A planing device for needle cylinder processing
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- QUANZHOU HENGYI HARDWARE MASCH CO LTD
- Filing Date
- 2025-08-07
- Publication Date
- 2026-07-03
Smart Images

Figure CN224445471U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of syringe processing equipment technology, and in particular to a planing device for syringe processing. Background Technology
[0002] The circular knitting machine cylinder is a core component of knitting machinery, mainly used to fix the knitting needles and drive them to complete the knitting action. During the production process of the cylinder, after rough processing such as milling and turning, burrs will form on the edge of the needle groove. If not removed, it will cause the knitting needles to jam, the yarn to be scratched or even broken, and ultimately cause defects such as thin lines and straight stripes on the fabric surface. Therefore, the cylinder needs to be planed and polished to achieve the final precision. However, most of the existing planing operations are done manually, which makes the polishing time long and the manual polishing is affected by factors such as the fatigue of the technicians and the difference in their techniques, making it difficult to guarantee consistency, resulting in large precision dispersion and poor precision stability. Utility Model Content
[0003] The purpose of this invention is to provide a planing device for syringe processing in order to solve the above-mentioned problems.
[0004] The technical solution of this application is implemented as follows:
[0005] This application provides a planing device for syringe processing, including a machine base, a receiving groove provided on the machine base, a frame provided on the machine base and located on one side of the receiving groove, a lead screw component rotatably provided on the frame, a drive motor connected to one end of the lead screw component, a bearing seat installed on the lead screw component, a connecting seat provided on the bearing seat, a side plate on the bearing seat, and a first grinding machine installed on the side plate.
[0006] The top of the frame has an extension seat, on which a first push rod component is provided. The piston end of the first push rod component passes through the extension seat and is connected to a receiving seat. A second grinder is installed on the receiving seat.
[0007] A second push rod component is provided on one side of the machine. The piston end of the second push rod component extends through the machine and into the receiving groove, where a storage seat is installed. A rotating component is provided in the storage seat and connected to a pneumatic chuck. The pneumatic chuck has several circumferentially distributed chucks, which form a clamping area for the syringe.
[0008] With the cooperation of the second push rod component, the storage seat drives the pneumatic chuck to move relative to each other along the length of the receiving groove. When the first polishing machine abuts against the outer periphery of the syringe with the cooperation of the lead screw component, the second polishing machine can move into the syringe with the cooperation of the first push rod component and abut against the inner wall of the syringe.
[0009] In one embodiment, spraying components are provided at both ends of the machine base. The spraying components include spray pipes, which are fixed on the machine base. A nozzle is provided on the side of the spray pipe facing the receiving groove, and one end of the nozzle is connected to the interior of the spray pipe.
[0010] Several nozzles are provided and distributed at intervals along the length of the spray pipe;
[0011] The spray pipe has a pipe interface on the side away from the nozzle.
[0012] In one embodiment, a support is also provided on the machine base, and a fan component is provided on the support. Two sets of fan components are provided and located above the receiving groove.
[0013] The second push rod component and the mounting base work together to make the blowing end of the blower component face the pneumatic chuck.
[0014] In one embodiment, a third push rod component is provided on the bracket, and two sets of the third push rod component are provided and located on one side of the two sets of fan components respectively;
[0015] The piston end of the third push rod component passes through the bracket and is connected to the support plate. A brush roller is mounted on the support plate, and the outer periphery of the brush roller has bristles.
[0016] With the cooperation of the third push rod component, when the pneumatic chuck is located below the blower component, the bristles abut against the outer periphery of the syringe.
[0017] In one embodiment, the spray pipe includes a vertical pipe with an inclined tube at the top, a portion of which is located above the machine platform.
[0018] The nozzle components are evenly distributed on the vertical and inclined pipes;
[0019] The vertical and inclined tubes are formed as one piece.
[0020] In one embodiment, the clamp has a slot for holding a syringe, with both ends of the slot extending to the outside of the clamp.
[0021] In one embodiment, the bottom of the machine is provided with support legs, and several support legs are provided and evenly distributed around the machine, so that gaps are formed between the machine legs.
[0022] The bottom of the machine is equipped with a liquid outlet, which is connected to the receiving tank and is located in the gap.
[0023] In one embodiment, guide rails are provided on both sides of the receiving groove, and a recess is provided on the storage seat corresponding to the position of the guide rail. Through the cooperation of the recess and the guide rail, the storage seat can move relative to the guide rail along its length.
