CN216028581U

CN216028581U - Automatic change equipment of attacking tooth

Info

Publication number: CN216028581U
Application number: CN202122238737.5U
Authority: CN
Inventors: 阮子斌; 阮子俊
Original assignee: Foshan Shunde Lihong Electronic Co ltd
Current assignee: Foshan Shunde Lihong Electronic Co ltd
Priority date: 2021-09-14
Filing date: 2021-09-14
Publication date: 2022-03-15
Anticipated expiration: 2031-09-14

Abstract

The utility model discloses automatic tapping equipment, which relates to the technical field of tapping equipment and comprises a tapping mechanism, a feeding mechanism, a cooling mechanism and a blowing mechanism, wherein the blowing mechanism is arranged on the tapping mechanism; the blowing mechanism comprises an air source and a blowing nozzle, and the blowing nozzle is provided with a through hole and a plurality of air outlet holes; the blowing nozzle is arranged at the terminal of the feeding mechanism, the terminal of the feeding mechanism is communicated with the through hole, the air outlets are arranged on the inner wall of the through hole in a surrounding mode, and the air source is communicated with the air outlets. When the processed material leaves from feeding mechanism's terminal, pass the blow gun through the through-hole, utilize the venthole to blow off gas in order to weather the adnexed coolant liquid on the material surface, make the material can directly collect the storage, need not to shift the material to corresponding drying workshop and carry out drying operation, degree of automation is high, improves production efficiency.

Description

Automatic change equipment of attacking tooth

Technical Field

The utility model relates to the technical field of tapping equipment, in particular to automatic tapping equipment.

Background

The tapping equipment, also called tapping machine, is a machining equipment for machining internal threads, screws or tapping buttons on the inner side surfaces of holes of various parts with through holes or blind holes of different specifications, such as a part shell, an equipment end surface, a nut, a flange plate and the like. The existing tapping equipment is additionally provided with a cooling mechanism, and the cooling mechanism is used for spraying cooling liquid to materials so as to avoid overhigh temperature when the materials are tapped. However, the existing tapping equipment cannot dry materials, the materials after tapping need to be transferred to a corresponding workshop for drying treatment, the automation degree is low, and the production efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide automatic tapping equipment, which aims to solve the problems that the existing tapping equipment cannot dry materials, the materials after tapping are required to be transferred to a corresponding workshop for drying treatment, the automation degree is low, and the production efficiency is low.

In order to solve the technical problems, the utility model discloses: an automatic tapping device comprises a tapping mechanism, a feeding mechanism and a cooling mechanism, wherein the tapping mechanism is used for tapping materials on a station; the feeding mechanism is used for sending out the materials which are processed at the working positions and conveying the next material to the working position of the tapping mechanism; the cooling mechanism is used for spraying cooling liquid to the materials on the station; the device also comprises a blowing mechanism;

the blowing mechanism comprises an air source and a blowing nozzle, and the blowing nozzle is provided with a through hole and a plurality of air outlet holes; the blowing nozzle is arranged at the terminal of the feeding mechanism, the terminal of the feeding mechanism is communicated with the through hole, the air outlets are arranged around the inner wall of the through hole, and the air source is communicated with the air outlets.

As an optional implementation manner, the through hole comprises a blowing part and a limiting part, the input end of the blowing part is connected with the terminal of the feeding mechanism, the output end of the blowing part is connected with the input end of the limiting part, and the length of the blowing part is less than half of the length of a single material in the conveying direction; the air blowing part is horn-shaped, and the aperture of the input end of the air blowing part is larger than that of the output end of the air blowing part; the air outlet is arranged on the inner wall of the air blowing part, and the central axis of the air outlet is parallel to the central axis of the through hole.

As an optional implementation manner, the feeding mechanism comprises a material storage rack, a material conveying line rail and a material pushing assembly; the material conveying line rail is provided with a material conveying groove with an upward opening, and the length direction of the material conveying groove is arranged along the horizontal direction; the material pushing assembly comprises a material pushing driving part and a material pushing plate, the material pushing plate is laid on the bottom surface of the material conveying groove, the thickness of the material pushing plate is smaller than or equal to that of a single material, and the material pushing driving part is used for driving the material pushing plate to stretch and move along the length direction of the material conveying groove; the material storage rack is provided with a material groove, and the material groove extends downwards from the top surface of the material storage rack to the bottom surface of the material storage rack; the material storage rack is arranged on the top surface of the material conveying line rail, the material groove is communicated with the material conveying groove, and the distance from the bottom surface of the material storage rack to the bottom surface of the material conveying groove is larger than the thickness of a single material and smaller than the sum of the thickness of the single material and the thickness of the material pushing plate.

