CN217894169U - Continuous feeding device - Google Patents
Continuous feeding device Download PDFInfo
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- CN217894169U CN217894169U CN202221015617.7U CN202221015617U CN217894169U CN 217894169 U CN217894169 U CN 217894169U CN 202221015617 U CN202221015617 U CN 202221015617U CN 217894169 U CN217894169 U CN 217894169U
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Abstract
The application provides a continuous feeding device, including feeding mechanism, feeding mechanism is used for sending panel to processing agency, continuous feeding device still includes: tailing conveying mechanism is located feeding mechanism's tail end, tailing conveying mechanism includes driving piece and non return subassembly, the output of driving piece is connected the non return subassembly, the driving piece drive the non return subassembly is along being on a parallel with feeding mechanism's pay-off direction reciprocating motion, the non return subassembly is used for driving feeding mechanism's pay-off direction removes extremely processing mechanism processes, and this application provides continuous material feeding unit, through feeding mechanism and the cooperation of tailing conveying mechanism to the realization provides panel to processing mechanism in succession, with the machining efficiency who promotes processing mechanism.
Description
Technical Field
The application relates to the technical field of machining, in particular to a continuous feeding device.
Background
In the plate processing process, the feeding mechanism is required to provide plates for the processing mechanism, and the feeding mechanism is required to continuously push the plates to the processing mechanism when the feeding mechanism provides the plates for the processing mechanism because the plates are flaky, so that the processing mechanism can continuously process the whole plates; when the plate is machined, the feeding mechanism needs to return to the original point to convey the plate again, and during the return period of the feeding mechanism, the machining mechanism does not have a new plate to be machined and needs to stop to wait, so that the machining time of the machining mechanism is wasted, and the machining efficiency is influenced.
SUMMERY OF THE UTILITY MODEL
In view of the above, it is necessary to provide a continuous feeding device for continuously providing the processing mechanism with the sheet material to be processed, so as to improve the processing efficiency.
The embodiment of the application provides a continuous feeding device, including feeding mechanism, feeding mechanism is used for sending panel to processing agency, continuous feeding device still includes:
the tailing conveying mechanism is located at the tail end of the feeding mechanism and comprises a driving piece and a non-return assembly, the output end of the driving piece is connected with the non-return assembly, the driving piece drives the non-return assembly to move in a reciprocating mode in the feeding direction of the feeding mechanism, and the non-return assembly is used for driving plates to move in the feeding direction of the feeding mechanism to the processing mechanism to process.
In one embodiment, the non-return assembly comprises a connecting piece, a non-return piece and an elastic piece, the connecting piece is connected with the output end of the driving piece, the non-return piece comprises a first rotating portion and a first abutting portion, the middle portion of the first rotating portion is rotatably connected with the connecting piece, one end portion of the first rotating portion is abutted to the connecting piece, the other end portion of the first rotating portion is abutted to the connecting piece through the elastic piece, and the first abutting portion is located on one side, away from the elastic piece, of the first rotating portion and abutted to the plate so as to drive the plate to move towards the machining mechanism in a one-way mode.
In one embodiment, the connecting element has a first receiving groove, the first rotating portion of the check element is rotatably connected to a sidewall of the first receiving groove, the elastic element is located in the first receiving groove, and one end of the elastic element abuts against a groove bottom of the first receiving groove.
In an embodiment, a first abutting groove is formed at the bottom of the first accommodating groove, and one end of the elastic member is accommodated in the first abutting groove.
In an embodiment, the first abutting portion includes a first sliding surface and a first abutting surface, the first abutting surface is arranged toward the direction of the processing mechanism, the first sliding surface is arranged opposite to the direction of the processing mechanism, the first sliding surface is arranged along the feeding direction of the feeding mechanism in an inclined manner, and the first abutting surface is arranged along the feeding direction perpendicular to the feeding mechanism and is used for abutting against the end surface of the plate to drive the plate to move unidirectionally toward the processing mechanism.
In one embodiment, the feeding mechanism comprises a feeding driving part and a conveying part which are connected, and the feeding driving part drives the conveying part to move.
