A forming device for fast food box production
By integrating a fast food box production molding device, which combines ultraviolet sterilization, airflow dust removal, upper and lower mold linkage, and rotating rod cutting, the problems of raw material contamination and low molding and cutting efficiency have been solved, thereby improving food safety and production efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ZHUOZHOU JUNTENG PLASTIC PROD CO LTD
- Filing Date
- 2025-08-14
- Publication Date
- 2026-07-03
AI Technical Summary
Existing fast food box production molding equipment lacks raw material sterilization and dust removal treatment, and the molding and cutting processes have poor coordination, resulting in food safety hazards and low production efficiency.
An integrated forming device for fast food box production was designed, comprising a processing component, a forming component, and a cutting component. The processing component ensures the cleanliness of raw materials through ultraviolet sterilization lamps and airflow dust removal; the forming component achieves efficient forming through the linkage of upper and lower molds; and the cutting component achieves precise cutting through a rotating rod and a double-bladed blade.
It achieves comprehensive sterilization and dust removal of raw materials, ensuring food safety, improving molding accuracy and cutting efficiency, reducing time costs in intermediate steps, meeting food hygiene standards, and improving production efficiency.
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Figure CN224446196U_ABST
Abstract
Description
Technical Field
[0001] The embodiments disclosed herein relate to the technical field of plastic product processing, and more specifically, to a molding apparatus for producing fast food boxes. Background Technology
[0002] Against the backdrop of the rapid development of the fast food industry, fast food boxes, as an important component of disposable tableware, are directly related to food safety and industry cost control in terms of production quality and efficiency. Fast food box production mainly uses pulp, plastic, and other raw materials, which are processed into specific shapes by molding equipment to meet the basic needs of food holding. The cleanliness of the raw materials and the efficiency of molding and cutting are key factors affecting product quality and production efficiency.
[0003] Currently, existing molding equipment for fast food box production has significant drawbacks. On the one hand, it lacks sterilization and dust removal treatment for raw materials. Raw materials are easily contaminated with dust, microorganisms, and impurities during storage and transportation. If they directly enter the molding process, the finished product will carry contaminants, posing food safety risks, especially failing to meet the hygiene standards for food contact materials.
[0004] On the other hand, the poor coordination between the forming and slitting processes leads to low efficiency. Traditional equipment often has separate forming and slitting modules, requiring manual transfer of raw materials to the slitting equipment after forming. This not only increases time costs in intermediate steps but also risks affecting slitting accuracy due to compression and deformation during transfer. Furthermore, the slitting blades lack sufficient adjustment flexibility, making it difficult to adapt to rapid production changes for different sizes of fast food boxes, thus hindering the efficiency of mass production.
[0005] Therefore, in response to the problems of insufficient sterilization and dust removal of raw materials and low forming and cutting efficiency, the development of an integrated forming device for fast food box production has become an urgent need to ensure food safety and improve production efficiency. Utility Model Content
[0006] To overcome the above-mentioned defects, the embodiments of this disclosure provide a molding apparatus for fast food box production, which solves the technical problems of lack of sterilization and dust removal treatment for raw materials, poor coordination between molding and cutting processes, and low efficiency in the prior art.
[0007] According to one aspect, at least one embodiment of this disclosure provides a molding apparatus for fast food box production, comprising:
[0008] Equipment rack and gantry frame, wherein the gantry frame is mounted on the equipment rack;
[0009] A molding assembly, which is disposed on the equipment frame and the gantry frame;
[0010] A pair of feed rollers and a processing assembly, wherein the feed rollers are rotatably connected within the equipment frame and the processing assembly is disposed on the equipment frame;
[0011] A slitting assembly is mounted on the equipment rack;
[0012] The processing component includes a housing, which is fixed in the equipment frame. Inside the housing, there is a pair of ultraviolet germicidal lamp plates and a pair of pipes. Air blowing holes are opened on the surface of the pipes. Rolling rods are provided at the upper and lower ends of the openings on both sides of the housing. The equipment frame is equipped with a conveyor roller that is driven by electricity to rotate. The conveyor roller is located above one of the feed rollers.
[0013] As a further technical solution, the molding component includes an upper mold, which is connected to the portal frame via a vertical linear drive. A rectangular opening is provided on the surface of the equipment frame, and a lower mold connected via a vertical linear drive is disposed within the rectangular opening. The lower mold is located directly below the upper mold.
