A slotting and crimping mechanism and a carton forming machine including the same.
By designing a slotting and creasing mechanism with double-sided cutters, the problem of cardboard flipping when a carton forming machine and a digital printing machine are used together is solved, achieving efficient cardboard processing and high-quality creasing effect without flipping.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- QINGDAO AOPACK ON DEMAND PACKAGING CO LTD
- Filing Date
- 2025-07-01
- Publication Date
- 2026-07-03
AI Technical Summary
When existing carton forming machines are used in conjunction with digital printing machines, the cardboard needs to be flipped to change the orientation of the face paper, which increases the complexity of the process and reduces processing efficiency.
Design a grooving and creasing mechanism, comprising a grooving module, a creasing module and a power module, adopting a double-sided cutter design, which can perform grooving and creasing on the same side of the cardboard, adapting to processing requirements with the face paper facing up or the liner paper facing up.
It simplifies the cardboard processing steps, improves processing efficiency, ensures stitch quality, and makes the cardboard easier to bend.
Smart Images

Figure CN224447039U_ABST
Abstract
Description
Technical Field
[0001] This application belongs to the field of automated processing equipment for corrugated boxes, and particularly relates to a slotting and crimping mechanism and a carton forming machine including the same. Background Technology
[0002] The background description provided herein serves to give a general overview of the background of this application. The work to the extent described by the currently identified inventors in this background section, and aspects of this description that do not constitute prior art at the time of application, are neither expressly nor impliedly acknowledged as prior art in conflict with this application.
[0003] Currently, automated equipment for cardboard box forming mainly includes die-cutting machines, proofing machines, and cardboard box forming machines. Among them, existing cardboard box forming machines utilize the reciprocating motion of grooving and crease-setting knives to achieve grooving and crease-setting of the cardboard during processing.
[0004] For consistency, cardboard forming machines use blades on the same side of the cardboard for both grooving and stitching, with the face paper facing down and the liner paper facing up. This serves two purposes: first, it ensures optimal processing results, as the face paper is the thickest, hardest, and strongest component in the multi-layered structure of corrugated cardboard. Having the face paper facing down minimizes deformation during cutting, guaranteeing cut quality. Second, it ensures effective stitching, as stitching creates a deeper indentation on the stitching side to facilitate post-processing. To maintain a neat appearance and reduce stitching cracks, the relatively softer liner paper is used for stitching.
[0005] However, when digitally printing on cardboard, the cardboard needs to have the face paper facing up and the liner paper facing down in order to print text and patterns on the face paper. When existing carton forming machines are used in conjunction with digital printing machines, the cardboard needs to be flipped after processing by the carton forming machine so that the face paper faces up for the printing process. This undoubtedly increases the complexity of the process and reduces processing efficiency.
[0006] Therefore, a new device is needed to solve the above problems. Utility Model Content
[0007] This section presents the selection of utility model concepts in a simplified form, which will be further illustrated in the detailed description below. This section is not intended to identify key or essential features of the claimed subject matter, nor is it intended to assist in determining the scope of the claimed subject matter.
[0008] To address the problems existing in the prior art, this application provides a grooving and wire-catching mechanism, which includes a grooving module, a wire-catching module, and a first power module. The grooving module includes a grooving crossbeam, a grooving lower cutter mounting beam, a grooving cutter disposed on the grooving crossbeam, and a grooving lower cutter disposed on the grooving lower cutter mounting beam. The wire-catching module includes a wire-catching crossbeam, a first wire-catching cutter disposed on the grooving crossbeam, and a second wire-catching cutter disposed on the wire-catching crossbeam. The first power module is connected to the grooving crossbeam and the wire-catching crossbeam. The grooving lower cutter mounting beam is disposed opposite to the grooving cutter and the first wire-catching cutter, and the second wire-catching cutter is disposed on one side of the grooving lower cutter mounting beam.
[0009] Preferably, the grooving cutter and the first wire-contacting cutter are positioned above the grooving cutter mounting beam.
