Hose cutting and oiling mechanism

By integrating clamping, feeding, oiling, waste removal, cutting, and collection components onto a vertical moving platform, the problem of separate steps in hose cutting and lubrication is solved, achieving efficient and precise hose processing and environmental protection, while reducing equipment footprint and management costs.

CN121756413BActive Publication Date: 2026-07-14ZHUHAI DERUI MEDICAL INSTR CO LTD +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
ZHUHAI DERUI MEDICAL INSTR CO LTD
Filing Date
2026-03-03
Publication Date
2026-07-14

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    Figure CN121756413B_ABST
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Abstract

The application discloses a hose cutting and oil sticking mechanism and relates to the technical field of hose cutting and oil sticking equipment.The mechanism comprises a bottom plate, a first moving assembly and a second moving assembly arranged on the upper surface of the bottom plate, a clamping and feeding assembly for clamping and feeding a hose, an oiling assembly for oiling the surface of the hose, a shaving assembly for sucking away excess lubricating oil on the hose, a cutting assembly for cutting the hose after the hose is sucked by the shaving assembly, and a collecting assembly for receiving the waste generated by the shaving assembly.The mechanism realizes integrated operation through two vertically arranged moving platforms, the first moving platform feeds the hose, the second moving platform synchronously drives the oiling assembly, the shaving assembly and the cutting assembly to move close to the hose, and the whole process of oiling, excess oil removing and cutting is completed in one clamping, so that the transfer and repeated positioning between devices are avoided, the processing efficiency of the hose is significantly improved, and the floor area occupied by the device is reduced.
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Description

Technical Field

[0001] This invention relates to the field of hose cutting and oil-adhesive equipment, and more specifically to a hose cutting and oil-adhesive mechanism. Background Technology

[0002] In fluid connection systems in industries such as automobiles, home appliances, and medical devices, hoses must be cut to a fixed length and have a lubricating layer formed on their surface before use to facilitate subsequent press-fitting with connectors. Currently, hose length cutting and surface lubrication generally adopt a step-by-step "cut first, then coat" approach: the cutting process is completed manually or by an independent hose cutting machine, while the lubrication process relies on workers holding the hose and dipping it in an open oil tank, or using a semi-automatic oiling device to apply lubricant section by section. Although there are models on the market specifically designed for hose cutting, as well as models specifically designed for oiling or dispensing adhesive, these two processes still exist as independent functional units. Even if some production lines connect the two units in series through an assembly line, they still face the problems of large equipment size, secondary positioning between processes, and cumulative errors caused by handling.

[0003] The above processing mode requires multiple transfers and repositioning between processes, resulting in long production cycles, large cumulative errors, and difficulty in accurately controlling the amount of oil applied manually, which can easily lead to oil dripping, insufficient oil, or uneven axial distribution, polluting the working environment and reducing the yield of press-fit products. In addition, each of the two devices is equipped with its own control unit and operating interface, resulting in a large equipment footprint, many maintenance points, and high management costs. Summary of the Invention

[0004] In order to overcome the above-mentioned technical problems, the purpose of this invention is to provide a hose cutting mechanism for removing oil residue.

[0005] The objective of this invention can be achieved through the following technical solutions:

[0006] A hose cutting mechanism for removing oil residue, comprising:

[0007] A base plate, the upper surface of which is provided with a first moving component and a second moving component;

[0008] A clamping and feeding assembly for clamping and conveying a hose;

[0009] An oiling assembly for applying oil to the surface of a hose;

[0010] A shaving assembly for removing excess lubricating oil from a hose;

[0011] A cutting assembly for cutting off the hose after the shaving assembly has absorbed oil;

[0012] Collection component, the collection component being used to receive waste generated by the shaving component;

[0013] The first moving component includes a first moving platform, and the second moving component includes a second moving platform. The moving paths of the first moving platform and the second moving platform are perpendicular to each other. The clamping and feeding component is disposed on the first moving platform and moves back and forth with it. The oiling component, waste removal component, cutting component and collecting component are all disposed on the second moving platform and move back and forth with it. The cutting component, waste removal component and collecting component are arranged sequentially along the moving direction perpendicular to the clamping and feeding component.

