CN212858027U - Aerospace catheter allowance cutting equipment - Google Patents

Abstract

The utility model discloses an aerospace pipe surplus excision equipment, the reciprocating impact tunnel drilling machine comprises a machine body, install angle adjusting device, cutting device, pipe clamping device and planker mechanism on the fuselage, install positioner and flat mouthful device in the planker mechanism, positioner and flat mouthful device set up in tandem, and planker mechanism and pipe clamping device a left side right side set up. The technical scheme is used for quickly and accurately cutting the allowance at the two ends of the aerospace catheter.

Description

Aerospace catheter allowance cutting equipment

Technical Field

The utility model relates to an aerospace technical field especially relates to an aerospace pipe surplus excision equipment.

Background

In the aerospace craft such as the plane, rocket, etc., there are tens of thousands of fittings, and many fittings are connected by metal conduit, for example, there are many metal conduits on the rocket body and engine, which are used for transmitting various fluids, and supporting each task of rocket flight, and are extremely important parts on the rocket. The analysis of the failure of the pipeline fracture of the liquid Rocket engine and the optimization of the power in the 03 stage of 2018 of Rocket Propulsion/Journal of Rocket Propulsion are described in the text: the safety and reliability of the pipeline system of the liquid rocket engine become the key to whether the engine can work safely.

The aerospace conduit is bent in a complex shape, so that numerical control pipe bending equipment is required to be adopted for bending the conduit, technological margins such as bending clamping and the like are required to be reserved in the bending process, but due to the limitation of installation space and the like of the actual conduit, short straight line sections are usually designed at two ends of the conduit, and redundant lengths are required to be cut off after the conduit is bent and formed. The rocket guide pipe is a precise pipe part, the requirement on the length precision of the end part is high during cutting, the pipe wall of the rocket guide pipe is usually very thin and is generally in the range of 0.5-2.0mm, the length of a straight line section reserved at two ends of a plurality of guide pipes is only 25mm, and a lot of difficulties are brought to reliable clamping during cutting. And the rocket conduit has high technical requirements on clamping deformation, indentation and the like. Especially, the rocket conduit has the characteristics of multiple specifications, multiple varieties, small batch and the like.

In the early stage of rocket starting stage in China, due to the weak foundation of the manufacturing industry, the margins are cut off by a manual saw, an operator lines the cutting position by a line-cutting method during processing and then saws the cutting position by a saw, a bench vice is usually adopted to clamp the guide tube during the cutting, cloth strips, abrasive cloth, wood strips and the like can be padded on the guide tube if necessary to reduce the damage to the guide tube, and the end face of the guide tube is filed and flattened by a file after the cutting. This process is still used in some applications. For example, the duct filing technique is described in detail in the long-standing series liquid Rocket engine duct filing technique in Rocket Propulsion/Journal of Rocket Propulsion in 2012 05.

With the development of the aerospace industry in China, in recent years, some end-cutting and end-flattening processing equipment is adopted successively, during processing, a guide pipe is clamped reliably, then a cutting saw blade is adopted to cut the guide pipe, redundant parts at two ends of the guide pipe can be cut off orderly, and after the end face of the guide pipe is cut off, the end face of the guide pipe is flattened through a end-flattening cutter. In addition, in the prior art, the device for clamping the guide pipe is usually fixed by screws, so that much time is needed for replacing the clamping device every time, and the mass production of rockets is directly influenced.

The rocket is provided with tens of thousands of fittings, a plurality of fittings are connected by a guide pipe, wherein a plurality of pipeline connecting and mounting positions have deviation in the assembling process, namely, the guide pipe mounting surface has accumulated error with the original design, usually between 1 and 3 degrees, and the deviation angle is commonly called as a 'horseshoe mouth'. If the 'horseshoe mouth' of the rocket conduit is not accurately machined, the installation stress exists when the rocket conduit is installed on the rocket, the stress is easy to aggravate to cause the breakage of the rocket conduit, and potential fatal risks are brought to the rocket (see 'stress corrosion of the rocket conduit and preventive measures thereof' in 'missile and Space delivery technologies and Space Vehicles' 2005-01).

Disclosure of Invention

In order to solve the technical problem, the utility model aims at providing an aerospace pipe surplus excision equipment for the quick accurate excision of aerospace pipe both ends surplus.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides an aerospace pipe surplus excision equipment, includes fuselage (2), install angle adjusting device (3), cutting device (8), pipe clamping device (9) and planker mechanism (5) on fuselage (2), install positioner (6) and peaceful mouthful device (7) on planker mechanism (5), positioner (6) and peaceful mouthful device (7) set up in tandem, planker mechanism (5) and pipe clamping device (9) one left right side setting.

Preferably, the conduit clamping device (9) is arranged on a workbench (22) of the machine body (2), the conduit clamping device (9) comprises a first clamping seat (901), a second clamping seat (902), a third clamping seat (903), a fourth clamping seat (904) and a clamping device base (906), the first clamping seat (901) and the second clamping seat (902) are arranged on the clamping device base (906) in a front-back opposite mode and are matched with the clamping conduit (1) in the front-back direction, the third clamping seat (903) and the fourth clamping seat (904) are arranged on the clamping device base (906) in a front-back opposite mode and are matched with the clamping conduit (1) in the front-back direction, the first clamping seat (901) and the third clamping seat (903) are arranged at left-right intervals, the second clamping seat (902) and the fourth clamping seat (904) are arranged at left-right intervals, the third clamping seat (903) and the fourth clamping seat (904) are positioned on one side, close to the waste chute (21), of the clamping device base (906), the clamping device base (906) is provided with a waste slide slope (915) between a third clamping seat (903) and a fourth clamping seat (904), a first clamping seat (901) is fixed on the clamping device base (906), a second clamping seat (902) is driven by a clamping motor (908)/a third clamping cylinder (916) to slide back and forth on the clamping device base (906), a third clamping seat (903) is driven by a first clamping cylinder (905) to slide back and forth on the clamping device base (906), the moving end of the first clamping cylinder (905) is hinged with the third clamping seat (903), the fourth clamping seat (904) is driven by a second clamping cylinder (907) to slide back and forth on the clamping device base (906), the moving end of the second clamping cylinder (907) is hinged with the fourth clamping seat (904), wherein the cutting device (8) feeds and cuts between the second clamping seat (902) and the fourth clamping seat (904).

