CN209834111U - Wafer separator, wafer separation system and boxing system - Google Patents

Abstract

The application provides a wafer separator, a wafer separation system and a boxing system, and relates to the technical field of wafer separators. A wafer separator comprises a first conveying mechanism, a second conveying mechanism and a shunting conveying belt. The first transport mechanism is configured to transport the sheet material from the first transport end to the second transport end. The second transport mechanism is configured to transport the sheet material from the third transport end to the fourth transport end. The diversion conveyor belt is disposed upstream of the first conveying mechanism and the second conveying mechanism, and a conveying end of the diversion conveyor belt is configured to switch back and forth between the first conveying end and the third conveying end to selectively convey the sheet material to the first conveying end or the third conveying end. This wafer separator need not artifical collection piece dress material, can realize the automatic counting and reach the number of piles that the packing needs, increases production efficiency, improves economic benefits.

Description

Wafer separator, wafer separation system and boxing system

Technical Field

The application relates to the technical field of wafer separators, in particular to a wafer separator, a wafer separation system and a boxing system.

Background

As products of mask manufacturers are more and more diversified, the change speed is faster and faster, and the yield and the packaging grade are correspondingly improved, automatic packaging becomes a choice for the manufacturers to improve the efficiency and the packaging grade. The production efficiency of the existing mask production line is extremely low and the packaging quality is not high.

SUMMERY OF THE UTILITY MODEL

The utility model provides a wafer separator, burst system and dress box system to improve facial mask production line production efficiency, improve packaging quality.

In a first aspect, an embodiment of the present application provides a wafer separator, which includes a first conveying mechanism, a second conveying mechanism, and a split-flow conveying belt. The first transport mechanism is configured to transport the sheet material from the first transport end to the second transport end. The second transport mechanism is configured to transport the sheet material from the third transport end to the fourth transport end. The diversion conveyor belt is disposed upstream of the first conveying mechanism and the second conveying mechanism, and a conveying end of the diversion conveyor belt is configured to switch back and forth between the first conveying end and the third conveying end to selectively convey the sheet material to the first conveying end or the third conveying end.

The wafer separator is used for dividing single-wafer materials, manual collection is not needed, and the number of layers required by packaging is automatically counted. This structure sets up two conveyer belts, for a conveyer belt, improves conveying speed, improves the fractional efficiency of piece dress material, increases production efficiency, improves economic benefits. This wafer separator also does not influence its score when subsequent dress box is produced the line and meets the trouble, can shunt automatically.

In a possible implementation manner, the first conveying mechanism includes a first conveying belt, the second conveying mechanism includes a second conveying belt, the first conveying belt is vertically disposed above the second conveying belt, the first conveying end is vertically disposed above the third conveying end, and the conveying end of the shunt conveying belt is configured to be lifted between the first conveying end and the third conveying end.

The shunt conveyor belt can well ensure the stability of facial mask conveying in the vertical direction. Because the conveying speed on the reposition of redundant personnel conveyer belt is very fast, and the direction of delivery of reposition of redundant personnel conveyer belt is the straight line, consequently at this transportation process, if the reposition of redundant personnel conveyer belt moves on the horizontal direction, the facial mask can receive the effort of horizontal direction, and the direction of delivery of the reposition of redundant personnel conveyer belt of deviating easily probably leads to dropping, and then influences the accuracy of facial mask score and the efficiency of score. The reposition of redundant personnel conveyer belt carries out the layering through going up and down then does not have above-mentioned problem, and the effort that the facial mask received can not influence the transport of facial mask, can guarantee that the facial mask is firm to be carried to first conveyer belt or second conveyer belt on the reposition of redundant personnel conveyer belt.

In one possible implementation, the second transmitting end and the fourth transmitting end have the same height.

In operation, first transport mechanism and second transport mechanism can convey the lamella material to same device and pack, therefore the second conveying end is the same with the height of fourth conveying end, can not need the manual work to realize conveying the good piece dress material of mark to next device.

