract

The invention relates to the technical field of power source covering wires, in particular to a power source covering wire production device for mixing materials through rotary stirring. The material feeding device at least comprises a shell, wherein the inner side of the shell is used for bearing materials, a feeding nozzle is arranged on the surface of the shell, a driving blade fan is arranged on the inner side of the shell, and a gap is reserved between the driving blade fan and the inner wall of the shell; the lower gear is connected with the driving leaf through a shaft rod, the surface of the lower gear is meshed and connected with an upper gear, the side surface of the upper gear is connected with a driving motor, a driving screw rod is installed on the side surface of the upper gear, an installation plate is sleeved at one end of the driving screw rod, a screw nut is connected to the surface of the driving screw rod in a threaded mode, and a driving ring is installed below the screw nut. Through the rotation of drive leaf fan, the drive ring is located and connects between the clearance, erases the material between the clearance and makes it drop in the inboard of casing for the material mixes with the cooperation of drive leaf fan, accelerates the mixing rate of whole material.

Description

Power envelope curve apparatus for producing that carries out material mixing through rotatory stirring

Technical Field

The invention relates to the technical field of power source covering wires, in particular to a power source covering wire production device for mixing materials through rotary stirring.

Background

When the power source covered wire is produced, the power source covered wire needs to be combined with the internal cable wire through the shell, wherein the shell of the power source covered wire is formed by mixing and stirring various materials and is nested on the inner side of the cable wire through shaping.

The power envelope production device comprises a shell and a blade fan, wherein a plurality of materials are mixed through stirring equipment, the stirring equipment is composed of the shell and the blade fan, a gap exists between the blade fan and the shell, the materials can be mixed and stirred at the inner side through the rotation of the blade fan, but in the stirring process, the materials attached to the surface of the gap cannot be in contact with the blade fan due to the gap, so that the materials attached to the gap cannot be fully stirred as far as possible, and the speed and the precision of material mixing are influenced.

Disclosure of Invention

The invention aims to provide a power source covered wire production device for mixing materials through rotary stirring, which solves the problems in the background technology.

In order to achieve the above object, the present invention provides a power source covered wire production apparatus for mixing materials by rotating and stirring, at least comprising:

the material mixing device comprises a shell, a material conveying device and a material mixing device, wherein the inner side of the shell is used for bearing materials, a feeding nozzle is arranged on the surface of the shell, a driving blade fan is arranged on the inner side of the shell and used for rotationally stirring the borne materials, and a gap is reserved between the driving blade fan and the inner wall of the shell and used for carrying out contact mixing on the materials when the driving blade fan rotates;

the lower gear is positioned on the outer side of the shell and connected with the driving leaf through a shaft rod, the surface of the lower gear is connected with an upper gear in a meshed mode, the side surface of the upper gear is connected with a driving motor which is used for driving the upper gear, a driving screw rod is installed on the side surface of the upper gear and positioned above the shell, an installation plate is sleeved at one end of the driving screw rod and installed on the surface of the shell, a screw nut is connected to the surface of the driving screw rod in a threaded mode, the surface of the screw nut is positioned on the inner side of the shell and slides, a driving ring is installed below the screw nut and used for sliding on the inner side of the shell, and the driving ring is positioned between gaps;

