Multi-surface machining numerical control lathe with overturning structure
By designing a flipping structure and flipping components on a CNC lathe, multi-faceted processing of products is achieved, solving the problem that traditional CNC lathes cannot process in all directions, and improving the flexibility and efficiency of processing.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DONGGUAN SNIKE CNC TECH CO LTD
- Filing Date
- 2025-06-24
- Publication Date
- 2026-06-02
AI Technical Summary
Traditional CNC lathes can only perform CNC machining on products from a single angle or four directions, which cannot meet the needs of all-round machining.
A multi-faceted CNC lathe with a flipping structure was designed. Through the cooperation of the flipping component and the clamping plate, the product can be processed on multiple sides of the CNC machine tool. The flipping motor drives the length shell to rotate, and the position of the product to be processed is adjusted.
It improves the practicality of CNC machine tools for product processing, realizes all-round CNC machining of products, and meets the production needs of personalized customization and small batch orders.
Smart Images

Figure CN224310127U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of CNC lathe technology, specifically a multi-faceted CNC lathe with a flipping structure. Background Technology
[0002] CNC lathes employ a computer control system, which can precisely control the cutting path and machining accuracy of the cutting tool. Through preset machining parameters and feedback mechanisms, high-precision product manufacturing can be achieved. CNC lathes utilize an automated control system, enabling continuous production operations and a highly efficient workflow. Furthermore, they can be quickly adjusted and product switched according to requirements, improving production efficiency and quality. CNC lathes can be adjusted and designed according to different machining needs and product types, maintaining high-efficiency production while also meeting the customization needs of personalized products and the production requirements of small-batch orders.
[0003] However, traditional CNC lathes have the following disadvantages:
[0004] Traditional CNC lathes perform CNC machining on products from a single angle or from four directions, which cannot meet people's needs for all-round CNC machining of products. Utility Model Content
[0005] The purpose of this utility model is to provide a multi-faceted CNC lathe with a flipping structure to solve the problem mentioned in the background art that traditional CNC lathes can only perform CNC machining on products from a single angle or from four directions, which cannot meet people's needs for all-round CNC machining of products.
[0006] To achieve the above objectives, this utility model provides the following technical solution: a multi-faceted machining CNC lathe with a flipping structure, comprising a CNC frame, a CNC component fixedly mounted on the top of the CNC frame, a worktable fixedly mounted on one side of the CNC frame, a displacement component mounted on the top of the worktable, and flipping components fixedly mounted on both sides of the top of the displacement component. Each of the two flipping components includes a limiting frame and a length shell. One side of the limiting frame is rotatably connected to one end of the length shell, and a length rod is slidably connected to the other end of the length shell. A clamping plate is fixedly mounted on one end of the length rod. The CNC component includes a first vertical plate and two first sliding tracks. Two sliding tracks are mounted on one side of the first vertical plate. Each end is fixedly connected to one side of two first sliding rails. A first sliding block is slidably connected to the middle of each of the two first sliding rails. A second upright plate is fixedly installed between the two first sliding blocks. A second sliding rail is fixedly installed at both ends of one side of the second upright plate. A second sliding block is slidably connected to the middle of each of the two second sliding rails. A connecting platform is fixedly installed between the two second sliding blocks. A processing shell is fixedly installed at the bottom of the connecting platform. A main shaft is rotatably connected to one side of the top of the inner wall of the processing shell. The product is placed on the displacement plate. The user slides the length rod along the length shell to adjust the distance between the two clamping plates. The two clamping plates clamp and fix the product from both sides.
[0007] Preferably, a stepper motor is fixedly installed in the middle of one side of the first upright plate, and a first lead screw is fixedly installed at the output end of the stepper motor. The middle part of the first lead screw is connected to the internal thread of the second upright plate, and the bottom end of the first upright plate is fixedly connected to the CNC machine frame. When the stepper motor is powered on, it starts and drives the first lead screw to rotate. The thread on the surface of the first lead screw matches the thread on the inner wall of the second upright plate. The second upright plate drives the first sliding block to slide along the first sliding track, which improves the stability of the second upright plate sliding along the first lead screw and indirectly adjusts the machining position of the spindle.
[0008] Preferably, a push cylinder is fixedly installed in the middle of one side of the second upright plate. The movable end of the push cylinder is fixedly connected to the middle of the top of the connecting platform. A micro motor is fixedly installed on the bottom of the processing shell away from the spindle. A drive pulley is fixedly installed at the output end of the micro motor. A driven pulley is fixedly installed on the surface of the spindle. A connecting belt is connected between the drive pulley and the driven pulley. The push cylinder performs a telescopic movement, pushing the connecting platform from the top. The connecting platform drives the second sliding block to slide along the second sliding track, improving the stability of the connecting platform's sliding and adjusting the processing height of the spindle. After the micro motor is powered on, it starts and drives the drive pulley to rotate. The drive pulley drives the driven pulley to rotate through the connecting belt, and the driven pulley drives the spindle to rotate. The spindle then performs CNC machining on the product.