In a possible implementation manner, the first conveyor belt includes a first main conveyor belt and a first auxiliary conveyor belt, the first main conveyor belt and the first auxiliary conveyor belt are sequentially arranged along a direction from the first conveying end to the second conveying end, the setting height of the first main conveyor belt is the same as the height of the first conveying end, and the setting height of the first auxiliary conveyor belt is the same as the height of the second conveying end.

In order to guarantee the stable conveying of facial mask, the direction of delivery of every conveyer belt is the horizontal straight line, compares the slope and sets up first conveyer belt, and this structure can be stable with facial mask from first conveying end conveying to second conveying end, avoids the piece dress material to drop with higher speed on the conveyer belt of slope, and its conveying speed is difficult to control, leads to the mark result to have the mistake.

In a possible implementation manner, a first bin for receiving the chip material is disposed downstream of the first conveying mechanism, the first conveying mechanism further includes a first shunt belt disposed between the first conveying belt and the first bin for conveying the chip material on the first conveying belt to the first bin, and one end of the first shunt belt, which is close to the first conveying belt, is configured to be close to or far away from the first conveying belt.

In order to avoid that the normal operation of the wafer separator is influenced by the fault of the processing equipment after the wafer separation, the conveying direction of the wafer-contained materials is changed through the first shunting belt. When first reposition of redundant personnel area kept away from first conveyer belt, the piece dress material on the first conveyer belt drops to the receipts workbin that the conveying end of first transmission end set up, and can not get into first feed bin, can not produce and pile up. When the first diverter belt approaches the first conveyor belt, the transfer resumes and the sheet material is transferred into the first hopper. The structure does not affect the operation of each step, so that the production can be normally carried out.

In one possible implementation manner, the sheet material conveying device further comprises a first bin and a second bin, wherein the first bin and the second bin are respectively arranged at the downstream of the first conveying mechanism and the downstream of the second conveying mechanism and are respectively used for containing the sheet materials conveyed by the first conveying mechanism and the second conveying mechanism;

the first bin comprises a bin body, at least one partition plate and a driving device, wherein the partition plate is configured to be driven by the driving device to selectively penetrate through the bin body so as to layer the bin body.

In the production process, the first conveying mechanism and the second conveying mechanism are high in conveying speed, the structure can be used for layering the sheet materials in the bin body, and the number of scores is guaranteed to be correct.

In a possible implementation mode, the side wall of the bin body is provided with a through hole matched with the partition board, one end of the partition board is arranged in the through hole, and the driving device is connected with the other end of the partition board. This arrangement allows the separator to achieve delamination quickly.

In a possible implementation manner, the first storage bin comprises at least two partition plates, and the at least two partition plates are respectively arranged on two sides of the storage bin body. The partition plates are arranged on the two sides, so that the motion path of each partition plate can be reduced, the layering speed of the bin body is improved, and the fractional result is more accurate.

In a second aspect, a wafer dividing system is provided, which comprises a control device, a driving device and the wafer dividing machine, wherein the driving device is respectively connected with the first conveying mechanism, the second conveying mechanism and the shunting conveying belt and is used for driving the first conveying mechanism, the second conveying mechanism and the shunting conveying belt; the control device is respectively in charged connection with the first conveying mechanism, the second conveying mechanism and the shunt conveying belt and is used for controlling the first conveying mechanism, the second conveying mechanism and the shunt conveying belt.

The slicing system realizes automatic slicing, reduces labor and improves efficiency.

And the boxing machine is connected with the wafer separator and is used for boxing the sliced sheet materials. The boxing system realizes automatic packaging of the sheet materials and is high in production efficiency.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained from the drawings without inventive effort.

Fig. 1 is a schematic structural diagram of a first view angle of a wafer separator according to an embodiment of the present application;

fig. 2 is a schematic structural diagram of a second view angle of a wafer separator according to an embodiment of the present application;

fig. 3 is a schematic partial structural diagram of a wafer separator according to an embodiment of the present application;

fig. 4 is a schematic partial structural diagram of a wafer separator according to an embodiment of the present application.