In one embodiment, the conveying member includes a rotating shaft and a conveying belt, the conveying belt is sleeved on the rotating shaft, and the feeding driving member is connected with the rotating shaft and used for driving the rotating shaft to rotate so as to drive the conveying belt to move.
In an embodiment, the feeding mechanism further comprises a feeding assembly, and the feeding assembly is arranged on the conveying belt.
In an embodiment, the feeding assembly includes a supporting member, an abutting member and a feeding elastic member, the supporting member is disposed on the conveying belt, the abutting member includes a second rotating portion and a second abutting portion, a middle portion of the second rotating portion is rotatably connected to the supporting member, one end portion of the second rotating portion abuts against the supporting member, the other end portion of the second rotating portion abuts against the supporting member through the feeding elastic member, and the second abutting portion is located on a side of the second rotating portion away from the feeding elastic member and abuts against the plate, so as to drive the plate on the conveying belt to move toward the processing mechanism.
In an embodiment, the supporting member has a second receiving groove, the second rotating portion of the abutting member is rotatably connected to a sidewall of the second receiving groove, the feeding elastic member is located in the second receiving groove, and one end of the feeding elastic member abuts against a bottom of the second receiving groove.
The application provides a continuous feeding device, carry panel to the tail end through feeding mechanism, driving piece drive non return subassembly along the pay-off direction reciprocating motion who is on a parallel with feeding mechanism, and non return subassembly drives panel and moves to processing agency along the pay-off direction that is on a parallel with feeding mechanism and processes, and feeding mechanism returns the initial point and continues to provide panel to the realization is to the continuous pay-off of processing agency, thereby promotes panel machining efficiency.
Drawings
Fig. 1 is an assembly schematic diagram of a continuous feeding device and a processing mechanism according to an embodiment of the present invention.
Fig. 2 is a schematic perspective view of a check assembly according to an embodiment of the present invention.
Fig. 3 is a schematic perspective view of another angle of the check assembly according to an embodiment of the present invention.
Fig. 4 is an exploded view of the check assembly of fig. 2.
Fig. 5 is a schematic perspective view of a feeding assembly according to an embodiment of the present invention.
Fig. 6 is an exploded view of the feed assembly of fig. 5.
Description of the main elements
Check assembly 22
Feeding driving piece 11
The conveyor 12
Connecting piece 221
Check 222
First rotating part 2221
First receiving groove 2211
First abutting groove 2212
First sliding surface 2223
First end holding groove 2225
Feeding elastic member 133
Second rotating part 1321
Second abutting groove 1312
Second abutting surface 1323
Second sliding surface 1324
Detailed Description
Reference will now be made in detail to embodiments of the present application, 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 and are only for the purpose of explaining the present application and are not to be construed as limiting the present application.
The utility model provides a continuous feeding device, including feeding mechanism, feeding mechanism is used for sending panel to the processing agency, continuous feeding device still includes: the tailing conveying mechanism is located feeding mechanism's tail end, tailing conveying mechanism includes driving piece and non return subassembly, the output of driving piece is connected the non return subassembly, the driving piece drive the non return subassembly is along being on a parallel with feeding mechanism's pay-off direction reciprocating motion, the non return subassembly is used for driving panel is followed feeding mechanism's pay-off direction removes extremely processing mechanism processes.
Foretell continuous feeding device, carry panel towards the processing agency through feeding mechanism, reach feeding mechanism's tail end when panel, tailing conveying mechanism's driving piece drive non return subassembly along the pay-off direction reciprocating motion that is on a parallel with feeding mechanism, when the direction of motion of non return subassembly is opposite with the direction of transport of panel, the non return subassembly does not have the effort to panel, the direction of motion of non return subassembly is the same with the direction of transport of panel, the effort is applyed to panel to the non return subassembly, in order to drive panel and continue to move towards the processing agency, in order to realize providing panel to the processing agency in succession, thereby promote the machining efficiency of processing agency.
The embodiments of the present invention will be further described with reference to the accompanying drawings.