[0010] Preferably, the slotted cutting tool mounting beam has a first through groove along its length, and the slotted cutting tool is located on both sides of the first through groove along its length on the upper side of the slotted cutting tool mounting beam.
[0011] Preferably, the second wire-contacting knife is located on the underside of the slotting knife mounting beam and directly opposite the first through slot.
[0012] Preferably, the wire-contacting module further includes a wire-contacting support beam, which is disposed between the grooving knife, the first wire-contacting knife, and the grooving lower knife mounting beam.
[0013] Preferably, the first power module includes a cam mechanism, which is connected to both ends of the slotted crossbeam and the line-touching crossbeam.
[0014] Preferably, the wire-connecting support beam is provided with a second through groove along its length, and the grooving knife and the first wire-connecting knife are directly opposite the second through groove.
[0015] Preferably, the second through slot has protruding ribs on both sides along its length on the side facing the slotted cutting tool mounting beam.
[0016] Preferably, the slotted cutting tool mounting beam is a groove with the opening facing downwards, and the wire-connecting crossbeam is set in the groove.
[0017] Preferably, the wire-connecting support beam is a groove with an upward opening, and the grooving knife and the first wire-connecting knife are located in the groove.
[0018] Preferably, the slotting and wire-touch mechanism further includes a second power module, and the wire-touch support beam includes a first body and a second body connected to the second power module. The first body and the second body can move closer to or further away from each other in the horizontal direction under the drive of the second module.
[0019] Preferably, the opposing edges of the first body and the second body have protruding ridges along their respective length directions on the side facing the slotted cutting tool mounting beam.
[0020] Preferably, the grooving and wire-connecting mechanism further includes wall panels located at both ends of the grooving beam and the wire-connecting beam, and both ends of the grooving cutter mounting beam and the wire-connecting support beam are connected to the wall panels.
[0021] Preferably, the slotting and wire-connecting mechanism further includes a first height adjustment module, which is connected to the slotting crossbeam, thereby enabling adjustment of the vertical height of the slotting crossbeam.
[0022] Preferably, the first height adjustment module further includes a first slider connected to the slotted crossbeam, and the wall panel is provided with a first slide rail, with the first slider slidably connected to the first slide rail.
[0023] Preferably, the slotting wire-catching mechanism further includes a second height adjustment module, which is connected to the wire-catching beam, thereby enabling the adjustment of the height of the wire-catching beam in the vertical direction.
[0024] Preferably, the second height adjustment module further includes a second slider connected to the line-connecting beam, and the wall panel is provided with a second slide rail, with the second slider slidably connected to the second slide rail.
[0025] Preferably, the slotting and wire-catching mechanism further includes a third height adjustment module, which is connected to the wire-catching support beam, thereby enabling the adjustment of the height of the wire-catching support beam.
[0026] Preferably, the third height adjustment module is a lead screw and lead screw nut mechanism.
[0027] Preferably, the third height adjustment module further includes a third slider connected to the line support beam, and the wall panel is provided with a first slide rail, with the third slider slidably connected to the first slide rail.
[0028] In another aspect, this application also provides a carton forming machine, which includes a slotting and creasing mechanism according to the principles of this application. Attached Figure Description
[0029] Other or additional features, advantages, and details are presented by way of example only in the following detailed description of the embodiments. In the accompanying drawings:
[0030] Figure 1 The slotting and wire-catching mechanism according to the principles of this application, as well as its slotting beam and wire-catching beam, are schematically shown.
[0031] Figure 2 The grooving wire-catching mechanism according to the principles of this application, as well as its grooving cutter and grooving cutter mounting beam, are schematically shown.
[0032] Figure 3 A perspective view of a slotting wire-contacting mechanism according to the principles of this application is schematically shown;
[0033] Figure 4A schematic front view of a slotted wire-clamping mechanism according to the principles of this application is shown.