[0014] As a further aspect of the present invention: the clamping and feeding assembly includes a mounting base disposed on the first moving platform, the mounting base having a sliding groove, a first movable frame being slidably connected in the sliding groove, a first cylinder being mounted on the mounting base, the movable end of the first cylinder being connected to the first movable frame to drive the first movable frame to reciprocate, and a clamp for clamping the hose being mounted above the first movable frame.

[0015] As a further aspect of the present invention: the oiling assembly includes a first support frame disposed on the second mobile platform, an oiling machine disposed on the upper side of the first support frame, and a bearing platform disposed on the upper side of the first support frame;

[0016] The bearing platform has a groove, and an upward-opening oil box is fitted inside the groove. The oiling machine has an oiling head that can move up and down. When the oiling head moves down, it draws oil from the oil box. When the oiling head moves up, it applies oil to the hose below the oil outlet of the oiling head.

[0017] As a further aspect of the present invention: the cutting assembly includes a second support frame disposed on the second moving platform, a mounting frame disposed on the second support frame, a second cylinder disposed on the mounting frame, a blade holder disposed at the movable end of the second cylinder, and a blade nested on the blade holder.

[0018] As a further aspect of the present invention: the second support frame is connected to the first connecting frame on the side facing the cutter, the first connecting frame is provided with a mating plate, the mating plate is provided with a through groove for the flexible tube to pass through, the mating plate is provided with a receiving groove for the cutter to pass through on the side facing the cutter, and the inner wall spacing of the receiving groove is slightly greater than the thickness of the cutter.

[0019] As a further embodiment of the present invention: a second connecting frame is fixedly connected to the second support frame, and the waste removal component is fixedly installed on the second connecting frame. The waste removal component is used to suck away excess lubricating oil and cut-off hose waste from the hose through negative pressure. The inlet of the waste removal component faces and is aligned with the through groove.

[0020] As a further aspect of the present invention: the collection component includes a waste collection box disposed on the second mobile platform and a connecting pipe connected to the outlet of the waste removal component.

[0021] As a further aspect of the present invention: the through groove has a conical groove with an opening facing the clamp side and a columnar groove connected to the conical groove.

[0022] As a further aspect of the present invention: the first moving component includes a support base disposed on the surface of the base plate, a first guide rail disposed on the support base, and a first sliding seat slidably connected to the first guide rail, and the first moving platform is fixedly connected to the first sliding seat.

[0023] As a further aspect of the present invention: the second moving component includes two parallel second guide rails disposed on the surface of the base plate, and a second sliding seat slidably connected to the two second guide rails respectively, and the second moving platform is fixedly connected to the second sliding seat.

[0024] Compared with the prior art, the beneficial effects of the present invention are as follows: The hose cutting and oil-removing mechanism sets the clamping and feeding assembly on the first moving platform and integrates the oiling, waste removal, cutting and collection components on the second moving platform. The first and second moving platforms move along mutually perpendicular paths, allowing the clamping and feeding assembly to transport the hose along the first moving platform. The hose then sequentially reaches the workstations corresponding to the oiling and cutting steps. At the same time, the second moving platform can drive the oiling assembly, waste removal assembly, cutting assembly and mobile phone assembly to move toward or away from the hose along a moving direction perpendicular to the first platform. Thus, multiple continuous processes of oiling, removing excess oil and cutting are completed in one clamping. After the hose is clamped, all processes of oiling, removing excess oil and cutting can be completed sequentially within this mechanism without the need to transfer between different devices. This eliminates the physical intervals and repetitive positioning links between processes, significantly shortens the processing cycle of a single product, and significantly reduces cumulative errors due to the reduction of multiple clamping and positioning.

[0025] Meanwhile, the oiling and shaving components enable quantitative and uniform application of lubricating oil and immediate recovery of excess oil, improving the yield rate of press-fitted hoses. Furthermore, the parallel integration of the oiling and shaving components on the second moving platform allows the hoses to be quickly moved to the shaving station for residual oil removal after oiling, largely preventing oil drips from contaminating the working environment. In addition, the highly integrated modular layout significantly reduces the overall footprint of the equipment, lowering maintenance and management costs. Attached Figure Description

[0026] The invention will now be further described with reference to the accompanying drawings.

