CN217195502U - Material cutting system - Google Patents

Abstract

The application provides a material cutting system for material cuts and balance on the material area, the material area includes material area main part, material and connecting portion, the material passes through connecting portion with the material area main part is connected, material cutting system cuts the mechanism and connects material transfer mechanism including dialling the material, wherein, dial the material and cut the mechanism and include: dial material mechanism and cut the mechanism, connect material transfer mechanism to include first receiving device, be used for when connecting portion are cut off, bear the weight of the material. From this, the material system of cutting that this application provided can finely cut material and waste material to carry out the material through automated machine and balance, improve production efficiency and production quality.

Description

Material cutting system

Technical Field

The application relates to the field of machinery, in particular to a material cutting system.

Background

With the development of large-scale production process, the automatic vibration plate material placing and manual plate placing technology is widely applied. However, the material throwing rate of the automatic vibration disc material swinging technology is high, and the material swinging success rate is related to the experience of operators; the manual tray placing technology has large requirements on manpower, high manual operation error rate and low production efficiency.

SUMMERY OF THE UTILITY MODEL

In view of the above problem, the application provides a material cutting system, can finely cut the material to carry out the material balance through automated machinery, improve production efficiency and production quality.

The application provides a material cutting system for material takes cutting and balance of material, and the material area includes material area main part, material and connecting portion, and the material passes through connecting portion and is connected with the material area main part, and material cutting system cuts the mechanism and connects material transfer mechanism including dialling the material, and wherein, it includes to dial the material to cut the mechanism: the material poking mechanism comprises a slideway, the slideway is used for accommodating a material belt, and the material belt moves in the slideway; the cutting mechanism comprises a first driving device, a first cutter set and a second cutter set, the first cutter set is connected with the first driving device, the second cutter set is arranged on the slideway, the first driving device is used for driving the first cutter set to move close to or far away from the second cutter set in a reciprocating mode, the material belt is located between the first cutter set and the second cutter set, and when the first cutter set moves to be meshed with the second cutter set, the connecting portion of the material belt is cut off to enable the material to be separated from the material belt main body; the material receiving and transferring mechanism comprises a first material receiving device, wherein the first material receiving device and the bottom of the slide way are arranged at intervals and used for bearing materials when the connecting portion is cut off.

In some possible implementation manners, the material receiving and transferring mechanism further comprises a second material receiving device, the second material receiving device and the first material receiving device are arranged at intervals, the first material receiving device and the second material receiving device are fixed on a fixing plate, the first material receiving device and the second material receiving device are perpendicular to the fixing plate, the fixing plate is fixed on a translation shaft along the direction of the material belt, and the fixing plate is driven by a second driving device to reciprocate along the translation shaft so as to realize continuous material receiving.

In some possible implementation modes, the material receiving transfer mechanism further comprises a first turnover shaft and a second turnover shaft, when the first material receiving device bears the material, the first material receiving device moves towards the direction perpendicular to the material belt and far away from the material belt, the fixing plate moves horizontally along the translation shaft to drive the first material receiving device to move along the direction close to the first turnover shaft, when the first material receiving device moves to the position below the first turnover shaft, the first material receiving device is driven to ascend by a third driving device connected to the bottom of the first material receiving device, the top of the first material receiving device and the bottom of the first turnover shaft are located on the same horizontal plane, the first turnover shaft absorbs the material to the bottom of the first turnover shaft and turns over, and the third driving device drives the first material receiving device to descend to complete material transfer.

In some possible implementation manners, when the first material receiving device bears the material, the fixing plate drives the second material receiving device to move along the direction close to the slide way, when the material receiving device moves to the position below the slide way, the second material receiving device is driven to ascend by the third driving device connected to the bottom of the second material receiving device, the second material receiving device and the slide way are located on the same horizontal plane, the second material receiving device bears the material, and the third driving device drives the second material receiving device to descend.