[0014] As a further technical solution, the slitting assembly includes a pair of upright plates, which are fixed at both ends of the surface of the equipment frame. A pair of first rotating rods are rotatably connected between the upright plates. Each of the first rotating rods is provided with a plurality of pressure rollers, and a drive shaft is provided on the side surface of one of the upright plates.
[0015] As a further technical solution, a second rotating rod is rotatably connected between the upright plates. A transmission gear is provided on the drive shaft, and at one end of both the first and second rotating rods. Several double-edged cutter discs are provided on the second rotating rod. Several long openings are provided on the surface of the equipment frame, and the long openings correspond to the positions of the double-edged cutter discs.
[0016] As a further technical solution, a stabilizing frame is provided at one end of the surface of the equipment frame, and a pair of vertical cylinders are provided on the stabilizing frame. A double-edged cutter is provided at the output end of the vertical cylinders, and a horizontal hole is opened on the surface of the equipment frame, which is located directly below the double-edged cutter.
[0017] As a further technical solution, a receiving hopper is provided at one end of the equipment frame, and the receiving hopper is located on one side of the double-edged cutter.
[0018] As a further technical solution, a pair of waste material conveying rollers are rotatably connected to the surface of the equipment frame.
[0019] As a further technical solution, the pressure roller is located on both the front and rear sides of the double-edged cutter head.
[0020] The beneficial effects of the embodiments disclosed herein are as follows:
[0021] In this disclosure, the processing component solves the problem of substandard raw material hygiene through a composite cleaning design. The ultraviolet germicidal lamp panel comprehensively covers the raw material, ensuring sterilization without blind spots; airflow is evenly sprayed from the air outlets, efficiently removing surface impurities and preventing contaminants from entering subsequent processes. The rolling rods and conveyor rollers work together to ensure smooth raw material transport, preventing scratches or jamming, providing clean raw materials for fast food box production, meeting hygiene standards for food contact materials, ensuring product safety from the source, and reducing molding defects caused by impurities. Attached Figure Description
[0022] To more clearly illustrate the technical solutions in the embodiments of this disclosure, the accompanying drawings used in the description of the embodiments of this disclosure will be briefly introduced below. Obviously, the drawings described below are merely some exemplary embodiments of this disclosure. For those skilled in the art, other drawings can be obtained based on the content of the exemplary embodiments of this disclosure and these drawings without any creative effort.
[0023] Figure 1 This is a schematic diagram of a structure in one embodiment of the present disclosure;
[0024] Figure 2 This is an isometric drawing of the present disclosure;
[0025] Figure 3 This is an isometric sectional view of the present disclosure;
[0026] In the diagram: 1. Equipment frame; 2. Gantry frame; 3. Feed roller; 4. Processing assembly; 4-1. Outer shell; 4-2. UV sterilization lamp plate; 4-3. Pipe; 4-4. Air blowing hole; 4-5. Rolling rod; 4-6. Conveying roller; 5. Forming assembly; 5-1. Upper mold; 5-2. Rectangular opening; 5-3. Lower mold; 6. Slitting assembly; 6-1. Vertical plate; 6-2. First rotating rod; 6-3. Pressure roller; 6-4. Drive shaft; 6-5. Transmission gear; 6-6. Second rotating rod; 6-7. Double-edged cutter head; 6-8. Long opening; 6-9. Stabilizing frame; 6-10. Vertical cylinder; 6-11. Double-edged cutter; 6-12. Horizontal hole; 7. Receiving hopper; 8. Waste material conveying roller. Detailed Implementation
[0027] The present disclosure will now be described in further detail with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present disclosure and are not intended to limit the scope of the disclosure.
[0028] To keep the drawings concise, each drawing only schematically shows the parts relevant to the disclosure; these do not represent the actual structure of the product. Furthermore, for ease of understanding, in some drawings, only one of components with the same structure or function is schematically shown, or only one is labeled. In this document, "one" not only means "only one," but can also mean "more than one," and "several" includes "two" and "more than two."
[0029] In this document, it should be noted that, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "linkage" should be interpreted broadly. For example, they can refer to fixed connections, detachable connections, or integral connections; they can refer to mechanical connections or electrical connections; they can refer to direct connections or indirect connections through an intermediate medium; and they can refer to the internal connection between two components. Those skilled in the art can understand the specific meaning of the above terms in this disclosure based on the specific circumstances.