[0024] The advantages or beneficial effects of the above technical solutions include at least the following:
[0025] This application discloses a planing device for syringe processing. The device places the syringe to be processed onto a pneumatic chuck on a mounting base. Due to the connection between the mounting base and a second push rod assembly, the mounting base can move the syringe. When the syringe moves to a side close to the machine frame, a first polishing machine, with the cooperation of a lead screw and a bearing seat, moves to one side of the syringe and abuts against the outer circumference of the syringe to perform planing and polishing operations. Since the first push rod assembly is located on an extension seat at the top of the machine frame and a second polishing machine is mounted on a receiving seat, when the outer circumference of the syringe contacts the first polishing machine, the second polishing machine, with the cooperation of the first push rod assembly, can move into the interior of the syringe and polish its inner wall. This allows for polishing of the syringe's outer circumference and inner wall without manual intervention, thus solving the problem of low processing efficiency caused by the need for manual planing operations in existing syringe processing. Attached Figure Description
[0026] The accompanying drawings illustrate exemplary embodiments of the present application and, together with the description thereof, serve to explain the principles of the present application. These drawings are included to provide a further understanding of the present application and are incorporated in and constitute a part of this specification.
[0027] Figure 1 A structural schematic diagram of the planing device according to an embodiment of this application is shown from a first perspective;
[0028] Figure 2 A structural schematic diagram of the planing device according to an embodiment of this application is shown from a second perspective;
[0029] Figure 3 A structural schematic diagram of the planing device according to an embodiment of this application is shown from a third perspective;
[0030] Figure 4 A structural schematic diagram of the rack according to an embodiment of this application is shown;
[0031] Figure 5 A partial cross-sectional view of the planing device according to an embodiment of this application is shown;
[0032] Figure 6 Examples of this application are presented. Figure 1 Enlarged view of point A in the middle;
[0033] Reference numerals: 1. Machine base; 11. Receiving tank; 111. Guide rail; 12. Support legs; 13. Liquid outlet port;
[0034] 2. Frame; 21. Lead screw; 211. Drive motor; 212. Bearing seat; 213. Connecting seat; 2131. Side plate; 22. First grinding machine; 23. Extension seat;
[0035] 3. First push rod assembly; 31. Receiving seat; 32. Second grinding machine;
[0036] 4. Second push rod assembly; 41. Placement seat; 411. Recess; 42. Pneumatic chuck; 421. Clamp; 4211. Slot;
[0037] 5. Spraying components; 51. Spray pipe; 511. Vertical pipe; 512. Inclined pipe; 52. Spray nozzle;
[0038] 6. Bracket; 61. Fan assembly; 62. Third push rod assembly; 621. Support plate; 622. Brush roller assembly. Detailed Implementation
[0039] Embodiments of this application will now be described in more detail with reference to the accompanying drawings. While some embodiments of this application are shown in the drawings, it should be understood that this application can be implemented in various forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided to provide a more thorough and complete understanding of this application. It should be understood that the drawings and embodiments of this application are for illustrative purposes only and are not intended to limit the scope of protection of this application.
[0040] It should be noted that, where there is no conflict, the embodiments and features described in this application can be combined with each other. This application will now be described in detail with reference to the accompanying drawings and embodiments.
[0041] It should be understood that the term "comprising" and its variations as used herein are open-ended, meaning "including but not limited to". The term "based on" means "at least partially based on". The term "one embodiment" means "at least one embodiment"; the term "another embodiment" means "at least one additional embodiment"; the term "some embodiments" means "at least some embodiments". Definitions of other terms will be given in the following description. It should be noted that the concepts of "first", "second", etc., mentioned in this application are used only to distinguish different devices, modules, or units, and are not intended to limit the order of functions performed by these devices, modules, or units or their interdependencies.
[0042] It should be noted that the terms "a" and "several" used in this application are illustrative rather than restrictive, and those skilled in the art should understand that, unless otherwise expressly indicated in the context, they should be understood as "one or more".
[0043] The names of the messages or information exchanged between multiple devices in the embodiments of this application are for illustrative purposes only and are not intended to limit the scope of these messages or information.
