CN114734366B

CN114734366B - Finishing device, finishing method and sealing system

Info

Publication number: CN114734366B
Application number: CN202210659826.3A
Authority: CN
Inventors: 雷力明; 米天健; 王小康; 樊林娜; 王威; 周新民; 高军帅
Original assignee: Shaanxi Jinxintian Titanium Material Technology Co ltd; AECC Commercial Aircraft Engine Co Ltd
Current assignee: Shaanxi Jinxintian Titanium Material Technology Co ltd; AECC Commercial Aircraft Engine Co Ltd
Priority date: 2022-06-13
Filing date: 2022-06-13
Publication date: 2022-09-06
Anticipated expiration: 2042-06-13
Also published as: CN114734366A; WO2023241412A3; WO2023241412A2

Abstract

The invention relates to a finishing device, a finishing method and a sealing system. The sealing and finishing device comprises a thrust system and a plurality of sealing systems, wherein each sealing system comprises a piston and a cylinder body matched with the piston; and each conveying pipeline system conveys the finishing medium contained in the corresponding sealing system to different ports of the inner runner workpiece for finishing, and the plurality of sealing systems are communicated through the inner runner workpiece. Wherein, finishing device's thrust system includes vertical plunger pump, vertical plunger pump with the piston is connected in order to provide drive power for the piston can move for the cylinder body along vertical direction, multistage pipeline includes first order pipeline, and is located the adjacent second level pipeline of connecting of first order pipeline low reaches, first order pipeline include with the elbow structure that the exit end of cylinder body is connected, just the elbow structure extends second level pipeline with the level and is connected.

Description

Finishing device, finishing method and sealing system

Technical Field

The invention relates to the field of precision machining of an inner runner, in particular to a finishing device, a finishing method and a sealing system.

Background

Parts with fine and complex inner flow passage structures are widely applied to the industrial fields of aerospace, ships, nuclear, automobiles, molds and the like, particularly parts related to a fluid power system are often provided with fine flow passages, deep small holes, complex inner cavity structures such as the fine flow passages and the deep small holes, and the like, and have the functions of conveying, exchanging or applying hydraulic pressure to fluid, and the like, such as fuel nozzles of various engines of the aerospace, ships and automobiles, heat exchangers, hydraulic components, oil passage control throttlers and the like.

The process technology for machining the micro complex inner flow passage comprises precision machining, femtosecond/water guide/long pulse laser machining, electric spark machining, additive manufacturing (3D printing) and the like. Except for an additive manufacturing technology, the micro-complicated inner flow passage processed by other single processes has a relatively simple structure and a small length-diameter ratio, and can be processed by combining other combined processes such as welding and the like. The problems of burrs, sharp corners of inflection points or tool connecting steps and the like can be generated in the micro complex inner flow channel machined by a precision machine; the surface of the inner runner processed by the femtosecond laser can generate adhered residual particles and a surface step effect; a remelted layer is generated on the surface of the inner runner processed by the water guide/long pulse laser and the electric spark; additive manufacturing (3D printing) is a technology for dispersing a complex three-dimensional structure part model into a two-dimensional structure to perform layer-by-layer superposition forming, and enables the integrated forming of complex fine and complex inner runner parts to be possible, so that the application of the method in the industrial fields of aerospace, automobiles, molds and the like is increasing day by day. However, in the process of forming a part by using the additive manufacturing technology, semi-sintered or bonded powder particles and a surface step effect exist on the surface of a flow channel in the part due to the self process characteristics of temperature gradient, layer-by-layer forming and the like.

Machining burrs, femtosecond laser machining inner flow passage adhesion sintering particles, additive manufacturing inner flow passage surface bonding powder and the like all influence the use performance and safety of parts: when fluid introduced into the inner flow passage rubs with the surface layer at a high speed to cause burrs, adhered residue particles or bonded powder to fall off, the fluid becomes redundant and diffuses everywhere along with the fluid, or an oil way is blocked or a mechanical abrasion fault is caused, thereby causing a major safety accident; the inner surface with large roughness is easy to become a fatigue crack source in the long-term use process, and the carbon deposition phenomenon is easy to occur if the inner surface is a high-temperature oil way system; the machining of knife lines, inflection point sharp corners or knife connecting steps on the surface of a flow channel, the femtosecond laser and the step phenomenon of machining the surface of an inner flow channel in additive manufacturing can cause turbulence, vortex and sharp increase of on-way resistance of fluid in the motion process of the fluid, even cause the fluid to be out of control, generate vibration and reduce the service life of parts. The rough surface can also generate a large amount of cavitation bubbles in the fluid to influence combustion and hydraulic power, and even generate cavitation corrosion; for the inner flow channel and the communicating small hole of some parts (such as hollow blades) made of specific materials, the parts fail prematurely due to the fact that micro cracks are prone to occur on the surface of a remelted layer, and therefore the thickness of the remelted layer is required to be reduced or the remelted layer is not allowed to occur.

Therefore, when the channel surface in the fluid dynamic part is processed by the technologies such as precision machining, femtosecond/water guide/long pulse laser processing, electric spark processing, additive manufacturing (3D printing) and the like, the adverse problems of residues such as burrs, bonding powder and sintered particles, surface roughness, a re-melted layer and the like are caused, and the performance requirement of the product can be met only after the adverse effects are eliminated by adopting a proper surface finishing technology.

However, the technology for effectively finishing the surface of the fine and complex inner flow channel does not appear at present, so that the roughness of the inner surface of the fine and complex inner flow channel workpiece manufactured by the additive manufacturing only has the original average roughness after the additive manufacturing at presentRa is more than or equal to 6.3 mu m, and the surface optimal roughness of the inner flow passage does not appearRa is less than or equal to 1.6 mu m, and the surface optimal roughness of the inner flow channel does not appear on the micro complex inner flow channel workpiece processed by laser and electric sparkRa is less than or equal to 0.8 μm; and surface optimum roughness of inner flow channel for machined micro-complicated inner flow channel workpieceRa is less than or equal to 0.4 mu m, and the existing micro-complicated inner flow channel cannot be realized by machining only capable of linear feeding if the existing micro-complicated inner flow channel has complicated special-shaped flow channels such as S-shaped bend, L-shaped bend, U-shaped bend, O-shaped bend and the like, but can be realized only by additive manufacturing and the like, so that the optimal roughness of the surface of the micro-complicated inner flow channel manufactured by the additive manufacturing does not appear at presentRa is less than or equal to 1.6 μm.

Disclosure of Invention

The application aims to provide a finishing device, a finishing method and a sealing system.

In a first aspect, the present application provides a finishing apparatus comprising a thrust system; the thrust system is communicated with one end of the piston and provides driving force for the sealing system so as to push the finishing medium to be output from an outlet end of the cylinder body; each conveying pipeline system conveys the finishing medium contained in the corresponding sealing system to different ports of the inner runner workpiece for finishing, and the plurality of sealing systems are communicated through the inner runner workpiece; the upstream end of the conveying pipeline system is connected with the outlet end of the sealing system, the downstream end of the conveying pipeline system is used for outputting an inner runner workpiece for finishing by a finishing medium, the length-diameter ratio of the conveying pipeline system is greater than 10:1, the caliber of the outlet end is greater than 3mm, the conveying pipeline system is provided with a plurality of stages of pipelines, and the sectional area ratio of a front stage pipeline to a rear stage pipeline of two adjacent stages of pipelines is greater than 1; the thrust system of the finishing device comprises a vertical plunger pump, the vertical plunger pump is connected with the piston to provide driving force, so that the piston can move relative to the cylinder body along the vertical direction, the multistage pipeline comprises a first-stage pipeline and a second-stage pipeline, the downstream of the first-stage pipeline is adjacently connected with the second-stage pipeline, the first-stage pipeline comprises an elbow structure connected with the outlet end of the cylinder body, and the elbow structure is connected with a horizontally extending second-stage pipeline.