[0034] Figure 5 A side view of a slotting wire-contacting mechanism according to the principles of this application is schematically shown;
[0035] Figure 6 One embodiment of the line-supporting beam according to the principles of this application is illustrated schematically. Detailed Implementation
[0036] The following description is exemplary in nature and is not intended to limit this application, application, or use. Furthermore, it is not intended to be limited by any express or implied theory presented in the foregoing description of the technical field, background art, or utility model, or the following detailed description. It should be understood that throughout the drawings, corresponding reference numerals identify similar or corresponding parts or features.
[0037] This application will now be further elaborated. In the following paragraphs, different aspects of this application are defined in more detail. Unless expressly indicated to the contrary, each aspect so defined may be combined with any other aspect(s). In particular, any feature indicated as preferred or advantageous may be combined with any other feature(s) indicated as preferred or advantageous.
[0038] To address the problems existing in the prior art, this application provides a slotting and crimping mechanism that can be used in a carton forming machine. (See attached document.) Figure 1 and attached Figure 2 This paper illustrates a slotting and creasing mechanism 100 according to the principles of this application. The slotting and creasing mechanism 100 includes a slotting module, a creasing module, and a first power module. The slotting module includes a slotting crossbeam 110, a slotting blade 111 disposed on the slotting crossbeam 110, a slotting lower blade mounting beam 112, and a slotting lower blade 113 disposed on the slotting lower blade mounting beam 112. The creasing module includes a creasing crossbeam 120, a first creasing blade 114 disposed on the slotting crossbeam 110, and a second creasing blade 121 disposed on the creasing crossbeam 120. The slotting lower blade mounting beam 112 is disposed opposite to the slotting blade 111 and the first creasing blade 114, so that the slotting blade 111 and the slotting lower blade 113 disposed on the slotting lower blade mounting beam 112 cooperate to complete the slotting of the cardboard. The second grooving knife 121 is positioned on one side of the slotting lower knife mounting beam 112, that is, on the side opposite to the slotting knife 111 and the first grooving knife 114. Therefore, when the cardboard passes between the slotting knife 111, the first grooving knife 114, and the slotting lower knife mounting beam 112, the first grooving knife 114 or / and the second grooving knife 121 can be used to groove the cardboard, depending on the application scenario.
[0039] The first power module is connected to the grooving crossbeam 110 and the crimping crossbeam 120, thereby driving the two to reciprocate, which in turn drives the grooving knife 111 and the first crimping knife 114 on the first crossbeam 110, and the second crimping knife 121 on the crimping crossbeam 120 to reciprocate, so as to realize the grooving and crimping of the cardboard.
[0040] The first power module may include one or more identical or different power mechanisms. In some embodiments, the first power module may include one or more identical power mechanisms; for example, the first power module may include two identical cam mechanisms that simultaneously provide power to both the slotting beam 110 and the line-touching beam 120 from both sides. In some embodiments, the first power module may also include two or more power mechanisms with different structures or uses; for example, the slotting beam 110 may be driven by one set of cam mechanisms, and the line-touching beam 120 may be driven by another set of cam mechanisms. The slotting and line-touching mechanism 100 may also include a wall plate 170, which may be disposed at both ends of the slotting beam 110 and the line-touching beam 120. The first power module may be mounted on the wall plate 170 or the housing of the carton forming machine for fixation.
[0041] The grooving module may further include a grooving knife drive mechanism 116, which is connected to the grooving knife 111, thereby driving the grooving knife 111 to move along the length of the grooving beam 110 to meet the grooving requirements of cardboard of various widths. Those skilled in the art will readily understand that the grooving knife drive mechanism 116 can be of various types. For example, the grooving knife drive mechanism 116 can drive the grooving knife 111 through the cooperation of a lead screw and a lead screw nut, or it can drive the grooving knife 111 to move along the length of the grooving beam 110 through the cooperation of a gear and a rack, etc.