In some possible implementation manners, the first knife group comprises a first sub-knife group and a second sub-knife group, the first sub-knife group and the second sub-knife group both comprise at least two cutting edges, the first sub-knife group and the second sub-knife group are arranged in a pairwise adjacent manner, and the vertical distance between the cutting edge in the first sub-knife group and the material belt is smaller than the vertical distance between the cutting edge in the second sub-knife group and the material belt.

In some possible implementation modes, a first positioning hole is formed in the material belt, a positioning needle is arranged on the material shifting mechanism, and when the material belt is moved to a specific position after being cut once, the positioning needle is matched with the first positioning hole and used for positioning the material belt.

In some possible implementation manners, the connecting portion of the material belt includes a first connecting portion and a second connecting portion, the second knife group includes a third sub-knife group and a fourth sub-knife group, the third sub-knife group is arranged relative to the first connecting portion, the fourth sub-knife group is arranged relative to the second connecting portion, when a knife edge in the first knife group is engaged with a knife edge in the third sub-knife group, the first connecting portion is cut off, and when a knife edge in the first knife group is engaged with a knife edge in the fourth sub-knife group, the second connecting portion is cut off.

In some possible implementations, the material shifting and cutting mechanism further includes a waste material cutting mechanism, and when the material in the material belt is cut off by the cutting mechanism, the waste material cutting mechanism is used for cutting the remaining material belt.

In some possible implementation manners, positioning pins are arranged on the first material receiving device and the second material receiving device, and the positioning pins are matched with the second positioning holes and used for positioning the position of the material.

In some possible implementation manners, the bottom of each of the first turnover shaft and the second turnover shaft is provided with an air exhaust hole for absorbing the material carried by the first material receiving device or the material receiving device onto the first turnover shaft or the second turnover shaft through vacuum.

From this, the material system of cutting that this application provided can finely cut material and waste material to carry out the material through automated machine and balance, improve production efficiency and production quality.

Drawings

Fig. 1 is a schematic structural diagram of a material balance system according to an embodiment of the present application.

Fig. 2 is a schematic structural view of the material setting and cutting mechanism in fig. 1.

Figure 3 is a schematic view of a portion of the web of figure 2.

Fig. 4 is a partial structure schematic diagram of the material stirring and cutting mechanism in fig. 2.

Fig. 5 is a schematic structural view of the first knife set in fig. 2.

Fig. 6 is a schematic structural view of the second knife set in fig. 2.

Fig. 7 is a schematic structural view of the material receiving and transferring mechanism in fig. 1.

Fig. 8 is a partial structure schematic diagram of the receiving material transfer mechanism in fig. 7.

Fig. 9 is a side view of the receiving device in fig. 8.

Fig. 10 is a schematic view of the second flipping axis of fig. 7.

Description of the main elements

Material balance system 100

Material-poking and cutting mechanism 10

Material receiving and transferring mechanism 20

Material taking mechanism 30

Material tray receiving mechanism 40

First drive device 101

First knife tackle 102

Slide 103

Material belt 104

Second knife tackle 105

Waste cutting mechanism 106

First connection portion 107

Second connecting portion 108

Material 109

First material 1091

Second material 1092

First positioning hole 110

Second pilot hole 1101

Positioning pin 111, 2021

Waste tape 112

Kick-out device 113

Kick-off mechanism 114

Cutting mechanism 115

The first sub-knife set 1021

Second sub-knife set 1022

Knife edges 1023, 1024

Casing 1025, 1053, 2024

Sliding part 1026

Third sub-group 1051

Fourth sub-knife group 1052

First receiving device 201

Receiving device 202

Fixing plate 203

First flipping axis 205

Second flipping axis 204

Second drive device 206

Third drive device 207

Guide rail 208

Vacuum valve 2022

Extraction hole 2023

Fourth drive 2041

Rotating shaft 2042

Support 2043

The following detailed description of the invention will be further described in conjunction with the above-identified drawings.