As an optional implementation manner, the blowing nozzle is further provided with a connecting part, the connecting part is in threaded connection with a terminal end of the material conveying line rail, and the through hole is communicated with the material conveying groove.

As an optional implementation manner, the tapping mechanism includes a lifting driving component, a lifting seat and a tapping drill, the lifting seat is located above the material conveying line rail, the tapping drill is installed at the bottom of the lifting seat and located above the material conveying groove, the lifting seat is in transmission connection with a driving end of the lifting driving component, and the lifting driving component is used for driving the lifting seat to ascend and descend.

As an optional embodiment, the lifting seat is provided with a connecting rod assembly and an adjusting rod, the connecting rod assembly comprises a first connecting rod, a second connecting rod, a first universal joint and a second universal joint, and the adjusting rod is arranged at the bottom of the lifting seat in a horizontally rotatable and horizontally movable manner;

the top end of the first connecting rod is connected with the lifting seat through a first universal joint;

the bottom end of the first connecting rod is connected with the top end of the second connecting rod through a second universal joint;

the bottom end of the second connecting rod is connected with the tapping drill bit;

one end of the adjusting rod is fixedly sleeved on the periphery of the second connecting rod.

As an optional implementation mode, the adjusting rod is provided with a strip-shaped hole, the strip-shaped hole extends along the length direction of the adjusting rod, a locking stud and a locking nut are arranged between the adjusting rod and the lifting seat, the head of the locking stud is fixed on the bottom surface of the lifting seat, and a screw rod of the locking stud passes through the strip-shaped hole and then is in threaded connection with the locking nut.

As an optional implementation manner, the cooling mechanism includes a cooling liquid tank, a power pump, and a flow guide pipe, an input end of the power pump communicates with the inside of the cooling liquid tank, the flow guide pipe is connected with an output end of the power pump, and an output end of the flow guide pipe is located below the lifting seat and is arranged toward a material located below the tapping drill bit.

Compared with the prior art, the embodiment of the utility model has the following beneficial effects:

in the embodiment of the utility model, the material which is processed at the station is sent out by the feeding mechanism, and the next material is conveyed to the station of the tapping mechanism, so that the material to be processed is continuously sent to the station. Tapping is carried out on the material through the tapping mechanism, the cooling mechanism is used for spraying cooling liquid on the material on the station, the temperature of the material in the tapping process is effectively reduced, the situation that tapping scraps are melted due to high temperature is avoided, the situation that the output end of the tapping mechanism is welded with the material is avoided, the tapping mechanism can effectively separate from the material, and the tapping of the material to be processed on the station is continuously carried out.

Wherein, when the material that has processed leaves from feeding mechanism's terminal, pass the blow gun through the through-hole, utilize the venthole to blow off gas in order to weather the attached coolant liquid on the material surface, make the material can directly collect the storage, need not to shift the material to corresponding drying shop and carry out drying operation, degree of automation is high, improves production efficiency. It is worth explaining that, through surrounding the air outlet holes on the inner wall of the through hole, the through hole can blow air out in a plurality of directions of the material, one surface of the material is effectively prevented from being dried, the other surface of the material is not dried, and the efficiency of drying the material is greatly improved.

Drawings

FIG. 1 is a schematic structural diagram of one embodiment of the present invention;

FIG. 2 is a schematic diagram of another perspective of the embodiment of FIG. 1;

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

FIG. 4 is a schematic cross-sectional view of a feeding mechanism according to one embodiment of the present invention;

FIG. 5 is a schematic view of a material inlet through hole of one embodiment of the present invention, but with its center of gravity still in the material trough;

FIG. 6 is a schematic view of the structure of the center of gravity of the material leaving the material trough according to one embodiment of the present invention;

FIG. 7 is a schematic structural view of a tapping mechanism according to an embodiment of the present invention;

FIG. 8 is a schematic diagram of the structure of the embodiment of FIG. 7 from another perspective;

in the drawings: 100-tapping mechanism, 110-lifting driving component, 120-lifting seat, 121-connecting rod component, 122-first connecting rod, 123-second connecting rod, 124-first universal joint, 125-second universal joint, 126-adjusting rod, 127-strip-shaped hole, 128-locking stud, 129-locking nut, 130-tapping drill bit, 200-feeding mechanism, 210-material storage rack, 211-material groove, 220-material conveying line rail, 221-material conveying groove, 230-material pushing component, 231-material pushing driving part, 232-material pushing plate, 300-cooling mechanism, 310-guide pipe, 400-air blowing mechanism, 410-blowing nozzle, 411-through hole, 412-air outlet hole, 413-air blowing part, 414-limiting part, 415-a connecting part.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Furthermore, features defined as "first" and "second" may explicitly or implicitly include one or more of the features for distinguishing between descriptive features, non-sequential, non-trivial and non-trivial.