[0042] See attached document Figure 2 and attached Figure 5 The grooving blade 111 and the first grooving blade 114 can be positioned above the grooving lower blade mounting beam 112 to groove the cardboard from top to bottom, allowing the paper scraps generated during grooving to fall off under gravity. The grooving lower blade mounting beam 112 has a first through groove 115 along its length. The grooving lower blade 113 is located on the upper side of the grooving lower blade mounting beam 112, facing the grooving blade 111, and is positioned on both sides of the first through groove 115 along its length. When grooving, the grooving blade 111 can extend into the first through groove 115 and cooperate with the grooving lower blade 113 to cut the cardboard, thereby completing the grooving.
[0043] See attached document Figure 2 and attached Figure 5The second thread-matching knife 121 can be located below the slotting lower knife mounting beam 112 and directly opposite the first through slot 115. This allows the second thread-matching knife 121 to pass through the first through slot 115 to match the cardboard above it during thread matching. Side plates can be provided on both sides of the slotting lower knife mounting beam 112 along its length, making the slotting lower knife mounting beam 112 a downward-opening groove shape. The side plates enhance the strength of the slotting lower knife mounting beam 112. The thread-matching crossbeam 120 can be located within this groove, thus saving space and making the overall structure of the slotting thread-matching mechanism 100 compact. It should be understood that the thread-matching crossbeam 120 being located within this groove does not necessarily mean that it is completely within the groove; it may only be partially within the groove.
[0044] In some alternative embodiments, the grooving cutter 111 and the first wire-contacting cutter 114 may also be located below the grooving cutter mounting beam 112. In some alternative embodiments, the second wire-contacting cutter 121, which is located on the same side as the grooving cutter mounting beam 112, may not be located below the grooving cutter mounting beam 112, but may be located on the left and right sides of the grooving cutter mounting beam 112 in the width direction, so that it is offset from the grooving cutter 111 and the first wire-contacting cutter 114.
[0045] Refer to Annex 1 to Annex 2. Figure 5 The creasing module may further include a creasing support beam 122, which is positioned between the slotting knife 111, the first creasing knife 114, and the slotting lower knife mounting beam 112. When the second creasing knife 121 passes through the first through slot 115 to creasing the cardboard, the creasing support beam 122 can provide support or pressure to the cardboard, ensuring its stability during the creasing process. The creasing support beam 122 has a second through slot 123 along its length. The slotting knife 111 and the first creasing knife 114 face the second through slot 123, allowing them to pass through and slot and creasing the cardboard between the creasing support beam 122 and the slotting lower knife mounting beam 112.
[0046] See attached document Figure 5 The wire-connecting support beam 122 has side plates on both sides along its length and width, thus forming an upward-opening groove. The side plates enhance the strength of the wire-connecting support beam 122. The grooving cutter 111 is located within this groove, thereby saving space. It should be understood that the grooving cutter 111 being located within this groove does not necessarily mean that it is completely within the groove; it may only be partially within it.
[0047] Both ends of the slotted cutting and cutting installation beam 112 and the line-connecting support beam 122 can be connected to the wall panel 170 or to the housing of the carton forming machine. It should be understood that the connection in this application can be either a direct connection or an indirect connection.
[0048] See attached document Figure 1 In some embodiments, both the slotted crossbeam 110 and the wire-connecting crossbeam 120 may be provided with a cutout 101 to reduce their weight. The cutout 101 may be, for example, a rounded rectangle.
[0049] See attached document Figure 6 The second through groove 123 facing the slotted cutting blade mounting beam 112 can be provided with protruding ribs 124 on both sides of its length direction. The protruding ribs 124 extend along both sides of the length direction of the second through groove 123, so that when the second thread-fitting knife 121 is processing the cardboard thread, the protruding ribs 124 can support or press the cardboard, avoiding the problems of corrugation and bursting thread.
