A device for marking stainless steel cutlery handles

By designing a mold engraving device with a sliding mold mounting slot and a locking mechanism, the problems of low mold replacement efficiency and complex finished product sorting in existing equipment have been solved, realizing efficient mold replacement and tableware classification and collection, and improving the applicability and processing efficiency of the equipment.

CN224465546UActive Publication Date: 2026-07-07SHENZHEN YEANSOEN IMPORT & EXPORT CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN YEANSOEN IMPORT & EXPORT CO LTD
Filing Date
2025-09-03
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing die-cutting equipment has poor applicability, low efficiency when molds need to be changed, and complex finished product sorting, which can easily lead to confusion and affect processing and packaging efficiency.

Method used

A die-cutting device for stainless steel cutlery handles was designed, which uses a sliding die mounting slot and locking mechanism, combined with a storage frame and a feeding component, to achieve quick die replacement and classified collection of cutlery.

Benefits of technology

It improved mold replacement efficiency, expanded the equipment's applicability, reduced manual sorting error rate, and improved processing and collection efficiency.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224465546U_ABST
    Figure CN224465546U_ABST
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Abstract

The utility model discloses a kind of moulding device of stainless steel tableware handle part, it is related to tableware processing technical field, including processing machine box and fixedly installed in the moulding machine of processing machine box top, the top of processing machine box is provided with moving mechanism, and one end fixedly installed is limited frame, storage frame is slidably arranged in limited frame, moving mechanism includes reciprocating screw rod and mounting seat, the top of mounting seat is fixedly installed with bearing seat, reciprocating screw rod can drive bearing seat reciprocating movement when rotating, the top of bearing seat is provided with two installation grooves, and two sliding grooves are provided in installation groove;Through the intercoordination between bearing frame, installation groove, sliding groove and two locking mechanisms, mould can slide in installation groove, then extrude mould by several locking plates, can quickly lock and unlock mould, can according to the size of tableware quickly replace corresponding mould, high efficiency is installed and dismantled, expand the application range of equipment, strong applicability.
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Description

Technical Field

[0001] This utility model relates to the field of tableware processing technology, specifically to a die-cutting device for the handle of stainless steel tableware. Background Technology

[0002] Stainless steel tableware has become the mainstream choice for homes, restaurants, and hotels due to its rust resistance, ease of cleaning, and long service life. The annual production of basic categories such as knives, forks, and spoons exceeds 10 billion pieces. With the upgrading of consumption, the market demand for stainless steel tableware has shifted from basic use to a combination of personalization and functionality. This requires not only that the handles be engraved with brand logos, anti-slip textures, or decorative patterns to enhance recognizability and user experience, but also that they be suitable for different user groups.

[0003] The lower molds of existing die-cutting devices are mostly integrated fixed structures, with the size and shape of the handle groove corresponding one-to-one with the handles of the tableware to be processed. If different types (such as knife handles and spoon handles) or different sizes of tableware need to be processed, it is necessary to change the equipment or spend a lot of time installing and disassembling to replace the mold, which seriously affects the operating efficiency of the equipment and thus the processing efficiency. The applicability is poor. At the same time, the existing equipment is only equipped with a single collection frame. The finished products after die-cutting are directly mixed into the frame, and manual sorting is required afterward. Due to the large number of tableware, human operation errors are prone to occur, resulting in confusion of finished products of different specifications, which affects the efficiency of subsequent packaging and delivery, and thus increases the complexity of the operation process. Utility Model Content

[0004] To address the shortcomings of existing technologies, this utility model provides a die-cutting device for the handle of stainless steel tableware, thereby overcoming the aforementioned technical problems in existing related technologies.