In the technical scheme of this application embodiment, through the vertical structure that adopts vertical plunger pump, vertical removal's piston to constitute and conveying line's horizontal structure in the finishing device, the pressure stability of finishing medium at the finishing in-process is guaranteed in the realization of both cooperations to realize reliable finishing effect. Particularly, the vertical plunger pump, the vertical structure of the piston and the cylinder body and the elbow structure are correspondingly connected with the horizontal conveying pipeline and the workpiece, namely, a vertical and horizontal combined framework is adopted in the finishing device, so that the gravity action can be skillfully utilized, the piston and the cylinder body of the vertical plunger pump are not influenced by the gravity side-tipping force, the provided pressure is very stable, and meanwhile, a larger operable workbench space is provided for the finishing processing of the workpiece; in addition, the conveying pipeline adopts a structure that the length-diameter ratio is greater than 10:1, the caliber of an outlet end is greater than 3mm, and the sectional area ratio of a front-stage pipeline to a rear-stage pipeline of two adjacent stages of pipelines of the multi-stage pipeline is greater than 1, so that the conveying of the saturated flow of the conveyed finishing medium is realized, and the pressure stability of the finishing medium in the conveying pipeline is ensured.

In some embodiments, the ratio of the cross-sectional area of the first stage conduit to the second stage conduit is 1.2 to 1.8.

In some embodiments, the multistage pipeline further comprises a third stage pipeline which is adjacently connected at the downstream of the second stage pipeline, and the cross-sectional area ratio of the second stage pipeline to the third stage pipeline is 1.2-1.8.

In some embodiments, the device further comprises a tool, the tool is provided with a port, and the sectional area ratio of the third-stage pipeline to the port of the tool is 1.2-2.2. The cross-sectional area ratio of the port of the tool to the port of the flow channel in the workpiece is 1.2-10.

In some embodiments, the piston has at least a first groove and a second groove from top to bottom, the sealing system further comprises a sealing ring between the piston and the cylinder, the sealing ring comprises a first sealing ring arranged in the first groove and a second sealing ring arranged in the second groove, and a gap between the piston and the cylinder in the radial direction is 1 mm-2.5 mm.

In some embodiments, the first groove is a split structure, the top surface of the piston is a flat surface, a cover plate is detachably arranged on the piston, the periphery of the cover plate is provided with an inclined surface, and the inclined surface and the top surface of the piston form a single-side inclined groove to form the first groove; the second groove is formed in the side wall of the piston; the first sealing ring is made of hard materials, and the second sealing ring is made of soft materials.

In some embodiments, the second grooves comprise at least two grooves in the direction from top to bottom, including a first sub-groove and a second sub-groove, wherein the ratio of the depth of the second sub-groove to the depth of the first sub-groove is 1.2-1.5.

In some embodiments, the single-sided chute has an inclination angle of greater than 60 °.

In some embodiments, the material of the first seal ring satisfies: the flexural modulus is 1.9GPa to 3.6GPa, the elongation is 60 percent to 120 percent, and the Knoop hardness is 90HK to 100 HK; the material of the second sealing ring satisfies that: the flexural modulus is 0.2GPa to 0.25GPa, the elongation is 300 percent to 380 percent, and the flexural strength is 80MPa to 100 MPa.

In some embodiments, the material of the first sealing ring is one of pp, teflon, nylon and peek, and the material of the second sealing ring is one of silica gel, rubber and butyronitrile.

In some embodiments, the cylinder wall of the cylinder block has a coating having a thickness of 50 to 220 μm, a hardness of 1500 to 2200HV, and a material of one or a combination of oxide, carbide, boride and nitride ceramics.

In some embodiments, the surface of the coating has a roughness ofRa 0.05-0.4 μm, roundness less than or equal to 100 μm and cylindricity less than or equal to 200 μm.

In some embodiments, the finishing device further comprises a diagnostic device having a flow rate and/or flow sensor and a pressure sensor for sensing the flow rate and/or flow of the finishing medium and the pressure.

In some embodiments, the finishing medium comprises a liquid phase having a viscosity <1000cP and a solid phase comprising abrasive particles, the finishing work piece is a micro-scale internal flow channel piece having an aperture of less than or equal to 3mm and an aspect ratio of greater than or equal to 50: 1.

In a second aspect, the present application provides a finishing method, which employs the finishing apparatus according to the first aspect, where the finishing medium includes a liquid phase and a solid phase, the viscosity of the liquid phase is less than 1000cP, the solid phase includes abrasive particles, a workpiece to be finished is a micro internal flow channel, the caliber of the micro internal flow channel is less than or equal to 3mm, and the length-diameter ratio of the micro internal flow channel is greater than or equal to 50:1, the thrust system of the finishing apparatus applies a predetermined pressure to the finishing medium, so that the finishing medium flows in the micro internal flow channel at a flow rate greater than 5m/s, and the flow rate of the finishing medium flowing into the interior of the micro internal flow channel at one end of the micro internal flow channel reaches a saturation value capable of accommodating the flow rate of the micro internal flow channel, so that the hydraulic pressure in the internal flow channel is in a pressure-holding state.

In a third aspect, the present application provides a sealing system comprising: the piston can reciprocate along the extending direction of the cylinder wall of the cylinder body, and a thrust system is communicated with one end of the piston and provides driving force for the piston; the sealing system comprises a piston, a cylinder body and a sealing system, wherein the piston at least comprises a first groove and a second groove from the top to the bottom, the sealing system also comprises a sealing ring positioned between the piston and the cylinder body, the sealing ring comprises a first sealing ring arranged in the first groove and a second sealing ring arranged in the second groove, and the radial gap between the piston and the cylinder body is 1-2.5 mm; the first groove is of a split structure, the top surface of the piston is a plane, a cover plate is detachably arranged on the top surface of the piston, an inclined surface is arranged on the periphery of the cover plate, and a single-side inclined groove is formed by the inclined surface and the top surface of the piston to form the first groove; the second groove is formed in the side wall of the piston.

Drawings

The above and other features, properties and advantages of the present invention will become more apparent from the following description of the embodiments in conjunction with the accompanying drawings, it being noted that the drawings are given by way of example only and are not drawn to scale, and should not be taken as limiting the scope of the invention which is actually claimed, wherein:

fig. 1 is a schematic flow diagram of a method of finishing according to some embodiments of the present application.

FIG. 2 is a schematic diagram of a structure of a finishing device according to some embodiments of the present application.

Fig. 3 is a partial enlargement at a according to fig. 2.

Fig. 4 is a partial enlarged view at B according to fig. 2.

Detailed Description

The following discloses a variety of different implementation or examples implementing the subject technology. Specific examples of components and arrangements are described below to simplify the present disclosure, but these are merely examples and do not limit the scope of the invention. "one embodiment," "an embodiment," and/or "some embodiments" mean a certain feature, structure, or characteristic described in connection with at least one embodiment of the present application. Therefore, it is emphasized and should be appreciated that two or more references to "an embodiment" or "one embodiment" or "an alternative embodiment" in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, some features, structures, or characteristics may be combined as appropriate in some embodiments, yet other embodiments, still other embodiments, and so on, of the present application.

Flow charts are used herein to illustrate operations performed by systems according to embodiments of the present application. It should be understood that the preceding or following operations are not necessarily performed in the exact order in which they are performed. Other operations may also be added to, or removed from, the processes.

In addition, the average roughness of the measured surface is obtained by selecting a plurality of regions on the measured surface, measuring and averaging the regions. And (3) selecting a plurality of areas on the measured surface to measure and taking the minimum value to obtain the optimal roughness of the measured surface. For example, when roughness measurement is performed, for example, a certain area of the roughness measurement may be a pipeline section with a length of 8mm, and a plurality of pipeline sections with a length of 8mm are selected for measurement in the measured pipeline and the minimum value is removed.

Parts with fine and complex inner flow channel structures are widely applied to the industrial fields of aerospace, ships, nuclear, automobiles, molds and the like, however, when the inner flow channel surface of a fluid dynamic part is processed by the current processing technology, such as precision machining, femtosecond/water guide/long pulse laser processing, electric spark processing, additive manufacturing (3D printing) and the like, the adverse problems of residues such as burrs, bonding powder, sintered particles and the like, a rough surface, a re-melting layer and the like are caused, and the performance requirements of the product can be met only after the adverse effects are eliminated by adopting a proper surface finishing technology.