[0044] Reference Figures 1-6 A planing device for syringe processing includes a machine base 1 with a receiving groove 11. A frame 2 is also mounted on the machine base 1 and located on one side of the receiving groove 11. A lead screw 21 is rotatably mounted on the frame 2. One end of the lead screw 21 is connected to a drive motor 211. The output end of the lead screw 21 and the drive motor 211 are connected via a coupling. The drive motor 211 is located at the top of the frame 2 and is a servo drive motor as used in the prior art. 21. Driven by the drive motor 211, it can rotate precisely, thereby driving the bearing seat 212 to move along the length direction of the lead screw 21. The bearing seat 212 is installed on the lead screw 21, and the bearing seat 212 is provided with a connecting seat 213. The bearing seat 212 has a side plate 2131, and the first grinding machine 22 is installed on the side plate 2131. The lead screw drive has high transmission efficiency and positioning accuracy, and can quickly respond to the command of the drive motor 211 to realize the rapid movement and positioning of the first grinding machine 22.
[0045] The top of the frame 2 has an extension seat 23, on which a first push rod component 3 is mounted. The piston end of the first push rod component 3 passes through the extension seat 23 and is connected to a receiving seat 31. A second polishing machine 32 is mounted on the receiving seat 31. The extension seat 23 at the top of the frame 2 provides a stable mounting base for the first push rod component 3. The first push rod component 3 can provide a strong and controllable thrust, enabling the second polishing machine 32 to move precisely into the syringe and fit tightly against the inner wall of the syringe. By adjusting the thrust of the first push rod component 3, the contact pressure between the second polishing machine 32 and the inner wall of the syringe can be controlled, ensuring uniform polishing of the inner wall of the syringe and avoiding over-polishing or under-polishing. This effectively improves the processing quality of the inner wall of the syringe and can adapt to the processing needs of syringes of different lengths and diameters. By adjusting the piston extension of the first push rod component 3, the depth to which the second polishing machine 32 enters the syringe can be changed, meeting the polishing requirements of the inner walls of syringes of different specifications and enhancing the versatility and adaptability of the equipment.
[0046] A second push rod component 4 is provided on one side of the machine base 1. The piston end of the second push rod component 4 extends through the machine base 1 into the receiving groove 11 and is fitted with a storage seat 41. A rotating component is provided in the storage seat 41 and connected to a pneumatic chuck 42. The rotating component adopts a rotary cylinder in the prior art, which can drive the pneumatic chuck 42 to rotate synchronously. The pneumatic chuck 42 has several circumferentially distributed chucks 421, which form a clamping area for the syringe. The several circumferentially distributed chucks 421 can clamp the syringe from multiple directions, so that the clamping force on the syringe is uniform. The uniform distribution of clamping force avoids syringe deformation caused by uneven clamping force, ensuring the original shape and dimensional accuracy of the syringe. The stable thrust of the second push rod component 4 can drive the placement seat 41 and pneumatic chuck 42 to move smoothly, ensuring that the syringe will not shake or deviate during the movement. This ensures the relative positional accuracy of the syringe with the first grinding machine 22 and the second grinding machine 32, providing a guarantee for precise processing. At the same time, the movement range of the placement seat 41 can be adjusted according to the length of the syringe, which can meet the processing needs of syringes of different lengths and further enhance the applicability of the equipment.
[0047] With the cooperation of the second push rod component 4, the placement seat 41 drives the pneumatic chuck 42 to move relative to each other along the length of the receiving groove 11. When the first polishing machine 22 abuts against the outer periphery of the syringe under the cooperation of the lead screw component 21, the second polishing machine 32 can move into the syringe under the cooperation of the first push rod component 3 and abut against the inner wall of the syringe. This realizes the simultaneous polishing of the outer periphery and inner wall of the syringe, eliminating the need to process the outer periphery and inner wall of the syringe separately, shortening the processing cycle and improving production efficiency. In addition, during the operation, the movements of the first polishing machine 22 and the second polishing machine 32 cooperate with each other to ensure the force balance of the syringe during the processing, avoiding syringe offset or deformation caused by unilateral force, and improving the overall processing accuracy.