[0009] Preferably, the displacement assembly includes two third sliding tracks and a displacement plate. A third sliding block is slidably connected to the middle of each of the two third sliding tracks. The top ends of the two third sliding blocks are fixedly connected to the two sides of the bottom end of the displacement plate, and the two sides of the top end of the displacement plate are fixedly connected to two flipping assemblies.
[0010] Preferably, the bottom ends of both third sliding tracks are fixedly connected to the worktable. A servo motor is fixedly installed on the surface of the worktable, and a second lead screw is fixedly installed at the output end of the servo motor. A movable block that is slidably connected to the worktable is threadedly connected to the middle of the second lead screw. The top end of the movable block is fixedly connected to the middle of the bottom end of the displacement plate. When the servo motor is powered on, it starts and drives the second lead screw to rotate. The thread on the surface of the second lead screw matches the thread on the inner wall of the movable block. The movable block is limited by the worktable, which matches its shape and size. Therefore, the movable block slides along the second lead screw to adjust the position of the displacement plate. During the sliding of the displacement plate, the third sliding block slides along the third sliding track, improving the stability of the sliding of the displacement plate and indirectly adjusting the processing position of the product.
[0011] Preferably, the bottom ends of both limiting frames are fixedly connected to the displacement component, and a flipping motor for driving the length shell to rotate is fixedly installed on the surface of one of the limiting frames. After the flipping motor is powered on, it starts and drives the length shell to rotate to flip the product clamped between the two clamping plates.
[0012] Preferably, a tool holder is fixedly mounted on the surface of the CNC component.
[0013] Compared with the prior art, the beneficial effects of this utility model are: by setting a flipping component, the product is clamped and fixed from both sides by two clamping plates, and the flipping motor drives the length shell to rotate to adjust the position of the product to be processed, which facilitates multi-face processing of the product on the CNC machine tool and improves the practicality of the CNC machine tool for product processing. Attached Figure Description
[0014] Figure 1 This is a side view of the present invention;
[0015] Figure 2 This is a side view of the flipping component of this utility model;
[0016] Figure 3 This is a side view of the CNC component of this utility model;
[0017] Figure 4 This is a connection diagram of the displacement component and the worktable of this utility model.
[0018] In the diagram: 1. CNC machine frame; 2. CNC assembly; 201. First vertical plate; 202. First sliding rail; 203. Stepper motor; 204. First lead screw; 205. First sliding block; 206. Second vertical plate; 207. Push cylinder; 208. Second sliding rail; 209. Second sliding block; 210. Connecting table; 211. Spindle; 212. Machining housing; 213. Micro motor; 214. Drive pulley; 215. Driven pulley; 216. Connecting belt; 3. Tool holder; 4. Tilting assembly; 41. Limiting frame; 42. Length housing; 43. Length rod; 44. Clamping plate; 5. Tilting motor; 6. Displacement assembly; 61. Third sliding rail; 62. Third sliding block; 63. Displacement plate; 64. Movable block; 65. Second lead screw; 7. Worktable. Detailed Implementation
[0019] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention.
[0020] Please see Figure 1-4 This utility model provides a multi-faceted machining CNC lathe with a flipping structure, including a CNC frame 1, a CNC component 2 fixedly installed at the top of the CNC frame 1, a worktable 7 fixedly installed on one side of the CNC frame 1, a displacement component 6 installed at the top of the worktable 7, and flipping components 4 fixedly installed on both sides of the top of the displacement component 6. Each flipping component 4 includes a limiting frame 41 and a length shell 42. One side of the limiting frame 41 is rotatably connected to one end of the length shell 42, and the other end of the length shell 42 is slidably connected to a length rod 43. A clamping plate 44 is fixedly installed at one end of the length rod 43. The CNC component 2 includes a first vertical plate 201 and two first sliding rails 202. The two ends of one side of the first vertical plate 201 are respectively fixed to one side of the two first sliding rails 202. The two first sliding rails 202 are slidably connected to the middle of each first sliding block 205. A second upright plate 206 is fixedly installed between the two first sliding blocks 205. A second sliding rail 208 is fixedly installed at both ends of one side of the second upright plate 206. A second sliding block 209 is slidably connected to the middle of each of the two second sliding rails 208. A connecting platform 210 is fixedly installed between the two second sliding blocks 209. A processing shell 212 is fixedly installed at the bottom of the connecting platform 210. A main shaft 211 is rotatably connected to one side of the top of the inner wall of the processing shell 212. The product is placed on the displacement plate 63. The user slides the length rod 43 along the length shell 42 to adjust the distance between the two clamping plates 44. The two clamping plates 44 clamp and fix the product from both sides.