With reference to fig. 1 to 8, an automatic tapping device according to an embodiment of the present invention is described below, including a tapping mechanism 100, a feeding mechanism 200, and a cooling mechanism 300, where the tapping mechanism 100 is used for tapping materials at a station; the feeding mechanism 200 is used for feeding out the materials which are processed at the working positions and conveying the next material to the working position of the tapping mechanism 100; the cooling mechanism 300 is used for spraying cooling liquid to the materials on the station; also comprises a blowing mechanism 400;

the blowing mechanism 400 comprises a gas source (not shown in the figure) and a blowing nozzle 410, wherein the blowing nozzle 410 is provided with a through hole 411 and a plurality of air outlet holes 412; the blowing nozzle 410 is arranged at the terminal of the feeding mechanism 200, the terminal of the feeding mechanism 200 is communicated with the through hole 411, a plurality of air outlets 412 are arranged around the inner wall of the through hole 411, and the air source is communicated with the air outlets 412. Specifically, a communication pipeline is arranged in the blowing nozzle 410, an output end of the air source is communicated to an input end of the communication pipeline, and each air outlet 412 is respectively used as an output end of the communication pipeline, so that the air source is communicated with the air outlet 412, and the air outlet 412 blows air to dry the material. More specifically, in this embodiment, the air source is an air tank that carries high pressure air. In other embodiments, the gas source may also be a nitrogen tank.

In the embodiment of the utility model, the material to be processed is continuously fed to the working stations by feeding the material which is processed at the working stations by the feeding mechanism 200 and conveying the next material to the working stations of the tapping mechanism 100. Tapping is carried out on the material through the tapping mechanism 100, the cooling liquid is sprayed on the material on the station through the cooling mechanism 300, the temperature of the material in the tapping process is effectively reduced, the situation that tapping scraps are melted due to high temperature is avoided, the situation that the output end of the tapping mechanism 100 is welded with the material is avoided, the tapping mechanism 100 can effectively separate from the material, and the tapping of the material to be processed on the station is continuously carried out.

Wherein, when the processed material left from feeding mechanism 200's terminal, passed blow gun 410 through-hole 411, utilized gas outlet 412 to blow out gas in order to weather the adnexed coolant liquid on the material surface, made the material can directly collect the storage, need not to shift the material to corresponding drying shop and carry out drying operation, degree of automation is high, improves production efficiency. It is worth explaining that, through surrounding the air outlet 412 on the inner wall of the through hole 411, the through hole 411 can blow air in a plurality of directions of the material, so that the situation that one surface of the material is dried and the other surface of the material is not dried is effectively avoided, and the efficiency of drying the material is greatly improved.

In an alternative embodiment, the through hole 411 includes a blowing portion 413 and a limiting portion 414, an input end of the blowing portion 413 is connected to a terminal of the feeding mechanism 200, an output end of the blowing portion 413 is connected to an input end of the limiting portion 414, and a length of the blowing portion 413 is less than half of a length of a single material in the conveying direction; the blowing part 413 is horn-shaped, and the aperture of the input end of the blowing part 413 is larger than that of the output end of the blowing part 413; the air outlet 412 is disposed on an inner wall of the air blowing part 413, and a central axis of the air outlet 412 is parallel to a central axis of the through hole 411. Specifically, as shown in the embodiment shown in fig. 5, the material is sheet-shaped, the blowing portion 413 is a hole formed by arranging four inclined planes in a trumpet shape, and the limiting portion 414 is a square hole and is in clearance fit with the material. Through being the setting of loudspeaker form with gas blowing portion 413, and the aperture of the input of gas blowing portion 413 is greater than the aperture of the output of gas blowing portion 413 realizes the aperture of increase through-hole 411 input, does benefit to the material and penetrates through-hole 411. Further, the gas outlet 412 is provided on the inclined surface of the gas blowing portion 413, and the central axis of the gas outlet 412 is parallel to the central axis of the through hole 411, so that the gas outlet 412 blows gas in the opposite direction to the material conveying direction. When the material passes through the blowing part 413, the gas flows in the opposite direction, so that the relative flow rate of the gas between the surfaces of the material is increased, the cooling liquid on the surface of the material is favorably taken away, and the cooling liquid is effectively prevented from entering the through hole 411. It is worth to say that due to the presence of the inclined surface, the gas discharged from the gas discharge holes is diffused toward the middle of the gas blowing portion 413, so that the gas is blown toward the material, thereby carrying away the cooling liquid on the surface of the material. It is further worth mentioning that by making the length of the blowing part 413 less than half the length of a single material in the transport direction. As shown in fig. 6, when the center of gravity of the material is still at the feeding mechanism 200, one end of the material away from the feeding mechanism 200 is suspended in the middle of the air blowing part 413, but the material can still be stably on the feeding mechanism 200. Along with the material passes through the through hole 411, when the center of gravity of the material is not located at the feeding mechanism 200, one end of the material far away from the feeding mechanism 200 enters the limiting portion 414 for limiting, so that the material is effectively prevented from inclining when passing through the air blowing portion 413, and the material is prevented from passing through the through hole 411.