Referring to fig. 1, the present invention provides a continuous feeding device 100 for continuously feeding a sheet material 300 to a processing mechanism 200.
Wherein sheet material 300 is in the form of a sheet, and processing mechanism 200 is configured to process sheet material 300, for example, punch process sheet material 300.
Specifically, the continuous feeding device 100 comprises a feeding mechanism 10 and a tailing conveying mechanism 20, wherein the feeding mechanism 10 is used for conveying the plate 300 to the processing mechanism 200, the tailing conveying mechanism 20 is positioned at the tail end of the feeding mechanism 10, and the tailing conveying mechanism 20 is used for pushing the tailing of the plate 300 being conveyed to continue conveying to the processing mechanism 200 when the feeding mechanism 10 returns to convey the next plate 300 again; the tailing conveying mechanism 20 comprises a driving piece 21 and a non-return assembly 22, the output end 211 of the driving piece 21 is connected with the non-return assembly 22, the driving piece 21 drives the non-return assembly 22 to reciprocate along the feeding direction parallel to the feeding mechanism 10, and the non-return assembly 22 is used for driving the tailing of the plate 300 to be conveyed to the processing mechanism 200 for processing.
When the plate feeding mechanism 10 is used, the plate 300 is conveyed into the processing mechanism 200 by the feeding mechanism 10 to be processed on the plate 300, but the plate 300 cannot be completely conveyed into the processing mechanism 200, a tail material with a certain length is left, and then the feeding mechanism 10 needs to return to the initial end to continuously convey the next plate 300. During the return of the feeding mechanism 10, the tailing conveying mechanism 20 will continue to convey the tailing of the plate 300 being conveyed and processed into the processing mechanism 200 for processing. Specifically, the tailing conveying mechanism 20 is located at the tail end of the feeding mechanism 10, the driving element 21 drives the check assembly 22 to reciprocate in the feeding direction parallel to the feeding mechanism 10, when the movement direction of the check assembly 22 is opposite to the conveying direction of the plate 300, the check assembly 22 has no acting force on the plate or the acting force is smaller than a preset value, and the check assembly 22 cannot push the plate 300 to move in the direction opposite to the conveying direction of the plate 300; when the movement direction of the check assembly 22 is the same as the conveying direction of the sheet material 300, the check assembly 22 applies a force to the sheet material 300, and the check assembly 22 drives the tailing of the sheet material 300 to move further toward the processing mechanism 200 until the next sheet material 300 conveyed by the feeding mechanism 10 contacts the sheet material 300 being processed, so that the next sheet material 300 pushes the sheet material 300 being processed to be conveyed toward the processing mechanism 200. Through the cooperation of the feeding mechanism 10 and the tailing conveying mechanism 20, the tailing conveying mechanism 20 can continuously convey the plate 300 to the processing mechanism 200 when the feeding mechanism 10 returns, so that the plate 300 is continuously provided to the processing mechanism 200, and the processing efficiency of the processing mechanism 200 is improved.
In this embodiment, the driving member 21 is a cylinder.
Referring to fig. 1, in an embodiment, the feeding mechanism 10 includes a feeding driving member 11 and a conveying member 12 connected to each other, and the feeding driving member 11 drives the conveying member 12 to move. In this manner, the feeding driving member 11 drives the conveying member 12 to move, so as to convey the plate material 300 to the tail end of the feeding mechanism 10. It is understood that the continuous feeding device 100 further has a carrier for carrying the plate material 300, and the tailing conveying mechanism may be disposed on the carrier.
In this embodiment, the feeding driving member 11 is a motor.
In an embodiment, the conveying member 12 includes a rotating shaft 121 and a conveying belt 122, the conveying belt 122 is sleeved on the rotating shaft 121, the feeding driving member 11 is connected to the rotating shaft 121, and the feeding driving member 11 is used for driving the rotating shaft 121 to rotate so as to drive the conveying belt 122 to move. The feeding driving member 11 drives the rotating shaft 121 to rotate, so as to drive the conveying belt 122 to move, thereby conveying the plate 300 to the tail end of the feeding mechanism 10.