Detailed Description

In the embodiments of the present application, the terms "first", "second", and the like are used only for distinguishing different objects, and are not intended to indicate or imply relative importance, nor order to indicate or imply order. For example, a first application, a second application, etc. is used to distinguish one application from another application and not to describe a particular order of applications, and features defined as "first" and "second" may explicitly or implicitly include one or more of the features.

Referring to fig. 1, a schematic structural diagram of a material balance system 100 according to an embodiment of the present application is shown. The material placing plate system 100 may include a material shifting and cutting mechanism 10, a material receiving and transferring mechanism 20, a material taking mechanism 30 and a material tray receiving mechanism 40, wherein the material shifting and cutting mechanism 10 is used for cutting materials on a material belt, the material receiving and transferring mechanism 20 is used for bearing and turning over the cut materials, and the material taking mechanism 30 may be used for transferring the materials from the material receiving and transferring mechanism 20 to the material tray receiving mechanism 40. In one embodiment, the reclaiming mechanism 30 may be a robot structure. The tray receiving mechanism 40 includes a tray for receiving the material.

Please refer to fig. 2, which is a schematic structural diagram of a setting mechanism 10 according to an embodiment of the present application. The material shifting and cutting mechanism 10 comprises a material shifting mechanism 114, a cutting mechanism 115 and a waste material cutting mechanism 106, wherein the material shifting mechanism 114 comprises a slide way 103 and a material shifting device 113, the cutting mechanism 115 comprises a first driving device 101, a first cutter set 102 and a second cutter set 105, the slide way 103 is approximately in a hollow shape, the slide way 103 is used for accommodating the material belt 104, it can be understood that the extending direction of the hollow area of the slide way 103 is consistent with the extending direction of the material belt 104, and the material belt 104 is arranged in the hollow area of the slide way 103. The first knife group 102 is arranged at the bottom of the first driving device 101, the first knife group 102 and the slide way 103 are arranged at intervals, the first knife group 102 is arranged above the slide way 103, the first driving device 101 is used for driving the first knife group 102 to move in a reciprocating mode along the direction perpendicular to the material belt 104 so as to cut the material belt 104, the second knife group 105 is arranged in the hollow area of the slide way 103, the second knife group 105 is arranged below the material belt 104, and the second knife group 105 is used for being meshed with the first knife group 102 so as to cut the material belt 104.

In some embodiments, the waste cutting mechanism 106 is disposed at one end of the slide channel 103 extending along the sliding direction of the material belt 104, and a hollow area is disposed in the waste cutting mechanism 106, through which the slide channel 103 passes. After the material belt 104 is cut by the first knife set 102 and the second knife set 105, the waste cutting mechanism 106 is used for cutting the remaining part of the material belt 104 to complete the waste cutting of the material belt 104.

Referring to fig. 3, fig. 3 is a schematic top view of a partial structure of the material belt 104, the material belt 104 includes a material belt main body, materials 109 and a connecting portion, in some embodiments, the material belt main body includes a first positioning hole 110 and a waste material belt 112, the connecting portion includes a first connecting portion 107 and a second connecting portion 108, the materials 109 include a first material 1091 and a second material 1092, the first material 1091 is substantially L-shaped, the first material 1091 and the second material 1092 have the same structure, the first material 1091 and the second material 1092 are disposed opposite to each other, the first material 1091 is connected to the waste material belt 112 through the first connecting portion 107, the second material 1092 is connected to the waste material belt 112 through the second connecting portion 108, the first material 1091 and the second material 1092 are both provided with a second positioning hole 1101, the first positioning hole 110 and the second positioning hole 1101 are substantially circular, and the first positioning holes 110 are disposed uniformly along two long sides of the waste material belt 112, for cooperating with a positioning pin 111 (see also fig. 4) provided on the kickoff 113 for positioning the material web 104.

Referring to fig. 4, fig. 4 is a schematic partial structure view of the setting mechanism 114, the setting device 113 is fixed on the upper surface of the chute 103, and a positioning pin 111 is disposed on a surface of the setting device 113 opposite to the chute 103, it can be understood that the positioning pin 111 can be adapted to the first positioning hole 110 disposed on the material belt 104 to complete the positioning function of the material belt 104.