Icon: 100-a wafer separator; 101-a first transmitting end; 102-a second transmitting end; 103-a third transmitting end; 104-a fourth transmit end; 110 — a first transport mechanism; 111-a first conveyor belt; 1111-a first main conveyor belt; 1113-first secondary conveyor; 1115-a first baffle; 113-a first shunt strip; 115-a second cylinder; 120-a second transport mechanism; 121-a second conveyor belt; 1211-two main conveyer belts; 1213-a second secondary conveyor; 1215 — a second baffle; 123-a second shunt strip; 125-third cylinder; 130-a split-flow conveyor belt; 131-a first cylinder; 140-a first silo; 141-a cartridge body; 143-a spacer; 145-fourth cylinder; 147-a through hole; 150-a second silo; 161-a first counter; 162-a second counter; 163-a third counter; 200-synchronous belt.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. The components of the embodiments of the present application, generally described and illustrated in the figures herein, can be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present application, presented in the accompanying drawings, is not intended to limit the scope of the claimed application, but is merely representative of selected embodiments of the application. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

In the description of the present application, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the application usually place when in use, and are used only for convenience in describing the present application and simplifying the description, but do not indicate or imply that the devices or elements being referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present application. Furthermore, the terms "first," "second," "third," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.

Some embodiments of the present application will be described in detail below with reference to the accompanying drawings.

Referring to fig. 1 and fig. 2, fig. 1 and fig. 2 are schematic structural diagrams of a first viewing angle and a second viewing angle of a wafer separator 100 according to the present embodiment, respectively.

The present embodiment provides a singulator 100 for singulating the sheet material. In this embodiment, the sheet material is a mask, and in other embodiments of the present application, the sheet material may be other products, which are not limited in the present application.

The wafer separator 100 includes a first transfer mechanism 110, a second transfer mechanism 120, a diverting conveyor 130, a first bin 140, and a second bin 150. The first conveyance mechanism 110 is configured to convey the sheet material from the first conveyance end 101 to the second conveyance end 102. The second transport mechanism 120 is configured to transport the sheet material from the third transport end 103 to the fourth transport end 104. A shunt conveyor 130 is disposed upstream of the first conveyor 110 and the second conveyor 120, and a conveying end of the shunt conveyor 130 is configured to switch back and forth between the first conveying end 101 and the third conveying end 103 to selectively convey the sheet material toward the first conveying end 101 or the third conveying end 103. A first magazine 140 and a second magazine 150 are disposed downstream of the first transfer mechanism 110 and the second transfer mechanism 120, respectively, for containing sheet material transferred from the second transfer end 102 and the fourth transfer end 104, respectively.

This structure sets up two conveyer belts, for a conveyer belt, improves out conveying speed, improves the fractional efficiency of facial mask, increases production efficiency, improves economic benefits.

Referring to fig. 3 and 4, fig. 3 and 4 are schematic partial structural views of the wafer separator 100, respectively.

The first conveying mechanism 110 includes a first conveying belt 111 and a first shunting belt 113, a conveying start end of the first conveying belt 111 is a first conveying end 101, a conveying end of the first shunting belt 113 is a second conveying end 102, and the conveying end of the first conveying belt 111 and the conveying start end of the first shunting belt 113 are arranged close to each other, so that the facial mask on the first conveying belt 111 is conveyed from the first conveying end to the second conveying end 102.

The second transfer mechanism 120 has the same structure as the first transfer mechanism 110. The second conveying mechanism 120 includes a second conveying belt 121 and a second shunt belt 123, a conveying start end of the second conveying belt 121 is a third conveying end 103, a conveying end of the second shunt belt 123 is a fourth conveying end 104, and the conveying end of the second conveying belt 121 is disposed close to the conveying start end of the second shunt belt 123, so that the mask on the second conveying belt 121 is conveyed from the third conveying end 103 to the fourth conveying end 104.