[0021] A stepper motor 203 is fixedly installed in the middle of one side of the first vertical plate 201. A first lead screw 204 is fixedly installed at the output end of the stepper motor 203. The middle part of the first lead screw 204 is connected to the internal thread of the second vertical plate 206. The bottom end of the first vertical plate 201 is fixedly connected to the CNC machine frame 1. When the stepper motor 203 is powered on, it starts and drives the first lead screw 204 to rotate. The thread on the surface of the first lead screw 204 matches the thread on the inner wall of the second vertical plate 206. The second vertical plate 206 drives the first sliding block 205 to slide along the first sliding track 202, which improves the stability of the second vertical plate 206 sliding along the first lead screw 204 and indirectly adjusts the machining position of the spindle 211.
[0022] A push cylinder 207 is fixedly installed in the middle of one side of the second vertical plate 206. The movable end of the push cylinder 207 is fixedly connected to the middle of the top of the connecting platform 210. A micro motor 213 is fixedly installed on the bottom of the machining housing 212 away from the main spindle 211. A drive pulley 214 is fixedly installed at the output end of the micro motor 213. A driven pulley 215 is fixedly installed on the surface of the main spindle 211. A connecting belt 216 is connected between the drive pulley 214 and the driven pulley 215. The push cylinder 207 performs telescopic movement. The cylinder 207 pushes the connecting platform 210 from the top. The connecting platform 210 causes the second sliding block 209 to slide along the second sliding track 208, improving the stability of the sliding of the connecting platform 210 and adjusting the machining height of the spindle 211. The micro motor 213 is started after being powered on. The micro motor 213 drives the drive pulley 214 to rotate. The drive pulley 214 drives the driven pulley 215 to rotate through the connecting belt 216. The driven pulley 215 drives the spindle 211 to rotate, and the spindle 211 performs CNC machining on the product.
[0023] The displacement component 6 includes two third sliding tracks 61 and a displacement plate 63. A third sliding block 62 is slidably connected to the middle of each of the two third sliding tracks 61. The top ends of the two third sliding blocks 62 are fixedly connected to the two sides of the bottom end of the displacement plate 63, and the two sides of the top end of the displacement plate 63 are fixedly connected to two flipping components 4.
[0024] The bottom ends of both third sliding tracks 61 are fixedly connected to the worktable 7. A servo motor is fixedly installed on the surface of the worktable 7. A second lead screw 65 is fixedly installed at the output end of the servo motor. A movable block 64 that is slidably connected to the worktable 7 is threadedly connected to the middle of the second lead screw 65. The top of the movable block 64 is fixedly connected to the middle of the bottom end of the displacement plate 63. When the servo motor is powered on, it starts and drives the second lead screw 65 to rotate. The thread on the surface of the second lead screw 65 matches the thread on the inner wall of the movable block 64. The movable block 64 is limited by the worktable 7, which matches its shape and size. Therefore, the movable block 64 slides along the second lead screw 65 to adjust the position of the displacement plate 63. During the sliding of the displacement plate 63, the third sliding block 62 slides along the third sliding track 61 to improve the stability of the sliding of the displacement plate 63 and indirectly adjust the processing position of the product.
[0025] The bottom ends of both limit frames 41 are fixedly connected to the displacement component 6. A flip motor 5 that drives the length shell 42 to rotate is fixedly installed on the surface of one of the limit frames 41. After the flip motor 5 is powered on, it starts and drives the length shell 42 to rotate to flip the product clamped between the two clamping plates 44.
[0026] The tool holder 3 is fixedly mounted on the surface of the CNC component 2.
[0027] In this embodiment, during use: the product is placed on the displacement plate 63, and the user slides the length rod 43 along the length shell 42 to adjust the distance between the two clamping plates 44. The flipping motor 5 is activated and rotates, causing the length shell 42 to rotate and flip the product clamped between the two clamping plates 44. The two clamping plates 44 clamp and fix the product from both sides. The stepper motor 203 is activated and rotates, causing the first lead screw 204 to rotate. The thread on the surface of the first lead screw 204 matches the thread on the inner wall of the second vertical plate 206. The second vertical plate 206 causes the first sliding block 205 to slide along the first sliding track 202, improving the stability of the second vertical plate 206 sliding along the first lead screw 204 and indirectly adjusting the machining position of the spindle 211. The servo motor is activated and rotates, causing the second lead screw 65 to rotate. The thread on the surface of the second lead screw 65 matches the thread on the inner wall of the movable block 64. The movable block 64 is limited by the worktable 7, which matches its shape and size. Therefore, the movable block 64 slides along the second lead screw 65 to adjust the position of the displacement plate 63. During the sliding of the displacement plate 63, the third sliding block 62 slides along the third sliding track 61 to improve the stability of the sliding of the displacement plate 63 and indirectly adjust the processing position of the product. The cylinder 207 is pushed to perform telescopic movement, and the cylinder 207 pushes the connecting table 210 from the top. The connecting table 210 drives the second sliding block 209 to slide along the second sliding track 208, improving the stability of the sliding of the connecting table 210 and adjusting the processing height of the spindle 211. After the micro motor 213 is powered on, it starts and drives the drive pulley 214 to rotate. The drive pulley 214 drives the driven pulley 215 to rotate through the connecting belt 216. The driven pulley 215 drives the spindle 211 to rotate, and the spindle 211 performs CNC machining on the product.