It can be appreciated that the positioning of the material belt 104 by the material ejecting mechanism 114 can improve the cutting accuracy of the material belt 104 by the first knife group 102 and the second knife group 105, and reduce the risk of material breakage.

Please refer to fig. 5, which is a schematic structural diagram of the first blade set 102 according to an embodiment of the present disclosure. The first blade set 102 includes a housing 1025, a sliding portion 1026, a first sub-blade set 1021, a second sub-blade set 1022, and a blade 1023 disposed at a bottom end of the first sub-blade set 1021 and a blade 1024 disposed at a bottom end of the second sub-blade set 1022, respectively. In some embodiments, the first blade set includes a plurality of first sub-blade sets 1021 and a plurality of second sub-blade sets 1022, and the plurality of first sub-blade sets 1021 and the plurality of second sub-blade sets 1022 are arranged at intervals, that is, there is only one second sub-blade set 1022 between two adjacent first sub-blade sets 1021. In some embodiments, the first sub-blade set 1021 includes at least two sliding portions 1026, the second sub-blade set 1022 also includes at least two sliding portions 1026, and the sliding portions 1026 of the first sub-blade set 1021 and the sliding portions 1026 of the second sub-blade set 1022 are disposed one by one adjacent to each other.

In some embodiments, the cutting edge 1023 and the cutting edge 1024 are disposed at the bottom end of the sliding part 1026, and the cutting edge 1023 may comprise at least two cutting edges, one blade for cutting the first connecting portion 107 on the material belt 104 and the other blade for cutting the second connecting portion 108 on the material belt 104, it is understood that the blade 1024 may include at least two blades, one blade is used for cutting a first connecting part 107 on the material belt 104, the other blade is used for cutting a second connecting part 108 on the material belt 104, in some embodiments, the vertical distance of the blade edge 1023 in the first sub-blade set 1021 from the web 104 is greater than the vertical distance of the blade edge 1024 in the second sub-blade set 1022 from the web 104, in other embodiments, the vertical distance of the blade edge 1023 in the first sub-blade set 1021 from the web 104 may be less than the vertical distance of the blade edge 1024 in the second sub-blade set 1022 from the web 104.

Optionally, the blade set installation heights of the first sub-blade set 1021 and the second sub-blade set 1022 are different, or the lengths of the blades in the first sub-blade set 1021 and the second sub-blade set 1022 are different, or the lengths of the sliding portions 1026 in the first sub-blade set 1021 and the second sub-blade set 1022 are different, so that the vertical distance from the blade 1023 in the first sub-blade set 1021 to the material belt 104 is different from the vertical distance from the blade 1024 in the second sub-blade set 1022 to the material belt 104.

It can be appreciated that, because the vertical distance from the blade edge of the first sub-blade set 1021 to the material belt 104 is not the same as the vertical distance from the material belt 104 in the second sub-blade set 1022, the time when two adjacent materials 109 on the material belt 104 are cut is not the same, for example, if the vertical distance from the blade edge 1023 of the first sub-blade set 1021 to the material belt 104 is greater than the vertical distance from the blade edge 1024 of the second sub-blade set 1022 to the material belt 104, the material 109 corresponding to the first sub-blade set 1021 is cut earlier when cutting, and the material 109 corresponding to the second sub-blade set 1022 is cut later when cutting, the difference between the cutting time of the two adjacent materials 109 is the difference between the vertical distances from the blade edge of the first sub-blade set 1021 and the blade edge of the second sub-blade set 1022 to the material belt 104 divided by the moving speed of the first driving device 101 when cutting. Therefore, the deformation risk of the material 109 in the cutting process can be reduced, the driving efficiency of the first driving device 101 is improved, and the cutting force of the material cutting belt 104 is reduced. The housing 1025 of the first blade set 102 includes at least two elongate grooves for receiving the sliding portion 1026, and the sliding portion 1026 may be pushed in the elongate grooves by the first drive 101 to slide reciprocally in a direction perpendicular to the material web 104 such that the cutting edges 1023 and 1024 contact the first and second connections 107 and 108 on the material web 104 to engage with the cutting edges in the second blade set 105 to cut the material 109 on the material web 104.