The shunt conveyor 130 is disposed upstream of the first transfer mechanism 110 and the second transfer mechanism 120, and selectively transfers the mask to the first transfer mechanism 110 or the second transfer mechanism 120. In order to improve the efficiency of the fractional facial mask, the conveying speed on the shunt conveyor belt 130 is faster, so the first conveyor belt 111 and the second conveyor belt 121 are disposed closer to each other, so that the shunt conveyor belt 130 can be rapidly switched back and forth between the first conveying end 101 and the third conveying end 103.

As one implementation, the first conveyor belt 111 is disposed above the second conveyor belt 121 in the vertical direction, and the first conveying end 101 is disposed directly above the third conveying end 103 in the vertical direction. The transfer ends of the shunt conveyor belt 130 are disposed near the first transfer end 101 and the third transfer end 103 to transfer in cooperation with the first conveyor belt 111 and the second conveyor belt 121. The shunt conveyor belt 130 is connected to a driving device, and the shunt conveyor belt 130 is provided with a first counter 161 for counting the number of the facial masks conveyed on the shunt conveyor belt 130. In the present embodiment, the first counter 161 is a photoelectric switch. When the first counter 161 counts the mask of a preset value, the control device drives the driving device to make the conveying end of the shunt conveyor belt 130 ascend and descend between the first conveying end 101 and the third conveying end 103. The photoelectric switch is a general device in the present technical field, and the operation mode, the connection relation with the control device, and the like of the photoelectric switch are general techniques in the present technical field, and the present application does not limit the photoelectric switch.

In other embodiments of the present application, the first conveyor belt 111 and the second conveyor belt 121 may be disposed on the same horizontal plane, such as side by side. The shunt conveyor belt 130 is driven by the driving device so that the conveying end of the shunt conveyor belt 130 moves in the horizontal direction so as to move between the first conveying end 101 and the third conveying end 103.

Compared with the shunt conveyor belt 130 moving in the horizontal direction, the shunt conveyor belt 130 provided by the embodiment can better ensure the stability of facial mask conveying in the vertical direction. Because the conveying speed on the reposition of redundant personnel conveyer belt 130 is very fast, and the direction of delivery of reposition of redundant personnel conveyer belt 130 is the straight line, therefore in this transportation process, if reposition of redundant personnel conveyer belt 130 moves on the horizontal direction, the facial mask can receive the effort of horizontal direction, and the direction of delivery of reposition of redundant personnel conveyer belt 130 is squinted easily, probably leads to dropping, and then influences the accuracy of facial mask score and the efficiency of score. The shunting conveyor belt 130 shunts the facial mask through lifting, so that the problem is solved, the acting force applied to the facial mask does not influence the conveying of the facial mask, and the facial mask can be conveyed to the first conveyor belt 111 or the second conveyor belt 121 on the shunting conveyor belt 130 stably.

In order to ensure the stable conveying of the facial mask, the conveying direction of each conveying belt is a straight line, and the arrangement can occupy more space. In the present embodiment, in order to save the space of the site, the first conveyor belt 111 and the second conveyor belt 121 each include two conveyor belts, the first conveyor belt 111 includes a first main conveyor belt 1111 and a first sub-conveyor belt 1113, and the second conveyor belt 121 includes a second main conveyor belt 1211 and a second sub-conveyor belt 1213. The first main conveyor 1111 and the first sub conveyor 1113 are sequentially disposed in a direction from the first conveying end 101 to the second conveying end 102, that is, the mask is conveyed from the first main conveyor 1111 to the first sub conveyor 1113. Likewise, the second main transfer belt 1211 and the second sub-transfer belt 1213 are sequentially disposed in a direction from the third transfer end 103 to the fourth transfer end 104, that is, the mask film is transferred from the second main transfer belt 1211 to the second sub-transfer belt 1213.

Further, in the present embodiment, the conveying direction of the first main conveyor 1111 is the same as the conveying direction of the divided conveyor 130, and the conveying direction of the first sub conveyor 1113 is perpendicular to the conveying direction of the first main conveyor 1111. Since the conveyor belts in this embodiment are all linear conveyor belts, the first main conveyor belt 1111 and the first sub conveyor belt 1113 are perpendicular to each other. Since the movement direction is changed after the mask is transferred from the first main transfer belt 1111 to the first sub-transfer belt 1113. In order to prevent the mask from falling off the first sub-conveyor 1113, a first stopper 1115 is provided on a side of the first sub-conveyor 1113 away from the first main conveyor 1111, for restricting the movement of the mask in the conveying direction of the first main conveyor 1111.