[0027] Figure 1 This is a schematic diagram of the overall structure of an embodiment of the present invention;

[0028] Figure 2 This is another perspective of the overall structural schematic diagram of an embodiment of the present invention;

[0029] Figure 3 This is a schematic diagram of the structure of the base plate, the first moving component, and the second moving component according to an embodiment of the present invention;

[0030] Figure 4 This is a schematic diagram of the structure of the clamping and feeding assembly according to an embodiment of the present invention;

[0031] Figure 5 This is a schematic diagram of the structure of the oiling assembly according to an embodiment of the present invention;

[0032] Figure 6 This is a schematic diagram of the shaving component and the cutting component according to an embodiment of the present invention;

[0033] Figure 7 This is a schematic diagram of the structure of the cutting component according to an embodiment of the present invention;

[0034] Figure 8 This is a schematic diagram of the structure of the first connecting frame and the mating plate according to an embodiment of the present invention;

[0035] Figure 9 This is a schematic diagram showing the positions of the mating plate and the tool holder in an embodiment of the present invention.

[0036] Explanation of reference numerals in the attached drawings: 1. Base plate; 2. First moving assembly; 3. Second moving assembly; 4. Clamping and feeding assembly; 5. Oiling assembly; 6. Waste removal assembly; 7. Cutting assembly; 8. Collection assembly; 21. First moving platform; 31. Second moving platform; 41. Mounting base; 411. Slide groove; 42. First movable frame; 43. First cylinder; 44. Clamp; 45. Second movable frame; 46. Connecting rod; 51. First support frame; 52. Oiling machine; 53. Bearing platform; 531. Recess 54. Groove; 521. Oil nozzle; 61. Second support frame; 62. Mounting frame; 63. Second cylinder; 64. Tool holder; 65. Blade; 66. First connecting frame; 67. Mating plate; 68. Through groove; 69. Receiving groove; 661. Channel; 71. Second connecting frame; 81. Waste collection box; 82. Connecting pipe; 681. Conical groove; 682. Columnar groove; 24. Support base; 22. First guide rail; 23. First sliding seat; 33. Second guide rail; 32. Second sliding seat. Detailed Implementation

[0037] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0038] See Figures 1-3 An embodiment of the present invention provides a hose cutting and oil-adhesive mechanism, comprising: a base plate 1, on the upper surface of which a first moving component 2 and a second moving component 3 are disposed; a clamping and feeding component 4, used to clamp and convey the hose; an oiling component 5, used to apply oil to the surface of the hose; a waste removal component 6, used to remove excess lubricating oil from the hose; a cutting component 7, used to cut the hose after the waste removal component 6 has absorbed the oil, and the operator can also use the cutting component 7 to cut off unwanted waste material from the hose end as needed; and a collecting component 8, used to receive the waste material generated by the waste removal component 6; wherein, the first moving component... 2 includes a first moving platform 21 that can reciprocate along a single straight path, and a second moving component 3 includes a second moving platform 31 that can reciprocate along a single straight path. The moving paths of the first moving platform 21 and the second moving platform 31 are perpendicular to each other. The clamping and feeding component 4 is disposed on the first moving platform 21 and moves back and forth with it. The oiling component 5, the waste shaving component 6, the cutting component 7 and the collecting component 8 are all disposed on the second moving platform 31 and move back and forth with it. The cutting component 7, the waste shaving component 6 and the collecting component 8 are arranged sequentially along the moving direction perpendicular to the clamping and feeding component 4. The oiling component 5 and the cutting component 7 are arranged side by side with intervals.