[0030] In this disclosure, unless otherwise expressly specified and limited, "above" or "below" the second feature can include direct contact between the first and second features, or contact between the first and second features through another feature between them. Furthermore, "above," "over," and "on top" of the second feature includes the first feature directly above or diagonally above the second feature, or simply indicates that the first feature is at a higher horizontal level than the second feature. "Below," "below," and "under" the second feature includes the first feature directly below or diagonally below the second feature, or simply indicates that the first feature is at a lower horizontal level than the second feature.
[0031] In the description of this embodiment, terms such as "upper," "lower," "left," and "right" are based on the orientation or positional relationship shown in the accompanying drawings. They are used only for the convenience of description and simplification of operation, and are not intended to indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this disclosure.
[0032] Furthermore, in the description of this application, the terms "first," "second," etc., are used only to distinguish descriptions and should not be construed as indicating or implying relative importance.
[0033] like Figures 1-3 As shown, a molding apparatus for producing fast food boxes according to an embodiment of the present disclosure is illustrated, comprising:
[0034] Equipment rack 1 and portal frame 2, wherein the portal frame 2 is mounted on the equipment rack 1;
[0035] Molding component 5, which is disposed on the equipment frame 1 and the portal frame 2;
[0036] A pair of feed rollers 3 and a processing component 4, wherein the feed rollers 3 are rotatably connected inside the equipment frame 1, and the processing component 4 is disposed on the equipment frame 1;
[0037] Slitting component 6, which is disposed on the equipment rack 1;
[0038] The processing component 4 includes a housing 4-1, which is fixed in the equipment frame 1. A pair of ultraviolet germicidal lamp plates 4-2 are provided inside the housing 4-1. A pair of pipes 4-3 are provided inside the housing 4-1. Air blowing holes 4-4 are opened on the surface of the pipes 4-3. Rolling rods 4-5 are provided at the upper and lower ends of the openings on both sides of the housing 4-1. A conveying roller 4-6 driven by electricity is provided on the equipment frame 1. The conveying roller 4-6 is located on the upper end of one of the feeding rollers 3.
[0039] In some examples, a processing component 4 is designed to achieve clean pretreatment of fast food box raw materials. This component includes a housing 4-1 fixed to the equipment frame 1 by welding, with ultraviolet germicidal lamp plates 4-2 distributed parallel on both sides inside and mounted by brackets. The surface of the lamp plates is covered with a light-transmitting protective cover to avoid direct contact with the raw materials. The pipes 4-3 inside the housing 4-1 are symmetrically distributed vertically, and the air blowing holes 4-4 on the surface are evenly opened along the axial direction of the pipes 4-3, facing the raw material conveying path. The pipes 4-3 are connected to an external air source. The rolling rods 4-5 at the openings on both sides of the housing 4-1 are rotatably connected by bearings, symmetrically distributed vertically, and have smooth surfaces that contact the surface of the raw materials. The conveying rollers 4-6 on the equipment frame 1 are rotatably connected by bearings, located on the upper end of one of the feed rollers 3, driven by a motor to rotate, and have a rubber anti-slip layer on their surface, forming a clamping conveying structure with the feed roller 3.
[0040] During operation, the raw materials are held and conveyed by the feed roller 3 and the conveyor roller 4-6. After entering the outer shell 4-1, the ultraviolet germicidal lamp plate 4-2 emits ultraviolet light to sterilize and disinfect the surface of the raw materials. At the same time, an external air source sprays airflow through the pipe 4-3 from the air blowing hole 4-4 to blow away dust and impurities from the surface of the raw materials, achieving dust removal. The rolling rod 4-5 rotates with the raw materials during conveying, assisting the raw materials to pass smoothly through the outer shell 4-1 and avoiding jamming. The symmetrical distribution of the ultraviolet germicidal lamp plate 4-2 ensures that both the upper and lower surfaces of the raw materials can be sterilized, and the light-transmitting protective cover protects the lamp plate without affecting the penetration of ultraviolet light. The evenly spaced air blowing holes 4-4 allow the airflow to cover the entire surface of the raw materials, improving the dust removal effect. The rotational support of the rolling rod 4-5 reduces the resistance of the raw materials during conveying and avoids scratching the raw materials. The clamping cooperation between the conveyor roller 4-6 and the feed roller 3 ensures smooth material conveying, and the rubber anti-slip layer prevents slippage. This component, through the combination of ultraviolet sterilization and airflow dust removal, provides clean raw materials for subsequent molding, ensuring the hygiene and safety of the fast food boxes.