[0050] In some alternative embodiments, the creasing support beam 122 includes a first body and a second body, and the slotting creasing mechanism 100 includes a second power module. The second power module can be connected to the first body and the second body, thereby driving the first body and the second body to move closer or further apart in the horizontal direction. When the first body and the second body move closer together, that is, when they come to abut each other, the first body and the second body form a complete creasing support beam 122. In these embodiments, when the slotting knife 111 moves toward the slotting lower knife 113, the second power module drives the first body and the second body to move away from each other, so that the slotting knife 111 passes between them; when the second creasing knife 121 moves toward the creasing support beam 122, the second power module drives the first body and the second body to move closer together until they come to abut each other to form a complete creasing support beam 122, thereby providing support for the cardboard when creasing. At the opposite edges of the first body and the second body, that is, at the edges where they come to abut each other when they move closer together, a protruding ridge may be provided along their respective length directions on the side facing the slotting lower knife mounting beam 112. When the first body and the second body come into contact, the protruding ridge can provide support or pressure to the cardboard when the second thread cutter 121 makes a thread cut on the cardboard.
[0051] See attached document Figure 1 To be continued Figure 5In some embodiments, the first power module includes cam mechanisms 130 disposed at both ends of the slotting and crimping mechanism 100. The cam mechanism 130 includes a cam assembly 131 and a connecting shaft 132 connected to the cam assembly 131. The cam mechanism 130 is connected to both ends of the slotting beam 110 and the crimping beam 120 via the connecting shaft 132. When the cam assembly 131 rotates, it drives the connecting shaft 132 to reciprocate up and down, thereby driving the slotting cutter 111, the first crimping cutter 114, and the second crimping cutter 121 to reciprocate vertically. The cam assemblies 131 located at both ends of the slotting and crimping mechanism 100 can be connected via a transmission shaft 133 to achieve coaxial rotation. In some embodiments, the cam mechanism 130 may include a cam motor 134 connected to the cam assembly 131 to provide power to the cam assembly 131. In some alternative embodiments, the cam mechanism 130 may not include a cam motor, but instead obtain power from other power mechanisms of the carton forming machine. In some embodiments, the cam mechanism 130 may be an eccentric wheel mechanism. Thus, a single rotation of the cam in the cam mechanism 130 drives the grooving knife 111, the first thread-fitting knife 114, and the second thread-fitting knife 121 to move from both sides of the cardboard towards the cardboard, thereby completing the grooving and thread-fitting of the cardboard. It should be understood that, in alternative embodiments, the first power module may also include any mechanism capable of reciprocating the grooving knife 111, the first thread-fitting knife 114, and the second thread-fitting knife 121, such as a cylinder, a hydraulic cylinder, or a rack and pinion mechanism.
[0052] See attached document Figure 1 To be continued Figure 5 The grooving and wire-connecting mechanism 100 may further include a first height adjustment module 140, which is connected to the grooving beam 110. This allows adjustment of the vertical height of the grooving beam 110, thereby adjusting the height of the grooving blade 111 and the first wire-connecting blade 114 mounted on the grooving beam 110 to meet different grooving and wire-connecting depth requirements. The first height adjustment module 140 may include a first slider 141 connected to the grooving beam 110. The wall panel 170 is provided with a first slide rail 171, and the first slider 141 is slidably connected to the first slide rail 171, ensuring the stability of the grooving beam 110 during height adjustment. The first slider 141 may be directly connected to the grooving beam 110 or indirectly connected via connecting plates or other connecting components.
[0053] See attached document Figure 1 To be continued Figure 5The slotting and wire-catching mechanism 100 may further include a second height adjustment module 150, which is connected to the wire-catching beam 120. This allows adjustment of the vertical height of the wire-catching beam 120, thereby adjusting the height of the second wire-catching knife 121 mounted on the wire-catching beam 120 to meet different wire-catching depth requirements. The second height adjustment module 150 may include a second slider 151 connected to the wire-catching beam 120. The wall panel 170 is provided with a second slide rail 172, and the second slider 151 is slidably connected to the second slide rail 171, ensuring the stability of the wire-catching beam 120 during height adjustment. The second slider 151 may be directly connected to the wire-catching beam 120 or indirectly connected via connecting plates or other connecting components.
[0054] The slotting and creasing mechanism 100 may also include a third height adjustment module 160, which is connected to the creasing support beam 122, thereby adjusting the height of the creasing support beam 122 and thus adjusting the gap between the creasing support beam 122 and the slotting cutter mounting beam 112 to meet the processing requirements of paperboards of different thicknesses.