[0039] Specifically, in the initial state, the cutting component 7, the waste removal component 6, the collection component 8, and the oiling component 5 are all located in an initial position away from the clamping and feeding component 4, that is, the second moving platform 31 is located on the side away from the clamping and feeding component 4. The working process of this hose cutting and oiling mechanism is as follows: First, the clamping and feeding component 4 clamps the hose to be processed. The first moving component 2 drives the clamping and feeding component 4 and the hose to move, so that the section of the hose to be processed reaches the oiling station and is aligned with the oiling component 5. Then, the second moving component 3 drives the oiling component 5 to move toward the hose. During the contact or approach to the hose, the oiling operation on the hose body is completed. After completion, the oiling component 5 retracts. Then, the first moving component 2 drives the clamping and feeding component 4 and the hose to move again, so that the oiled section to be processed reaches the cutting station. Subsequently, the second moving component 3 drives the cutting component 7 and the waste removal component 6 to move toward the hose together. The waste removal component 6 sucks away the excess lubricating oil on the surface of the hose. Then, the cutting component 7 is used to cut the hose, thereby obtaining a section of processed hose. For continuous production, repeat the above steps: the first moving component 2 drives the clamping and feeding component 4 and the remaining hose, so that the next section to be processed enters the oiling and subsequent cutting station, thus realizing continuous operation.

[0040] Furthermore, this hose cutting and oil-adhesive mechanism integrates the clamping and feeding assembly 4 on the first moving platform 21 and the oiling, waste removal, cutting, and collection assembly 8 on the second moving platform 31. The first and second moving platforms 21 move along mutually perpendicular paths, allowing the clamping and feeding assembly 4 to transport the hose along with the first moving platform 21. This ensures the hose sequentially reaches the workstations corresponding to the oiling and cutting steps. Simultaneously, the second moving platform 31 can move the oiling assembly 5, waste removal assembly 6, cutting assembly 7, and mobile phone assembly along a direction perpendicular to the first platform towards or away from the hose. This allows multiple consecutive processes of oiling, removing excess oil, and cutting to be completed in a single clamping operation. Once the hose is clamped, all processes—oiling, removing excess oil, and cutting—can be completed sequentially within this mechanism, eliminating the need for transfer between different devices. This removes physical intervals and repetitive positioning steps between processes, significantly shortens the processing cycle time for a single product, and significantly reduces cumulative errors due to fewer clamping and positioning operations.

[0041] Meanwhile, the oiling component 5 and the waste removal component 6 enable quantitative and uniform application of lubricating oil and immediate recovery of excess oil, improving the yield rate of press-fitted hoses. Furthermore, the oiling component 5 and the waste removal component 6 are integrated side-by-side on the second moving platform 31, allowing the hose to be quickly moved to the waste removal station for residual oil removal after oiling, which largely avoids oil dripping and contamination of the working environment. In addition, the highly integrated modular layout significantly reduces the overall footprint of the equipment and lowers maintenance and management costs.

[0042] See Figures 1-4 Optionally, the clamping and feeding assembly 4 includes a mounting base 41 fixedly connected to the first moving platform 21. The mounting base 41 has a slide groove 411, which is perpendicular to the movement path of the first moving platform 21. A first movable frame 42 is slidably connected in the slide groove 411. A first cylinder 43 is fixedly mounted on the mounting base 41. The movable end of the first cylinder 43 is connected to the first movable frame 42 to drive the first movable frame 42 to reciprocate. A clamp 44 for clamping the hose is fixedly mounted above the first movable frame 42. A second movable frame 45 is fixedly mounted below the clamp 44. The second movable frame 45 is located on the mounting base 41, and a connecting rod 46 is fixedly connected to one end of the second movable frame 45. The connecting rod 46 is connected to the first movable frame 42. The second movable frame 45 and the first movable frame 42 together provide support for the first cylinder 43.

[0043] In this embodiment, the first cylinder 43 can drive the clamp 44 to reciprocate in a direction perpendicular to the first moving component 2, which facilitates the adjustment of the distance between the hose and the second moving platform 31 by adjusting the position of the clamp 44, thereby improving the accuracy of hose processing.