In an alternative embodiment, the feeding mechanism 200 includes a material storage rack 210, a material conveying line rail 220 and a material pushing assembly 230; the material conveying line rail 220 is provided with a material conveying groove 221 with an upward opening, and the length direction of the material conveying groove 221 is arranged along the horizontal direction; the material pushing assembly 230 comprises a material pushing driving part 231 and a material pushing plate 232, the material pushing plate 232 is laid on the bottom surface of the material conveying groove 221, the thickness of the material pushing plate 232 is smaller than or equal to that of a single material, and the material pushing driving part 231 is used for driving the material pushing plate 232 to move in a telescopic manner along the length direction of the material conveying groove 221; the material storage rack 210 is provided with a material groove 211, and the material groove 211 extends downwards from the top surface of the material storage rack 210 to the bottom surface of the material storage rack 210; the material storage rack 210 is arranged on the top surface of the material conveying line rail 220, the material groove 211 is communicated with the material conveying groove 221, and the distance from the bottom surface of the material storage rack 210 to the bottom surface of the material conveying groove 221 is greater than the thickness of a single material and smaller than the sum of the thickness of the single material and the thickness of the material pushing plate 232.

Specifically, the pushing driving part 231 may be an air cylinder, a hydraulic cylinder, or an electric push rod. In this embodiment, the materials are stacked in the material grooves 211 of the material storage rack 210 layer by layer, when the material storage rack 210 is disposed on the top surface of the material conveying line rail 220, the material grooves 211 are communicated with the material conveying grooves 221, so that the material located at the bottom of the material grooves 211 falls on the bottom surface of the material conveying grooves 221, the material pushing driving portion 231 pushes the material pushing plate 232 to extend along the material conveying grooves 221 to push out the material falling in the material conveying grooves 221, at this time, the material pushing plate 232 replaces the pushed material, and the material located at the bottom of the material grooves 211 falls on the top surface of the material pushing plate 232. Then, the pushing driving part 231 drives the pushing plate 232 to reset, so that the material at the bottom of the material groove 211 falls on the bottom surface of the material conveying groove 221. The material pushing driving part 231 sequentially and circularly drives the material pushing plates 232 to move, so that the materials in the material grooves 211 can be pushed out one by one, and the materials are conveyed along the length direction of the material conveying grooves 221, and the materials to be processed are continuously conveyed to the stations. It should be noted that the thickness of the material pushing plate 232 is smaller than or equal to the thickness of a single material, so that when the material pushing plate 232 moves along the material conveying groove 221, only a single material can be pushed, and the material pushing plate 232 is prevented from pushing out multiple materials. Further, the distance from the bottom surface of the material storage rack 210 to the bottom surface of the material conveying groove 221 is greater than the thickness of a single material and smaller than the sum of the thickness of the single material and the thickness of the material pushing plate 232, so that when the material pushing plate 232 pushes out the bottommost material, the material of the penultimate layer is at least partially located in the material groove 211. When the material pushing plate 232 returns to the original position, at least a portion of the material on the top surface of the material pushing plate 232 is located in the material groove 211, so that the material falling on the material conveying groove 221 can only be moved by one reciprocating motion of the material pushing plate 232.