when the lower gear is used specifically, materials are placed in the lower gear along the inner side of the feeding nozzle, the materials are positioned between the inner sides of the shell and are filled in the inner sides and gaps of the shell, the driving motor is powered on and turned on at the moment, the driving motor drives the upper gear to rotate, the lower gear is meshed with the upper gear to drive the lower gear to rotate, the lower gear drives the shaft to rotate due to the connection and the matching of the lower gear and the driving leaf, namely the driving leaf rotates on the inner side of the shell, so that the driving leaf rotates to mix and stir the materials in the inner side of the shell, wherein the driving lead screw is driven to rotate along with the rotation of the upper gear, the lead screw nut is in threaded connection and matching with the driving lead screw, the lead screw nut moves linearly along with the rotation direction of the driving lead screw, and the driving ring is arranged at the bottom of the lead screw nut, the screw rod nut is positioned on the shell and slides, so that the driving ring can move along with the linear motion of the screw rod nut, the driving ring can transversely move on the inner side of the shell, the driving ring is positioned between the gaps and connected, the materials attached between the gaps can be erased and fall on the inner side of the shell, and the materials and the driving fan can be matched and stirred, so that the materials in the shell can be completely mixed as much as possible, and the mixing rate of the whole materials is increased; wherein, when the time that the drive leaf fan need stir is longer, can be with comparatively closely spaced that the screw thread grooved rail on drive lead screw surface was seted up for screw-nut moves comparatively slowly on the drive lead screw, and after screw-nut reached the terminal position of drive lead screw, accessible driving motor's antiport makes screw-nut carry out the reverse operation, clears away the material of laminating on the clearance that exists in the casing once more, improves the mixing efficiency of material, accelerates the production efficiency to the power envelope curve.

As a further improvement of the technical scheme, a notch is formed in the bottom surface of the shell, a sealing nozzle is connected to the inner side of the notch from threads, the top surface of the sealing nozzle is arc-shaped, the top surface of the sealing nozzle is matched with the inner wall of the shell, a fixing seat is installed below the shell, and the fixing seat is used for supporting the shell.

As a further improvement of the technical scheme, a cavity is formed in the surface of the fixing seat, a push plate is arranged on the inner side of the cavity, a sliding groove is formed in the surface of the push plate, and the push plate is located on the inner side of the sliding groove and slides.

As a further improvement of the technical scheme, the concave rail is arranged on the side face of the lower gear, the vertical rod is arranged on the surface of the fixing seat, the side face of the vertical rod is connected with the lower gear in a laminating mode, the top side of the vertical rod is provided with a protrusion, the protrusion is matched with the inner diameter of the concave rail, and the protrusion is located on the inner side of the concave rail and slides.

As a further improvement of the technical solution, one side of the shaft rod penetrates through a side surface of the housing and is connected with the lower gear, one side of the shaft rod extends out of a surface of the lower gear, one side of the driving screw rod extends out of a surface of the upper gear, the shaft rod and the driving screw rod are movably connected through a connecting arm, and the connecting arm is used for limiting connection of the shaft rod and the driving screw rod.

As a further improvement of the technical scheme, a slide way is formed in the surface of the shell, the lead screw nut is located on the inner side of the slide way and slides, a limiting block is arranged on the surface of the lead screw nut and can contact with the outer surface of the shell, and the limiting block is used for improving the stability of the lead screw nut in linear motion.

As a further improvement of the technical scheme, the side surface of the slide way is provided with a sliding cavity in a split manner, the surface of the screw rod nut is provided with a sliding opening, a sealing plate is connected in the sliding opening in a sliding manner, the side surface of the screw rod nut is provided with a sliding block, and the sliding block is positioned in the sliding cavity and slides.

As a further improvement of the technical scheme, one side of the slide way extends out of the side face of the shell, one side of the sealing plate is provided with a clamping block, the clamping block is in clamping fit with the slide way, and one side of the sealing plate extends out of the slide way.

As a further improvement of the technical scheme, the side face of the shell is in a through opening shape, the inner side of the through opening is in threaded connection with a baffle, and the baffle is used for sealing the through opening.

As a further improvement of the technical scheme, the charging box is installed in the outside of casing, the inboard of charging box is equipped with carries the flitch, the side of carrying the flitch is the opening form, the opening inboard of carrying the flitch is equipped with the fly leaf, fly leaf and carry through spring coupling between the flitch, be connected through the body between the side of charging box and the feed nozzle, the surface mounting who carries the flitch carries the material pole, it stretches out the surperficial outside of charging box to carry the material pole.