[0005] A die-cutting device for stainless steel cutlery handles includes a processing housing and a die-cutting machine fixedly mounted on the top of the processing housing. A moving mechanism is provided on the top of the processing housing, and a limiting frame is fixedly mounted at one end. A storage frame is slidably disposed within the limiting frame. The moving mechanism includes a reciprocating screw and a mounting base. A bearing seat is fixedly mounted on the top of the mounting base. When the reciprocating screw rotates, it drives the bearing seat to move back and forth. Two mounting slots are formed on the top of the bearing seat, and two sliding grooves are formed within each mounting slot. A mold (first mold) and a mold (second mold) are respectively installed in the two mounting slots. Locking mechanisms are provided on both sides of the bearing seat. Each locking mechanism includes a screw and two locking plates. When the two screws rotate, they drive several locking plates to move horizontally and press against one side of mold (first mold) and mold (second mold). A feeding assembly is provided on one side of the processing housing. The feeding assembly includes a motor (second motor) and a feeding plate. The motor (second motor) drives the feeding plate to rotate. Several partition plates are fixedly mounted on the top of the feeding plate. Two fixing components are provided on the top of the bearing seat.

[0006] Preferably, the moving mechanism further includes a support platform, a motor, and a moving groove. The support platform is fixedly installed on the top of the processing machine housing. The moving groove is opened on the top of the moving mechanism. The motor is fixedly installed on the outer wall of the support platform. The reciprocating screw is rotatably connected to the support platform, and one end is fixedly connected to the output end of the motor. The mounting seat is threaded onto the reciprocating screw and slides against the inner wall of the moving groove.

[0007] Preferably, the fixing assembly includes a fixing frame, an electric push rod, and a clamping plate. The fixing frame is fixedly installed on the top of the support seat, the electric push rod is fixedly installed on the bottom of the fixing frame, and the clamping plate is fixedly connected to the output end of the electric push rod.

[0008] Preferably, the locking mechanism further includes a sleeve plate and two sliding rods. The sleeve plate is threaded onto the screw. Both sliding rods are fixedly connected to the sleeve plate and slide in cooperation with the bearing seat. The two locking plates are fixedly connected to the two sliding rods respectively and slide in cooperation with the two sliding grooves respectively.

[0009] Preferably, the locking mechanism further includes a fixed seat and a rotating handle. The fixed seat is fixedly installed on the outer wall of the bearing seat, and the rotating handle is fixedly installed on one end of the screw. The screw is rotatably connected to the fixed seat.

[0010] Preferably, the feeding assembly further includes a rotating shaft, which is fixedly connected to the output end of the second motor, and the feeding plate is fixedly sleeved on the rotating shaft.

[0011] Preferably, the unloading assembly further includes a support frame, which is fixedly installed on the side of the processing machine housing, the second motor is fixedly installed on one end of the support frame, and the rotating shaft is rotatably connected to the support frame.

[0012] Due to the adoption of the above technical solution, the technological progress achieved by this utility model compared to the prior art is as follows:

[0013] 1. This utility model provides a die-cutting device for the handle of stainless steel tableware. Through the cooperation between the support frame, the mounting groove, the slide groove and two locking mechanisms, the die can slide in the mounting groove. Then, by pressing the die with several locking plates, the die can be quickly locked and unlocked. The die can be quickly replaced according to the size of the tableware. The installation and disassembly efficiency is high, the application range of the equipment is expanded and the applicability is strong.

[0014] 2. This utility model provides a die-cutting device for the handle of stainless steel tableware. Through the cooperation between the storage frame, the feeding component and the limiting frame, the limiting frame limits the storage frame. The staff places tableware of different sizes into the feeding channel separated by the partition plate for sorting. At the same time, the motor adjusts the rotation angle of the feeding plate through the rotating shaft, which can reduce the probability of tableware accumulation, improve the tableware collection effect and further improve applicability. Attached Figure Description

[0015] Figure 1 This is a three-dimensional structural diagram of the present invention;

[0016] Figure 2 This is a three-dimensional structural diagram of the moving mechanism in this utility model;

[0017] Figure 3 This is a three-dimensional structural diagram of the support base in this utility model;

[0018] Figure 4 This is a three-dimensional structural diagram of the support base in this utility model;

[0019] Figure 5 for Figure 4 A magnified structural diagram of part A in the middle;

[0020] Figure 6 This is a three-dimensional structural diagram of the feeding component in this utility model.