At present, the surface optimal roughness of the inner flow channel does not appear on the micro inner flow channel workpiece manufactured by additive manufacturingRa is less than or equal to 1.6 mu m, and the surface optimal roughness of the inner flow channel does not appear on the micro inner flow channel workpiece processed by laser and electric sparkRa is less than or equal to 0.8 μm; and surface-optimized roughness without internal flow channels for machined micro internal flow channel workpiecesRa is less than or equal to 0.4 mu m, if the micro inner flow channel has S-shaped bent, L-shaped bent, U-shaped bent, O-shaped bent and other special-shaped flow channel structures, the micro inner flow channel cannot be realized by linear feeding machining, and can only be realized by additive manufacturing and other modes, so that the optimal roughness of the surface of the micro inner flow channel for additive manufacturing does not appear at presentRa is less than or equal to 1.6 μm.

The inventor of the invention has made extensive research and trial and comparison on various inner runner surface finishing methods, and found that when the inner runner of a part has a larger caliber (>3mm), a smaller length diameter (< 50:1) and is in an approximately linear trend, the finishing can be performed by adopting common methods such as manual polishing, chemical, electrochemical, plasma, magnetic force, magnetorheological, abrasive flow, water jet, ultrasonic wave and the like, however, for a micro inner runner with a smaller caliber (less than or equal to 3mm) and a larger length diameter (greater than or equal to 50: 1):

(1) by adopting an abrasive flow technology and utilizing a semi-solid soft paste polishing medium with high rigidity to polish an inner cavity through an extrusion and diffraction grinding mechanism, the inventor finds that the creep fluid with extremely small Reynolds number is difficult to uniformly process through a complex long-range micro flow channel, is easy to block at a corner and a dead angle, and can cause flow channel deformation and even suppress and crack the flow channel when forcibly passing through the flow channel. Even if the internal flow passage with the length-diameter ratio of more than or equal to 50:1 is barely passed through, the pressure and the flow velocity are sharply attenuated along with the increase of the fluid stroke, so that the port of the internal flow passage is over-polished, and the internal part is not polished due to the excessive pressure and flow velocity loss. In addition, the colloid abrasive flow medium which is insoluble in water is easy to remain at the turning and dead angle of the inner flow channel, and is difficult to even not completely removed after the processing is finished.

(2) The abrasive water jet technology, also called micro-abrasive slurry body jet flow, high-speed flow and high-speed water particle finishing, is adopted, hydraulic pressure is applied to a water jet nozzle, water jet impact kinetic energy with abrasive particles is sprayed out by the nozzle to erode and remove a workpiece surface layer material, and the water jet nozzle keeps a short distance with the surface of a part, so that the abrasive water jet technology is difficult to act on a micro inner runner with a small inner runner caliber (less than or equal to 3mm) and a large long diameter (greater than or equal to 50: 1);

(3) the magnetic finishing technology is adopted, the surface of an inner flow passage with the caliber of more than 3mm and the nearly straight line trend can only be slightly brightened, and the effective surface finishing of a micro complex inner flow passage with the caliber of less than or equal to 3mm and the three-dimensional trend, which contains an S-shaped bend, an L-shaped bend, a U-shaped bend, an O-shaped bend and a spiral bend, can not be carried out, the magnetic finishing is a flexible processing method utilizing magnetic needle abrasive particles with larger sizes, and the principle is that surface salient points and concave points can be simultaneously processed under the action of an external magnetic field, so the flexible processing means can only slightly brighten and improve the surface, and the step effect of the surface, the surface roughness and the powder, particles and burrs adhered to the large-scale stripping surface can not be obviously improved even if the material removal amount is large; in addition, the method can not cope with the complex inner flow passage finishing with three-dimensional space trend on the part due to the movement of the controlled magnetic field;

(4) by adopting the chemical finishing method, when the caliber of the inner runner is small, less corrosive solution can be accommodated, the efficiency of the chemical finishing method is extremely low, and even reaction bubbles are locally blocked and cannot be finished;

(5) by adopting electrochemical, plasma finishing and ultrasonic methods, profiling electrodes are difficult to place in narrow runners with three-dimensional trends, such as S-shaped bends, L-shaped bends, U-shaped bends, O-shaped bends, spiral bends and the like, so that micro-fine complex inner runners cannot be finished;

in addition, as for (4) and (5), chemical, electrochemical, plasma polishing and other methods can generate various corrosion and deterioration layer defects on the microstructure of the channel substrate material, and corrosive liquid and reaction gas can have adverse effects on the environment and equipment; meanwhile, (4) and (5) are also flexible processing means, and also face similar defects of (3), the surface can be slightly brightened and improved, and the step effect of the surface, the surface roughness reduction and the large-scale peeling of powder, particles and burrs adhered to the surface cannot be obviously improved even if the material removal amount is large.

As described above, the inventors have made extensive studies and found that the above-described processing method is hardly applicable to the finishing process of the fine inner flow path because it is difficult to deeply finish the inner portion of the fine inner flow path and/or the finishing quality is not satisfactory in the structure of the fine inner flow path.

Based on the above, the inventor has further studied and invented a surface finishing method for a micro internal flow passage, by using a two-phase flow finishing medium with a liquid phase having a viscosity of less than 1000cP, the flow rate of the two-phase flow finishing medium in the micro internal flow passage>5m/s, and the flow flowing into the micro inner flow channel at one end of the micro inner flow channel to reach the saturation value of the flow which can be contained by the caliber of the micro inner flow channel, and the hydraulic pressure in the inner flow channel is in a pressure-holding state to form a means of the saturation flow of the liquid relative to the micro inner flow channel, namely, the difficult problem of the finishing processing of the micro inner flow channel is solved through the synergistic action of the low-viscosity liquid phase, the fluid flow velocity of the finishing medium and the saturation flow. The principle is that firstly, due to the synergistic action of the low-viscosity liquid phase, the fluid flow velocity and the saturated flow, the finishing medium can smoothly enter the fine and complex inner flow passage and is in the fine and complex inner flow passageA state similar to that of non-Newtonian fluid is formed in the complex inner flow channel, a fluid boundary layer is parallel to the surface of the inner flow channel, and the surface salient point target processing is realized by abrasive particle shearing friction in the hard non-Newtonian fluid like a cutter. In addition, the three components have synergistic effect, so that the friction micro-cutting force generated by the abrasive particles in the polishing medium and the surface of the fine and complicated inner flow passage can be obtained without being limited by the material of the fine and complicated inner flow passage, the optimal surface roughness can be consistent with the average contact length range of the abrasive particle blade tip, and even the optimal surface roughness can be realizedRThe a is the super mirror surface quality of 0.05 mu m, which breaks through the limitation of the principle of abrasive flow and water jet technology, and the principle is that the cutting mechanism of the abrasive flow technology is the volume force generated by the extrusion surface of abrasive particles, so pits and pocks are easy to appear in the metal and high polymer flexible materials with low processing hardness (theRa>0.8 μm). In the abrasive water jet technology, the cutting force is the erosion force generated by the impact of abrasive particles on the surface, and the processed soft metal is easy to coarsen the surface (Ra>0.8μm)。

In order to develop a polishing device corresponding to the above surface polishing method, the inventors found that the polishing device needs to provide a large pressure to the polishing medium to ensure a sufficient speed of the polishing medium to achieve a "knife-like" hard fluid shear friction and a surface bump targeted processing, and under a large pressure condition, the requirements on the pressure precision and the fluctuation range are high to avoid the grinding and polishing runaway of the polishing medium and obtain a desired polishing effect, and the inventors found that the sealing of the polishing system and the service life of the corresponding sealing system are also problems to be solved because the two-phase flow polishing medium has a strong abrasive action on the sealing system under a high pressure.