Preferably, the first link (909), the second link (910), and the moving ends of the clamping motor (908)/the third clamping cylinder (916) share a hinge shaft.

Preferably, the movable end of the clamping motor (908)/the third clamping cylinder (916) moves downwards in an inclined manner to clamp the conduit, and at this time, the upper end of the first connecting rod (909) is hinged to the movable end of the clamping motor (908)/the third clamping cylinder (916), the lower end of the first connecting rod (909) is hinged to the clamping device base (906), the upper end of the second connecting rod (910) is hinged to the second clamping seat (902), and the lower end of the second connecting rod (910) is hinged to the movable end of the clamping motor (908)/the third clamping cylinder (916).

Preferably, the first clamping seat (901), the second clamping seat (902), the third clamping seat (903) and the fourth clamping seat (904) are respectively provided with a clamp block for contacting and clamping the conduit (1), the clamp blocks are semi-annular, the inner side surfaces of the clamp blocks are semicircular clamping grooves, two clamp blocks which are opposite from each other in the front and back are matched to form a clamping hole (1013) for accommodating a straight line section of the end part of the conduit (1), the outer side surfaces of the clamp blocks are provided with positioning protrusions, and correspondingly, the clamping seats are provided with fixing clamping grooves matched with the positioning protrusions of the clamp blocks.

Preferably, the clamping device base (906) is rotatably mounted on the workbench (22) through a rotating shaft (913), and after the first clamping seat (901) and the second clamping seat (902) clamp the conduit (1), the axis of the straight line section of the pipe end of the conduit (1) is intersected with the axis of the rotating shaft (913) and the intersection point is positioned on the feed cutting surface of the cutting device (8).

Preferably, the angle adjusting device (3) comprises a gear (302), the gear (302) is in meshing transmission with arc-shaped teeth (911) arranged on one side of a clamping device base (906), the gear (302) is driven to rotate by a rotating driving device, the arc-shaped teeth (911) are in an arc shape, and the center of the arc is positioned on the axis of the rotating shaft (913).

Preferably, the cutting device (8) comprises a cutting device base (801), a cutting motor (802), a machine head reduction box (803), a cutting saw blade (804) and a feed motor (806), the cutting device base (801) is fixed on the machine body (2), the machine head reduction box (803) is in sliding connection with the cutting device base (801) through a sliding rail and drives the cutting blade to move back and forth through the feed motor (806), the cutting saw blade (804) is arranged on one side of the machine head reduction box (803), and the cutting motor (802) drives the cutting saw blade (804) to cut after passing through a speed reduction mechanism; the cutting blade (804) is a circular saw blade, or jigsaw.

Preferably, the carriage mechanism (5) comprises a Y-direction carriage (53) and an X-direction carriage (54), the X-direction carriage (54) is connected with the machine body (2) in a left-right sliding mode and driven by a feeding motor (51) to move and feed, the Y-direction carriage (53) is connected with the X-direction carriage (54) in a front-back sliding mode and driven by a conversion motor (52) to move back and forth, a positioning device (6) and a flat mouth device (7) are mounted on the Y-direction carriage (53), the positioning device (6) and the flat mouth device (7) are adjacent to each other in a front-back mode, and when the Y-direction carriage (53) moves back and forth, the positioning device (6) and the flat mouth device (7) can respectively correspond to the positions of the clamping catheters (1) of; the positioning device (6) comprises a positioning device base (63), a positioning block (64) and a positioning driver (61), the positioning device base (63) is fixed on the Y-direction carriage (53), and the positioning block (64) is connected with the positioning device base (63) in a left-right sliding mode and driven by the positioning driver (61) to move and feed; one side of the positioning block (64) close to the conduit clamping device (9) is a positioning surface which is parallel to a feed cutting surface of the cutting device (8) and is also parallel to a flat opening processing surface of the flat opening device (7); the flat mouth device (7) comprises a flat mouth device base (71), a flat mouth motor (72) and a cutter rotary table (73), the flat mouth device base (71) is fixed on the Y-direction carriage (53), the cutter rotary table (73) is installed on the flat mouth device base (71) and driven to rotate by the flat mouth motor (72), a plurality of flat mouth cutters (74) are installed on the cutter rotary table (73), the cutter rotary table (73) drives the flat mouth cutters (74) to rotate to form a flat mouth processing surface when rotating, and the flat mouth processing surface is parallel to a feed cutting surface of the cutting device (8) and is also parallel to a positioning surface of the positioning device (6).

The utility model discloses owing to adopted above technical scheme, adopt pipe tip length positioner to carry out accurate location to the tip position before the pipe is cut, adopt pipe clamping device to carry out reliable centre gripping to the pipe earlier when the unnecessary material of pipe tip is amputated, pipe tip location is accurate and reliable centre gripping back, adopts cutting device to cut processing to it, and the design has the flat mouthful device of pipe, carries out cutting process to the pipe tip mouth of pipe behind the pipe cutting to realize that the pipe end is smooth level and smooth. The utility model discloses a combination such as positioner, pipe clamping device, cutting device, flat mouthful of device can be fast, accurately carry out cutting process to the unnecessary technology surplus in aerospace pipe both ends.

Drawings

FIG. 1 is a schematic structural view of the apparatus of the present invention;

FIG. 2 is a schematic view of the structure of the mechanism of the present invention;

FIG. 3 is a schematic view of the catheter retention device of the present invention;

FIG. 4 is a second schematic view of the catheter clamping device of the present invention;

figure 5 is a top view of the catheter retention device of the present invention;

FIG. 6 is a cross-sectional view A-A of FIG. 5;

FIG. 7 is a schematic view of the catheter retention device and angular adjustment device of the present invention;

FIG. 8 is a second schematic view of the catheter retention device and angular adjustment device of the present invention;

figure 9 is a schematic diagram of another embodiment of the conduit gripping device of the present invention;

fig. 10 is a schematic view of a clamp mounting structure of the catheter holding device of the present invention;

fig. 11 is a schematic structural view of the clamp of the present invention;

fig. 12 is a schematic structural view of the cutting device of the present invention;

fig. 13 is a schematic structural view of the positioning device and the flat mouth device of the present invention;

fig. 14 is a schematic diagram of the positioning device of the present invention implementing digital positioning;

figure 15 is a top view (not angled) of the apparatus of the present invention;