[0041] like Figures 1-3 As shown in the figure, the molding component 5 in this embodiment includes an upper mold 5-1, which is connected to the portal frame 2 by a vertical linear drive. A rectangular opening 5-2 is provided on the surface of the equipment frame 1, and a lower mold 5-3 connected by a vertical linear drive is provided in the rectangular opening 5-2. The lower mold 5-3 is located directly below the upper mold 5-1.
[0042] In some examples, to achieve thermoforming of fast food boxes, the upper mold 5-1 on the portal frame 2 is slidably connected to the guide rail via a slider and driven by a vertical linear drive device (such as a hydraulic cylinder), allowing it to rise and fall vertically. Heating elements are installed on the mold surface to achieve temperature control. A rectangular opening 5-2 on the surface of the equipment frame 1 is opened vertically, and the lower mold 5-3 is slidably connected to the rectangular opening 5-2 via a slide rail and driven by another set of vertical linear drive devices, corresponding vertically to the upper mold 5-1. The mold cavity is adapted to the shape of the fast food box.
[0043] During operation, the pre-treated raw material is conveyed between the upper mold 5-1 and the lower mold 5-3. The vertical linear drive device drives the upper mold 5-1 to descend and the lower mold 5-3 to rise, closing the molds. The heating element heats and softens the raw material while applying pressure, causing the material to conform to the mold cavity for molding. After molding, the upper and lower molds 5-3 move in opposite directions to reset, and the molded fast food box is conveyed to the next process. The vertical linear drive device ensures precise movement of the upper and lower molds 5-3 and controllable mold closing pressure, ensuring dimensional accuracy. The rectangular opening 5-2 provides lifting space for the lower mold 5-3, avoiding interference with the equipment frame 1. The temperature control of the heating element can be adapted to different materials (such as paper and plastic) to ensure appropriate softening effect. The cavity design of the upper and lower molds 5-3 determines the final shape of the fast food box, and a tight fit ensures complete molding. This component achieves efficient thermoforming of the fast food box through the combination of upper and lower mold linkage and pressure control, ensuring stable molding quality.
[0044] like Figures 1-3As shown in the figure, the slitting assembly 6 in this embodiment includes a pair of upright plates 6-1, which are fixed at both ends of the surface of the equipment frame 1. A pair of first rotating rods 6-2 are rotatably connected between the upright plates 6-1. Each of the first rotating rods 6-2 is provided with a plurality of pressure rollers 6-3. A drive shaft 6-4 is provided on the side surface of one of the upright plates 6-1. A second rotating rod 6-6 is rotatably connected between the upright plates 6-1. A transmission is provided on the drive shaft 6-4 at one end of each of the first rotating rods 6-2 and the second rotating rod 6-6. The device has a moving gear 6-5, and a number of double-edged cutter discs 6-7 are provided on the second rotating rod 6-6. The surface of the device frame 1 has a number of elongated openings 6-8, which correspond to the positions of the double-edged cutter discs 6-7. A stabilizing frame 6-9 is provided at one end of the surface of the device frame 1. A pair of vertical cylinders 6-10 are provided on the stabilizing frame 6-9. A double-edged cutter 6-11 is provided at the output end of the vertical cylinders 6-10. A transverse hole 6-12 is provided on the surface of the device frame 1, which is located directly below the double-edged cutter 6-11.