In an alternative embodiment, the blowing nozzle 410 is further provided with a connecting portion 415, the connecting portion 415 is in threaded connection with the terminal end of the material conveying line rail 220, and the through hole 411 is communicated with the material conveying groove 221. As shown in fig. 5, the blowing nozzle 410 is detachably mounted on the material conveying line rail 220 by screwing the connecting portion 415 to the terminal end of the material conveying line rail 220, so that the blowing nozzle 410 is convenient to mount and dismount, and cleaning and maintenance of the blowing nozzle 410 are facilitated.

In an alternative embodiment, the tapping mechanism 100 includes a lifting driving assembly 110, a lifting seat 120 and a tapping drill 130, the lifting seat 120 is located above the material conveying line rail 220, the tapping drill 130 is mounted at the bottom of the lifting seat 120 and located above the material conveying groove 221, the lifting seat 120 is in transmission connection with a driving end of the lifting driving assembly 110, and the lifting driving assembly 110 is used for driving the lifting seat 120 to ascend and descend. Specifically, in this embodiment, the lifting driving assembly 110 is a lifting column driven by a servo motor to lift through a gear, and the output is stable and the control is convenient. In other embodiments, the lifting drive mechanism may also be one of a pneumatic cylinder or a hydraulic cylinder. Since the feeding mechanism 200 pushes out the materials one by one, when the materials to be processed are located below the tapping drill 130, the lifting driving assembly 110 drives the lifting seat 120 to descend, so that the tapping drill 130 descends to tap the materials. After the machining is completed, the lifting driving assembly 110 drives the lifting base 120 to ascend, so that the tapping drill 130 ascends and resets to be separated from the material. Then the feeding mechanism 200 pushes the next material to be processed to the lower part of the tapping drill 130, and simultaneously pushes out the material which has been tapped, and the above circulation is performed, so that the automatic tapping of a plurality of materials is realized.

In an alternative embodiment, the lifting base 120 is provided with a connecting rod assembly 121 and an adjusting rod 126, the connecting rod assembly 121 comprises a first connecting rod 122, a second connecting rod 123, a first universal joint 124 and a second universal joint 125, and the adjusting rod 126 is horizontally rotatably and horizontally movably arranged at the bottom of the lifting base 120; the top end of the first connecting rod 122 is connected with the lifting seat 120 through a first universal joint 124; the bottom end of the first connecting rod 122 is connected with the top end of the second connecting rod 123 through a second universal joint 125; the bottom end of the second connecting rod 123 is connected with the tapping drill 130; specifically, the tapping drill 130 includes an electric drill and a tapping screw tap, and an electric drill is mounted at the bottom end of the second link 123 and is used to rotate the tapping screw tap. One end of the adjusting rod 126 is fixedly sleeved on the periphery of the second connecting rod 123. In this embodiment, the top end of the first connecting rod 122 is connected to the lifting base 120 through the first universal joint 124, and the bottom end of the first connecting rod 122 is connected to the top end of the second connecting rod 123 through the second universal joint 125, so that the second connecting rod 123 can change the position of the lifting base 120 through horizontal rotation and/or horizontal movement of the adjusting rod 126, so as to conveniently adjust the position of the tapping drill 130 according to the production requirements, and meet the processing requirements of different positions of materials, thereby improving the practicability of the present invention.

In an alternative embodiment, the adjusting rod 126 is provided with a strip-shaped hole 127, the strip-shaped hole 127 extends along the length direction of the adjusting rod 126, a locking stud 128 and a locking nut 129 are arranged between the adjusting rod 126 and the lifting seat 120, the head of the locking stud 128 is fixed on the bottom surface of the lifting seat 120, and the screw of the locking stud 128 passes through the strip-shaped hole 127 and then is in threaded connection with the locking nut 129. Thus, the locking nut 129 is screwed to clamp the adjusting rod 126, so that the adjusting rod 126 is fixed under the lifting seat 120, thereby fixing the position of the second connecting rod 123, preventing the second connecting rod 123 from being displaced when the lifting seat 120 is lifted, and further ensuring the accuracy of tapping and drilling. The adjusting rod 126 can move along the length direction by loosening the locking nut 129 and can horizontally rotate around the locking stud 128, so that the position of the second connecting rod 123 can be adjusted, the position adjusting range is wide, and the adjustment is simple.