[0044] See Figures 1-5 Optionally, the oiling assembly 5 includes a first support frame 51 fixedly installed on the second mobile platform 31, an oiling machine 52 fixedly installed on the upper surface of the first support frame 51, and a carrying platform 53 disposed on the upper side of the first support frame 51; the carrying platform 53 has a groove 531, and an upwardly opening oil box 54 is fitted inside the groove 531. The groove 531 is used to prevent the oil box 54 from deviating. The upward opening of the oil box 54 facilitates both the oiling head 521 to draw oil and the oil to be received. The oiling machine 52 is equipped with an oiling head 521 that can move up and down. The oil box 54 is located directly below the oiling head 521. When the oiling head 521 moves down, it can draw oil from the oil box 54. When the oiling head 521 moves up, it can apply oil to the hose below the oil outlet of the oiling head 521.

[0045] In this embodiment, when the hose moves below the oiling head 521, the oiling machine 52 moves relative to the hose, and the oiling head 521 applies a quantitative amount of oil to the surface of the hose. Since the oil box 54 is located directly below the oiling head 521 of the oiling machine 52, the oil box 54 can catch any lubricating oil that may overflow when the oiling head 521 applies oil to the hose. The amount of oil applied can be precisely controlled by the oiling machine 52 to form a uniform lubricating layer, while reducing oil splashing and evaporation and keeping the work area clean.

[0046] See Figures 1-7Optionally, the cutting assembly 7 is located below the hose to be cut. The cutting assembly 7 includes a second support frame 61 fixedly mounted on the second moving platform 31, a mounting frame 62 disposed on the second support frame 61, a second cylinder 63 fixedly mounted on the mounting frame 62, a blade holder 64 fixedly connected to the movable end of the second cylinder 63, and a blade 65 fixedly nested on the blade holder 64. The upper side of the blade 65 protrudes from the upper surface of the blade holder 64.

[0047] In this embodiment, the second cylinder 63 is used to drive the tool holder 64 and the blade 65 to move linearly upward as a whole, so that the blade 65 cuts the hose. After cutting, it moves downward and retracts the tool holder 64 and the blade 65. The tool holder 64 is used to protect the blade 65.

[0048] See Figures 6-9 Optionally, the second support frame 61 is connected to the first connecting frame 66 on the side facing the cutter. The first connecting frame 66 is located above the blade 65. A mating plate 67 is provided on the side of the first connecting frame 66 away from the clamping and feeding assembly 4. A through groove 68 is provided on the mating plate 67 for the passage of a flexible hose. A channel 661 is provided on the first connecting frame 66 for the passage of a flexible hose. The channel 661 is connected to the through groove 68 and passes through the first connecting frame 66 and the mating plate 67 respectively. The inner diameter of the channel 661 is larger than the inner diameter of the through groove 68. A receiving groove 69 is provided on the side of the mating plate 67 facing the blade 65 for the blade 65 to pass through. The spacing between the inner walls of the receiving groove 69 is slightly larger than the thickness of the blade 65.

[0049] In this embodiment, when oil suction is required, the hose first enters the channel 661 on the first connecting bracket 66, then passes through the through groove 68 on the mating plate 67, passes above the blade 65 and below the receiving groove 69, and then enters the shaving assembly 6. After the blade 65 moves up to cut the hose, the upper part of the blade 65 enters the receiving groove 69. The receiving groove 69 is used to protect the blade 65 and prevent the blade 65 from deforming or even breaking when cutting the hose. The channel 661 is used to guide the hose into the cutting assembly 7 and the shaving assembly 6. The through groove 68 is used to guide and keep the radial position of the hose unchanged, ensuring the accuracy of the cutting position and ensuring that the hose can be smoothly aligned and enter the shaving assembly 6.

[0050] See Figure 6 Optionally, a second connecting frame 71 is fixedly connected to the second support frame 61, and the waste removal component 6 is fixedly installed on the second connecting frame 71. The waste removal component 6 is used to suck away excess lubricating oil and cut-off hose waste on the hose through negative pressure. The inlet of the waste removal component 6 faces and is aligned with the through groove 68.