Please refer to fig. 6, which is a schematic structural diagram of the second knife set 105 according to an embodiment of the present application. The second knife tackle 105 includes a housing 1053, a third sub-knife tackle 1051 and a fourth sub-knife tackle 1052, wherein the housing 1053 is substantially rectangular, a hollow area is arranged in the middle, the material belt 104 passes through the hollow area, the first sub-knife tackle 1021 includes at least two blades, the at least two blades are arranged on one side of the long side of the housing 1053 at intervals, the second sub-knife tackle 1022 also includes at least two blades, the at least two blades are arranged on the other side of the long side of the housing 1053 at intervals, and the blades of the first sub-knife tackle 1021 and the blades of the second sub-knife tackle 1022 are arranged oppositely.

When the first driving device 101 drives the sliding portion 1026 of the first knife group 102 to slide in a direction close to the material belt 104, the knife edge 1023 and the knife edge 1024 on the first knife group 102 engage with the third sub-knife group 1051 and the fourth sub-knife group 1052 in the second knife group 105 to cut the first connecting portion 107 and the second connecting portion 108, and the cutting of the material 109 is completed. The remainder of the web 104 (i.e., the scrap web 112) will be cut by the scrap cutter mechanism 106 and discarded.

Referring to fig. 7, fig. 7 is a schematic structural diagram of the material receiving and transferring mechanism 20. The material receiving and transferring mechanism 20 comprises a first material receiving device 201, a material receiving device 202, a fixing plate 203, a first turning shaft 205 and a second turning shaft 204, wherein, the length of the first material receiving device 201 is not less than the length of the first knife group 102 and the second knife group 105 along the extending direction of the slide 103, and the first material receiving device 201 is arranged below the hollow area of the slide 103, when the first knife set 102 and the second knife set 105 finish cutting the material 109, the material 109 moves downwards due to gravity, the first material receiving device 201 is used for bearing the material 109 cut when the first knife set 102 is engaged with the second knife set 105, one end of the first material receiving device 201 along the sliding direction of the material belt 104 is fixed with the fixing plate 203, and the fixing plate 203 is also connected with one end of the receiving device 202 along the sliding direction of the material belt 104, the fixing plate 203 is used for fixing the receiving device 202, and the fixing plate 203 is perpendicular to the first receiving device 201 and the receiving device 202.

The first turnover shaft 205 and the second turnover shaft 204 are respectively arranged on two sides of the chute 103, the first turnover shaft 205 is arranged opposite to the first material receiving device 201, the second turnover shaft 204 is arranged opposite to the material receiving device 202, the first turnover shaft 205 is used for adsorbing the material 109 loaded on the first material receiving device 201 and turning the material 109 over, and the material taking mechanism 30 can transfer the turned material 109 to the material tray receiving mechanism 40 to complete the swinging of the material 109. The working principle of the cooperation between the second turning shaft 204 and the second material receiving device 202 is similar to that of the first turning shaft 205 and the first material receiving device 201, and the details are not repeated here.