FIG. 16 is a schematic view of the apparatus of the present invention performing a flat-end process;

FIG. 17 is a plan view of the apparatus of the present invention for performing the flat-end processing of the horseshoe opening;

wherein, 1, a conduit; 101. a first clamp block; 102. a second clamp block; 103. a third clamp block; 104. a fourth clamp block; 105. a locking member; 1011. a fixture positioning groove; 1012. a circular arc bulge; 1013. a clamping hole; 2. a body; 21. a waste chute; 22. a work table; 23. an outer ring member; 3. an angle adjusting device; 301. a hand wheel; 302. a gear; 303. a gear shaft; 304. a worm gear; 305. an indicator panel; 306. a worm; 4. a waste bin; 5. a carriage mechanism; 51. a feed motor; 52. a switching motor; 53. a Y-direction carriage; 54. an X-direction carriage; 6. a positioning device; 61. a positioning driver; 62. a guide bar; 63. a positioning device base; 64. positioning blocks; 7. a flat mouth device; 71. a flatting device base; 72. a flat motor; 73. a tool turret; 74. a flat cutter; 8. a cutting device; 801. a cutting device base; 802. cutting the motor; 803. a handpiece reduction gearbox; 804. Cutting the saw blade; 805. a screw rod; 806. a feed motor; 9. a conduit gripping device; 901. a first clamping seat; 902. a second clamping seat; 903. a third clamping seat; 904. a fourth clamping seat; 905. a first clamping cylinder; 906. a clamping device base; 907. a second clamping cylinder; 908. a clamping motor; 909. a first link; 910. a second link; 911. arc-shaped teeth; 912. An angle encoder; 913. a rotating shaft; 914. a flat bearing; 915. landslide of waste material; 916. a third clamping cylinder; 917. a holder positioning groove; 918. an arc groove; 919. and a limiting block.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "clockwise", "counterclockwise" and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, unless otherwise specified, "a plurality" means two or more unless explicitly defined otherwise.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the present disclosure, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact between the first and second features, or may comprise contact between the first and second features not directly. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

Example 1:

the device for cutting off the surplus of the guide pipe as shown in the figures 1 and 2 is used for surplus cutting and plane opening processing of engine guide pipes and the like in the aerospace field and comprises a machine body 2, wherein an angle adjusting device 3, a cutting device 8, a guide pipe clamping device 9 and a carriage mechanism 5 are installed on the machine body 2, a positioning device 6 and a plane opening device 7 are installed on the carriage mechanism 5, the positioning device 6 and the plane opening device 7 are arranged in tandem, the carriage mechanism 5 and the guide pipe clamping device 9 are arranged in a left-right mode, a waste material sliding groove 21 is further formed in the machine body 2, the waste material sliding groove 21 is located between the carriage mechanism 5 and the guide pipe clamping device 9, the cutting device 8 feeds in the front and back mode, and a waste material box 4 used for collecting waste materials is.

This equipment adopts digital control, and this digital controller includes the PLC controller, and the PLC controller sets up in the regulator cubicle, and the PLC controller can also be connected with touch screen and control cabinet, and the operator inputs and sets for each technological parameter according to each processing needs, and when automatic operation, each technological parameter is carried out to full-automatic the carrying out of equipment, realizes the quick accurate cutting process of the unnecessary technology surplus allowance of pipe tip. In other embodiments, the numerical controller may be replaced with a CNC controller.

Because of the pipe will produce great torsion and vibration when the cutting, pipe clamping device is used for pipe tip location to carry out reliable centre gripping to the pipe after being steady, prevents that the pipe from producing not hard up in cutting process, and the guarantee pipe cutting is steady. As shown in fig. 2 to 5, the conduit gripping device 9 is mounted on the table 22 of the body 2, the conduit gripping device 9 includes a first grip holder 901, a second grip holder 902, a third grip holder 903, a fourth grip holder 904 and a grip holder base 906, the first grip holder 901 and the second grip holder 902 are disposed on the grip holder base 906 in a front-back opposite manner and engage with and grip the conduit 1 in a front-back manner, the third grip holder 903 and the fourth grip holder 904 are disposed on the grip holder base 906 in a front-back opposite manner and engage with and grip the conduit 1 in a front-back manner, the first grip holder 901 and the third grip holder 903 are disposed in a left-right spaced manner, the second grip holder 902 and the fourth grip holder 904 are disposed in a left-right spaced manner, the third grip holder 903 and the fourth grip holder 904 are disposed on the side of the grip holder base 906 close to the waste chute 21, the grip holder base 906 is provided with a waste material landslide 915 between the third grip holder 903 and the fourth grip, the first clamping seat 901 is fixed on the clamping device base 906, the second clamping seat 902 is driven by a clamping motor 908 to slide back and forth on the clamping device base 906, the third clamping seat 903 is driven by a first clamping cylinder 905 to slide back and forth on the clamping device base 906, the moving end of the first clamping cylinder 905 is hinged with the third clamping seat 903, the fourth clamping seat 904 is driven by a second clamping cylinder 907 to slide back and forth on the clamping device base 906, and the moving end of the second clamping cylinder 907 is hinged with the fourth clamping seat 904, wherein the cutting device 8 feeds and cuts between the first clamping seat 901 and the third clamping seat 903 (or between the second clamping seat 902 and the fourth clamping seat 904). Like this, all reliably the centre gripping is carried out with keeping the straightway to the surplus waste material section of pipe end, guarantees cutting process's stability and machining precision. And the remaining straightway at the end part of the conduit adopts a movable clamping seat and a fixed clamping seat to cooperate for clamping, the fixed first clamping seat is used as a positioning reference, the clamping position of the conduit on the clamping device base can be accurately positioned, the residual waste section at the end part of the conduit adopts two clamping cylinders to drive the clamping, the clamping is quick and convenient, and the flexible adaptability is good.

In a preferred embodiment, as shown in fig. 4, the clamping motor 908 is connected to the second clamping seat 902 through a first link 909 and a second link 910, a moving end of the clamping motor 908 is hinged to one end of the first link 909, the other end of the first link 909 is hinged to the clamping device base 906, one end of the second link 910 is hinged to a moving end of the clamping motor 908, and the other end of the second link 910 is hinged to the second clamping seat 902. Therefore, the clamping motor pushes and locks the second clamping seat through the double-connecting-rod structure, so that the clamping and/or pre-clamping of the conduit can be realized, and the clamping is stable and reliable. It is further preferable that the moving ends of the first link 909, the second link 910 and the clamp motor 908 share a hinge shaft to further ensure reliable clamp locking and convenient assembly.