[0021] In the picture:

[0022] 1. Processing chassis; 101. Limiting frame; 102. Storage frame; 2. Moving mechanism; 201. Support platform; 202. Motor 1; 203. Moving groove; 204. Reciprocating lead screw; 205. Mounting base; 3. Support base; 300. Mounting groove; 301. Mold 1; 302. Mold 2; 303. Slide groove; 4. Fixing frame; 5. Electric push rod; 6. Pressing plate; 7. Locking mechanism; 700. Fixing base; 701. Screw; 702. Rotary handle; 703. Socket plate; 704. Sliding rod; 705. Locking plate; 8. Die-cutting machine; 9. Material feeding assembly; 901. Support frame; 902. Motor 2; 903. Rotating shaft; 904. Material feeding plate; 905. Partition plate. Detailed Implementation

[0023] To make the technical means, creative features, objectives, and effects of this utility model easier to understand, the following describes this utility model in conjunction with specific embodiments:

[0024] like Figure 1-6As shown, this utility model provides a die-cutting device for the handle of stainless steel tableware, including a processing housing 1 and a die-cutting machine 8 fixedly installed on the top of the processing housing 1. A moving mechanism 2 is provided on the top of the processing housing 1, and a limiting frame 101 is fixedly installed at one end. The moving mechanism 2 includes a reciprocating screw 204 and a mounting base 205. A bearing seat 3 is fixedly installed on the top of the mounting base 205. When the reciprocating screw 204 rotates, it can drive the bearing seat 3 to move back and forth. Two mounting grooves 300 are opened on the top of the bearing seat 3, and two sliding grooves 303 are opened in the mounting grooves 300. Mold 1 301 and Mold 2 302 are respectively installed in the two mounting slots 300. Locking mechanisms 7 are provided on both sides of the support base 3. Each locking mechanism 7 includes a screw 701 and two locking plates 705. When the two screws 701 rotate, they drive several locking plates 705 to move horizontally and press against one side of Mold 1 301 and Mold 2 302 respectively. Two fixing components are provided on the top of the support base 3. The moving mechanism 2 also includes a support platform 201, a motor 1 202, and a moving groove 203. The support platform 201 is fixedly installed on the top of the processing machine housing 1, and the moving groove 203... Located at the top of the moving mechanism 2, motor 202 is fixedly mounted on the outer wall of the support platform 201. A reciprocating screw 204 is rotatably connected to the support platform 201, and one end is fixedly connected to the output end of motor 202. Mounting seat 205 is threaded onto the reciprocating screw 204 and slides against the inner wall of the moving groove 203. The fixing assembly includes a fixing frame 4, an electric push rod 5, and a pressure plate 6. The fixing frame 4 is fixedly mounted on the top of the support platform 3, the electric push rod 5 is fixedly mounted on the bottom of the fixing frame 4, and the pressure plate 6 is fixedly connected to the output end of the electric push rod 5. A locking mechanism is also included. 7 also includes a socket plate 703 and two sliding rods 704. The socket plate 703 is threaded onto the screw 701. The two sliding rods 704 are fixedly connected to the socket plate 703 and are slidably engaged with the bearing seat 3. Two locking plates 705 are fixedly connected to the two sliding rods 704 respectively and are slidably engaged with the two sliding grooves 303 respectively. The locking mechanism 7 also includes a fixed seat 700 and a rotating handle 702. The fixed seat 700 is fixedly installed on the outer wall of the bearing seat 3, and the rotating handle 702 is fixedly installed on one end of the screw 701. The screw 701 is rotatably connected to the fixed seat 700.

[0025] The operator drives the screw 701 to rotate clockwise using the handle 702. When the screw 701 rotates clockwise, it engages with the threaded sleeve of the socket plate 703, causing the socket plate 703 to slide on the screw 701. As the socket plate 703 moves, it drives the two sliding rods 704 to slide on one side of the bearing seat 3. Simultaneously, the sliding rods 704 drive the locking plate 705 to slide within the groove 303. Continuous movement of the locking plate 705 causes the two sets of locking plates 705 to press and fix mold one 301 and mold two 302 respectively. When mold one 301 and mold two 302 need to be replaced, the two screws 701 are reversed, thus releasing the locking of mold one 301 and mold two 302, allowing them to be removed from the mounting slot 300. After mold 2 302 is fixed, the staff places the tableware to be processed into the processing grooves at the top of mold 1 301 and mold 2 302. Then, the two electric push rods 5 are activated, which push the pressure plate 6, causing the pressure plate 6 to move vertically downward and press and fix the tableware. Finally, the die-cutting machine 8 is started to process the tableware. The rotation frequency and start-stop interval of the output end of motor 1 202 are preset. Then, motor 1 202 is started. Motor 1 202 drives the reciprocating screw 204 to rotate, which drives the mounting base 205 and the bearing base 3 to move back and forth. This causes mold 1 301 and mold 2 302 to move cyclically to the bottom of the output end of die-cutting machine 8, so that multiple tableware can be processed in sequence.