Compared with the prior art, the invention has the beneficial effects that:

1. this carry out power envelope curve apparatus for producing of material mixture through rotatory stirring, rotate through the drive leaf fan, the material mixes the stirring, along with the drive lead screw is driven the operation, the drive ring slides on the casing, the drive ring is located to connect between the clearance, to the material between the clearance erase and make it drop in the inboard of casing, make the material cooperate the stirring with the drive leaf fan, with the material of as far as in the casing carry out the intensive mixing, accelerate the mixing rate of whole material.

2. In this power source envelope curve apparatus for producing that carries out material mixing through rotatory stirring, through the connection cooperation of linking arm, the both ends of linking arm carry out swing joint with axostylus axostyle and drive lead screw respectively to gear and last gear are down injectd to the side of linking arm, make the position of gear and last gear injectd down, in order to ensure that gear and last gear only can carry out the meshing connection down, the shake can not appear and lead to the offset.

3. In this power envelope curve apparatus for producing that carries out material mixing through rotatory stirring, slide in the sliding opening through the shrouding, screw-nut's side slider slides in sliding chamber, can make screw-nut normally slide along slide and sliding chamber, and screw-nut drives the drive ring and normally operates to the slide is in encapsulated situation, and inboard material is in the closure under blockking of shrouding, can outwards splash.

Drawings

Fig. 1 is a first schematic view of the overall structure of embodiment 1 of the present invention;

FIG. 2 is a sectional view of the whole structure of example 1 of the present invention;

FIG. 3 is a schematic structural view of a housing according to embodiment 1 of the present invention;

FIG. 4 is a schematic structural view of a housing, a drive screw and a drive ring according to embodiment 1 of the present invention;

FIG. 5 is an exploded view of a drive ring and a closing plate structure in accordance with embodiment 1 of the present invention;

FIG. 6 is an exploded view of the entire structure of embodiment 2 of the present invention;

fig. 7 is a first schematic view of the overall structure of embodiment 3 of the present invention;

fig. 8 is a second overall structural view of embodiment 3 of the present invention;

FIG. 9 is a sectional view of the structure of a charging box in example 3 of the present invention;

fig. 10 is an exploded view of the structure of the lifting plate and the moving plate in embodiment 3 of the present invention.

The various reference numbers in the figures mean:

1. a housing; 11. a feed nozzle; 12. sealing the nozzle; 13. a slideway; 2. a fixed seat; 21. a cavity; 22. pushing the plate; 23. a chute; 3. a lower gear; 31. driving the blade fan; 32. a shaft lever; 4. an upper gear; 41. a drive motor; 42. a connecting arm; 5. driving the screw rod; 51. mounting a plate; 6. a feed screw nut; 61. a limiting block; 7. a drive ring; 71. closing the plate; 8. a baffle plate; 9. a feed box; 91. a material extracting plate; 911. a movable plate; 912. a spring; 92. a material lifting rod.

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.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Example 1

Referring to fig. 1-5, the present embodiment aims to provide a power source covered wire production device for mixing materials by rotating and stirring, which at least comprises:

the material mixing device comprises a shell 1, wherein the inner side of the shell 1 is used for bearing materials, a feeding nozzle 11 is arranged on the surface of the shell 1, a driving blade fan 31 is arranged on the inner side of the shell 1, the driving blade fan 31 is used for rotationally stirring the borne materials, a gap is reserved between the driving blade fan 31 and the inner wall of the shell 1, and the gap is used for carrying out contact mixing on the materials when the driving blade fan 31 rotates;

the lower gear 3 is positioned on the outer side of the shell 1, the lower gear 3 is connected with the driving leaf 31 through a shaft lever 32, the surface of the lower gear 3 is meshed with and connected with an upper gear 4, the side surface of the upper gear 4 is connected with a driving motor 41, the driving motor 41 is used for driving the upper gear 4, the side surface of the upper gear 4 is provided with a driving screw 5, the driving screw 5 is positioned above the shell 1, one end of the driving screw 5 is sleeved with a mounting plate 51, the mounting plate 51 is mounted on the surface of the shell 1, the surface of the driving screw 5 is in threaded connection with a screw nut 6, the surface of the screw nut 6 is positioned on the inner side of the shell 1 and slides, a driving ring 7 is mounted below the screw nut 6, the driving ring 7 is used for sliding on the inner side of the shell 1, and the driving ring 7 is positioned between gaps;