[0045] In some examples, a cutting assembly 6 is designed to achieve longitudinal and transverse separation and waste removal after the fast food box is formed. This assembly includes upright plates 6-1 symmetrically distributed at both ends of the surface of the equipment frame 1 and fixed by welding. The first rotating rod 6-2 and the second rotating rod 6-6 are connected in parallel rotation. The pressure rollers 6-3 on the first rotating rod 6-2 are evenly distributed along the axial direction and contact the surface of the raw material. The double-edged blade disc 6-7 on the second rotating rod 6-6 is alternately distributed with the pressure roller 6-3. The blades correspond to the longitudinal cutting position of the fast food box. The long opening 6-8 on the surface of the equipment frame 1 is opened along the trajectory of the double-edged blade disc 6-7 to provide rotation space for the blade disc and avoid interference with the equipment frame 1. The drive shaft 6-4 on the side surface of one side plate 6-1 is rotatably connected by a bearing and driven by a motor. The shaft meshes with the transmission gear 6-5 at one end of the first rotating rod 6-2 and the second rotating rod 6-6 to achieve synchronous transmission. The stabilizing frame 6-9 at one end of the surface of the equipment frame 1 is fixed by bolts. The vertical cylinder 6-10 at the top is vertically installed. The double-edged cutter 6-11 at the output end is located directly above the horizontal hole 6-12, corresponding to the horizontal cutting position of the fast food box.
[0046] During operation, the formed continuous strip is conveyed to the slitting assembly 6. The drive shaft 6-4 drives the first and second rotating rods 6-6 to rotate synchronously via the transmission gear 6-5. The pressure roller 6-3 presses the strip to prevent deviation. The double-edged cutter disc 6-7 rotates along the long opening 6-8 to longitudinally slit the strip, separating the side waste of individual fast food boxes. The strip continues to be conveyed to the area below the double-edged cutter 6-11, where the vertical cylinder 6-10 drives the cutter to descend and transversely cut the strip along the horizontal hole 6-12, separating individual complete fast food boxes. The meshing of the transmission gear 6-5 ensures that the rotation speed of each rotating rod is consistent, making the slitting position precise. The pressing action of the pressure roller 6-3 prevents the strip from slipping, improving slitting accuracy. The design of the double-edged cutter disc 6-7 and the double-edged cutter 6-11 allows for simultaneous cutting of both sides, improving slitting efficiency. The long opening 6-8 and the horizontal hole 6-12 provide space for the cutter to move, preventing cutter wear. This component combines roller pressing and precise cutting to achieve longitudinal and transverse cutting of fast food boxes and waste removal, completing the separation process after molding.
[0047] For example, such as Figure 1 As shown, a receiving hopper 7 is provided at one end of the equipment frame 1, and the receiving hopper 7 is located on one side of the double-edged cutter 6-11.
[0048] In some examples, the receiving hopper 7 at one end of the equipment frame 1 is located on one side of the double-edged cutter 6-11 and can receive the fast food boxes after they have been cut laterally. After the cutter cuts the fast food box, it falls into the receiving hopper 7 under the action of gravity. The receiving hopper 7 is inclined, which can guide the fast food boxes to slide and stack in an orderly manner, avoid scattering, facilitate subsequent centralized collection and sorting, reduce the amount of manual picking up, and improve production efficiency.
[0049] For example, such as Figure 1 As shown, a pair of waste material conveying rollers 8 are rotatably connected to the surface of the equipment frame 1.
[0050] In some examples, a pair of waste conveyor rollers 8 on the surface of the equipment frame 1 can convey the waste belt generated by slitting. The longitudinally slit waste belt is held between the two conveyor rollers, which pull the waste belt out of the equipment by rotating, preventing waste from accumulating next to the slitting assembly 6 and affecting normal operation, keeping the equipment clean, and realizing continuous recycling of waste.
[0051] For example, such as Figure 1 As shown, the pressure roller 6-3 is located on both the front and rear sides of the double-edged cutter head 6-7.
[0052] In some examples, pressure rollers 6-3 are located on both sides of the double-bladed cutter head 6-7, which can stabilize the material strip during slitting. Before slitting, the front pressure roller 6-3 presses the material strip to ensure accurate slitting position; after slitting, the rear pressure roller 6-3 continues to press to prevent the material strip from shifting due to the force of slitting, ensuring smooth subsequent conveying, improving the accuracy and stability of longitudinal slitting, and making the edges of the slitting fast food box neat.