[0028] Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A multi-faceted machining CNC lathe with a flipping structure, comprising a CNC frame (1), characterized in that: A CNC assembly (2) is fixedly installed at the top of the CNC machine frame (1). A worktable (7) is fixedly installed on one side of the CNC machine frame (1). A displacement assembly (6) is installed at the top of the worktable (7). A flipping assembly (4) is fixedly installed on both sides of the top of the displacement assembly (6). Each of the two flipping assemblies (4) includes a limit frame (41) and a length shell (42). One side of the limit frame (41) is rotatably connected to one end of the length shell (42). A length rod (43) is slidably connected to the other end of the length shell (42). A clamping plate (44) is fixedly installed at one end of the length rod (43). The CNC assembly (2) includes a first upright plate (201) and two first sliding rails (202). The first upright plate (201) One end of the first slide rail (202) is fixedly connected to one end of the second slide rail (202). The middle of the two slide rails (202) is slidably connected to the first slide block (205). The two slide blocks (205) are fixedly installed between the two slide blocks (205). The two ends of one side of the second slide rail (206) are fixedly installed to the second slide rail (208). The middle of the two slide rails (208) is slidably connected to the second slide block (209). The two slide blocks (209) are fixedly installed between the two slide blocks (209). The bottom end of the connecting platform (210) is fixedly installed to the processing shell (212). The top of the inner wall of the processing shell (212) is rotatably connected to the main shaft (211).
2. The CNC lathe with a flipping structure for multi-face machining according to claim 1, characterized in that: A stepper motor (203) is fixedly installed in the middle of one side of the first upright plate (201). A first lead screw (204) is fixedly installed at the output end of the stepper motor (203). The middle part of the first lead screw (204) is connected to the internal thread of the second upright plate (206). The bottom end of the first upright plate (201) is fixedly connected to the CNC machine frame (1).
3. A multi-face machining CNC lathe with a flipping structure according to claim 1, characterized in that: A push cylinder (207) is fixedly installed in the middle of one side of the second upright plate (206). The movable end of the push cylinder (207) is fixedly connected to the middle of the top of the connecting platform (210). A micro motor (213) is fixedly installed on the bottom of the processing shell (212) away from the spindle (211). A drive pulley (214) is fixedly installed at the output end of the micro motor (213). A driven pulley (215) is fixedly installed on the surface of the spindle (211). A connecting belt (216) is connected between the drive pulley (214) and the driven pulley (215).
4. A multi-face machining CNC lathe with a flipping structure according to claim 1, characterized in that: The displacement component (6) includes two third sliding tracks (61) and a displacement plate (63). The middle of each of the two third sliding tracks (61) is slidably connected to a third sliding block (62). The top ends of the two third sliding blocks (62) are fixedly connected to the two sides of the bottom end of the displacement plate (63). The two sides of the top end of the displacement plate (63) are fixedly connected to two flipping components (4).
5. A multi-face machining CNC lathe with a flipping structure according to claim 4, characterized in that: The bottom ends of the two third sliding tracks (61) are fixedly connected to the worktable (7). A servo motor is fixedly installed on the surface of the worktable (7). A second lead screw (65) is fixedly installed at the output end of the servo motor. A movable block (64) that is slidably connected to the worktable (7) is threaded in the middle of the second lead screw (65). The top end of the movable block (64) is fixedly connected to the middle of the bottom end of the displacement plate (63).
6. A multi-face machining CNC lathe with a flipping structure according to claim 1, characterized in that: The bottom ends of both limiting frames (41) are fixedly connected to the displacement assembly (6), and a flip motor (5) for driving the length shell (42) to rotate is fixedly installed on the surface of one of the limiting frames (41).
7. A multi-face machining CNC lathe with a flipping structure according to claim 1, characterized in that: The surface of the CNC component (2) is fixedly mounted with a tool holder (3).