when the lower gear 3 is used specifically, materials are placed in the lower gear along the inner side of the feeding nozzle 11, the materials are located between the inner sides of the shell 1, the inner sides and gaps of the shell 1 are filled with the materials, at the moment, the driving motor 41 is powered on and turned on, the driving motor 41 drives the upper gear 4 to rotate, the upper gear 3 and the upper gear 4 are in meshed connection, so that the upper gear 4 rotates to drive the lower gear 3 to rotate, the lower gear 3 drives the shaft lever 32 to rotate due to the connection and matching of the lower gear 3 and the driving leaf fan 31, namely, the driving leaf fan 31 rotates on the inner side of the shell 1, the driving leaf fan 31 mixes and stirs the materials on the inner side of the shell 1, wherein the driving screw rod 5 is driven to operate along with the rotation of the upper gear 4, the screw rod nut 6 is in threaded connection and matching with the driving screw rod 5, so that the screw rod nut 6 can linearly move along with the rotation direction of the driving screw rod 5, because the bottom of the screw nut 6 is provided with the driving ring 7, and the screw nut 6 is positioned on the shell 1 to slide, the driving ring 7 can move along with the linear motion of the screw nut 6, the driving ring 7 can move transversely on the inner side of the shell 1, and the driving ring 7 is positioned between the gaps and connected, so that materials attached between the gaps can be erased and fall on the inner side of the shell 1, and the materials and the driving leaf fan 31 are matched and stirred, so that the materials in the shell 1 can be completely mixed as much as possible, and the mixing speed of the whole materials is accelerated; wherein, when the time that drive leaf fan 31 need stir is longer, can be with the comparatively fine and close that the screw thread grooved rail on drive lead screw 5 surface was seted up, make that screw-nut 6 moves comparatively slowly on drive lead screw 5, and after screw-nut 6 reached drive lead screw 5's terminal position, accessible driving motor 41's antiport, make screw-nut 6 carry out the run-back, the material of laminating on the clearance that exists in the casing 1 again is clear away, the mixing efficiency of material is improved, accelerate the production efficiency to the power envelope curve.

In order to enable the shell 1 to easily discharge materials after the materials are mixed, a notch is formed in the bottom surface of the shell 1, a sealing nozzle 12 is connected to the inner side of the notch from threads, the top surface of the sealing nozzle 12 is arc-shaped, the top surface of the sealing nozzle 12 is matched with the inner wall of the shell 1, a fixing seat 2 is installed below the shell 1, the fixing seat 2 is used for supporting the shell 1, the sealing nozzle 12 is screwed out along the notch, so that the materials can fall along the notch of the shell 1, the materials can be discharged to the shell 1 conveniently, and in consideration of the fact that when the shape of the sealing nozzle 12 is not matched with the inner wall of the shell 1, the notch of the shell 1 is enabled to be protruded or sunken under the connection of the sealing nozzle 12, the surface of the sealing nozzle 12 protruded out of the inner side of the shell 1 can affect the normal sliding of the driving ring 7, and the surface of the sealing nozzle 12 recessed in the shell 1 can cause local materials to fall on the inner side of the notch, the mixing precision of the materials is influenced, the top surface of the sealing nozzle 12 is attached to the inner wall of the shell 1, so that the materials in the shell 1 can be discharged in a matched mode, the driving ring 7 cannot be influenced by the sealing nozzle 12, and the normal operation of the driving ring 7 can be guaranteed.

In order to further improve the stability of lower gear 3 when rotating, borrow this to make upper gear 4 and drive lead screw 5 moving stability when driving, concave rail has been seted up to lower gear 3's side, the surface mounting of fixing base 2 has the montant, the side of montant is connected with the laminating of lower gear 3, the top side of montant is equipped with the arch, protruding internal diameter adaptation with concave rail, the protruding inboard that is located concave rail slides, fixed connection through the montant, protruding sliding adaptation in concave rail, make lower gear 3 stability when rotating promoted, and make the last gear 4 of top meshing connection and pivoted drive lead screw 5 all can comparatively stabilize, the feasibility of implementing of whole device has been improved.