The clamping motor 908 is preferably a servo cylinder, so that the digital controller can control the moving speed and the moving position of the servo cylinder according to the conduits with different specifications and different materials and the clamping contact area, thereby ensuring that the clamping force does not damage the conduits and the clamping is stable and reliable. In other embodiments, the clamp motor 908 may be replaced by a pneumatic cylinder to achieve rapid conduit replacement, as shown in fig. 9, the cylinder of the third clamp cylinder 916 is hinged to the clamp base 906, and the moving end of the third clamp cylinder 916 is hinged to the first link 909 and the second link 910, respectively.

And preferably, the movable end of the clamp motor 908 or the third clamp cylinder 916 moves obliquely downward to clamp the conduit, and at this time, the upper end of the first link 909 is hinged to the movable end of the clamp motor 908 or the third clamp cylinder 916, the lower end of the first link 909 is hinged to the clamp base 906, the upper end of the second link 910 is hinged to the second clamp seat 902, and the lower end of the second link 910 is hinged to the movable end of the clamp motor 908 or the third clamp cylinder 916. Such locking structure has bigger locking force and guarantees that the centre gripping is firm to the pine moves back and the quick adjustment of centre gripping action is nimble.

As shown in fig. 10 and 11, in order to adapt to catheters of different specifications, clamp blocks for contacting and clamping the catheter 1 are mounted on the first clamping seat 901, the second clamping seat 902, the third clamping seat 903 and the fourth clamping seat 904, the clamp blocks are semicircular, inner side surfaces of the clamp blocks are semicircular clamping grooves, two clamp blocks which are opposite from each other in the front and back are matched to form a clamping hole 1013 for accommodating a straight line section at the end of the catheter 1, positioning protrusions are formed on outer side surfaces of the clamp blocks, and accordingly, fixing clamping grooves matched with the positioning protrusions of the clamp blocks are formed on the clamping seats. In this embodiment, the first fixture block 101 is fixed on the first clamping seat 901, the second fixture block 102 is fixed on the second clamping seat 902, the third fixture block 103 is fixed on the third clamping seat 903, the fourth fixture block 104 is fixed on the fourth clamping seat 904, and the four fixture blocks have the same structure.

As shown in fig. 10, in the embodiment, the positioning protrusion is an arc protrusion 1012, correspondingly, the fixing slot is an arc groove 918, the clamp block is provided with a clamp positioning groove 1011, the clamping seat is provided with a clamping seat positioning groove 917 communicated with the clamp positioning groove 1011, and the locking member 105 passes through the clamp positioning groove 1011 and the clamping seat positioning groove 917 and is fixed on the clamping seat by fastening members. Like this, set up a unified outer circular arc location installation benchmark on the grip slipper, be the semicircle form, the outer circular arc of anchor clamps piece is just installed on this benchmark, the inboard circular arc of anchor clamps piece designs according to the external diameter specification of pipe respectively, the unified installation of multiple pipe centre gripping anchor clamps has just been realized, adopt the semicircle arc structure to have better centering degree of accuracy, help improving the machining precision, and only can pinpoint and lock the mounting fixture piece through a retaining member, convenient quick installation and dismantlement, can realize that many specifications are in batches rocket pipe end portion surplus excision and change the type fast.

In other embodiments, the positioning protrusion and the fixing slot as the positioning and mounting reference may also be designed to have special shapes such as an ellipse, a rectangle, a square, and the like.

In further preferred embodiment, anchor clamps constant head tank 1011 sets up under the up end of anchor clamps piece clamping side or terminal surface down, correspondingly, holder positioning groove 917 also sets up on the up end of holder clamping side or terminal surface down, anchor clamps constant head tank 1011 and holder positioning groove 917 have the same forked tail cross section, it has waist shape hole to open on the retaining member 105, the fastener passes this waist shape hole and holder threaded connection, when the retaining member 105 is not locked to the fastener, retaining member 105 can reciprocate insert or withdraw from anchor clamps constant head tank 1011 so that quick assembly disassembly anchor clamps piece, when the fastening of fastener lock, retaining member 105 can be fixed on the holder with the quick accuracy of anchor clamps piece, the fixed screw that does not need, it is all very convenient to install and dismantle.

As shown in fig. 5 to 8, the gripping device base 906 is rotatably mounted on the table 22 via a rotating shaft 913, and after the first gripper seat 901 and the second gripper seat 902 grip the pipe 1, the axis of the straight line segment of the pipe end of the pipe 1 intersects with the axis of the rotating shaft 913 and the intersection point is located on the cutting surface of the cutting device 8. Like this, not only can realize the horse's hoof mouth cutting process and the processing of the flat mouthful of horse's hoof mouth at the catheter tip, make things convenient for the quick accurate positioning of catheter tip moreover, guarantee higher positioning accuracy, cutting process precision and flat mouthful machining precision.

As shown in fig. 6, in the preferred embodiment, the clamping device base 906 is supported on the worktable 22 through a plane bearing 914 and performs centering rotation through a rotating shaft 913, the upper end of the rotating shaft 913 is inserted into a fixing hole at the bottom of the clamping device base 906 and is locked and fixed through a fastener, and the lower part of the rotating shaft 913 is in mesh transmission with an angle encoder 912 installed on the worktable 22 through a gear. Thus, the angle encoder 912 can transmit the angle rotation information of the clamping device base 906 to the digital controller, and the 'horseshoe mouth' adjustment angle is directly displayed on the operation screen through a numerical value, so that the operator can conveniently control the angle rotation information.