[0026] The mounting slot 300 can guide mold one 301 and mold two 302, improving the efficiency of mold installation and disassembly. At the same time, the installation and disassembly method is simple, and molds with different sizes of processing slots on the top can be replaced in time according to the specifications of the tableware being processed, effectively improving the scope of application and applicability.

[0027] like Figure 1 and Figure 6 As shown, in one embodiment, a storage frame 102 is slidably disposed within the limiting frame 101. The unloading assembly 9 also includes a rotating shaft 903, which is fixedly connected to the output end of the second motor 902. The unloading plate 904 is fixedly sleeved on the rotating shaft 903. The unloading assembly 9 is disposed on one side of the processing machine housing 1. The unloading assembly 9 includes a second motor 902 and an unloading plate 904. The second motor 902 can drive the unloading plate 904 to rotate. Several partition plates 905 are fixedly installed on the top of the unloading plate 904. The unloading assembly 9 also includes a support frame 901, which is fixedly installed on the side of the processing machine housing 1. The second motor 902 is fixedly installed on one end of the support frame 901. The rotating shaft 903 is rotatably connected to the support frame 901.

[0028] Several partitions 905 divide the top of the feeding plate 904 into several feeding channels, which correspond to different storage spaces inside the storage frame 102, so that the tableware can be collected and classified in a timely manner after processing. At the same time, the feeding plate 904 is rotated by the motor 902 and the rotating shaft 903, and the tableware can be placed in different positions by adjusting the tilt angle of the feeding plate 904. This prevents the situation where materials are piled up on one side of the storage space while there are no tableware or few tableware on the other side, thus improving the collection effect and further improving the applicability.

[0029] The working principle of the die-cutting device for the handle of this stainless steel cutlery will be explained in detail below:

[0030] The operator drives the screw 701 to rotate forward using the handle 702. When the screw 701 rotates forward, it engages with the threaded sleeve of the socket plate 703, causing the socket plate 703 to slide on the screw 701. As the socket plate 703 moves, it drives the two sliding rods 704 to slide on one side of the bearing seat 3. At the same time, the sliding rods 704 drive the locking plate 705 to slide within the slide groove 303. Continuous movement of the locking plate 705 causes the two sets of locking plates 705 to press and fix the mold 1 301 and the mold 2 302 respectively. When it is necessary to replace the mold 1 301 and the mold 2 302, the two screws 701 are reversed, which will de-lock the mold 1 301 and the mold 2 302, and then they can be removed from the mounting slot 300. After the mold 1 301 and the mold 2 302 are fixed, the operator places the tableware to be processed in the processing slots on top of the mold 1 301 and the mold 2 302, and then activates the two electric push rods 5, causing the electric push rods 5 to push the clamping plate 6. This causes the pressing plate 6 to move vertically downwards and press and fix the tableware. Finally, the die-cutting machine 8 is started to process the tableware. The motor 1 202 drives the reciprocating screw 204 to rotate, which in turn drives the mounting base 205 and the bearing base 3 to move back and forth. This causes the mold 1 301 and the mold 2 302 to move cyclically to the bottom of the output end of the die-cutting machine 8, so that multiple tableware can be processed in sequence. The die-cut tableware is placed on the feeding plate 904 for feeding. Due to the setting of the partition plate 905, the staff can store tableware of different sizes in different storage spaces inside the storage frame 102 through the feeding plate 904, which effectively improves the classification effect. At the same time, the staff can also manually start the motor 2 902 to drive the rotating shaft 903 and the feeding plate 904 to rotate and adjust the tilt angle of the feeding plate 904 so that the tableware can fall in different positions inside the storage frame 102, reducing the probability of tableware piling up and affecting the collection effect.