Based on the above, through intensive research, the inventor designs a vertical and horizontal combined device structure, specifically, a vertical thrust system and a sealing system are adopted, a horizontal conveying pipeline system is combined, a vertical structure formed by a vertical plunger pump and a vertically moving piston and a horizontal structure of a conveying pipeline are adopted in a finishing device, and the vertical structure and the horizontal structure cooperate to ensure the pressure stability of a finishing medium in the finishing process, so that a reliable finishing effect is realized. Particularly, the vertical plunger pump, the vertical structure of the piston and the cylinder body and the elbow structure are correspondingly connected with the horizontal conveying pipeline and the workpiece, namely, a vertical and horizontal combined framework is adopted in the finishing device, so that the gravity action can be skillfully utilized, the vertical plunger pump, the piston and the cylinder body are not influenced by the gravity side-tipping force, the provided pressure is very stable, and meanwhile, a larger operable workbench space is provided for the finishing processing of the workpiece; in addition, the conveying pipeline adopts a structure that the length-diameter ratio is greater than 10:1, the caliber of an outlet end is greater than 3mm, and the sectional area ratio of a front-stage pipeline to a rear-stage pipeline of two adjacent stages of pipelines of the multi-stage pipeline is greater than 1, so that the conveying of the saturated flow of the conveyed finishing medium is realized, and the pressure stability of the finishing medium in the conveying pipeline is ensured. In addition, through the synergistic effect of the means that the grooves in the sealing system correspond to the sealing rings and the clearance between the piston and the cylinder body is 1 mm-2.5 mm, the sealing system can well seal the polishing medium, the piston can be smoothly pushed when the polishing medium is pushed, and the balance of the sealing performance, the pushing performance and the service life of the sealing system is realized.

It can be understood that the surface finishing device for the inner flow channel disclosed in the embodiment of the present application is helpful to solve the problem that the fine inner flow channel with a small inner diameter (less than or equal to 3mm) and a large long diameter (greater than or equal to 50:1) cannot be finished by the surface finishing by providing a stable pressure with a large pressure, so as to obtain the optimal roughness of the surface of the inner surfaceRa is smaller than or equal to 1.6 mu m, the workpiece can be provided with a three-dimensional micro complex inner flow passage workpiece with S-shaped bend, L-shaped bend, U-shaped bend, O-shaped bend and spiral bend, such as fuel nozzles of various engines of aviation/aerospace/ships/automobiles, heat exchangers, hydraulic components and oil way control throttlers. In addition, it is understood that the disclosure of the embodiments of the present application is not only applicable to the described surface finishing method, but also applicable to other fluid processing methods requiring high pressure and stability.

It is to be construed that the terms "caliber", "length" in this context mean equivalent caliber as well as equivalent length, the aspect ratio being the ratio of equivalent length to equivalent caliber. The equivalent caliber, the cross section shape of the inner runner can be round, oval and the like, and the cross section outline is formed by a closed curve (non-broken line). The cross section of the inner runner can also be rectangular, triangular and the like, and the cross section outline is formed by a closed broken line. The cross-sectional profile is composed of any closed curve (non-broken line) or closed broken line, and the cross-sectional profile is of an irregular shape, so that an equivalent caliber is introduced, the equivalent caliber is defined as an ideal circle which is equal to the actual cross-sectional area of any cross-sectional shape, and the diameter of the ideal circle is the equivalent caliber. The equivalent length refers to the full path that the fluid in the inner flow passage takes to actually flow between the two ports of the inner flow passage.

First, a surface finishing method of a micro internal flow channel to which the finishing device of the present application can be applied is described to facilitate understanding of the effect of the finishing device.

Referring to fig. 1, the present application provides a surface finishing method of an inner fluid pathway, including:

adopting a liquid-solid two-phase flow finishing medium, wherein the liquid phase viscosity of the finishing medium is less than 1000cP, and the solid phase is abrasive particles;

applying a preset pressure to the finishing medium to enable the finishing medium to flow in the micro inner flow channel at a flow speed of more than 5m/s, wherein the finishing medium flows into the flow of the micro inner flow channel at one end of the micro inner flow channel to reach a saturation value of the flow which can be contained by the caliber of the micro inner flow channel, and the hydraulic pressure in the inner flow channel is in a pressure-holding state;

the liquid herein has a property of viscosity <1000cP, and the numerical value of viscosity in the present application refers to the wustite viscosity at normal temperature (around 25 degrees celsius). The optimal value of the viscosity of the liquid phase corresponding to the finishing method corresponding to the fine internal flow passages with different materials, sizes and initial average roughness can be obtained by continuously increasing the viscosity on the basis of a lower limit value. The lower limit value of the viscosity of the current embodiment is about 50cP, and the inventor obtains the viscosity of the liquid phase at least at 50cP for the common material such as a titanium alloy, a high-temperature alloy, steel, ceramic, an aluminum alloy, a polymer material and other fine internal flow channels through a large amount of test data, and the roughness target value is reached after the finishing. The threshold value of 1000cP is not an optimum value, but a limit value at which the polishing medium continuously, smoothly and stably flows in the fine internal flow channel.

The liquid phase described in the examples, taking the water-based liquid phase as an example, adds a certain tackifier on the basis of deionized water to make the water-based liquid have a certain viscosity. The water-based liquid has the advantages of low cost, easy acquisition, environmental protection and easy cleaning of the finishing medium after finishing. It is understood, however, that the liquid phase is not limited to water-based liquids, as long as the viscosity is metμ<1000cP of liquid.

The material of the solid-phase abrasive grains may be a common abrasive grain material such as carbide ceramics: including silicon carbide, tungsten carbide, and the like; oxide ceramics: including alumina, zirconia, ceria, and the like; nitride ceramics: including boron nitride, chromium nitride, and the like; natural minerals: including diamond/sand, mica, quartz, olivine, and the like. Preferably, the material can be one or more of diamond/sand and oxide ceramic.

In selecting the particle diameter and the mass concentration of the abrasive grains, the range in which the optimum value is obtained is generally increased stepwise on the basis of a lower limit value. If the particle size and the mass concentration of the abrasive particles are lower than the lower limit value, an expected polishing effect cannot be achieved, that is, the fine inner channel cannot reach a target value of surface roughness, the principle is that if the particle size is too small, the mass of the abrasive particles per se is too low, sufficient kinetic energy cannot be generated to achieve effective polishing, if the mass concentration is too small, the probability of a grinding surface processing point is reduced, and effective polishing cannot be achieved, the lower limit value is generally conservative, for example, any one lower limit value is selected conservatively on the premise that the particle size upper limit value is not exceeded, the lower limit value of the ratio of the caliber of the inner channel to the particle size of the abrasive particles is generally 20, that is, when at least 20 abrasive particles are ensured to pass through in parallel, that is, the upper limit value of the particle size of the abrasive particles is generally 1/20 of the caliber of the inner channel, and the lower limit value of the abrasive particles is generally 1/5 of the upper limit value. The lower limit value of the mass concentration of the abrasive particles is generally 10g/L, and the selection of the lower limit value is generally conservative because the pressure of the system is high, if the abrasive particles are blocked, the workpiece and the system can be scrapped, and even the workpiece and the system can be choked and exploded. Therefore, on the basis of the specified lower limit, the particle size and the mass concentration of the abrasive particles are gradually increased until the flow velocity and the flow rate are reduced due to the obvious flow resistance caused by the overlarge particle size or the overlarge mass concentration of the abrasive particles, and the flow velocity is influenced by the mutual collision among the abrasive particles, so that the flow velocity and the flow rate are reduced and the grinding effect are reduced, namely, the optimal value can be obtained through experiments on the basis of the lower limit.