Considering that the lower gear 3 is rotatably connected with the shaft 32, the upper gear 4 is connected with the driving screw 5 in a matching manner, in order to further improve the rotational stability of the lower gear 3 and the upper gear 4, no position deviation caused by shaking occurs, so that the meshing connection between the lower gear 3 and the upper gear 4 is limited, one side of the shaft 32 penetrates through the side surface of the housing 1 and is connected with the lower gear 3, one side of the shaft 32 extends out of the surface of the lower gear 3, one side of the driving screw 5 extends out of the surface of the upper gear 4, the shaft 32 and the driving screw 5 are movably connected through a connecting arm 42, the connecting arm 42 is used for connecting and limiting the shaft 32 and the driving screw 5, the two ends of the connecting arm 42 respectively movably connect the shaft 32 and the driving screw 5 through the connection matching of the connecting arm 42, and the side surface of the connecting arm 42 limits the lower gear 3 and the upper gear 4, so that the positions of the lower gear 3 and the upper gear 4 are limited, to ensure that the lower gear 3 and the upper gear 4 can only be engaged without causing positional deviation due to shaking.

In order to make the screw-nut 6 slide comparatively stably in the casing 1, and the overall structure is comparatively perfect, the slide 13 has been seted up on the surface of casing 1, the screw-nut 6 is located the inboard slip of slide 13, the surface of screw-nut 6 is equipped with stopper 61, stopper 61 can contact at the surface of casing 1, stopper 61 is used for improving the stability that screw-nut 6 carries out linear motion, slide in slide 13 through screw-nut 6, make screw-nut 6 can drive ring 7 and carry out the steady slip, guarantee that drive ring 7 can clear away the material in the clearance, make the complete mixing.

Considering that the slide way 13 is in an exposed state after being opened, the rotation of the driving leaf 31 can make the material in the housing 1 be thrown out along the slide way 13 by pressurization, which causes the waste of the material, the side of the slide way 13 is relatively provided with a sliding cavity, the surface of the screw-nut 6 is provided with a sliding opening, the sliding opening is connected with a sealing plate 71 in a sliding way, the side of the screw-nut 6 is provided with a slide block, the slide block is positioned in the sliding cavity and slides in the sliding cavity through the sealing plate 71, the side slide block of the screw-nut 6 slides in the sliding cavity, so that the screw-nut 6 can slide normally along the slide way 13 and the sliding cavity, and the screw-nut 6 drives the driving ring 7 to normally operate, and the slide way 13 is in a sealing state, the material at the inner side is in a sealing state under the blocking of the sealing plate 71 and can not splash outwards.

In order to make the tip of shrouding 71 stably be located slide 13 inboard, the side of casing 1 is stretched out to one side of slide 13, one side of shrouding 71 is equipped with the fixture block, the fixture block cooperates with slide 13 joint, slide 13 is stretched out to one side of shrouding 71, through the fixture block with slide 13's inner wall tip joint, shrouding 71 can be in comparatively stable state, and consider shrouding 71 and the long-time friction of screw-nut 6 meeting process, wearing and tearing can appear in shrouding 71, move out the change in order to do benefit to shrouding 71, slide 13 is stretched out to one side of shrouding 71, can make personnel do benefit to and install and change shrouding 71.

Consider casing 1 after long-term or repetitious usage, the residue of material can be adhered to casing 1 and drive leaf 31, when carrying out the mixed stirring of other materials, be unfavorable for the washing use, the side of casing 1 is the through-hole form, the inboard threaded connection of through-hole has baffle 8, baffle 8 is used for sealing the through-hole, hold baffle 8 through the personnel and screw out outward, baffle 8 leaves in casing 1 obtains the through-hole, personnel alright adopt the water pipe to carry out the water bath to the inboard of casing 1 and wash, after casing 1 and the clean completion of drive leaf 31, alright twist baffle 8 again and seal casing 1, carry out the mixed stirring of material.