In this embodiment, the number of the rotating shafts 121 is two, one of the rotating shafts 121 is connected to the feeding driving member 11, the other rotating shaft 121 is fixedly disposed, and the conveying belt 122 is sleeved on the two rotating shafts 121.
In one embodiment, the feeding mechanism 10 further includes a feeding assembly 13, and the feeding assembly 13 is disposed on the conveyor belt 122. By disposing the feeding assembly 13 on the conveyor belt 122, the feeding assembly 13 conveys the sheet material 300 under the driving of the conveyor belt 122 to push the sheet material 300 to move toward the processing mechanism 200.
Referring to fig. 2 and 3, the check assembly 22 includes a connecting member 221, a check member 222 and an elastic member 223, the connecting member 221 is connected to the output end 211 of the driving member 21, the check member 222 includes a first rotating portion 2221 and a first abutting portion 2222, the middle portion of the first rotating portion 2221 is rotatably connected to the connecting member 221, one end of the first rotating portion 2221 abuts against the connecting member 221, the other end of the first rotating portion 2221 abuts against the connecting member 221 through the elastic member 223, and the first abutting portion 2222 is located on a side of the first rotating portion 2221 away from the elastic member 223 and abuts against the plate 300, so as to drive the plate 300 to move unidirectionally toward the processing mechanism 200.
When the non-return assembly 22 is used, the driving member 21 drives the non-return assembly 22 to reciprocate along the feeding direction parallel to the feeding mechanism 10, when the movement direction of the non-return assembly 22 is opposite to the conveying direction of the plate 300, the first abutting portion 2222 drives the first rotating portion 2221 to rotate due to the abutting thrust of the plate 300, the other end of the first rotating portion 2221 compresses the elastic member 223, and the first abutting portion 2222 rotates towards the direction far away from the plate 300, so that the first abutting portion 2222 moves towards the direction far away from the processing mechanism 200 when avoiding the plate 300, and the plate 300 cannot be driven to move; when the check assembly 22 moves to the end of the plate 300, the first abutting portion 2222 loses the abutting force of the plate 300 and returns to the initial state under the action of the elastic member 223, and at this time, the driving member 21 drives the check assembly 22 to move toward the conveying direction of the plate 300, so that the first abutting portion 2222 abuts against the end of the plate 300, because one end of the first rotating portion 2221 abuts against the connecting member 221 (as shown in fig. 3), the first rotating portion 2221 cannot rotate, and further the first abutting portion 2222 can stably abut against the end of the plate 300, thereby pulling the plate 300 to move toward the direction close to the processing mechanism 200 under the driving of the driving member 21.
Referring to fig. 4, in an embodiment, the connecting member 221 has a first receiving slot 2211, the first rotating portion 2221 of the check member 222 is rotatably connected to a sidewall of the first receiving slot 2211, the elastic member 223 is located in the first receiving slot 2211, and one end of the elastic member 223 abuts against a bottom of the first receiving slot 2211. The check 222 is received by the first receiving groove 2211 and defines a movable range of the check 222.
In an embodiment, a rotating shaft (not shown) may be disposed in the first receiving slot 2211, and the first rotating portion 2221 is rotatably sleeved on the rotating shaft to rotatably connect the first rotating portion 2221 and the connecting member 221, but in other embodiments, the first rotating portion 2221 may be rotatably connected to the connecting member 221 through other structures.
In an embodiment, a first abutting groove 2212 is disposed at the bottom of the first accommodating groove 2211, one end of the elastic member 223 is accommodated in the first abutting groove 2212, and the other end of the elastic member 223 abuts against the other end of the first rotating portion 2221. The elastic member 223 is received by the first abutting groove 2212 and the position of the elastic member 223 is defined.
In an embodiment, the first supporting portion 2222 includes a first sliding surface 2223 and a first supporting surface 2224, the first supporting surface 2224 is disposed toward the processing mechanism 200, the first sliding surface 2223 is disposed opposite to the processing mechanism 200, the first sliding surface 2223 is disposed obliquely along the feeding direction of the feeding mechanism 10, and the first supporting surface 2224 is disposed perpendicular to the feeding direction of the feeding mechanism 10, and is configured to support an end surface of the plate 300 to drive the plate 300 to move unidirectionally toward the processing mechanism 200.