In an alternative embodiment, the cooling mechanism 300 includes a cooling liquid tank (not shown), a power pump (not shown), and a flow guide pipe 310, the cooling liquid tank is used for loading cooling liquid, an input end of the power pump is communicated to the cooling liquid tank, the flow guide pipe 310 is connected to an output end of the power pump, and an output end of the flow guide pipe 310 is located below the lifting base 120 and is disposed toward the material located below the tapping drill 130. So, utilize the power pump to pump the inside coolant liquid of coolant liquid case to the output of honeycomb duct 310 and flow to the realization sprays the coolant liquid to the material on the station, simple structure, the coolant liquid sprays stably.

Other constructions and operation of an automated tapping apparatus according to embodiments of the utility model are known to those skilled in the art and will not be described in detail here.

In the description herein, references to the description of the terms "embodiment," "example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the utility model have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the utility model, the scope of which is defined by the claims and their equivalents.

Claims

1. An automatic tapping device comprises a tapping mechanism, a feeding mechanism and a cooling mechanism, wherein the tapping mechanism is used for tapping materials on a station; the feeding mechanism is used for sending out the materials which are processed at the working positions and conveying the next material to the working position of the tapping mechanism; the cooling mechanism is used for spraying cooling liquid to the materials on the station; the method is characterized in that: the device also comprises a blowing mechanism;

2. An automated tapping apparatus as claimed in claim 1, wherein: the through hole comprises an air blowing part and a limiting part, the input end of the air blowing part is connected with the terminal of the feeding mechanism, the output end of the air blowing part is connected with the input end of the limiting part, and the length of the air blowing part is less than half of the length of a single material in the conveying direction;

the air blowing part is horn-shaped, and the aperture of the input end of the air blowing part is larger than that of the output end of the air blowing part;

the air outlet is arranged on the inner wall of the air blowing part, and the central axis of the air outlet is parallel to the central axis of the through hole.

3. An automated tapping apparatus as claimed in claim 2, wherein:

the feeding mechanism comprises a material storage rack, a material conveying line rail and a material pushing assembly;

the material conveying line rail is provided with a material conveying groove with an upward opening, and the length direction of the material conveying groove is arranged along the horizontal direction;

the material pushing assembly comprises a material pushing driving part and a material pushing plate, the material pushing plate is laid on the bottom surface of the material conveying groove, the thickness of the material pushing plate is smaller than or equal to that of a single material, and the material pushing driving part is used for driving the material pushing plate to stretch and move along the length direction of the material conveying groove;

the material storage rack is provided with a material groove, and the material groove extends downwards from the top surface of the material storage rack to the bottom surface of the material storage rack; the material storage rack is arranged on the top surface of the material conveying line rail, the material groove is communicated with the material conveying groove, and the distance from the bottom surface of the material storage rack to the bottom surface of the material conveying groove is larger than the thickness of a single material and smaller than the sum of the thickness of the single material and the thickness of the material pushing plate.

4. An automated tapping apparatus as claimed in claim 3, wherein: the blowing nozzle is further provided with a connecting part, the connecting part is in threaded connection with the terminal of the material conveying line rail, and the through hole is communicated with the material conveying groove.

5. An automated tapping apparatus as claimed in claim 3, wherein: attack tooth mechanism and include lift drive assembly, lift seat and attack the tooth drill bit, the lift seat is located the top of material conveying line rail, attack the tooth drill bit install in the bottom of lift seat, and be located the top of material conveyer trough, the lift seat with lift drive assembly's drive end transmission is connected, lift drive assembly is used for the drive the lift seat rises and descends.

6. An automated tapping apparatus according to claim 5, wherein: the lifting seat is provided with a connecting rod assembly and an adjusting rod, the connecting rod assembly comprises a first connecting rod, a second connecting rod, a first universal joint and a second universal joint, and the adjusting rod is arranged at the bottom of the lifting seat in a horizontally rotatable and horizontally movable manner;

7. An automated tapping apparatus according to claim 6, wherein: the adjusting rod is provided with a strip-shaped hole, the strip-shaped hole extends along the length direction of the adjusting rod, the adjusting rod is provided with a locking stud and a locking nut between the lifting seat, the head of the locking stud is fixed on the bottom surface of the lifting seat, and a screw rod of the locking stud penetrates through the strip-shaped hole and then is in threaded connection with the locking nut.

8. An automated tapping apparatus according to claim 5, wherein: the cooling mechanism comprises a cooling mechanism body, a power pump and a flow guide pipe, wherein the cooling mechanism body comprises a cooling liquid box, the power pump and the flow guide pipe, the input end of the power pump is communicated into the cooling liquid box, the flow guide pipe is connected with the output end of the power pump, and the output end of the flow guide pipe is located below the lifting seat and faces to a material located below the tapping drill bit.