As shown in fig. 7 and 8, in the present embodiment, the angle adjusting device 3 includes a gear 302, the gear 302 is in meshing transmission with an arc-shaped tooth 911 disposed on one side of the clamping device base 906, the gear 302 is driven to rotate by the rotation driving device, the arc-shaped tooth 911 is in a circular arc shape, and the center of the circular arc is located on the axis of the rotating shaft 913. In this embodiment, the arc-shaped teeth 911 are arc-shaped racks fixed on the clamping device base 906. The rotation driving device is a hand wheel 301, a gear 302 is fixed or integrally formed on a gear shaft 303, a worm wheel 304 is fixed on the gear shaft 303, the worm wheel 304 is in meshing transmission with a worm 306, the hand wheel 301 drives the worm 306 to rotate so as to drive the gear 302 to rotate a clamping device base 906, and an indicating disc 305 for indicating a rotation angle is installed on the workbench 22. In other embodiments, the rotation driving device may be a motor, which may be connected to the worm, or may be in transmission connection with the gear 302 or the rotating shaft 913 through a speed reducing mechanism, and the motor may be a stepping motor, a servo motor, or a motor with a speed reducing mechanism. In other embodiments, the angular encoder 912 may also be coupled to the shaft 913 via a universal joint. The device is gone on along the horizontal plane direction when angle regulation, possesses the locking function after the adjustment, locks after horizontal direction angle adjustment is suitable, can not influence the change of other direction angles. The angle adjustment amount in the horizontal direction is displayed on the control screen in real time, so that the angle adjustment amount can be conveniently mastered by an operator.

In a preferred embodiment, an outer ring member 23 is further disposed between the clamp base 906 and the worktable 22, the outer ring member 23 is located outside the rotating shaft 913 and is fixed on the worktable 22 by a fastener for assisting in supporting the clamp base 906, and a rolling support member (such as a ball roller) or a smooth wear member is disposed between the outer ring member 23 and the clamp base 906 for facilitating the rotation of the clamp base 906. Further preferably, an arc-shaped limiting groove 231 is formed in the outer ring member 23, and a limiting column which can be inserted into the arc-shaped limiting groove 231 and is limited in movement is arranged on the clamping device base 906. In addition, as shown in fig. 5, a stopper 919 may be further fixed to the table 22 to limit the rotation range of the clamp base 906.

After receiving the processing technological parameters such as the saw blade speed, the feeding speed and the like of the digital controller, the cutting device realizes accurate movement according to the requirements of the technological parameters, and ensures that the guide pipe obtains the optimal technological parameters during cutting. As shown in fig. 12, the cutting device 8 includes a cutting device base 801, a cutting motor 802, a handpiece reduction gearbox 803, a cutting blade 804 and a feed motor 806, the cutting device base 801 is fixed on the machine body 2, the handpiece reduction gearbox 803 is slidably connected with the cutting device base 801 through a slide rail and drives the feed motor 806 to move forward and backward, the cutting blade 804 is arranged on one side of the handpiece reduction gearbox 803, and the cutting motor 802 drives the cutting blade 804 to cut through a reduction mechanism.

In this embodiment, the cutting blade 804 is a circular saw blade, and in other embodiments, the cutting blade 804 may also be a cutting tool such as a saw blade, a knife blade, or a jigsaw. The feed motor 806 is a servo motor and drives the handpiece reduction gearbox 803 to move through a screw 805. In a preferred embodiment, the cutting motor 802 and the feeding motor 806 are both servo motors, and servo encoders are installed on the servo motors, so that the feeding speed, the feeding position, the cutting speed and the like can be accurately controlled by a digital controller according to the specification of the catheter material.

In order to directly cut the 'horseshoe' needed to be realized in place at one time when the allowance of the conduit is cut, and to avoid a complex processing process in the traditional 'horseshoe' processing, the preferred embodiment is that the axis of the rotating shaft 913 on the clamping device base 906 is located on a feed cutting surface of the cutting saw blade 804, and the feed cutting surface refers to a cut plane of the conduit after the cutting is finished. When the pipe fitting is subjected to flat-end processing, the flat-end processing surface of the flat-end device 7 is parallel to the feed cutting surface of the cutting device 8, or the feed path of the cutting saw blade 804 is perpendicular to the feed path of the flat-end tool.

In this embodiment, the feeding path of the cutting blade 804 is inclined downward to cut, so that the two devices are prevented from interfering with each other by being arranged in a staggered manner with the conduit clamping device 9, and the influence of cutting vibration on the conduit 1 clamped by the conduit clamping device 9 is reduced, thereby ensuring the cutting precision.

As shown in fig. 2 and 13, the carriage mechanism 5 includes a Y-direction carriage 53 and an X-direction carriage 54, the X-direction carriage 54 is connected with the body 2 in a left-right sliding manner and is driven by a feeding motor 51 to move and feed, the Y-direction carriage 53 is connected with the X-direction carriage 54 in a front-back sliding manner and is driven by a switching motor 52 to move back and forth, a positioning device 6 and a flat mouth device 7 are mounted on the Y-direction carriage 53, the positioning device 6 and the flat mouth device 7 are adjacent to each other in a front-back manner, and when the Y-direction carriage 53 moves back and forth, the positioning device 6 and the flat mouth device 7 can respectively correspond to the positions of.

After receiving the positioning parameter that the digital controller transmitted, positioner's servo motor drive positioner fixes a position according to the positioning parameter, realizes the pipe tip length positioning digital control and possesses the precision. As shown in fig. 13, in this example, the positioning device 6 includes a positioning device base 63, a positioning block 64 and a positioning driver 61, the positioning device base 63 is fixed on the Y-direction carriage 53, and the positioning block 64 is connected with the positioning device base 63 in a left-right sliding manner and driven by the positioning driver 61 to move and feed. In a preferred embodiment, the positioning driver 61 is an electric servo cylinder, the positioning block 64 is fixed on the moving end of the electric servo cylinder, one side of the positioning block 64 close to the conduit clamping device 9 is a positioning surface, and the positioning surface is parallel to the cutting feed surface of the cutting device 8 and the flat mouth processing surface of the flat mouth device 7, so that the digital controller can accurately control the stop position of the positioning block 64, and the moving position of the positioning block 64 can be displayed on a control screen in real time, and is convenient for an operator to master. In other embodiments, the positioning actuator 61 may also be a hydraulic ram controlled by a servo proportional valve.

In a preferred embodiment, the positioning block 64 is slidably connected to the positioning device base 63 through the guide rod 62, so that the guide rod 62 and the piston rod of the servo electric cylinder cooperate to increase the positioning stability of the positioning block 64.

In a preferred embodiment, the positioning surface of the positioning block 64 may be a positioning plate surface capable of contacting the entire end surface of the conduit, or may be a straight positioning surface, that is, the surface contacting the conduit may be designed to have a straight knife-edge shape as required, so as to reduce the contact area with the conduit.