[0048] Based on the above structure, by placing the syringe to be processed on the pneumatic chuck 42, several clamps 421 abut against the inner wall of the syringe, thereby limiting the syringe. Since the pneumatic chuck 42 is mounted on the rotating component and located on the mounting base 41, the rotating component can drive the pneumatic chuck 42 and the syringe to rotate. The mounting base 41 is connected to the second push rod component 4, so the extension and retraction of the second push rod component 4 can drive the mounting base 41 to move. When the mounting base 41 moves the syringe to a position close to the frame 2, the cooperation of the lead screw component 21 and the drive motor 211 causes the bearing seat 212 to drive the first polishing machine 22 to move vertically, so that the grinding disc of the first polishing machine 22 abuts against the outer circumference of the syringe. The syringe rotates under the cooperation of the rotating component, completing the uniform polishing of the outer circumference of the syringe.
[0049] Furthermore, when the syringe comes into contact with the first polishing machine 22, the second polishing machine 32 is connected to the first push rod component 3 through the receiving seat 31, thus being positioned above the syringe. Through the extension and retraction of the first push rod component 3, the first polishing machine 22 is positioned inside the syringe and abuts against the inner wall of the syringe, thereby completing the polishing operation of the inner wall of the syringe. With the cooperation of the second push rod component 4, the syringe can be driven to move relative to each other, and with the cooperation of the lead screw component 21 and the first push rod component 3, the positions of the first polishing machine 22 and the second polishing machine 32 are moved, thereby realizing the planing and polishing operation of the outer periphery and inner wall of the syringe, solving the problem that the existing syringe planing and polishing requires manual intervention, resulting in low processing efficiency.
[0050] The first push rod component 3 and the second push rod component 4 mentioned above both adopt pneumatic push rods or hydraulic push rods in the prior art. The movement distance of the connecting component is adjusted by the extension and retraction of the piston end. The first grinder 22 and the second grinder 32 are both grinding discs driven by motors in the prior art.
[0051] In one embodiment, reference is made to Figure 1 and Figure 6 Spraying components 5 are provided at both ends of the machine base 1. The spraying components 5 include spray pipes 51, which are fixed on the machine base 1. Spray nozzles 52 are provided on the side of the spray pipes 51 facing the receiving groove 11. The spray nozzles 52 adopt water mist nozzles that can be adjusted in the prior art. One end of the spray nozzles 52 is connected to the inside of the spray pipes 51. The connection between the spray nozzles 52 and the spray pipes 51 adopts a threaded sealing structure. The liquid enters the inside of the spray pipes 51 under pressure. Since the inside of the spray pipes 51 is a hollow structure, the liquid can flow smoothly inside the pipe and be evenly distributed to each spray nozzle 52.
[0052] Several nozzles 52 are provided and distributed at intervals along the length of the spray pipe 51. The spray components 5 at both ends of the machine base 1 are important auxiliary structures to ensure the quality of syringe processing. The interval design allows the sprayed liquid to form a continuous and uniform coverage surface, completely covering the processing area of the syringe in the receiving tank 11. During the planing process, the coolant is sprayed into the contact point between the syringe and the planing tool in the form of mist or column, which can quickly absorb the heat generated during processing and reduce the change in the performance of the syringe material caused by high temperature. The water flow can thoroughly wash away the metal chips, cutting fluid residues and other substances attached to the surface of the syringe. The impurities after washing flow into the bottom of the receiving tank 11 with the liquid, which is convenient for subsequent centralized cleaning.
[0053] The spray pipe 51 has a pipe interface on the other side away from the nozzle 52. The specifications of the pipe interface are compatible with common coolant or cleaning fluid supply pipes, which facilitates quick connection.
[0054] The spray pipe 51 includes a vertical pipe 511. The nozzles 52 on the vertical pipe 511 are mainly responsible for rinsing the debris at the bottom of the receiving tank 11, and for cooling or cleaning the lower and sides of the syringe. The top of the vertical pipe 511 has an inclined pipe 512, part of which is located above the machine base 1. The nozzles 52 on the inclined pipe 512 are specifically designed to target the upper area of the syringe. This is because in traditional spray structures, the upper part of the syringe is often a dead zone for spraying, and the inclined design of the inclined pipe 512 precisely compensates for this. This defect allows the liquid to be sprayed directly onto the upper surface of the syringe. The nozzles 52 are evenly distributed on the vertical tube 511 and the inclined tube 512. The vertical tube 511 and the inclined tube 512 are formed as one piece. The integrated structure ensures that the liquid has low flow resistance and low pressure loss in the spray tube 51, and ensures that each nozzle 52 has sufficient spray pressure. This special spray tube 51 structure expands the spray range and reduces spray dead zones. During cleaning, all parts of the syringe can be fully rinsed by the cleaning liquid, improving the cleaning effect.