Similarly, the conveying direction of the second main conveying belt 1211 is the same as the conveying direction of the divided conveying belt 130, the conveying direction of the second sub-conveying belt 1213 is perpendicular to the conveying direction of the second main conveying belt 1211, and the second main conveying belt 1211 is perpendicular to the second sub-conveying belt 1213. A side of the second sub-conveyor belt 1213 remote from the second main conveyor belt 1211 is provided with a second stopper 1215 for restricting movement of the mask film in the conveying direction of the second main conveyor belt 1211.

In other embodiments of the present application, the first conveyor belt 111 and/or the second conveyor belt 121 may include three or four conveyor belts, and the specific arrangement manner is adjusted according to actual production conditions and production needs, which is not limited in the present application.

The first and second transfer mechanisms 110 and 120 are used to transfer the facial mask into the first and second bins 140 and 150, and the facial mask in the first and second bins 140 and 150 is transferred by the timing belt 200 for the next process. In the present application, the masks in the first and second bins 140 and 150 are transferred to the same timing belt 200, and the first and second bins 140 and 150 have the same structure, so that the second and fourth transferring ends 102 and 104 have the same height. Since the first transporting end 101 is disposed right above the third transporting end 103, the transporting height of the first transporting mechanism 110 needs to be changed during the transporting process.

As an implementation manner, as shown in fig. 1, the first sub-conveyor belt 1113, the second main conveyor belt 1211, and the second sub-conveyor belt 1213 in the present embodiment are at the same level, and the first main conveyor belt 1111 is disposed above the second main conveyor belt 1211 and a part of the second sub-conveyor belt 1213, and is parallel to the second conveyor belt 121. After the mask on the first main conveyor 1111 moves to the end of the first main conveyor 1111, the mask vertically drops onto the first sub conveyor 1113 and continues to move with the first sub conveyor 1113.

In other embodiments of the present application, the first sub-conveyor 1113 may be disposed to be inclined, or the first main conveyor 1111 and the first sub-conveyor 1113 may be disposed to be at the same horizontal height, and the second sub-conveyor 1213 may be disposed to be inclined such that the height of the conveying end of the second sub-conveyor 1213 is the same as the height at which the first sub-conveyor 1113 is disposed, or the first conveying mechanism 110 and the second conveying mechanism 120 may have the same function by other arrangement modes, which is not limited in the present application.

In some embodiments of the present application, the diversion conveyor belt 130 is horizontally disposed with the second conveyor belt 121, and a first cylinder 131 is disposed at the bottom of the conveying end of the diversion conveyor belt 130, and the first cylinder 131 is used for lifting and lowering the conveying end of the diversion conveyor belt 130. When the diversion conveyor 130 conveys the mask film to the second conveyor 121, the first counter 161 detects the number of the conveyed mask films, and when the detected value is a preset value, it indicates that the mask film of the preset value has been conveyed to the second conveyor 121. The first counter 161 transmits a signal to a control device (not shown), and the control device controls the first air cylinder 131 to lift the conveying end of the shunt conveyor belt 130, so that the shunt conveyor belt 130 is butted with the first conveyor belt 111; when the first counter 161 detects that the number of the facial masks conveyed to the first conveyor belt 111 is a preset value, a signal is transmitted to the control device, the control device controls the first cylinder 131 to lift the conveying tail end of the diversion conveyor belt 130 to fall back to the original position, so that the diversion conveyor belt 130 is in butt joint with the second conveyor belt 121, and the facial masks are conveyed to the second conveyor belt 121.

In other embodiments of the present disclosure, the diversion conveyor 130 may be horizontally disposed with the first conveyor 111, or may be horizontally disposed between the first conveyor 111 and the second conveyor 121, which is not limited in the present disclosure.