[0053] In actual use: the raw material is clamped by the feeding roller 3 and the conveying roller 4-6 and fed into the processing component 4. The rolling rod 4-5 assists in smoothly entering the outer shell 4-1. The ultraviolet germicidal lamp plate 4-2 sterilizes the upper and lower surfaces of the raw material. The pipe 4-3 sprays air through the blowing hole 4-4 to remove surface dust. The pre-treated raw material is conveyed to the forming component 5. The upper mold 5-1 and the lower mold 5-3 close under vertical linear drive. The raw material is heated and pressurized to form. Then the mold separates and the formed material strip enters the slitting component 6. The pressure roller 6-3 of the first rotating rod 6-2 presses the material strip. The drive shaft 6-4 drives the double-edged blade 6-7 of the second rotating rod 6-6 to longitudinally slit the material through the transmission gear 6-5. Then, the material is transversely cut by the double-edged cutter 6-11. The finished product falls into the receiving hopper 7. The waste material is conveyed to the outside by the waste material carry-out roller 8. The entire process realizes a continuous operation of cleaning, forming and slitting.
[0054] It should be noted that the above embodiments are only used to illustrate the technical solutions of this disclosure and are not intended to limit it. Although this disclosure has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solutions of this disclosure without departing from the spirit and scope of the technical solutions of this disclosure, and all such modifications and substitutions should be covered within the scope of the claims of this disclosure.
Claims
1. A molding apparatus for producing fast food boxes, characterized in that, include: Equipment rack (1) and portal frame (2), the portal frame (2) being mounted on the equipment rack (1); A molding component (5) is disposed on the equipment frame (1) and the portal frame (2); A pair of feed rollers (3) and a processing assembly (4), wherein the feed rollers (3) are rotatably connected inside the equipment frame (1) and the processing assembly (4) is disposed on the equipment frame (1); A slitting assembly (6) is disposed on the equipment rack (1); The processing component (4) includes a housing (4-1) which is fixed in the equipment frame (1). A pair of ultraviolet germicidal lamp plates (4-2) are provided inside the housing (4-1). A pair of pipes (4-3) are provided inside the housing (4-1). Air blowing holes (4-4) are opened on the surface of the pipes (4-3). Rolling rods (4-5) are provided at the upper and lower ends of the openings on both sides of the housing (4-1). A conveying roller (4-6) driven by electricity is provided on the equipment frame (1). The conveying roller (4-6) is located on the upper end of one of the feeding rollers (3).
2. The forming device for a fast food box production according to claim 1, characterized in that, The molding component (5) includes an upper mold (5-1), which is connected to the portal frame (2) by a vertical linear drive. A rectangular opening (5-2) is provided on the surface of the equipment frame (1), and a lower mold (5-3) connected by a vertical linear drive is provided in the rectangular opening (5-2). The lower mold (5-3) is located directly below the upper mold (5-1).
3. The forming device for a fast food box production according to claim 1, characterized in that, The slitting assembly (6) includes a pair of upright plates (6-1), which are fixed at both ends of the surface of the equipment frame (1). A pair of first rotating rods (6-2) are rotatably connected between the upright plates (6-1). Each of the first rotating rods (6-2) is provided with a plurality of pressure rollers (6-3). A drive shaft (6-4) is provided on the side surface of one of the upright plates (6-1).
4. The forming device for a fast food box production according to claim 3, characterized in that, A second rotating rod (6-6) is rotatably connected between the upright plates (6-1). A transmission gear (6-5) is provided on one end of the drive shaft (6-4) and one end of the first rotating rod (6-2) and the second rotating rod (6-6). A plurality of double-edged cutter discs (6-7) are provided on the second rotating rod (6-6). A plurality of elongated openings (6-8) are provided on the surface of the equipment frame (1), and the elongated openings (6-8) correspond to the positions of the double-edged cutter discs (6-7).
5. The forming device for a fast food box production according to claim 4, characterized in that, A stabilizing frame (6-9) is provided at one end of the surface of the equipment frame (1). A pair of vertical cylinders (6-10) are provided on the stabilizing frame (6-9). A double-edged cutter (6-11) is provided at the output end of the vertical cylinder (6-10). A horizontal hole (6-12) is opened on the surface of the equipment frame (1). The horizontal hole (6-12) is located directly below the double-edged cutter (6-11).
6. The forming device for a fast food box production according to claim 5, characterized in that, The equipment frame (1) is provided with a receiving hopper (7) at one end, and the receiving hopper (7) is located on one side of the double-edged cutter (6-11).
7. The forming device for a fast food box production according to claim 1, characterized in that, A pair of waste belt-out rollers (8) are rotatably connected to the surface of the equipment rack (1).
8. The forming device for a fast food box production according to claim 4, wherein The pressing wheels (6-3) are located on the front and back sides of the double-blade cutter head (6-7).