[0055] The third height adjustment module 160 can be a lead screw and lead screw nut mechanism, thereby achieving precise adjustment of the height of the line-connecting support beam 122 through the cooperation of the lead screw and lead screw nut. In some embodiments, the lead screw and lead screw nut mechanism may include a motor 161, a gear set 162, a drive shaft 163, a bearing assembly 164, a lead screw 165, and a lead screw nut 166. The drive shaft 163 and the lead screw 165 are connected to the wall plate 170 through the bearing assembly 164. The motor 161 and the gear set 162 are fixed to the wall plate 170. One end of the drive shaft 163 is connected to the motor 161 through the gear set 162, and the other end is connected to the lead screw 165. The lead screw nut 166 is connected to the line-connecting support beam 122 and is sleeved on the lead screw 165. The motor 161 can drive the lead screw 165 to rotate via the gear set 162 and the transmission shaft 163, thereby causing the lead screw nut 166 sleeved on the lead screw 165 to move along the lead screw 165, which in turn drives the wire-contact support beam 122 to move in the vertical direction. The third height adjustment module 160 can be set at both ends of the wire-contact support beam 122 so that the height of the wire-contact support beam 122 can be adjusted simultaneously from both ends.
[0056] The third height adjustment mechanism may also include a third slider 167 connected to the line-touching support beam 122. The third slider 167 is slidably connected to the first slide rail 171, thereby ensuring the stability of the line-touching support beam 122 when adjusting its height. The third slider 167 may be directly connected to the line-touching support beam 122, or it may be indirectly connected through connecting plates or other connecting components.
[0057] Because the slotting and creasing mechanism 100 of this application has a first creasing knife 114 and a second creasing knife 121 respectively arranged on opposite sides, it can crimp the cardboard from both sides. In scenarios where the carton forming machine is used in conjunction with a printing machine, the cardboard needs to be with the face paper facing upwards for printing. In this case, the creasing knife on the lower side can be used to crimp the cardboard on the inner paper side. In scenarios where the carton forming machine is not used in conjunction with a printing machine, the cardboard can be with the face paper facing downwards and the inner paper facing upwards. In this case, the creasing knife on the upper side can be used to crimp the cardboard on the inner paper side. Therefore, regardless of whether the carton forming machine is used in conjunction with a printing machine, the slotting and creasing mechanism 100 of this application can crimp the cardboard on the inner paper side, thus eliminating the need to flip the cardboard during processing, simplifying the process, and improving processing efficiency. Furthermore, depending on processing needs, the slotting and creasing mechanism 100 of this application can also crimp the cardboard on both sides, thereby further improving the crimping quality and making the cardboard easier to bend.
[0058] This application also provides a carton forming machine, which includes a slotting and creasing mechanism 100 according to the principles of this application, and thus has the beneficial effects brought about by the slotting and creasing mechanism 100.
[0059] While at least one exemplary embodiment has been described in the foregoing detailed description, it should be understood that numerous variations exist. It should also be understood that the one or more exemplary embodiments described herein are merely examples and are not intended to limit the scope, applicability, or construction of this application in any way. Rather, the foregoing detailed description will provide convenient guidance to those skilled in the art in implementing one or more exemplary embodiments. It should be understood that various changes, modifications, or alterations can be made to the function and arrangement of elements without departing from the scope of this application as set forth by the appended claims and their equivalents.
Claims
1. A slotting and wire contacting mechanism, characterized in that, The grooving and wire-catching mechanism includes a grooving module, a wire-catching module, and a first power module. The grooving module includes a grooving crossbeam, a grooving lower blade mounting beam, a grooving blade disposed on the grooving crossbeam, and a grooving lower blade disposed on the grooving lower blade mounting beam. The wire-catching module includes a wire-catching crossbeam, a first wire-catching blade disposed on the grooving crossbeam, and a second wire-catching blade disposed on the wire-catching crossbeam. The first power module is connected to the grooving crossbeam and the wire-catching crossbeam. The grooving lower blade mounting beam is disposed opposite to the grooving blade and the first wire-catching blade, and the second wire-catching blade is disposed on one side of the grooving lower blade mounting beam.