Referring to fig. 8, a schematic diagram of a first material receiving device 201 and a second material receiving device 202 according to an embodiment of the present application is provided. The spacing distance between the first receiving device 201 and the second receiving device 202 is equal to the spacing distance between the first turnover shaft 205 or the second turnover shaft 204 and the material belt 104, the fixing plate 203 is disposed on the guide rail 208, the second driving device 206 is disposed below the guide rail 208, the second driving device 206 is electrically connected to the fixing plate 203 for driving the fixing plate 203 to reciprocate along the direction of the guide rail 208, the third driving device 207 is disposed below the first receiving device 201 and the second receiving device 202, the third driving device 207 is connected to the first receiving device 201 and the second receiving device 202 for driving the first receiving device 201 and the second receiving device 202 to reciprocate along the direction perpendicular to the guide rail 208, it can be understood that when the first knife tackle 102 is engaged with the second knife tackle 105, the second driving device 206 drives the fixing plate 203 to move on the guide rail 208 along the direction close to the second knife tackle 105, the first material receiving device 201 is opposite to the second knife group 105, the third driving device 207 drives the first material receiving device 201 to move upwards to be close to the second knife group 105 and the material belt 104, the cut material 109 falls on the first material receiving device 201 due to gravity, and the third driving device 207 drives the first material receiving device 201 to be far away from the second knife group 105 and the material belt 104, so that the material 109 is transferred. The working principle of the second material receiving device 202 is similar to that of the first material receiving device 201, and is not described herein again.

Referring to fig. 9, a schematic structural diagram of a second material receiving device 202 according to an embodiment of the present application is provided, it can be understood that the first material receiving device 201 and the second material receiving device 202 have the same structure, and the second material receiving device 202 is taken as an example for description. The second material receiving device 202 includes a housing 2024, a vacuum air valve 2022, and a positioning pin 2021, where the housing 2024 is used to accommodate a shaft portion of the second material receiving device 202, the housing 2024 is provided with at least one gap, the gap is provided with the vacuum air valve 2022, the shaft portion of the second material receiving device 202 is provided with the positioning pin 2021, and the positioning pin 2021 may be adapted to a second positioning hole 1101 on the material 109, so as to position the material 109. An air suction hole 2023 is further formed in a shaft body of the second material receiving device 202, and the vacuum air valve 2022 can suck air between the material 109 and the first material receiving device 201 through the air suction hole 2023 to achieve adsorption, so that inaccurate positioning caused by sliding of the material 109 is prevented.

Referring to fig. 10, fig. 10 is a schematic structural diagram of the second flipping axis 204, and it can be understood that the second flipping axis 204 and the first flipping axis 205 have the same structure, and the second flipping axis 204 is taken as an example for description. The second flipping axle 204 includes a fourth driving device 2041, a rotating axle 2042 and a bracket 2043, wherein the bracket is used for supporting the rotating fourth driving device 2041 and the rotating axle 2042, and the fourth driving device 2041 is connected to the rotating axle 2042. It can be understood that the rotating shaft 2042 has the same length as the second material receiving device 202, and similar to the second material receiving device 202, the rotating shaft 2042 may be provided with an air suction hole to implement vacuum suction on the material 109 loaded on the second material receiving device 202. Optionally, a positioning pin may also be disposed on the rotating shaft 2042 to position the material 109.

After the rotating shaft 2042 absorbs the material 109 from the second material receiving device 202, the fourth driving device 2041 may drive the rotating shaft 2042 to turn over, so that the material taking mechanism 30 takes the material 109 from the rotating shaft 2042 to the material taking mechanism 30, and the material 109 is transferred. Because the rotating shaft 2042 adsorbs the material 109 on its surface by vacuum, the material 109 cannot be separated from the rotating shaft 2042 by gravity during the turning process of the rotating shaft 2042.

By using the material balance system 100 of the application, manpower saving can be realized, and the yield of production and the efficiency of production are improved.

It should be understood by those skilled in the art that the above embodiments are only for illustrating the present application and are not used as limitations of the present application, and that suitable modifications and changes of the above embodiments are within the scope of the claims of the present application as long as they are within the spirit and scope of the present application.

Claims (10)

1. The utility model provides a material cutting system for material cuts and balance on the material area, the material area includes material area main part, material and connecting portion, the material passes through connecting portion with the material area main part is connected, a serial communication port, material cutting system cuts the mechanism and connects material transfer mechanism including dialling the material, wherein, dial the material and cut the mechanism and include:

the material poking mechanism comprises a slide way, the slide way is used for accommodating the material belt, and the material belt moves in the slide way;

the cutting mechanism comprises a first driving device, a first cutter set and a second cutter set, the first cutter set is connected with the first driving device, the second cutter set is arranged on the slide way, the first driving device is used for driving the first cutter set to move close to or far away from the second cutter set in a reciprocating mode, the material belt is located between the first cutter set and the second cutter set, and when the first cutter set moves to be meshed with the second cutter set, the connecting portion of the material belt is cut off to enable the material to be separated from the material belt main body;

the material receiving and transferring mechanism comprises a first material receiving device, wherein the first material receiving device and the bottom of the slide way are arranged at intervals and used for bearing the materials when the connecting part is cut off.