[0051] In this embodiment, the oiled hose first passes through the cutting component 7 and then through the inlet of the waste removal component 6 to enter the waste removal component 6. The waste removal component 6 uses negative pressure to suck away the excess lubricating oil remaining on the surface of the hose after the oiling process. When the cut-off end of the hose is located inside the waste removal component 6, the waste removal component 6 can also suck in the waste material cut off by the cutting component 7.

[0052] See Figure 6 Optionally, the collection component 8 includes a waste collection box 81 disposed on the second mobile platform 31 and a connecting pipe 82 connected to the outlet of the waste removal component 6. The waste generated by the waste removal component 6 enters the waste collection box 81 through its outlet and the connecting pipe 82.

[0053] See Figures 6-9 Optionally, the through groove 68 has a tapered groove with an opening facing the clamp 44 and a columnar groove 682 communicating with the tapered groove.

[0054] In this embodiment, the hose is introduced and centered through the tapered groove, and the columnar groove 682 provides radial limiting for the hose, ensuring that the hose is stable in position during the cutting process.

[0055] See Figures 1-3 Optionally, the first moving component 2 includes a support base 24 fixedly mounted on the surface of the base plate 1, a first guide rail 22 fixedly connected to the upper side of the support base 24, and a first sliding seat 23 slidably connected to the first guide rail 22, and the first moving platform 21 fixedly connected to the first sliding seat 23.

[0056] In this embodiment, the first sliding seat 23 moves linearly back and forth on the first guide rail 22, which facilitates the smooth movement of the hose during the delivery process.

[0057] See Figures 1-3 Optionally, the second moving component 3 includes two parallel second guide rails 33 fixedly mounted on the surface of the base plate 1 and second sliding seats 32 slidably connected to the two second guide rails 33 respectively. The second guide rails 33 are perpendicular to the first guide rail 22. The second moving platform 31 is fixedly connected to the second sliding seats 32 and is disposed above the two second sliding seats 32.

[0058] In this embodiment, two parallel second guide rails 33 provide stable support for the second mobile platform 31, facilitating the stable movement of the second mobile platform 31 and other components mounted on it.

[0059] In the description of this invention, it should be understood that the terms "upper," "lower," "left," and "right," etc., indicating orientation or positional relationships based on the orientation or positional relationships shown in the accompanying drawings, are only for the convenience of describing the invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or a specific orientational structure and operation. Therefore, they should not be construed as limitations on the invention. Furthermore, "first" and "second" are only for descriptive purposes and should not be construed as indicating or implying relative importance or implicitly specifying the number of indicated technical features. Therefore, a feature defined with "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of this invention, unless otherwise stated, "multiple" means two or more.

[0060] In the description of this invention, it should be noted that, unless otherwise explicitly specified and limited, the terms "installation," "connection," "linking," etc., should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal communication between two components. Those skilled in the art can understand the specific meaning of the above terms in this invention based on the specific circumstances.

[0061] The foregoing has provided a detailed description of one embodiment of the present invention, but this description is merely a preferred embodiment and should not be construed as limiting the scope of the invention. All equivalent variations and modifications made within the scope of the claims of this invention should still fall within the patent coverage of this invention.