The roughness of the end face of the conduit after cutting is poor, and the opening flattening device is used for cutting the end pipe opening of the conduit after the conduit is cut so as to realize the smoothness and the flatness of the pipe end of the conduit. As shown in fig. 13, the flat mouth device 7 includes a flat mouth device base 71, a flat mouth motor 72, and a cutter turntable 73, the flat mouth device base 71 is fixed on the Y-direction carriage 53, the cutter turntable 73 is mounted on the flat mouth device base 71 and is driven to rotate by the flat mouth motor 72, a plurality of flat mouth cutters 74 are mounted on the cutter turntable 73, the flat mouth cutters 74 are driven to rotate by the rotation of the cutter turntable 73 to form a flat mouth processing surface, and the flat mouth processing surface is parallel to the feed cutting surface of the cutting device 8 and also parallel to the positioning surface of the positioning device 6.

In the embodiment, the flat mouth device 7 is driven by the feeding motor 51 to feed; the positioning device 6 may be driven by the feeding motor 51 to perform feeding, may be driven by the positioning driver 61 to perform feeding, or may be driven by a mixture of the two. In other embodiments, a steel wire brush can be arranged to clean the port of the catheter so that the port of the catheter is smoother and smoother, and the welding quality is improved.

The catheter allowance cutting method of the catheter allowance cutting device comprises the following steps:

1) determining the positioning parameters of the positioning device 6 according to the allowance of the pipe end of the catheter 1, and driving the positioning block 64 to reach the designated position by the positioning driver 61 and/or the feeding motor 51 according to the positioning parameters;

2) as shown in fig. 14, the end of the conduit 1 abuts against the positioning surface of the positioning block 64, the conduit 1 is clamped and fixed by the conduit clamping device 9, the waste section of the conduit 1 is clamped by the third clamping seat 903 and the fourth clamping seat 904, the remaining section of the conduit 1 is clamped by the first clamping seat 901 and the second clamping seat 902, and the positioning block 64 is reset;

3) as shown in fig. 15, the cutting device 8 performs a cutting operation, and the cutting blade 804 enters between the second clamping seat 902 and the fourth clamping seat 904 to cut off the residual amount of the catheter 1;

4) the cutting saw blade 804 is reset, the second clamping seat 902 and the fourth clamping seat 904 are opened, and the waste material slides into the waste material box 4 through the waste material chute 21; the switching motor 52 drives the Y-direction carriage 53 to move the flat mouth device 7 to a processing position, and the feeding motor 51 drives the flat mouth device 7 to feed to carry out flat mouth processing on the end face of the cut of the conduit 1, as shown in fig. 16;

5) after the flat opening processing is completed, the flat opening device 7 is reset, the first clamping seat 901 and the third clamping seat 903 are opened, and the catheter 1 is taken out.

In the step 1), as for how to obtain the allowance positioning parameters of the guide pipe after the pipe bending process is finished, the bent pipe measuring and allowance positioning method disclosed in the patent document with the publication number of CN 108074277A can be referred, and the method comprises the steps of carrying out global calibration of multiple sensors by means of a laser tracker and a target, and unifying the coordinate system of the multiple sensors to a global coordinate system; the method comprises the following steps that a plurality of sensors strictly and synchronously acquire bent pipe images, the center line of a bent pipe is obtained through edge detection and morphological refinement, and three-dimensional reconstruction of the center line is carried out by means of a bidirectional polar line matching algorithm; dispersing the central line into a spatial point cloud, calculating a control point, a straight line segment end point and an arc segment arc central point, and performing three-dimensional modeling by using the central line as a guide line; and finally, matching the design model and the measurement model by using a closest point iteration method, and calculating the position of the margin to obtain a margin positioning parameter.

In the above steps 2) and 5), a robot, a manipulator, or a manual transfer of the catheter 1 is employed.

The method for cutting the horseshoe opening by the catheter allowance cutting equipment comprises the following steps:

1) determining the positioning parameters of the positioning device 6 according to the allowance of the pipe end of the catheter 1, and driving the positioning block 64 to reach the designated position by the positioning driver 61 and/or the feeding motor 51 according to the positioning parameters;

2) the end part of the conduit 1 is abutted against the positioning surface of the positioning block 64, the conduit 1 is clamped and fixed by the conduit clamping device 9, the waste material section of the conduit 1 is clamped by the third clamping seat 903 and the fourth clamping seat 904, the reserved section of the conduit 1 is clamped by the first clamping seat 901 and the second clamping seat 902, and the positioning block 64 is reset;

3) rotating the conduit clamping device 9 and the conduit 1 to corresponding angles through the angle adjusting device 3 according to the deviation angle of the horseshoe opening of the mounting surface of the conduit 1;

4) the cutting device 8 performs feed cutting, and the cutting saw blade 804 enters between the second clamping seat 902 and the fourth clamping seat 904 to cut off the allowance of the conduit 1;

5) the cutting saw blade 804 is reset, the second clamping seat 902 and the fourth clamping seat 904 are opened, and the waste material slides into the waste material box 4 through the waste material chute 21; the switching motor 52 drives the Y-direction carriage 53 to move the flat mouth device 7 to a processing position, and the feeding motor 51 drives the flat mouth device 7 to feed to carry out flat mouth processing on the end face of the cut of the conduit 1, as shown in FIG. 17;

6) after the flat opening processing is completed, the flat opening device 7 is reset, the first clamping seat 901 and the third clamping seat 903 are opened, and the catheter 1 is taken out.

In the step 2), the rotation angle of the to-be-processed conduit 1 along the axis of the straight-line section of the pipe end can be adjusted by manual marking and positioning or a mechanical arm/robot, so that the equipment can be used for processing the pipe end of the conduit 1 by only adjusting the horizontal deflection angle of the conduit 1.

Example 2:

a pipe cutting device comprises a machine body 2, wherein an angle adjusting device 3, a cutting device 8, a conduit clamping device 9 and a carriage mechanism 5 are installed on the machine body 2, a positioning device 6 is installed on the carriage mechanism 5, the positioning device 6 and the conduit clamping device 9 are oppositely arranged left and right, and the cutting device 8 is fed in front and back. The only difference from example 1 is that: the flat mouth device 7 is not provided, only the catheter cutting function is performed, and the arrangement of the positions of the devices, the specific structure, and various embodiments are the same as those of example 1.