[0055] In one embodiment, reference is made to Figures 1-3 The machine base 1 is also equipped with a support 6, on which a fan component 61 is mounted. Two sets of fan components 61 are located above the receiving slot 11. The fan component 61 is an axial flow fan driven by a motor, as is common in the prior art.
[0056] The cooperation between the second push rod component 4 and the holder 41 directs the blowing end of the blower component 61 toward the pneumatic chuck 42. After the syringe has undergone spraying treatment, a large amount of moisture remains on its surface. If it is not dried in time, it is prone to oxidation and rust. After processing, when the blower component 61 is powered on, the motor drives the fan blades to rotate at high speed, drawing in and accelerating the surrounding air to form a directional airflow. Because the two sets of blower components 61 are arranged opposite each other, the airflow forms a circulation around the syringe, blowing the syringe from different directions. The airflow can quickly remove the moisture from the surface of the syringe, and the impact force of the airflow can remove small debris adhering to the surface of the syringe, thereby improving the overall cleanliness of the syringe.
[0057] In one embodiment, reference is made to Figures 1-3 The bracket 6 is provided with a third push rod component 62. The third push rod component 62 adopts the hydraulic push rod or pneumatic push rod in the prior art. There are two sets of the third push rod component 62, which are located on one side of the two sets of fan components 61 respectively. The spaced distribution can avoid mutual interference between the two when they are working.
[0058] The piston end of the third push rod component 62 passes through the bracket 6 and is connected to the support plate 621. A bristle roller component 622 is mounted on the support plate 621. The main function of the third push rod component 62 is to provide driving force so that the bristle roller component 622 can be positioned according to the position and size of the syringe, ensuring that the bristles always maintain good contact with the outer periphery of the syringe. The outer periphery of the bristle roller component 622 has bristles. With the cooperation of the third push rod component 62, when the pneumatic chuck 42 is located below the blower component 61, the bristles abut against the outer periphery of the syringe. When the syringe rotates, the friction of the bristles can clean the surface of the syringe and remove impurities. It can also effectively clean the debris in the small scratches on the surface of the syringe. When used in conjunction with the blower component 61, it forms a synergistic effect of wiping first and then drying. After the bristle roller component 622 removes larger impurities and most of the moisture, the blower component 61 can more efficiently dry the residual trace moisture and blow away the small impurities raised during the wiping process, thereby further improving the cleanliness of the syringe surface.
[0059] In one embodiment, reference is made to Figure 1 and Figure 5 The clamp 421 has a slot 4211 for placing a syringe. The two ends of the slot 4211 extend to the outside of the clamp 421. The slot 4211 provides a dedicated positioning and clamping space for the syringe. When the syringe is placed into the slot 4211, the clamp 421 tightens pneumatically or mechanically, so that the inner wall of the slot 4211 fits tightly against the outer periphery of the syringe, generating sufficient friction to fix the syringe. The design of the extended ends allows the operator to have enough space for their fingers to operate when placing or removing the syringe without the need for additional tools. At the same time, the extended part can also guide the two ends of the syringe, making it easy for the syringe to be quickly aligned with the slot 4211, thereby improving the flexibility of installation.
[0060] In one embodiment, reference is made to Figure 1 , Figure 3 and Figure 5 The bottom of the machine base 1 is provided with support legs 12. Several support legs 12 are provided and evenly distributed around the machine base 1, so that there are gaps between the machine base 1. They are installed at the four corners of the bottom of the machine base 1 to form a stable support system. The height of each support leg 12 can be finely adjusted by adjusting bolts at the bottom so that the machine base 1 can be adjusted to a horizontal state.
[0061] The bottom of the machine 1 is provided with a liquid outlet 13, which is connected to the receiving tank 11. The liquid outlet 13 is located in the gap. The support bracket 12 raises the machine 1, so that a gap is formed between the machine 1 and the ground. On the one hand, it avoids dust and impurities on the ground from directly contacting the bottom of the machine 1. On the other hand, it also provides sufficient space for the liquid outlet 13 to connect to the waste liquid collection device, which facilitates the collection and treatment of waste liquid.