In actual production, the operation of the whole production line is affected by the fault and stop of any mechanism in the production line. In order to avoid the fault of the processing equipment after slicing from affecting the normal operation of the slicing machine 100, the first conveying mechanism 110 further comprises a first shunting belt 113, and the first shunting belt 113 is arranged between the first sub-conveyor 1113 and the first storage bin 140. An end of the first branch belt 113 near the first sub-conveyor belt 1113 is disposed near or far from the first conveyor belt 111.

In this embodiment, the bottom of the first shunting belt 113 is provided with the second cylinder 115, and when production needs, the cylinder drives the first shunting belt 113 to rise, so that the first shunting belt 113 rises near one end of the first auxiliary conveyor belt 1113, and then is separated from the first auxiliary conveyor belt 1113 for the facial mask on the first auxiliary conveyor belt 1113 cannot enter the first bin 140, and further cannot be stacked on the production line. A collecting box (not shown) may be provided below the conveying end of the first sub-conveyor 1113 to collect the mask on the first sub-conveyor 1113. When the production is recovered to normal, the cylinder drives the first shunting belt 113 to fall back to the original position, so that the first shunting belt 113 is butted with the first auxiliary conveyor belt 1113 and the conveying is recovered.

Likewise, the second conveyor 120 further includes a second diverter belt 123. The second diversion belt 123 is disposed between the second sub-conveyor belt 1213 and the second magazine 150. The bottom of the second diversion area 123 is provided with a third cylinder 125 for lifting the second diversion area 123. In other embodiments of the present application, the second cylinder 115 and the third cylinder 125 may be replaced by other driving devices having the same function, and the present application is not limited thereto.

The first and second bins 140 and 150 in this application are used to collect the facial masks transferred from the first and second diverging belts 113 and 123 and to place the scored facial masks in the timing belt 200 for further processing. In order to ensure that the scored facial masks are correctly placed on the timing belt 200 at a high transfer speed during the production process, the first and second bins 140 and 150 have a layered structure for layering the facial masks.

As one implementation manner, the first storage bin 140 includes a storage body 141, at least one partition 143, and a driving device, and the partition 143 is configured to be selectively driven by the driving device to penetrate through the storage body 141 to layer the storage body 141. In this embodiment, the first bin 140 includes two sets of partitions 143, each set of partitions 143 includes three partitions 143, and one end of each partition 143 is connected to one fourth cylinder 145. The bin body 141 has a feeding end, and side walls disposed at both sides of the feeding end. Three through holes 147 matched with the size of the partition 143 are formed in the two side walls in the vertical direction, and one end, far away from the fourth cylinder 145, of the partition 143 is arranged in the through holes 147. The first storage bin 140 is layered by driving the partition 143 through the fourth cylinder 145, and then the facial mask in the first storage bin 140 is divided.

Likewise, the second silo 150 has the same structure as the first silo 140.

It should be noted that the number of the partition plates 143 can be adjusted as needed, the operation modes among the partition plates 143 can be set as needed to realize the fractional division, and the specific operation mode of the partition plates 143 is a general technique in the art, and is not limited in the present application.

In order to improve the accuracy of the wafer separator 100, the first shunting belt 113 and the second shunting belt 123 are respectively provided with a second counter 162 and a third counter 163, and the second counter 162 and the third counter 163 count the facial masks conveyed to the first bin 140 and the second bin 150 and are matched with the partition 143 to ensure the number of each group of facial masks after being divided.

It should be noted that the driving methods of the first conveying mechanism 110, the second conveying mechanism 120, and the diversion conveyor belt 130 in the present application are all general technologies in the present technical field, and if the motor is adopted for driving, the connection method and connection relationship between the motor and the driving device are also all general technologies in the present technical field, which is not limited in the present application.