Applying a predetermined pressure to the polishing medium to make the polishing medium in the fine inner flow channel>A flow velocity of 5 m/s. The predetermined pressure here means that the pressure is used in the initial state of the polishing process so that the polishing medium is in the interior of the fine inner flow channel>The flow velocity of 5m/s flows, the roughness of the surface of the inner flow channel is reduced along with the polishing, and the flow velocity of the polishing medium in the fine inner flow channel is faster and faster under the same pressure condition. It will be appreciated that the predetermined pressure is a range concept, as the flow rate achieved is a range, rather than applying only a specific value to the polishing medium. The flow velocity of the polishing medium in the micro inner flow channel is measured, immersion measurement cannot be adopted, and otherwise, any sensor probe can be damaged by abrasive particles. The method of ultrasonic speed measurement can be adopted, and the Hargen-Poarson law of viscous fluid can also be utilized:

performing indirect measurement; in the formula, whereinDIs the caliber of the inner flow passage,lthe length of the micro inner flow passage is,pis the pressure difference acting on two ends of the fine internal flow passage, i.e. hydraulic pressurep，Re is the Reynolds number of the gas,u _m is the liquid phase flow rate in the water-based two-phase flow,ρ _l the flow rate of the liquid phase is approximately equal to the flow rate of the polishing medium, which is the density of the liquid phase.

The flow rate of the polishing medium is greater than 5m/s, according to the critical conditions for the theoretical formation of non-newtonian fluids and the critical values obtained by the inventors for long-term practice. Engineering hydrodynamics data indicate (e.g. book data: poplar, wanning, what light, etc. engineering hydrodynamics [ M ] oil industry press, 2006.) that the viscosity of pure water of 1cP reaches the critical motion flow rate >16.6M/s of the non-newtonian fluid, whereas the lower limit of the viscosity of the liquid phase of this example is 50cP, greater than 1cP, so the critical flow rate of the non-newtonian fluid is less than 16.6M/s. Meanwhile, in combination with practical results, the inventors found that the ideal processing effect cannot be obtained when the processing time is less than 5m/s, and thus the critical value is 5 m/s.

The polishing medium flows into the inner flow of the micro inner flow channel at one end of the micro inner flow channel to reach a saturated value of the flow which can be contained by the caliber of the micro inner flow channel, and the hydraulic pressure in the inner flow channel is in a pressure holding state, namely a state of the saturated flow in the field.

The term "saturation value of the contained flow rate" and "state of the saturated flow rate" as used herein means that the fluid flows into the pipe so as to fill the cross section of the pipe, which contains the maximum number of fluid molecules in parallel.

It can be understood that the beneficial effects of adopting the above embodiment of the finishing method are as follows:

the flow velocity of the two-phase flow polishing medium in the micro inner flow channel is realized by adopting the liquid with the viscosity of the liquid phase of the polishing medium being less than 1000cP>5m/s and the flow flowing into the micro inner flow channel at one end of the micro inner flow channel to reach the saturation value of the flow which can be contained by the caliber of the micro inner flow channel, the hydraulic pressure in the inner flow channel is in a pressure-holding state, and a means of forming the saturation flow of the liquid relative to the micro inner flow channel is formed, namely the difficult problem of finishing the micro inner flow channel is solved through the synergistic action of a low-viscosity liquid phase, the flow velocity of the liquid and the saturation flow. The principle of the method is that firstly, due to the synergistic action of a low-viscosity liquid phase, a fluid flow velocity and a saturated flow, a finishing medium is in a low-viscosity high-flow-velocity state, so that the finishing medium can smoothly enter a micro inner flow channel and form a non-Newtonian fluid state in the micro inner flow channel, a fluid boundary layer is parallel to the surface of the inner flow channel, the surface salient point target processing is realized by abrasive particle shearing friction in the hard liquid phase like a cutter, and the surface salient point and the saturated flow in the flexible processing are overcome in principleThe concave points are simultaneously processed and can only brighten slightly, simultaneously because the abrasive particles of the polishing medium and the micro-cutting force generated by the friction of the surfaces of the micro-inner flow channels can obtain the optimal surface roughness consistent with the average contact length range of the abrasive particle blade tips without being limited by the materials of the micro-inner flow channels, the limitation of the principles of abrasive particle flow and water jet technology is broken through, the principle is that the cutting mechanism of the abrasive particle flow technology is the volume force generated by the abrasive particles extruding the surfaces, and pits and pocks (are easy to occur in the processing of metal and high polymer flexible materials with low hardness (the principle is that the abrasive particle flow technology is the volume force generated by the abrasive particle extruding the surfaces), so that pits and pocks (the pock) are easy to occur in the processing of metal and high polymer flexible materials with low hardnessRa>0.8 μm). In the abrasive water jet technology, the cutting force is the erosion force generated by the impact of abrasive particles on the surface, and the processed soft metal is easy to coarsen the surface (Ra>0.8 μm). In addition, the low-viscosity high-flow-rate fluid dynamics shape following processing mode enables the positions, which do not accord with fluid engineering, of the surface steps, the sharp corners, the geometric outline curvature and the like of the inner flow passage to be ground and polished more heavily, and the inflection points, the sharp edges, the geometric outline curvature and the hole patterns of the inner flow passage realize geometric streamline shaping, so that the fluid motion performance of the inner flow passage is further improved. In addition, the above embodiment proposes that the critical flow rate for realizing the targeted processing of the surface salient points by using the flow rate of the finishing medium to realize the hard non-Newtonian fluid like a cutter and the shear friction of the abrasive particles is 5 m/s.

As for the processing time of the finishing medium in the fine internal flow channel, the finishing medium may finish the fine internal flow channel in a standard time period until the optimal roughness of the surface of the fine internal flow channel is a target value. The standard time period may be a predetermined continuous time period, or may be a plurality of discontinuous time periods, or may be a non-predetermined continuous time period after the start, and after the flow rate of the finishing medium reaches the flow rate corresponding to the target value of the surface optimal roughness of the micro internal flow channel, the finishing process is automatically stopped. The meaning of the surface optimum roughness is a target value, and the surface optimum roughness is not limited to be directly measured, but can be indirectly characterized, for example, as described above, the flow velocity, flow quantity and the like of the polishing medium in the inner part of the micro inner flow channel can be characterized. The above target value refers to the set surface optimum roughness value, which generally refers to the requirement for the final surface optimum roughness of the fine internal flow channel, but does not exclude the requirement for further finishing after the above finishing step, in which case the set surface optimum roughness value is not the final surface optimum roughness value.

In summary, the finishing method described in the above embodiments solves the problem of finishing the micro internal flow channel with a caliber less than or equal to 3mm and a length-diameter ratio greater than or equal to 50:1, which exists in the industry for a long time, by combining the hydraulic pressure systems built at the two ends of the internal flow channel to be processed and the means of achieving the saturated flow rate of the internal flow channel to be processed and the micro-cutting mechanism generated by the high-speed friction of the abrasive particles on the surface of the internal flow channel in the two-phase flow by using the low-viscosity and high-speed solid-liquid two-phase fluid.

Referring to fig. 2 to 4, in some embodiments, a polishing apparatus 100 is provided, including: thrust system 101, a plurality of sealing system 102, a plurality of transfer pipe-line system 103.

Each sealing system 102 comprises a piston 21, a cylinder 18 cooperating with the piston 21 for receiving the finishing medium 8 for finishing, and a thrust system 101 communicating with one end of the piston 21 for providing a driving force to the piston 21 to push the finishing medium 8 out of an outlet end 190 of the cylinder 18.

Each of the conveying pipe systems 103 conveys the polishing medium 8 contained in the corresponding sealing system 102 to different ports of the inner flow channel workpiece 34 for polishing, for example, one group of the sealing systems 102 and the conveying pipe system 103 shown in fig. 2 correspond to an inlet and another group of the inlet and the outlet of the workpiece 34, so that the sealing systems communicate with each other through the workpiece 34. The upstream end of the conveying pipeline system 103 is connected with the outlet end 190 of the sealing system 102, the downstream end is used for outputting the inner flow channel workpiece 34 for finishing by the finishing medium 8, the length-diameter ratio of the conveying pipeline system 103 is larger than 10:1, the caliber of the outlet end is larger than 3mm, the conveying pipeline system 103 is provided with a plurality of stages of pipelines, and the cross-sectional area ratio of the front stage pipeline to the rear stage pipeline of the adjacent two stages of pipelines is larger than 1.