[0062] In one embodiment, reference is made to Figure 1 , Figure 2 and Figure 5 Guide rails 111 are provided on both sides of the receiving groove 11. The storage seat 41 is provided with a recess 411 corresponding to the guide rails 111. Through the cooperation of the recess 411 and the guide rails 111, the storage seat 41 can move relative to the guide rails 111 along their length. The guide mechanism composed of the guide rails 111 and the recess 411 provides a fixed and precise trajectory for the movement of the storage seat 41. When the second push rod 4 drives the storage seat 41 to move, the slider in the recess 411 slides along the guide rails 111, which restricts the displacement of the storage seat 41 in the direction perpendicular to the guide rails, ensuring that the storage seat 41 can only move in a straight line along the length of the guide rails 111. This guiding effect ensures that the storage seat 41 will not deviate, rotate or jam during the movement.
[0063] In the description of this application, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this application and simplifying the description, and do not 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 application.
[0064] Those skilled in the art should understand that the above embodiments are merely for illustrative purposes and are not intended to limit the scope of this application. Those skilled in the art can make other changes or modifications based on the above disclosure, and these changes or modifications still fall within the scope of this application.
Claims
1. A planing device for processing a syringe, characterized by: The machine includes a machine base, which is provided with a receiving groove. The machine base is also provided with a frame located on one side of the receiving groove. The frame is rotatably provided with a lead screw, one end of which is connected to a drive motor. A bearing seat is installed on the lead screw, and a connecting seat is provided on the bearing seat. The bearing seat has a side plate, and a first grinding machine is installed on the side plate. The top of the frame has an extension seat, on which a first push rod component is provided. The piston end of the first push rod component passes through the extension seat and is connected to a receiving seat. A second grinder is mounted on the receiving seat. A second push rod component is provided on one side of the machine tool. The piston end of the second push rod component extends through the machine tool into the receiving groove and is fitted with a storage seat. A rotating component is provided in the storage seat and connected to a pneumatic chuck. The pneumatic chuck has several circumferentially distributed clamps, and the several clamps form a clamping area for the syringe. With the cooperation of the second push rod component, the placement seat drives the pneumatic chuck to move relative to each other along the length of the receiving groove. When the first polishing machine abuts against the outer periphery of the syringe with the cooperation of the lead screw component, the second polishing machine can move into the syringe with the cooperation of the first push rod component and abut against the inner wall of the syringe.
2. The barrel processing planing apparatus of claim 1 wherein: Spraying components are provided at both ends of the machine base. Each spraying component includes a spray pipe, which is fixed to the machine base. A nozzle is provided on the side of the spray pipe facing the receiving groove, and one end of the nozzle is connected to the interior of the spray pipe. The spray nozzles are provided in several units and are distributed at intervals along the length of the spray pipe; The spray pipe has a pipe interface on the side away from the nozzle.
3. The barrel processing planing apparatus of claim 1 wherein: The machine platform is also equipped with a support, on which a fan component is mounted. Two sets of the fan component are mounted and located above the receiving slot. The second push rod component and the placement seat work together to make the blowing end of the fan component face the pneumatic chuck.
4. The barrel processing planing apparatus of claim 3, wherein: The bracket is provided with a third push rod component, and there are two sets of the third push rod component, which are respectively located on one side of the two sets of fan components; The piston end of the third push rod component passes through the bracket and is connected to a support plate. A bristle roller is mounted on the support plate, and the outer periphery of the bristle roller has bristles. With the cooperation of the third push rod component, when the pneumatic chuck is located below the blower component, the bristles abut against the outer periphery of the syringe.
5. The barrel processing planing apparatus of claim 2 wherein: The spray pipe includes a vertical pipe, the top of which has an inclined tube, a portion of which is located above the machine platform; The nozzle components are evenly distributed on the vertical pipe and the inclined pipe; The vertical tube and the inclined tube are formed integrally.
6. The barrel processing planing apparatus of claim 1 wherein: The clamp has a slot for placing the syringe, and the two ends of the slot extend to the outside of the clamp.
7. The barrel processing planing apparatus of claim 1 wherein: The bottom of the machine is provided with support legs. Several support legs are provided and evenly distributed around the machine, so that there are gaps between the machine legs. The bottom of the machine is provided with a liquid outlet interface which is communicated with the accommodating groove and located in the gap.
8. The barrel processing planing apparatus of claim 1 wherein: Both sides of the accommodating groove are provided with guide rail members, and the storage seat is provided with recesses corresponding to the positions of the guide rail members. Through the cooperation of the recesses and the guide rail members, the storage seat can move relatively along the length direction of the guide rail members.