The present embodiment provides a wafer dividing system (not shown), which includes a control device (not shown), a driving device (not shown), and a wafer divider 100. The driving device is respectively connected with the first conveying mechanism 110, the second conveying mechanism 120 and the shunt conveyor belt 130, and is used for driving the first conveying mechanism 110, the second conveying mechanism 120 and the shunt conveyor belt 130 to convey; the control device is electrically connected to the first conveying mechanism 110, the second conveying mechanism 120, the diversion conveyor 130, the first bin 140, the second bin 150, the first counter 161, the second counter 162, and the third counter 163, respectively, and is configured to receive detection results of the first counter 161, the second counter 162, and the third counter 163, control the transmission speeds of the first conveying mechanism 110, the second conveying mechanism 120, and the diversion conveyor 130, and control the operation of the partition 143 of the first bin 140 and the second bin 150.

The application also provides a boxing system, which comprises a boxing machine and a wafer separator 100, wherein the boxing machine is connected with the downstream of the wafer separator 100 and is used for boxing sliced sheet materials. Form a production line, realize the automation of facial mask partial shipment, improve facial mask partial shipment efficiency.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (10)

1. A wafer separator for fractional sheet material, comprising

A first transport mechanism configured to transport the sheet material from a first transport end to a second transport end;

a second transport mechanism configured to transport the sheet material from a third transport end to a fourth transport end;

a shunt conveyor disposed upstream of the first and second transfer mechanisms, a conveying end of the shunt conveyor configured to switch back and forth between the first and third transfer ends to selectively transfer the sheet material to the first or third transfer ends.

2. The wafer separator of claim 1, wherein the first transport mechanism comprises a first conveyor belt and the second transport mechanism comprises a second conveyor belt, the first conveyor belt being vertically disposed above the second conveyor belt, the first transport end being vertically disposed above the third transport end, the transfer end of the split conveyor belt being configured to be raised and lowered between the first transport end and the third transport end.

3. The wafer separator of claim 2, wherein the second transfer end is the same height as the fourth transfer end.

4. The wafer separator as claimed in claim 3, wherein the first conveyor belt comprises a first main conveyor belt and a first auxiliary conveyor belt, the first main conveyor belt and the first auxiliary conveyor belt are sequentially arranged along a direction from the first conveying end to the second conveying end, the first main conveyor belt is arranged at the same height as the first conveying end, and the first auxiliary conveyor belt is arranged at the same height as the second conveying end.

5. The wafer separator of claim 2, wherein a first bin is disposed downstream of the first conveyor for receiving the chip material, the first conveyor further comprising a first diverter strip disposed between the first conveyor and the first bin for conveying the chip material on the first conveyor to the first bin, an end of the first diverter strip proximate the first conveyor being configured to be proximate to or distal from the first conveyor.

6. The wafer separator of claim 1, further comprising a first bin and a second bin disposed downstream of the first conveyor mechanism and the second conveyor mechanism, respectively, for containing the sheet material conveyed from the first conveyor mechanism and the second conveyor mechanism, respectively;

the first storage bin comprises a storage body, at least one partition plate and a driving device, wherein the partition plate is driven by the driving device to selectively penetrate through the storage body so as to layer the storage body.

7. The wafer separator as claimed in claim 6, wherein through holes matched with the partition plates are arranged on two sides of the bin body, one ends of the partition plates are arranged in the through holes, and the driving device is connected with the other ends of the partition plates.

8. The wafer separator of claim 6, wherein the first bin comprises at least two baffles, at least two of the baffles being disposed on each side of the bin body.

9. A slicing system comprising a control device, a driving device and a slicing machine as claimed in any one of claims 1 to 8, wherein the driving device is connected to the first conveying mechanism, the second conveying mechanism and the diversion conveyor belt respectively, for driving the first conveying mechanism, the second conveying mechanism and the diversion conveyor belt; the control device is electrically connected with the first conveying mechanism, the second conveying mechanism and the shunt conveying belt respectively and used for controlling the first conveying mechanism, the second conveying mechanism and the shunt conveying belt.

10. A cartoning system comprising a cartoning machine and a wafer separator according to any one of claims 1 to 8, the cartoning machine being connected to the wafer separator for cartoning the sliced sheet material.