Example 2

In order to ensure that when the materials in the housing 1 are discharged and the materials are full in other carriers, the remaining materials can have a space for temporarily storing the materials, so as to ensure that the materials are normally discharged without affecting the mixing and stirring of the subsequent materials, the embodiment is further improved on the basis of embodiment 1, as shown in fig. 6:

cavity 21 has been seted up on the surface of fixing base 2, the inboard of cavity 21 is equipped with push pedal 22, spout 23 has been seted up on push pedal 22's surface, push pedal 22 is located 23 inboard slides of spout, it is outside to slide along spout 23 through push pedal 22, make seal nozzle 12 twist out when leaving casing 1, the material can accept in cavity 21 to the whereabouts, when all filling the material to the carrier that uses, can reach the effect of accepting the material temporarily, the material of avoiding mixing the completion occupies casing 1 and influences subsequent mixing, and drag closed cavity 21 along spout 23 through push pedal 22 after accepting, the material obtains storing.

Example 3

In consideration of the fact that the subsequent material adding and supplementing of the shell 1 is not convenient enough, the embodiment is further improved on the basis of the embodiment 2, as shown in fig. 7 to 10:

the feed box 9 is installed on the outer side of the shell 1, the material lifting plate 91 is arranged on the inner side of the feed box 9, the side face of the material lifting plate 91 is in an open shape, a movable plate 911 is arranged on the inner side of the opening of the material lifting plate 91, the movable plate 911 is connected with the material lifting plate 91 through a spring 912, the side face of the feed box 9 is connected with the feed nozzle 11 through a pipe body, a material lifting rod 92 is installed on the surface of the material lifting plate 91, the material lifting rod 92 extends out of the surface of the feed box 9, the feed box 9 is attached to the outer side of the shell 1, the inner side of the feed box 9 is in an arc-shaped structure, supplementary materials are placed between the material lifting plate 91 and the feed box 9, the volume of the materials can be reduced along with the mixing along with the materials, therefore when the materials are added into the shell 1 subsequently, the material lifting rod 92 is held tightly by hands and lifted upwards, the material lifting rod 92 drags the material lifting plate 91 upwards, the material lifting plate 91 enables the materials to be lifted upwards, be closer to the body more for the material just can outwards flow into to feed nozzle 11 along the body and get into casing 1, form reinforced, wherein, the inboard of charging box 9 is the arc, through the sliding connection of fly leaf 911, spring 912 forms the elastic extrusion to fly leaf 911, make it have the tension of outside expansion, thereby make fly leaf 911 under the elastic connection of spring 912, and along with the position change of lifting blade 91, the laminating is in the arc inner face of charging box 9 all the time, guarantee that the material all can be held up to reach reinforced.

The foregoing shows and describes the general principles, principal features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the preferred embodiments of the present invention are described in the above embodiments and the description, and are not intended to limit the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides a power envelope curve apparatus for producing that carries out material mixing through rotatory stirring which characterized in that: at least comprises the following steps:

the material mixing device comprises a shell (1), wherein the inner side of the shell (1) is used for bearing materials, a feeding nozzle (11) is installed on the surface of the shell (1), a driving blade fan (31) is arranged on the inner side of the shell (1), the driving blade fan (31) is used for rotationally stirring the borne materials, a gap is reserved between the driving blade fan (31) and the inner wall of the shell (1), and the gap is used for carrying out contact mixing on the materials when the driving blade fan (31) rotates;

the lower gear (3) is located on the outer side of the shell (1), the lower gear (3) is connected with the driving leaf (31) through a shaft rod (32), the surface of the lower gear (3) is meshed with the upper gear (4), the side surface of the upper gear (4) is connected with a driving motor (41), the driving motor (41) is used for driving the upper gear (4), the side surface of the upper gear (4) is provided with a driving screw rod (5), the driving screw rod (5) is located above the shell (1), one end of the driving screw rod (5) is sleeved with a mounting plate (51), the mounting plate (51) is mounted on the surface of the shell (1), the surface of the driving screw rod (5) is connected with a screw rod nut (6) in a threaded manner, the surface of the screw rod nut (6) is located on the inner side of the shell (1) to slide, a driving ring (7) is mounted below the screw rod nut (6), the drive ring (7) is adapted to slide inside the housing (1), the drive ring (7) being located between the gaps.