When the non-return assembly 22 is used, the driving member 21 drives the non-return assembly 22 to reciprocate in the feeding direction parallel to the feeding mechanism 10, when the movement direction of the non-return assembly 22 is opposite to the conveying direction of the plate 300, the first sliding surface 2223 of the first abutting portion 2222 receives the abutting force of the plate 300, the first abutting portion 2222 drives the first rotating portion 2221 to rotate, the other end of the first rotating portion 2221 compresses the elastic member 223, so that the first sliding surface 2223 of the first abutting portion 2222 slides along the plate 300, and the friction between the first sliding surface 2223 of the first abutting portion 2222 and the plate 300 is small and is not enough to pull the plate 300 to move in the direction away from the processing mechanism 200; when the check assembly 22 moves to the end of the plate 300, the first supporting portion 2222 loses the pushing force of the plate 300 and returns to the initial state under the action of the elastic member 223, and at this time, the driving member 21 drives the check assembly 22 to move toward the conveying direction of the plate 300, so that the first supporting surface 2224 of the first supporting portion 2222 supports the end of the plate 300, and the first supporting surface 2224 of the first supporting portion 2222 receives the pushing force of the plate 300, the first supporting portion 2222 transmits an acting force to the first rotating portion 2221, but one end of the first rotating portion 2221 supports against the connecting member 221, and the first rotating portion 2221 cannot rotate, so that the first supporting surface 2224 of the first supporting portion 2222 and the plate 300 are kept in a supporting state, and the plate 300 is pulled by the driving member 21 to move toward the direction close to the processing mechanism 200.
In this embodiment, the first abutting surface 2224 is provided with a first end abutting groove 2225, the shape of the first end abutting groove 2225 is matched with the end of the plate 300, and when the first abutting portion 2222 is located between two plates 300, the end of the plate 300 abuts against the first end abutting groove 2225, so that the check member 222 drives the plate 300 to move toward the direction close to the processing mechanism 200.
In an embodiment, the tailing conveying mechanism 20 may convey the tailing of one plate 300 to the processing mechanism 200 at one time during the conveying of the tailing, or may convey the tailing of one plate 300 to the processing mechanism 200 multiple times by conveying only a certain length each time. When the tailing of one plate is conveyed to the processing mechanism 200 for multiple times, the processing mechanism 200 is provided with a limiting assembly (not shown), when the feeding mechanism 10 conveys the plate 300 to the tail end, the tailing conveying mechanism 20 continues to push the plate 300 to continue to move, because the driving element 21 drives the check assembly 22 to reciprocate along the direction parallel to the feeding direction of the feeding mechanism 10, when the movement direction of the check assembly 22 is the same as the conveying direction of the plate 300, the check assembly 22 pushes the plate 300 to move towards the processing mechanism 200, the limiting assembly is used for limiting the distance that the check assembly 22 pushes the plate 300 every time, for example, the length of the plate 300 is 30 centimeters, the limiting assembly limits the distance that the check assembly 22 pushes the plate 300 every time to be 10 centimeters, and then the driving element 21 drives the check assembly 22 to reciprocate three times along the direction parallel to the feeding direction of the feeding mechanism 10, so that the plate 300 with the length of 30 can be completely pushed to the processing mechanism 200.
Referring to fig. 5, the feeding assembly 13 includes a supporting member 131, a supporting member 132 and a feeding elastic member 133, the supporting member 131 is disposed on the conveying belt 122, the supporting member 132 includes a second rotating portion 1321 and a second supporting portion 1322, a middle portion of the second rotating portion 1321 is rotatably connected to the supporting member 131, one end portion of the second rotating portion 1321 is abutted to the supporting member 131, the other end portion of the second rotating portion 1321 is abutted to the supporting member 131 through the feeding elastic member 133, and the second supporting portion 1322 is located on a side of the second rotating portion 1321 departing from the feeding elastic member 133 and is abutted to the plate 300, so as to drive the plate 300 on the conveying belt 122 to move toward the processing mechanism 200. Thus, when the plate 300 is placed on the conveyor belt 122, the second abutting portion 1322 abuts against the end of the plate 300, and when the feeding driving member 11 drives the rotating shaft 121 to drive the conveyor belt 122 to move, the second abutting portion 1322 abuts against to push the plate 300 to move.