The thrust system 101 includes a vertical plunger pump 5, the vertical plunger pump 5 is connected with a piston 21 to provide a driving force so that the piston 21 can move relative to the cylinder block 18 along a vertical direction, the multistage pipeline includes a first-stage pipeline 22 and a second-stage pipeline 23 adjacently connected at a downstream of the first-stage pipeline, the first-stage pipeline includes an elbow structure connected with an outlet end 190 of the cylinder block 18, and the elbow structure is connected with the horizontally extending second-stage pipeline 23, so that a combination of a vertical structure and a horizontal structure is realized.

The thrust system 101 may be a hydraulic system, as shown in fig. 2, and includes a motor 1, a hydraulic oil tank 2, a hydraulic pump 3, a pressure booster 6, a vertical plunger pump 5, and an oil pipe 4, where the motor 1 drives the hydraulic pump 2 to pump hydraulic oil at a certain pressure from the oil tank 2, and the hydraulic oil pressurized by the pressure booster 6 is delivered to the vertical plunger pump 5. The vertical plunger pump 5 is connected with the piston 21 through the ball 13 to drive the piston 21 to push the finishing medium 8 to be output from the output end 190 of the cylinder 18. The hydraulic system driven by the motor is large in thrust and high in thrust precision.

In the structure of the vertical plunger pump 5, the sealing system 102 is also required to be vertical, that is, the piston 21 moves in the vertical direction relative to the cylinder 18, but the workpiece 34 is required to be horizontal, so that the direction change can be performed by the conveying pipeline system.

The vertical structure formed by the vertical plunger pump and the vertically moving piston and the horizontal structure of the conveying pipeline are adopted in the finishing device, and the pressure stability of a finishing medium in the finishing process is guaranteed through the cooperation of the vertical plunger pump and the horizontal structure, so that the reliable finishing effect is realized. Particularly, the vertical plunger pump, the vertical structure of the piston and the cylinder body and the elbow structure are correspondingly connected with the horizontal conveying pipeline and the workpiece, namely, a vertical and horizontal combined framework is adopted in the finishing device, so that the gravity action can be skillfully utilized, the piston and the cylinder body of the vertical plunger pump are not influenced by the gravity side-tipping force, the provided pressure is very stable, and meanwhile, a larger operable workbench space is provided for the finishing processing of the workpiece; in addition, the conveying pipeline adopts a structure that the length-diameter ratio is larger than 10:1, the caliber of an outlet end is larger than 3mm, and the sectional area ratio of a front-stage pipeline to a rear-stage pipeline of two adjacent stages of the multi-stage pipelines is larger than 1, so that the conveying of the saturation flow of the conveyed finishing medium is realized, and the pressure stability of the finishing medium in the conveying pipeline is ensured.

A plurality of sealing systems 102 are employed to communicate with the workpiece 34, i.e., to effect fluid exchange through the workpiece 34 with the plurality of sealing systems 102 communicating with one another, i.e., one sealing system 102 outputs the finishing medium 8 to the workpiece 34, the other sealing system 102 receives the finishing medium 8 flowing from the workpiece 34, when the polishing medium 8 of one sealing system 102 is completely consumed, the other sealing system 102 can continue polishing the workpiece 34 by receiving the polishing medium 8 through it in the reverse direction to that before, i.e. the further sealing system 102 now outputs the finishing medium 8 to the workpiece 34, while the depleted sealing system 102 now receives the finishing medium 8 flowing out of the workpiece 34, this allows always at least one finishing medium 8 contained in the sealing system 102 to be supplied to the workpiece 34, ensuring that the finishing operation is carried out continuously and uninterruptedly on the workpiece 34, so that the finishing process is efficient.

As shown in fig. 2, the finishing device 100 may further include an operation module including a touch operation display screen 10, a start/stop switch 9 for turning on or off the device, and an emergency stop switch 11 for forcibly turning off the device, and an operation table 12 for externally connecting a processing operation module and the like.

The number of sealing systems 102 and delivery pipe systems 103 is illustrated as two, but not limited to, the number of thrust systems 101 may be one for each sealing system 102 illustrated in the figure.

The cylinder 18 is limited in space by a bottom plate and a top plate 19, the bottom plate and the top plate 19 can be connected to the cylinder 18 by bolts 7, the space between the piston 21 and the top plate 19 contains the finishing medium 8, and the opening of the top plate 19 is the outlet end 190 of the sealing system 102. The diameter ratio of the cylinder 18 to the outlet end 190 is 10-32 to further pressurize the optical finishing medium. Referring to fig. 4, in some embodiments, the ratio of the cross-sectional area of the first-stage pipeline 22 to the cross-sectional area of the second-stage pipeline 23 may be 1.2 to 1.8, so that the polishing medium can be stably and slowly pressurized and the saturation flow can be always maintained. In some embodiments, the multi-stage pipeline may further include a third stage pipeline 32 adjacently connected downstream of the second stage pipeline 22, the cross-sectional area ratio of the second stage pipeline 22 to the third stage pipeline 32 is 1.2-1.8, and as shown, the length of the third stage pipeline 32 may be short, similar to the form of a joint. By adopting a three-stage pipeline structure, the sectional area ratio of each stage is 1.2-1.8, stable and slow pressurization is realized, the saturated flow is always kept, the condition of providing stable pressure for the finishing medium is ensured, and the strength reliability and the service life of the conveying pipeline system 103 are also ensured.

Referring to fig. 4, in some embodiments, the finishing device may further include a tool 31, the tool 31 has at least two ports 310 corresponding to at least one inlet and at least one outlet of the workpiece 34, the tool 31 may be stably and fixedly installed by a three-axis clamp 33 on the worktable, and the workpiece 34 may be clamped and fixed inside the tool 31 by a tool clamping bolt 30. The aperture of the third pipeline 32 and the cross-sectional area ratio of the port of the tool 31 connected with the third pipeline can be 1.2-2.2, so that the beneficial effects are similar to those of the above, stable and slow pressurization is realized, and the saturated flow is always kept. It is noted that the upper limit of the port cross-sectional area ratio of the tool 31 to which the third pipe 32 is connected may be 2.2, which is higher than the upper limit of the cross-sectional area ratio between the pipes by 1.8, because the tool 31 is generally frequently replaced, which requires less strict service life than the pipes, and thus the upper limit of the cross-sectional area ratio may be set larger. In some embodiments, the ratio of the cross-sectional area of the tooling port to the cross-sectional area of the workpiece 34 port should be greater than 1, but not greater than 10, and both may be sealed with an epoxy seal. If the ratio is larger than 1, the flow channel in the workpiece can reach the saturation flow, but if the ratio is too large, the inventor finds that the pressure relief of the port of the workpiece 34 is too large, the strength and the sealing requirement of the joint of the port and the workpiece are high, and even the safety accidents of fracture of the joint exist, and therefore the ratio is not more than 10. It can be understood that a plurality of ports 310 suitable for internal flow passages of workpieces with different calibers can be reserved on the tool 31. When one of the ports is used, the other unused ports can be bolted for connection and blocking. The clamping bolt 30 of the tool 31 comprises an upper clamping bolt and a lower clamping bolt, and can clamp workpieces 34 with different specifications and sizes, and adjust a tool port and a workpiece inner flow passage port to be on the same axis with the tool port and a multistage pipeline port.

The inventor finds that by adopting the multi-stage pipeline conveying pipeline system, the structure of the thrust system combining the hydraulic pump and the vertical plunger pump and the framework combining the vertical type and the horizontal type, the high precision (with the error of 0.01MPa) can be realized under the condition of providing the thrust above 50MPa, the pressure fluctuation in the operation is small and is between plus or minus 0.1 percent, and the finishing method described in the previous embodiment can be very effectively realized.

Referring to fig. 2 and 3, for the sealing system 102, the inventor found that the problem of tightness between the piston 21 and the wall of the cylinder 18 is particularly important because of the need to provide a large pressure to the polishing medium, and that the tightness is ensured while ensuring that the movement of the piston 21 along the inner wall of the cylinder 18 is smooth.

