CN106475915B - The thermostatically-controlled equipment and its method of class joint prosthesis part curved surface turbulent flow polissoir - Google Patents
The thermostatically-controlled equipment and its method of class joint prosthesis part curved surface turbulent flow polissoir Download PDFInfo
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- CN106475915B CN106475915B CN201610980440.7A CN201610980440A CN106475915B CN 106475915 B CN106475915 B CN 106475915B CN 201610980440 A CN201610980440 A CN 201610980440A CN 106475915 B CN106475915 B CN 106475915B
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- joint prosthesis
- profiling
- wave
- prosthesis part
- electromagnetic wave
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Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24C—ABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
- B24C7/00—Equipment for feeding abrasive material; Controlling the flowability, constitution, or other physical characteristics of abrasive blasts
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24C—ABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
- B24C1/00—Methods for use of abrasive blasting for producing particular effects; Use of auxiliary equipment in connection with such methods
- B24C1/08—Methods for use of abrasive blasting for producing particular effects; Use of auxiliary equipment in connection with such methods for polishing surfaces, e.g. smoothing a surface by making use of liquid-borne abrasives
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B24—GRINDING; POLISHING
- B24C—ABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
- B24C3/00—Abrasive blasting machines or devices; Plants
- B24C3/32—Abrasive blasting machines or devices; Plants designed for abrasive blasting of particular work, e.g. the internal surfaces of cylinder blocks
Abstract
The invention discloses the thermostatically-controlled equipments and its method of a type joint prosthesis part curved surface turbulent flow polissoir, including glass restraint component, electromagnetic wave heating matrix, supporting rack and electromagnetism wave controller, the electromagnetic wave heating matrix is mounted on the side of the glass restraint component, the electromagnetic wave heating matrix includes multiple wave heaters, the shape of multiple wave heater distributions is identical as projection of shape of the profiling runner on class joint prosthesis part side, each wave heater is installed on supporting rack, and profiling runner described in the equal face of each wave heater.The present invention in the side of glass restraint component by placing electromagnetic wave heating matrix, increase the tubulence energy and speed of abrasive Flow cutting fluid, compensate the linear loss of abrasive Flow and head loss in profiling runner, so as to improve the effect of overall processing, be during overall processing in the temperature of abrasive Flow keep constant, keep class joint prosthesis part suface processing quality more uniform.
Description
Technical field
The present invention relates to abrasive Flow Machining technical fields, more specifically, a more particularly to type joint prosthesis part curved surface
The thermostatically-controlled equipment and its method of turbulent flow polissoir.
Background technology
Joint prosthesis is that people have lost a kind of artificial organs designed in the joint of function to save, it is in artificial organs
In belong to the best one kind of curative effect.The general common used material of material of joint prosthesis is metal alloy, wherein extraordinary titanium alloy is because of it
Biocompatibility, rotproofness and elasticity modulus etc. are close with skeleton, are suitable for manufacture of intraocular joint.Joint prosthesis surface
Quality determines mantle friction property, and roughness is bigger, and surface micro-bulge is in contact probability increase, and adhesive wear is caused to increase
Greatly.And it is well known that titanic alloy machining craftsmanship is poor, it is difficult to cut.And titanium alloy artificial joint is by the curved surface group of different curvature
At existing precision processing technology is difficult to adapt to the changeable curved surface of curvature, and joint prosthesis is still continued to use the artificial of inefficiency and beaten
Mill.Joint prosthesis is expensive, has been difficult to meet the widespread demand in market.
Abrasive Flow Machining technology is the technology of existing more advanced progress joint prosthesis polishing, abrasive Flow Machining technology
It is a kind of fluid that is formed by structuring runner, and abrasive grain is used to be mixed with liquid for complicated die mold cavity surface using special fixture
Abrasive material constantly washes away the polishing processing method of surface to be machined.In process, soft abrasive fluid is in workpiece surface and constraint
Turbulent flow is formed in the constraint profiling runner of module composition, abrasive grain disorderly hits finished surface under the drive of turbulent flow and reaches
Effect is cut, this polishing method not only overcomes since machining profile is complicated, the tiny processing difficulties brought of scale.Fluid adds
Work method is that logical base fluid driving abrasive grain carries out workpiece surface small plow.Its micro cutting can guarantee complex-curved position
And form accuracy, it prevents that the treatment of surfaces of components is caused affected layer and sub-surface damage occur.
Number of patent application be 201110041218.8 " titanium alloy artificial joint curved surface turbulent flow Precision Machining new method and its
Dedicated unit " provides a kind of partial mulching constraint precision machined new method of formula titanium alloy artificial joint turbulent flow, by with wait for
The prosthese shape of processing it is consistent match mould, form turbulent flow in artificial joint prosthesis outer surface and runner with mould inner surface,
The gradually finishing on surface is realized using the frequent effect of micro- power micro cutting of abrasive grain.But joint prosthesis surface is complicated bent
Face, abrasive Flow are easy to be obstructed when flowing through at joint prosthesis surface inflection point and the catastrophe point of singular point, and closer to the place of curved surface, mill
Grain stream viscous damping reduce tangential velocity pulsation, while it is complex-curved prevent normal velocity to pulse, leave curved surface slightly
The region of far point, due to the increase of abrasive Flow average velocity gradient, the Turbulent Kinetic of abrasive Flow generates rapidly variation so that polishing
It is uneven, it is difficult to reach ideal polishing effect.
Before carrying out joint prosthesis abrasive Flow polishing, it would be desirable to simulation test is carried out to turbulent flow polishing situation, but
Since the cost of joint prosthesis is higher, generally use is class joint prosthesis part to simulate joint prosthesis, passes through abrasive Flow turbulent flow
Burnishing device is polished experiment to the curved surface of class joint prosthesis part, and abrasive Flow polishing effect is examined by experimental result, from
And burnishing parameters are formulated, burnishing parameters can just be set as needed after the completion of experiment, then produce and process to joint prosthesis.Class
Joint prosthesis part is a kind of and the closely similar workpiece of joint prosthesis structure, since it is desired that the mainly joint prosthesis of simulating cutting
The curved surface at both ends, in order to simplify simulation process, the curved surface for the class joint prosthesis part that we use in actual experiment is flat by one
Made of the bending of face, two sides being connected with curved surface to be processed are to be added in planar, entire curved surface undulate to be processed
Work curved surface is projected as a curve on side.
Abrasive Flow Machining is the turbulent motion by abrasive Flow, drive abrasive grain to finished surface carry out it is unordered random plus
Work, so the Turbulent Kinetic of abrasive Flow weighs a key factor of abrasive Flow Machining effect.The turbulent flow total kinetic energy of abrasive Flow with
The variation of time, the variation of Turbulent Kinetic are to weigh the index of turbulent flow development or decline.In process, with abrasive grain with plus
The Turbulent Kinetic of the collision on work surface, abrasive Flow can be reduced constantly.For this problem, the present invention proposes a type and manually closes
Part curved surface turbulent flow simulation burnishing device and its method are saved, by temperature control to the Turbulent Kinetic of abrasive Flow in whole process
Temperature-compensating is carried out, ensures the uniformity of entire processing effect.
Invention content
The rapids of abrasive Flow during it is an object of the invention to solve existing class joint prosthesis part turbulent flow Precision Machining
Stream total kinetic energy changes with time the problem for causing the uniformity of processing effect in whole process poor, provides one kind
The thermostatically-controlled equipment and its method of class joint prosthesis part curved surface turbulent flow polissoir.
The present invention is achieved through the following technical solutions above-mentioned purpose:