2. The material cutting system according to claim 1, wherein the material receiving transfer mechanism further includes a second material receiving device, the second material receiving device and the first material receiving device are arranged at an interval, the first material receiving device and the second material receiving device are both fixed on a fixed plate, the first material receiving device and the second material receiving device are both perpendicular to the fixed plate, the fixed plate is fixed on a translation shaft along the material belt direction, and the fixed plate is driven by a second driving device to reciprocate along the translation shaft to achieve continuous material receiving.

3. The material cutting system as claimed in claim 2, wherein said material receiving transfer mechanism further comprises a first flipping axis and a second flipping axis, when the first material receiving device bears the material, the first material receiving device moves towards the direction vertical to the material belt and far away from the material belt, the fixed plate moves horizontally along the translation shaft to drive the first material receiving device to move along the direction close to the first turnover shaft, when the first material receiving device moves below the first turnover shaft, the first material receiving device is driven by a third driving device connected to the bottom of the first material receiving device to rise, so that the top of the first material receiving device and the bottom of the first turnover shaft are positioned on the same horizontal plane, the first turnover shaft absorbs the materials to the bottom of the first turnover shaft, and overturning, and driving the first material receiving device to descend by the third driving device so as to complete the transfer of the materials.

4. The material cutting system according to claim 3, wherein when the first receiving device carries the material, the fixing plate drives the second receiving device to move in a direction close to the chute, when the receiving device moves below the chute, the second receiving device is driven by a third driving device connected to a bottom of the second receiving device to ascend, so that the second receiving device and the chute are located on the same horizontal plane, the second receiving device carries the material, and the third driving device drives the second receiving device to descend.

5. The material cutting system of claim 1, wherein the first blade set comprises a first sub-blade set and a second sub-blade set, the first sub-blade set and the second sub-blade set each comprise at least two blades, the first sub-blade set and the second sub-blade set are arranged adjacent to each other, and a vertical distance between a blade in the first sub-blade set and the material belt is smaller than a vertical distance between a blade in the second sub-blade set and the material belt.

6. The material cutting system according to claim 1, wherein a first positioning hole is formed in the material belt, and a positioning needle is arranged on the material shifting mechanism, and when the material belt moves to a specific position after one cutting is completed, the positioning needle is matched with the first positioning hole and used for positioning the material belt.

7. The material cutting system of claim 1, wherein the connection portion of the material strip comprises a first connection portion and a second connection portion, wherein the second blade set comprises a third sub-blade set and a fourth sub-blade set, the third sub-blade set is arranged relative to the first connection portion, the fourth sub-blade set is arranged relative to the second connection portion, the first connection portion is cut when a blade of the first blade set engages a blade of the third sub-blade set, and the second connection portion is cut when a blade of the first blade set engages a blade of the fourth sub-blade set.

8. The material cutting system according to claim 1, wherein the material shifting and cutting mechanism further comprises a waste material cutting mechanism, and when the material in the material belt is cut off by the cutting mechanism, the waste material cutting mechanism is used for cutting the remaining material belt.

9. The material cutting system as claimed in claim 1, wherein a second positioning hole is formed in the material, and wherein a positioning pin is disposed on the first receiving device and the second receiving device, and the positioning pin is adapted to the second positioning hole for positioning the material.

10. The material cutting system as claimed in claim 3, wherein the bottom of each of the first and second turning shafts is provided with an air suction hole for sucking the material carried by the first or second receiving device onto the first or second turning shaft by vacuum.

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