In an embodiment, the supporting member 131 has a second receiving slot 1311, the second rotating portion 1321 of the abutting member 132 is rotatably connected to a sidewall of the second receiving slot 1311, the feeding elastic member 133 is located in the second receiving slot 1311, and one end of the feeding elastic member 133 abuts against a slot bottom of the second receiving slot 1311.
In an embodiment, referring to fig. 6, a second abutting groove 1312 is formed at the bottom of the second receiving groove 1311, and one end of the feeding elastic member 133 is received in the second abutting groove 1312.
In one embodiment, the second abutting portion 1322 includes a second abutting surface 1323, the second abutting surface is disposed toward the processing mechanism 200, and the second abutting surface 1323 is disposed along a feeding direction perpendicular to the feeding mechanism 10, and is used for abutting against an end surface of the plate 300 to drive the plate 300 to move toward the processing mechanism 200.
Further, the second abutting portion 1322 further includes a second sliding surface 1324, the second sliding surface 1324 is disposed opposite to the processing mechanism 200, and the second sliding surface 1324 is disposed along the feeding direction of the feeding mechanism 10 in an inclined manner.
The application provides a continuous feeding device's an implementation process:
placing a plate 300 to be processed on the bearing piece above the continuous feeding device 100 of the present application, wherein the second abutting portion 1322 of the feeding mechanism 10 abuts against the end portion of the plate 300, the feeding driving member 11 drives the rotating shaft 121 to rotate, so as to drive the conveying belt 122 to move, and the second abutting portion 1322 abuts against the end portion of the plate 300, so as to push the plate 300 to move toward the processing mechanism 200 until the plate moves to the tailing conveying mechanism 20 at the tail end of the feeding mechanism 10; at this time, the feeding mechanism 10 returns to the end for abutting against the next plate 300; in the process of returning the feeding mechanism 10, the driving element 21 of the tailing conveying mechanism 20 drives the non-return assembly 22 to move in the direction opposite to the conveying direction of the plate 300, in this process, the first sliding surface 2223 of the first abutting portion 2222 receives the abutting force of the plate 300, the first abutting portion 2222 drives the first rotating portion 2221 to rotate, the other end portion of the first rotating portion 2221 compresses the elastic element 223, so that the first sliding surface 2223 of the first abutting portion 2222 slides along the plate 300, the friction between the first sliding surface 2223 of the first abutting portion 2222 and the plate 300 is small, and the friction is not enough to pull the plate 300 to move in the direction away from the processing mechanism 200; when the check assembly 22 moves to the end of the plate 300, the first supporting portion 2222 loses the supporting force of the plate 300 and returns to the initial state under the action of the elastic member 223, and at this time, the driving member 21 drives the check assembly 22 to move toward the conveying direction of the plate 300, so that the first supporting portion 2222 supports the end of the plate 300, and since one end of the first rotating portion 2221 supports against the connecting member 221, the first rotating portion 2221 cannot rotate, and further the first supporting portion 2222 can stably support against the end of the plate 300, so that the driving member 21 drives the plate 300 to move continuously toward the direction close to the processing mechanism 200. In this way, the feeding mechanism 10 and the tailing conveying mechanism 20 cooperate with each other to continuously convey the plate 300 for the processing mechanism 200, so as to improve the processing efficiency of the processing mechanism 200.
Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present application and not for limiting, and although the present application is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made to the technical solutions of the present application without departing from the spirit and scope of the technical solutions of the present application.