2. The power supply covered wire production device for mixing materials through rotary stirring as claimed in claim 1, wherein: the bottom surface of casing (1) has been seted up the notch, there is sealed mouth (12) inboard from threaded connection of notch, the top surface of sealed mouth (12) is the arc, the top surface of sealed mouth (12) and the inner wall adaptation of casing (1), fixing base (2) are installed to the below of casing (1), fixing base (2) are used for supporting casing (1).

3. The power supply covered wire production device for mixing materials through rotary stirring as claimed in claim 2, wherein: cavity (21) have been seted up on the surface of fixing base (2), the inboard of cavity (21) is equipped with push pedal (22), spout (23) have been seted up on the surface of push pedal (22), push pedal (22) are located spout (23) inboard and slide.

4. The power supply covered wire production device for mixing materials through rotary stirring as claimed in claim 3, wherein: the concave rail has been seted up to the side of lower gear (3), the surface mounting of fixing base (2) has the montant, the side and the lower gear (3) laminating of montant are connected, the top side of montant is equipped with the arch, the internal diameter adaptation of arch and concave rail, the protruding inboard that is located the concave rail slides.

5. The power supply covered wire production device for mixing materials through rotary stirring as claimed in claim 1, wherein: one side of the shaft lever (32) penetrates through the side face of the shell (1) and is connected with the lower gear (3), one side of the shaft lever (32) extends out of the surface of the lower gear (3), one side of the driving screw rod (5) extends out of the surface of the upper gear (4), the shaft lever (32) and the driving screw rod (5) are movably connected through a connecting arm (42), and the connecting arm (42) is used for limiting connection of the shaft lever (32) and the driving screw rod (5).

6. The power supply covered wire production device for mixing materials through rotary stirring as claimed in claim 1, wherein: slide (13) have been seted up on the surface of casing (1), screw-nut (6) are located the inboard of slide (13) and slide, the surface of screw-nut (6) is equipped with stopper (61), stopper (61) contactable is at the surface of casing (1), stopper (61) are used for improving screw-nut (6) and carry out linear motion's stability.

7. The power supply covered wire production device for mixing materials through rotary stirring as claimed in claim 6, wherein: the side of slide (13) has seted up smooth chamber relatively, the surface of screw-nut (6) is equipped with the sliding opening, sliding opening sliding connection has shrouding (71), the side of screw-nut (6) is equipped with the slider, the slider is located and slides in the smooth chamber.

8. The power supply covered wire production device for mixing materials through rotary stirring as claimed in claim 7, wherein: one side of the slide way (13) extends out of the side face of the shell (1), one side of the sealing plate (71) is provided with a clamping block, the clamping block is in clamping fit with the slide way (13), and one side of the sealing plate (71) extends out of the slide way (13).

9. The power supply covered wire production device for mixing materials through rotary stirring as claimed in claim 1, wherein: the side of casing (1) is the opening form, the inboard threaded connection of opening has baffle (8), baffle (8) are used for sealing the opening.

10. The power supply covered wire production device for mixing materials through rotary stirring as claimed in claim 1, wherein: feed box (9) are installed in the outside of casing (1), the inboard of feed box (9) is equipped with carries flitch (91), the side of carrying flitch (91) is the opening form, the opening inboard of carrying flitch (91) is equipped with fly leaf (911), fly leaf (911) and carry and connect through spring (912) between flitch (91), be connected through the body between the side of feed box (9) and feed nozzle (11), the surface mounting of carrying flitch (91) has carries material pole (92), it is outside to stretch out the surface of feed box (9) to carry material pole (92).