2. The slotting and wire brushing mechanism of claim 1, wherein, The slotted cutting tool mounting beam has a first through groove along its length, and the slotted cutting tool is located on both sides of the first through groove along its length.
3. The slotting and line-up mechanism of claim 2, wherein, The second wire-contacting knife is directly opposite the first through slot.
4. The slotting contact-making mechanism of claim 3, wherein, The wire-contacting module also includes a wire-contacting support beam, which is disposed between the grooving knife, the first wire-contacting knife, and the grooving lower knife mounting beam.
5. The slotting contact-making mechanism of claim 4, wherein, The first power module includes a cam mechanism, which is connected to both ends of the slotted crossbeam and the line-touching crossbeam.
6. The slotting contact-making mechanism of claim 5, wherein, The wire-connecting support beam has a second through groove along its length, and the grooving knife and the first wire-connecting knife are directly opposite the second through groove.
7. The slotting and wire-contacting mechanism as described in claim 6, characterized in that, The second through groove has protruding ridges on both sides along its length on the side facing the slotted cutting tool mounting beam.
8. The slotting contact-making mechanism of claim 7, wherein, The slotted cutting tool mounting beam is a downward-facing groove, and the wire-connecting crossbeam is disposed in the groove.
9. The slotting contact-making mechanism of claim 7, wherein, The wire-connecting support beam is a groove with an upward opening, and the grooving knife and the first wire-connecting knife are located in the groove.
10. The slotting contact-making mechanism of claim 5, wherein, The slotting and wire-touch mechanism further includes a second power module, and the wire-touch support beam includes a first body and a second body connected to the second power module. The first body and the second body can move closer to or further away from each other in the horizontal direction under the drive of the second module.
11. The slotting and wire brushing mechanism of claim 10, wherein, The first body and the second body have protruding ridges along their respective lengths on the opposite edges facing the slotted cutting tool mounting beam.
12. A slotting and line-up mechanism as claimed in any one of claims 4 to 11, characterised in that, The slotting and wire-connecting mechanism also includes wall panels located at both ends of the slotting beam and the wire-connecting beam, and both ends of the slotting cutter mounting beam and the wire-connecting support beam are connected to the wall panels.
13. The slotting and wire-contacting mechanism as described in claim 12, characterized in that, The slotting and wire-connecting mechanism also includes a first height adjustment module, which is connected to the slotting beam to adjust the height of the slotting beam in the vertical direction.
14. The slotting and wire brushing mechanism of claim 13, wherein, The first height adjustment module also includes a first slider connected to the slotted crossbeam, and the wall panel is provided with a first slide rail, with the first slider slidably connected to the first slide rail.
15. The slotting and wire-contacting mechanism as described in claim 12, characterized in that, The slotted wire-connecting mechanism also includes a second height adjustment module, which is connected to the wire-connecting beam, thereby enabling adjustment of the height of the wire-connecting beam in the vertical direction.
16. The slotting and wire brushing mechanism of claim 15, wherein, The second height adjustment module also includes a second slider connected to the line-connecting beam, and the wall panel is provided with a second slide rail, with the second slider slidably connected to the second slide rail.
17. The grooved strike mechanism of claim 12 wherein, The slotting and wire-catching mechanism also includes a third height adjustment module, which is connected to the wire-catching support beam, thereby enabling adjustment of the height of the wire-catching support beam.
18. The slotting and wire brushing mechanism of claim 17, wherein, The third height adjustment module is a lead screw and lead screw nut mechanism.
19. The grooved strike mechanism of claim 18 wherein, The third height adjustment module also includes a third slider connected to the line support beam, and the wall panel is provided with a first slide rail, with the third slider slidably connected to the first slide rail.
20. A cardboard box forming machine, characterized in that, The carton forming machine includes a grooving and crimping mechanism as described in any one of claims 1-19.