Claims (10)
1. The utility model provides a continuous feeding device, includes feeding mechanism, feeding mechanism is used for sending panel to processing agency, its characterized in that, continuous feeding device still includes:
the tailing conveying mechanism is located feeding mechanism's tail end, tailing conveying mechanism includes driving piece and non return subassembly, the output of driving piece is connected the non return subassembly, the driving piece drive the non return subassembly is along being on a parallel with feeding mechanism's pay-off direction reciprocating motion, the non return subassembly is used for driving panel is followed feeding mechanism's pay-off direction removes extremely processing mechanism processes.
2. Continuous feed device according to claim 1,
the non-return component comprises a connecting piece, a non-return piece and an elastic piece,
the connecting piece is connected with the output end of the driving piece,
the non-return piece comprises a first rotating portion and a first abutting portion, the middle of the first rotating portion is rotatably connected with the connecting piece, one end portion of the first rotating portion is abutted to the connecting piece, the other end portion of the first rotating portion is abutted to the connecting piece through the elastic piece, the first abutting portion is located on one side, away from the elastic piece, of the first rotating portion and abutted to the plate, and the plate is driven to move towards the machining mechanism in a one-way mode.
3. Continuous feed device according to claim 2,
the connecting piece is provided with a first accommodating groove, a first rotating part of the check piece is rotationally connected with the side wall of the first accommodating groove, and the elastic piece is located in the first accommodating groove and one end of the elastic piece is abutted to the groove bottom of the first accommodating groove.
4. Continuous feed device according to claim 3,
the bottom of the first containing groove is provided with a first abutting groove, and one end of the elastic piece is contained in the first abutting groove.
5. Continuous feed device according to claim 3,
the first abutting part comprises a first sliding surface and a first abutting surface,
the first abutting surface is arranged towards the direction of the processing mechanism, the first sliding surface is arranged opposite to the direction of the processing mechanism, the first sliding surface is obliquely arranged along the feeding direction of the feeding mechanism, and the first abutting surface is arranged along the feeding direction perpendicular to the feeding mechanism and used for abutting against the end surface of the plate so as to drive the plate to move towards the processing mechanism in a single direction.
6. Continuous feed device according to claim 1,
the feeding mechanism comprises a feeding driving part and a conveying part which are connected, and the feeding driving part drives the conveying part to move.
7. Continuous feed device according to claim 6,
the conveying part comprises a rotating shaft and a conveying belt, the conveying belt is sleeved on the rotating shaft, and the feeding driving part is connected with the rotating shaft and used for driving the rotating shaft to rotate so as to drive the conveying belt to move.
8. Continuous feed device according to claim 7,
the feeding mechanism further comprises a feeding assembly, and the feeding assembly is arranged on the conveying belt.
9. Continuous feed device according to claim 8,
the feeding assembly comprises a supporting piece, a supporting piece and a feeding elastic piece, the supporting piece is arranged on the conveying belt and comprises a second rotating portion and a second supporting portion, the middle portion of the second rotating portion is rotatably connected with the supporting piece, one end portion of the second rotating portion is abutted to the supporting piece, the other end portion of the second rotating portion is abutted to the supporting piece through the feeding elastic piece, and the second supporting portion is located on one side, away from the feeding elastic piece, of the second rotating portion and is abutted to the plate so as to drive the plate on the conveying belt to move towards the processing mechanism.
10. The continuous feeding device according to claim 9, wherein the supporting member has a second receiving groove, the second rotating portion of the abutting member is rotatably connected to a sidewall of the second receiving groove, the feeding elastic member is located in the second receiving groove, and one end of the feeding elastic member abuts against a bottom of the second receiving groove.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202221015617.7U CN217894169U (en) | 2022-04-28 | 2022-04-28 | Continuous feeding device |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202221015617.7U CN217894169U (en) | 2022-04-28 | 2022-04-28 | Continuous feeding device |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN217894169U true CN217894169U (en) | 2022-11-25 |
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202221015617.7U Active CN217894169U (en) | 2022-04-28 | 2022-04-28 | Continuous feeding device |
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| CN (1) | CN217894169U (en) |
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- 2022-04-28 CN CN202221015617.7U patent/CN217894169U/en active Active
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