The piston 21 at least has a first groove 211 and a second groove 210 from the top to the bottom, the sealing system 102 further comprises a sealing ring between the piston 21 and the cylinder 18, the sealing ring comprises a first sealing ring 17 arranged in the first groove 211 and a second sealing ring 170 arranged in the second groove 210, the gap between the piston 21 and the cylinder 18 in the radial direction is 1 mm-2.5 mm, the structure of multi-stage grooves and multi-stage sealing rings and the gap between the piston and the cylinder is 1 mm-2.5 mm is adopted, so that the first-stage sealing ring can filter abrasive particles in two-phase flow, and the second-stage sealing ring seals a pure liquid phase, such as a water-based liquid phase, thereby realizing good sealing performance on the polishing medium, and in the gap range of 1 mm-2.5 mm, the inventor finds that not only good sealing effect can be maintained, but also the piston can be ensured to smoothly move along the wall surface of the cylinder 18, pushing the finishing medium 18 out.

Continuing to refer to fig. 3, the first groove 211 of the piston 21 is a split structure, the top surface 212 of the body of the piston 21 is a plane, the cover plate 20 is detachably disposed on the plane, the periphery of the cover plate 20 is provided with an inclined surface 201, and the inclined surface 201 and the top surface of the piston 21 form a single-side inclined slot to form the first groove 211; the second groove 210 is formed in the side wall of the piston, the first seal ring 17 is made of a hard polymer material, and the second seal ring 170 is made of a soft polymer material. The principle of this is that the inventor found that, because of the high pressure, no matter how the first seal ring is sealed, abrasive grains are inserted from the gap between the cylinder wall and the seal ring to scratch the seal ring, and therefore, the structure of the single-sided inclined groove and the hard seal ring is provided, and the abrasive grains are guided to be actively inserted/scraped into the first seal ring 17 to form an inserted self-sealing structure, and therefore, the first seal ring 17 is made of a hard polymer material. After the first seal ring 17 is actively embedded with most of the abrasive particles, the substance to be sealed by the second seal ring 170 is a liquid phase in a two-phase flow, so that the second seal ring 170 is used for sealing. First recess 211 needs be split type structure because the inventor discovers, because first sealing washer 17 adopts stereoplasm macromolecular structure, and receives very big pressure, if adopt and directly set up the recess at the piston lateral wall, then unable fixed first sealing washer 17, consequently adopts split type structure, when the equipment, earlier sets up first sealing washer in the top surface 212 of the body of piston 21, later compresses tightly through bolt 7 at apron 20 of covering. In some embodiments, the angle of inclination of the single-sided chute, i.e., the ramp 201, is greater than 60 ° to provide sufficient compressive force.

In some embodiments, the specific materials of the first and second seal rings 17 and 170 may be such that the polymer material of the first seal ring satisfies: the flexural modulus is 1.9GPa to 3.6GPa, the elongation is 60 percent to 120 percent, and the Knoop hardness is 90HK-100 HK. Therefore, the first sealing ring 17 has certain rigidity and is not easy to deform obviously, and meanwhile, the first sealing ring has good surface self-lubricating property, low extrusion contractility and abrasive particles can be embedded into the material well, and the abrasive particles are easy to continuously slide in the material after being embedded. The polymer material of the second seal ring 170 satisfies: the bending modulus is 0.2 GPa-0.25 GPa, the elongation is 300% -380%, and the bending strength is 80-100 MPa, so that the second sealing ring 170 has good elasticity and can generate obvious telescopic deformation, and meanwhile, the second sealing ring has the advantages of good sealing capability on water base and high bending strength due to the fact that the second sealing ring has obvious extrudable contraction length, and is easy to break after moving and bending.

In some embodiments, the material of the first sealing ring 17 may be one of pp, ptfe, nylon, and peek, and the material of the second sealing ring 170 may be one of silicone, rubber, and butyronitrile, which are easily available and low cost.

With continued reference to FIG. 3, the second groove 211 may include at least two grooves from top to bottom, including a first sub-groove 2111 and a second sub-groove 2112, wherein the ratio of the depth of the second sub-groove 2112 to the depth of the first sub-groove 2111 is 1.2-1.5. Further, a third sub-groove 2113 may be further formed in the bottom direction of the second sub-groove 2112, or even more sub-grooves may be further formed. The ratio of the depth of the second sub-groove 2112 to the depth of the third sub-groove 2113 is 1.2-1.5. The second sealing rings 170 correspondingly arranged on the first sub-groove 2111, the second sub-groove 2112 and the third sub-groove 2113 are respectively sealing

rings

16, 15 and 14, the functions of the sealing rings are sealing water, the grooves can be trapezoidal grooves which are easy to process and fix the sealing rings, and the depth of the second sub-groove 2112 is greater than that of the adjacent first sub-groove 2111 and third sub-groove 2113.

With continued reference to FIG. 3, in some embodiments, the cylinder walls of the cylinder block 18 have a coating having a thickness of 50 to 220 μm, a hardness of 1500 to 2200HV, and a material of one or a combination of oxide, carbide, boride and nitride ceramics. The sealing device has the beneficial effect of ensuring the reliability of the sealing effect. The principle of the method is that the inventor finds that during the operation of the device, abrasive particles are mixed in a crack between a sealing ring and a cylinder body to generate friction on the cylinder wall during the high-speed movement of two-phase flow of a fluid phase and an abrasive particle solid phase, and the cylinder wall is rubbed but scratchedThe marks will cause complete failure of the sealing system and leakage of the fluid phase, and the cylinder wall must therefore be hard. The process for realizing the coating introduced above can solve the problem of the wear resistance of the cylinder wall by flame spraying the WC coating in the inner cavity of the special cylinder body. The cylinder body flame spraying WC coating comprises the following specific components: the grain diameter of the WC powder is 15-100 mu m, and the content of the WC powder>85%, 1-4% of molybdenum powder, 1-5% of silicon powder and 1-5% of boron powder, forming a molybdenum-silicon-boron alloy phase in the WC coating after flame spraying and sintering, wherein the molybdenum-silicon-boron alloy has a low friction coefficient, and is doped in the WC coating to serve as a strengthening phase to improve the strength and hardness of the WC coating. Particle temperature during spraying<1500 ℃, the thermal deformation of the heated cylinder body is reduced at low temperature, the dimensional precision of the final cylinder body is ensured, the spraying distance is 10 mm-50 mm, and the smaller spraying distance ensures the binding force of the coating>100 MPa. In some embodiments, the surface of the coating has a roughness ofRa is 0.05-0.4 μm, the roundness of the cylinder body is less than or equal to 100 μm, the cylindricity is less than or equal to 200 μm, and the diameter of the cylinder body is 100-400 mm, so that the coating is prevented from being peeled off due to the side tilting force generated by the relative motion of the piston and the cylinder body, and the service life of a sealing system and the reliability of the sealing effect are further ensured. The process for realizing the effect can be that the surface of the coating is honed, the honing cutter adopts a zirconia ceramic cutter, and the honing rotating speed<80 r/min, and the lower rotating speed ensures that the coating does not peel off, collapse mouth and fall off in the honing process.

With continued reference to fig. 2, the finishing assembly 10 may further comprise a diagnostic device having a flow rate and/or flow sensor and a pressure sensor for sensing the flow rate and/or flow of the finishing medium and the pressure, and thus the status of the finishing process. The sensor may be located at a relatively close distance from the upstream end of the workpiece 34. the principle is that the inventors have found that if the finishing process is performed normally, the flow rate/pressure of the finishing medium at the upstream end of the micro inner flow channel is only affected by the configuration of the inner flow channel and the surface quality of the inner flow channel. The inner flow channel has self flow resistance and flow can generate reaction force to directly act on the flow velocity/flow/pressure at the upstream end. The downstream end of the inner flow passage is larger than the sectional area of the inner flow passage, so that the polishing medium is in an idle-load free flow state to the downstream end after flowing out of the inner flow passage, and the downstream end of the inner flow passage cannot influence the flow speed/flow/pressure of the upstream end. Therefore, the processing quality of the inner flow passage can be reflected only by measuring the change of the inlet speed at the upstream end.