Claims

1. A hose cutting mechanism for removing oil residue, characterized in that, include: The base plate (1) has a first moving component (2) and a second moving component (3) disposed on its upper surface; Clamping and feeding assembly (4), the clamping and feeding assembly (4) is used to clamp and feed the hose; Oiling assembly (5), the oiling assembly (5) is used to apply oil to the surface of the hose; The waste removal assembly (6) is used to remove excess lubricating oil from the hose; Cutting component (7), the cutting component (7) is used to cut the hose after the shaving waste component (6) has absorbed oil; Collection component (8) is used to receive waste generated by shaving component (6); The first moving component (2) includes a first moving platform (21), and the second moving component (3) includes a second moving platform (31). The moving paths of the first moving platform (21) and the second moving platform (31) are perpendicular to each other. The clamping and feeding component (4) is disposed on the first moving platform (21) and moves back and forth with it. The oiling component (5), the waste shaving component (6), the cutting component (7), and the collecting component (8) are all disposed on the second moving platform (31) and move back and forth with it. In motion, the cutting component (7), the waste removal component (6) and the collection component (8) are arranged in sequence along the direction of movement perpendicular to the clamping and feeding component (4). The oiled hose first passes through the cutting component (7) and then through the inlet of the waste removal component (6) into the waste removal component (6). The waste removal component (6) uses negative pressure to suck away the excess lubricating oil remaining on the surface of the hose after the oiling process. When the cut-off end of the hose is located in the waste removal component (6), the waste removal component (6) can also suck in the waste material cut off by the cutting component (7). The cutting assembly (7) includes a second support frame (61) disposed on the second moving platform (31). The second support frame (61) is connected to a first connecting frame (66) facing the cutter side. A mating plate (67) is disposed on the first connecting frame (66). A through groove (68) is provided on the mating plate (67) for the hose to pass through. A second connecting frame (71) is fixedly connected to the second support frame (61). The waste removal assembly (6) is fixedly installed on the second connecting frame (71). The waste removal assembly (6) is used to suck away excess lubricating oil and cut hose waste on the hose through negative pressure. The inlet of the waste removal assembly (6) faces and is aligned with the through groove (68).

2. The hose cutting and oil-adhesive mechanism according to claim 1, characterized in that, The clamping and feeding assembly (4) includes a mounting base (41) disposed on the first moving platform (21). A sliding groove (411) is provided on the mounting base (41). A first movable frame (42) is slidably connected in the sliding groove (411). A first cylinder (43) is mounted on the mounting base (41). The movable end of the first cylinder (43) is connected to the first movable frame (42) to drive the first movable frame (42) to reciprocate. A clamp (44) for clamping the hose is installed above the first movable frame (42).

3. The hose cutting and oil-adhesive mechanism according to claim 2, characterized in that, The oiling assembly (5) includes a first support frame (51) disposed on the second mobile platform (31), an oiling machine (52) disposed on the upper side of the first support frame (51), and a bearing platform (53) disposed on the upper side of the first support frame (51). The bearing platform (53) has a groove (531) and an oil box (54) that opens upwards is fitted inside the groove (531). The oiling machine (52) has an oiling head (521) that can move up and down. The oiling head (521) moves down to draw oil from the oil box (54), and the oiling head (521) moves up to apply oil to the hose below the oil outlet of the oiling head (521).

4. The hose cutting and oil-adhesive mechanism according to claim 1 or 3, characterized in that, The cutting assembly (7) includes a mounting bracket (62) disposed on the second support frame (61), a second cylinder (63) disposed on the mounting bracket (62), a blade holder (64) disposed at the movable end of the second cylinder (63), and a blade (65) nested on the blade holder (64).

5. The hose cutting and oil-adhesive-resistant mechanism according to claim 4, characterized in that, The mating plate (67) has a receiving groove (69) on the side facing the blade (65) for the blade (65) to pass through. The spacing between the inner walls of the receiving groove (69) is slightly greater than the thickness of the blade (65).

6. The hose cutting and oil-adhesive mechanism according to claim 5, characterized in that, The collection component (8) includes a waste collection box (81) disposed on the second mobile platform (31) and a connecting pipe (82) connected to the outlet of the waste removal component (6).

7. The hose cutting and oil-adhesive mechanism according to claim 6, characterized in that, The through groove (68) has a conical groove with an opening facing the clamp (44) and a columnar groove (682) connected to the conical groove.

8. The hose cutting and oil-adhesive mechanism according to claim 7, characterized in that, The first moving component (2) includes a support base (24) disposed on the surface of the base plate (1), a first guide rail (22) disposed on the support base (24), and a first sliding seat (23) slidably connected to the first guide rail (22). The first moving platform (21) is fixedly connected to the first sliding seat (23).

9. The hose cutting and oil-adhesive mechanism according to claim 8, characterized in that, The second moving component (3) includes two parallel second guide rails (33) disposed on the surface of the base plate (1), and a second sliding seat (32) slidably connected to the two second guide rails (33), and the second moving platform (31) is fixedly connected to the second sliding seat (32).