[0031] The present invention has been described in detail above. However, modifications or improvements can be made to it, which will be obvious to those skilled in the art. Therefore, any modifications or improvements that do not depart from the spirit of the present invention are within the protection scope of the present invention.

Claims

1. A die-cutting device for the handle of stainless steel tableware, comprising a processing housing (1) and a die-cutting machine (8) fixedly mounted on the top of the processing housing (1), characterized in that: The top of the processing machine housing (1) is provided with a moving mechanism (2), and a limiting frame (101) is fixedly installed at one end. A storage frame (102) is slidably arranged in the limiting frame (101). The moving mechanism (2) includes a reciprocating screw (204) and a mounting base (205). A bearing base (3) is fixedly installed on the top of the mounting base (205). When the reciprocating screw (204) rotates, it can drive the bearing base (3) to move back and forth. Two mounting slots (300) are opened on the top of the bearing base (3), and two sliding grooves (303) are opened in the mounting slots (300). Mold 1 (301) and Mold 2 (302) are respectively installed in the two mounting slots (300). Locking mechanisms (7) are provided on both sides of the seat (3). The locking mechanism (7) includes a screw (701) and two locking plates (705). When the two screws (701) rotate, they drive several locking plates (705) to move horizontally and press one side of the mold one (301) and the mold two (302) respectively. A feeding assembly (9) is provided on one side of the processing machine box (1). The feeding assembly (9) includes a motor two (902) and a feeding plate (904). The motor two (902) can drive the feeding plate (904) to rotate. Several partition plates (905) are fixedly installed on the top of the feeding plate (904). Two fixing components are provided on the top of the bearing seat (3).

2. The die-cutting device for the handle of stainless steel tableware according to claim 1, characterized in that: The moving mechanism (2) further includes a support platform (201), a motor (202), and a moving groove (203). The support platform (201) is fixedly installed on the top of the processing machine box (1). The moving groove (203) is opened on the top of the moving mechanism (2). The motor (202) is fixedly installed on the outer wall of the support platform (201). The reciprocating screw (204) is rotatably connected to the support platform (201), and one end is fixedly connected to the output end of the motor (202). The mounting seat (205) is threaded onto the reciprocating screw (204) and slides against the inner wall of the moving groove (203).

3. The die-cutting device for the handle of stainless steel tableware according to claim 1, characterized in that: The fixing assembly includes a fixing frame (4), an electric push rod (5), and a pressure plate (6). The fixing frame (4) is fixedly installed on the top of the bearing seat (3), the electric push rod (5) is fixedly installed on the bottom of the fixing frame (4), and the pressure plate (6) is fixedly connected to the output end of the electric push rod (5).

4. The die-cutting device for the handle of stainless steel tableware according to claim 1, characterized in that: The locking mechanism (7) further includes a sleeve plate (703) and two sliding rods (704). The sleeve plate (703) is threaded onto the screw (701). Both sliding rods (704) are fixedly connected to the sleeve plate (703) and are slidably engaged with the bearing seat (3). The two locking plates (705) are fixedly connected to the two sliding rods (704) respectively and are slidably engaged with the two sliding grooves (303) respectively.

5. The die-cutting device for the handle of stainless steel tableware according to claim 1, characterized in that: The locking mechanism (7) further includes a fixed seat (700) and a rotating handle (702). The fixed seat (700) is fixedly installed on the outer wall of the bearing seat (3), and the rotating handle (702) is fixedly installed on one end of the screw (701). The screw (701) is rotatably connected to the fixed seat (700).

6. The die-cutting device for the handle of stainless steel tableware according to claim 1, characterized in that: The feeding assembly (9) also includes a rotating shaft (903), which is fixedly connected to the output end of the second motor (902), and the feeding plate (904) is fixedly sleeved on the rotating shaft (903).

7. The die-cutting device for the handle of stainless steel tableware according to claim 6, characterized in that: The feeding assembly (9) also includes a support frame (901), which is fixedly installed on the side of the processing machine box (1), and the second motor (902) is fixedly installed on one end of the support frame (901). The rotating shaft (903) is rotatably connected to the support frame (901).