The cutting method of the pipe fitting cutting equipment comprises the following steps:

1) the positioning driver 61 and/or the feeding motor 51 drives the positioning block 64 to reach a designated position according to the positioning parameters of the catheter 1 to be cut;

2) the end part of the conduit 1 is abutted against the positioning surface of the positioning block 64, the conduit 1 is clamped and fixed by the conduit clamping device 9, one side of the conduit 1 is clamped by the third clamping seat 903 and the fourth clamping seat 904, the other side of the conduit 1 is clamped by the first clamping seat 901 and the second clamping seat 902, and the positioning block 64 is reset;

3) the cutting device 8 is fed, and the cutting saw blade 804 enters the second clamping seat 902 and the fourth clamping seat 904 to cut the conduit 1;

4) after the cut is completed, the cutting blade 804 is reset, the catheter holding device 9 is released, and the catheter 1 is removed.

The method for cutting the horseshoe opening by the pipe fitting cutting equipment comprises the following steps:

1) the positioning driver 61 and/or the feeding motor 51 drives the positioning block 64 to reach a designated position according to the positioning parameters of the catheter 1 to be cut;

2) the end part of the conduit 1 is abutted against the positioning surface of the positioning block 64, the conduit 1 is clamped and fixed by the conduit clamping device 9, one side of the conduit 1 is clamped by the third clamping seat 903 and the fourth clamping seat 904, the other side of the conduit 1 is clamped by the first clamping seat 901 and the second clamping seat 902, and the positioning block 64 is reset;

3) rotating the conduit clamping device 9 and the conduit 1 to corresponding angles through the angle adjusting device 3 according to the deviation angle of the horseshoe opening of the mounting surface of the conduit 1;

4) the cutting device 8 is fed, and the cutting saw blade 804 enters the second clamping seat 902 and the fourth clamping seat 904 to cut the conduit 1;

5) after the cut is completed, the cutting blade 804 is reset, the catheter holding device 9 is released, and the catheter 1 is removed.

Example 3:

a pipe fitting flat-end equipment comprises a machine body 2, wherein an angle adjusting device 3, a conduit clamping device 9 and a carriage mechanism 5 are installed on the machine body 2, a positioning device 6 and a flat-end device 7 are installed on the carriage mechanism 5, the positioning device 6 and the conduit clamping device 9 are oppositely arranged left and right, and a feed is moved left and right by the flat-end device 7. The only difference from example 1 is that: the cutting device 8 was not provided, and only the flat end face of the nozzle of the catheter was processed, and the arrangement of the positions of the devices, the specific structure, and the various embodiments were the same as those of example 1.

The flat-end processing method of the pipe fitting flat-end equipment comprises the following steps:

1) the positioning driver 61 and/or the feeding motor 51 drives the positioning block 64 to reach a designated position according to the positioning parameters of the catheter 1 to be processed;

2) the end part of the conduit 1 is abutted against the positioning surface of the positioning block 64, the conduit 1 is clamped and fixed by a first clamping seat 901 and a second clamping seat 902 in the conduit clamping device 9, and the positioning block 64 is reset;

3) the conversion motor 52 drives the Y-direction carriage 53 to move the leveling device 7 to a processing position, the leveling motor 72 drives the cutter turntable 73 to rotate, and the feeding motor 51 drives the leveling device 7 to feed to perform leveling processing on the end face of the pipe orifice of the guide pipe 1;

4) after the flat opening processing is completed, the flat opening device 7 is reset, the first clamping seat 901 and the third clamping seat 903 are opened, and the catheter 1 is taken out. The method for processing the flat mouth of the horseshoe mouth by the pipe fitting flat mouth equipment comprises the following steps:

1) the positioning driver 61 and/or the feeding motor 51 drives the positioning block 64 to reach a designated position according to the positioning parameters of the catheter 1 to be processed;

2) the end part of the conduit 1 is abutted against the positioning surface of the positioning block 64, the conduit 1 is clamped and fixed by a first clamping seat 901 and a second clamping seat 902 in the conduit clamping device 9, and the positioning block 64 is reset;

3) according to the deviation angle of the horseshoe opening of the conduit 1, rotating the conduit clamping device 9 and the conduit 1 to a corresponding angle through the angle adjusting device 3;

4) the conversion motor 52 drives the Y-direction carriage 53 to move the flat mouth device 7 to a processing position, and the feeding motor 51 drives the flat mouth device 7 to feed to carry out flat mouth processing on the end surface of the horseshoe mouth of the catheter 1;

5) after the flat opening processing is completed, the flat opening device 7 is reset, the first clamping seat 901 and the third clamping seat 903 are opened, and the catheter 1 is taken out.

All features described in the description, the appended claims and the drawings, either individually or in any combination thereof, are essential features of the invention.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "one implementation," "a specific implementation," "other implementations," "examples," "specific examples," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment, implementation, or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described above may also be combined in any suitable manner in any one or more of the embodiments, examples, or examples. The present disclosure also includes any one or more of the specific features, structures, materials, or characteristics described above, either individually or in any combination.

Although the embodiments of the present invention have been shown and described, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and those skilled in the art can make changes, modifications, substitutions, variations, deletion of partial features, addition of features or re-combination of features without departing from the spirit and scope of the present invention, and any simple modification, equivalent change and modification made to the above embodiments according to the innovative principles of the present invention are all within the scope of the present invention.

Claims (10)

1. The utility model provides an aerospace pipe surplus excision equipment, includes fuselage (2), its characterized in that, install angle adjusting device (3), cutting device (8), pipe clamping device (9) and planker mechanism (5) on fuselage (2), install positioner (6) and peaceful mouthful device (7) on planker mechanism (5), positioner (6) and peaceful device (7) set up in tandem, planker mechanism (5) and pipe clamping device (9) one left right side setting.