The pressure sensor comprises a high-sensitivity piezoelectric quartz sensor 28 and a high-resolution multi-path data acquisition device 27 which are used for monitoring data of pressure gauges 29 of a plurality of ports in real time, and completely recording quasi-static and high-dynamic pressure processes in a finishing process, so that accurate flow resistance data in each flow channel is obtained, and the optimal finishing effect is ensured. The flow velocity and/or flow sensor comprises a flow velocity flowmeter 24, a flow velocity flow piezoelectric sensor 25 and a flow velocity and flow data collector 26, and the ultrasonic flowmeter based on the Doppler method principle synchronizes the flow velocity and the flow of a plurality of ports by adopting the ultrasonic measurement principle. The ultrasonic wave is non-contact measurement, so that the damage of two-phase flow to the flow velocity flowmeter can be completely avoided, the response sensitivity of the whole system is greatly improved, and the optimal finishing time is obtained.

Although the present invention has been disclosed in the above-mentioned embodiments, it is not intended to limit the present invention, and those skilled in the art may make variations and modifications without departing from the spirit and scope of the present invention. Therefore, any modification, equivalent change and modification of the above embodiments according to the technical essence of the present invention are within the protection scope defined by the claims of the present invention, unless the technical essence of the present invention departs from the content of the present invention.

Claims

1. A finishing device, comprising:

a thrust system;

the thrust system is communicated with one end of the piston and provides driving force for the sealing system so as to push the finishing medium to be output from the outlet end of the cylinder body;

each conveying pipeline system conveys the finishing medium contained in the corresponding sealing system to different ports of the inner runner workpiece for finishing, and the plurality of sealing systems are communicated through the inner runner workpiece; the upstream end of the conveying pipeline system is connected with the outlet end of the sealing system, the downstream end of the conveying pipeline system is used for outputting a finishing medium to an inner flow channel workpiece for finishing, the length-diameter ratio of the conveying pipeline system is greater than 10:1, the caliber of the outlet end is greater than 3mm, the conveying pipeline system is provided with a plurality of stages of pipelines, and the sectional area ratio of a front stage pipeline to a rear stage pipeline of two adjacent stages of pipelines is greater than 1;

the thrust system of the finishing device comprises a vertical plunger pump, the vertical plunger pump is connected with the piston to provide driving force, so that the piston can move relative to the cylinder body along the vertical direction, the multistage pipeline comprises a first-stage pipeline and a second-stage pipeline which is adjacently connected at the downstream of the first-stage pipeline, the first-stage pipeline comprises an elbow structure connected with the outlet end of the cylinder body, and the elbow structure is connected with the horizontally extending second-stage pipeline;

the piston is at least provided with a first groove and a second groove from the top to the bottom, the sealing system further comprises a sealing ring positioned between the piston and the cylinder body, the sealing ring comprises a first sealing ring arranged in the first groove and a second sealing ring arranged in the second groove, and the radial gap between the piston and the cylinder body is 1-2.5 mm; the first groove is of a split structure, the top surface of the piston is a plane, a cover plate is detachably arranged on the top surface of the piston, an inclined surface is arranged on the periphery of the cover plate, and a single-side inclined groove is formed by the inclined surface and the top surface of the piston to form the first groove; the second groove is formed in the side wall of the piston; the first sealing ring is made of hard materials, and the second sealing ring is made of soft materials.

2. The polishing apparatus as set forth in claim 1, wherein the ratio of the cross-sectional area of the first-stage pipe to the cross-sectional area of the second-stage pipe is 1.2 to 1.8.

3. The skin pass device of claim 2, wherein the plurality of stages of piping further comprises a third stage piping adjacently connected downstream of the second stage piping, and a ratio of a cross-sectional area of the second stage piping to a cross-sectional area of the third stage piping is 1.2 to 1.8.

4. The finishing device of claim 3, further comprising a tool, wherein the tool is provided with a port, the cross-sectional area ratio of the third-stage pipeline to the port of the tool is 1.2-2.2, and the cross-sectional area ratio of the port of the tool to the port of the flow channel in the workpiece is 1.2-10.

5. The optical finishing device of claim 1, wherein the second grooves comprise at least two grooves in a top-to-bottom direction, including a first sub-groove and a second sub-groove, wherein a ratio of a depth of the second sub-groove to a depth of the first sub-groove is 1.2 to 1.5.

6. The finisher apparatus of claim 1, wherein the single edge chute has an inclination angle greater than 60 °.

7. The finishing apparatus of claim 1, wherein the first seal ring is made of a material selected from the group consisting of: the flexural modulus is 1.9GPa to 3.6GPa, the elongation is 60 percent to 120 percent, and the Knoop hardness is 90HK to 100 HK; the material of the second sealing ring satisfies that: the flexural modulus is 0.2GPa to 0.25GPa, the elongation is 300 percent to 380 percent, and the flexural strength is 80MPa to 100 MPa.

8. The finishing apparatus of claim 7, wherein the first sealing ring is made of one of pp, ptfe, nylon, and peek, and the second sealing ring is made of one of silicone, rubber, and nitrile.

9. A finishing device as claimed in claim 1, characterized in that the cylinder wall of the cylinder block is provided with a coating having a thickness of 50 μm to 220 μm, a hardness of 1500HV to 2200HV and a material of one or a combination of oxide, carbide, boride and nitride ceramics.

10. The finishing apparatus of claim 9,the surface of the coating has a roughness ofRa is 0.05-0.4 μm, the roundness of the cylinder body is less than or equal to 100 μm and the cylindricity is less than or equal to 200 μm.

11. A finishing device as claimed in claim 1, characterized in that it further comprises a diagnostic device with a flow rate and/or flow sensor and a pressure sensor for sensing the flow rate and/or flow and the pressure of the finishing medium.

12. The finishing apparatus of claim 1, wherein the finishing medium comprises a liquid phase having a viscosity <1000cP and a solid phase comprising abrasive particles, the finishing article is a micro-scale internal flow channel member having an aperture of 3mm or less and an aspect ratio of 50:1 or greater.

13. A method for finishing an internal flow passage member, comprising using the finishing apparatus according to any one of claims 1 to 12, wherein the finishing medium comprises a liquid phase and a solid phase, the viscosity of the liquid phase is less than 1000cP, the solid phase comprises abrasive particles, the finished workpiece is a fine internal flow passage member, the caliber of the fine internal flow passage member is less than or equal to 3mm, and the length-diameter ratio of the fine internal flow passage member is greater than or equal to 50:1, the thrust system of the finishing apparatus applies a predetermined pressure to the finishing medium, so that the finishing medium flows in the fine internal flow passage at a flow rate of greater than 5m/s, and the flow rate of the finishing medium flowing into the fine internal flow passage at one end of the fine internal flow passage reaches a saturation value capable of accommodating the flow rate of the caliber of the fine internal flow passage, so that the hydraulic pressure in the internal flow passage is in a pressure-holding state.

14. A sealing system for a finishing assembly as claimed in any one of claims 1 to 12, comprising:

the piston can reciprocate along the extending direction of the cylinder wall of the cylinder body, and a thrust system is communicated with one end of the piston and provides driving force for the piston;

the sealing system comprises a piston, a cylinder body and a sealing system, wherein the piston at least comprises a first groove and a second groove from the top to the bottom, the sealing system also comprises a sealing ring positioned between the piston and the cylinder body, the sealing ring comprises a first sealing ring arranged in the first groove and a second sealing ring arranged in the second groove, and the radial gap between the piston and the cylinder body is 1-2.5 mm;

the first groove is of a split structure, the top surface of the piston is a plane, a cover plate is detachably arranged on the top surface of the piston, an inclined surface is arranged on the periphery of the cover plate, and a single-side inclined groove is formed by the inclined surface and the top surface of the piston to form the first groove; the second groove is formed in the side wall of the piston.