2. The aerospace catheter allowance ablation apparatus according to claim 1, wherein the catheter clamping device (9) is mounted on a workbench (22) of a fuselage (2), the catheter clamping device (9) comprises a first clamping seat (901), a second clamping seat (902), a third clamping seat (903), a fourth clamping seat (904) and a clamping device base (906), the first clamping seat (901) and the second clamping seat (902) are arranged on the clamping device base (906) in a front-back opposite manner and are matched with the clamped catheter (1) in a front-back manner, the third clamping seat (903) and the fourth clamping seat (904) are arranged on the clamping device base (906) in a front-back opposite manner and are matched with the clamped catheter (1) in a front-back manner, the first clamping seat (901) and the third clamping seat (903) are arranged at left and right intervals, the second clamping seat (902) and the fourth clamping seat (904) are arranged at left and right intervals, a third clamping seat (903) and a fourth clamping seat (904) are positioned on one side of a clamping device base (906) close to a waste chute (21), a waste slide slope (915) is arranged between the third clamping seat (903) and the fourth clamping seat (904) of the clamping device base (906), the first clamping seat (901) is fixed on the clamping device base (906), the second clamping seat (902) is driven by a clamping motor (908)/a third clamping cylinder (916) to slide back and forth on the clamping device base (906), the third clamping seat (903) is driven by a first clamping cylinder (905) to slide back and forth on the clamping device base (906), the moving end of the first clamping cylinder (905) is hinged with the third clamping seat (903), the fourth clamping seat (904) is driven by a second clamping cylinder (907) to slide back and forth on the clamping device base (906), and the moving end of the second clamping cylinder (907) is hinged with the fourth clamping seat (904), wherein the cutting device (8) feeds and cuts between the second clamping seat (902) and the fourth clamping seat (904).

3. The aerospace conduit allowance removal apparatus of claim 2, wherein the moving ends of the first link (909), the second link (910), and the clamp motor (908)/the third clamp cylinder (916) share a common hinge axis.

4. The aerospace conduit allowance cutting apparatus of claim 2, wherein the moving end of the clamp motor (908)/the third clamp cylinder (916) moves obliquely downward to clamp the conduit, and the upper end of the first link (909) is hinged to the moving end of the clamp motor (908)/the third clamp cylinder (916), the lower end of the first link (909) is hinged to the clamp base (906), the upper end of the second link (910) is hinged to the second clamp base (902), and the lower end of the second link (910) is hinged to the moving end of the clamp motor (908)/the third clamp cylinder (916).

5. The aerospace catheter allowance cutting device according to claim 2, wherein the first clamping seat (901), the second clamping seat (902), the third clamping seat (903) and the fourth clamping seat (904) are respectively provided with a clamp block for contacting and clamping the catheter (1), the clamp blocks are semi-annular, the inner side surfaces of the clamp blocks are semicircular clamping grooves, the front clamp block and the rear clamp block are opposite to each other and matched to form a clamping hole (1013) for accommodating a straight line section at the end of the catheter (1), positioning protrusions are formed on the outer side surfaces of the clamp blocks, and accordingly fixing clamping grooves matched with the positioning protrusions of the clamp blocks are formed in the clamping seats.

6. The aerospace catheter allowance removal apparatus of claim 2, wherein the clamping device base (906) is rotatably mounted on the workbench (22) through a rotating shaft (913), and after the first clamping seat (901) and the second clamping seat (902) clamp the catheter (1), an axis line of a straight line segment of a tube end of the catheter (1) intersects with an axis line of the rotating shaft (913) and an intersection point is located on a feed cutting surface of the cutting device (8).

7. The aerospace catheter margin resection device according to claim 6, wherein the angle adjustment device (3) comprises a gear (302), the gear (302) is in meshing transmission with an arc-shaped tooth (911) arranged on one side of the clamping device base (906), the gear (302) is driven to rotate by a rotation driving device, the arc-shaped tooth (911) is in an arc shape, and the center of the arc is located on the axis of the rotating shaft (913).

8. The aerospace catheter allowance cutting device according to claim 1, wherein the cutting device (8) comprises a cutting device base (801), a cutting motor (802), a handpiece reduction gearbox (803), a cutting saw blade (804) and a feed motor (806), the cutting device base (801) is fixed on the machine body (2), the handpiece reduction gearbox (803) is in sliding connection with the cutting device base (801) through a sliding rail and drives the feed to move back and forth through the feed motor (806), the cutting saw blade (804) is arranged on one side of the handpiece reduction gearbox (803), and the cutting motor (802) drives the cutting saw blade (804) to cut after passing through a speed reduction mechanism; the cutting blade (804) is a circular saw blade, or jigsaw.

9. The aerospace catheter allowance cutting device according to claim 1, wherein the carriage mechanism (5) comprises a Y-direction carriage (53) and an X-direction carriage (54), the X-direction carriage (54) is connected with the body (2) in a left-right sliding mode and is driven by a feeding motor (51) to move and feed, the Y-direction carriage (53) is connected with the X-direction carriage (54) in a front-back sliding mode and is driven by a conversion motor (52) to move back and forth, a positioning device (6) and a flat mouth device (7) are mounted on the Y-direction carriage (53), the positioning device (6) and the flat mouth device (7) are adjacent to each other in a front-back mode, and when the Y-direction carriage (53) moves back and forth, the positioning device (6) and the flat mouth device (7) can respectively correspond to the positions of the catheter clamping device (9) for clamping the catheter (.

10. The aerospace catheter allowance cutting device according to any one of claims 1 to 9, wherein the positioning device (6) comprises a positioning device base (63), a positioning block (64) and a positioning driver (61), the positioning device base (63) is fixed on the Y-direction carriage (53), and the positioning block (64) is connected with the positioning device base (63) in a left-right sliding mode and driven by the positioning driver (61) to move and feed; one side of the positioning block (64) close to the conduit clamping device (9) is a positioning surface which is parallel to a feed cutting surface of the cutting device (8) and is also parallel to a flat opening processing surface of the flat opening device (7); the flat mouth device (7) comprises a flat mouth device base (71), a flat mouth motor (72) and a cutter rotary table (73), the flat mouth device base (71) is fixed on the Y-direction carriage (53), the cutter rotary table (73) is installed on the flat mouth device base (71) and driven to rotate by the flat mouth motor (72), a plurality of flat mouth cutters (74) are installed on the cutter rotary table (73), the cutter rotary table (73) drives the flat mouth cutters (74) to rotate to form a flat mouth processing surface when rotating, and the flat mouth processing surface is parallel to a feed cutting surface of the cutting device (8) and is also parallel to a positioning surface of the positioning device (6).

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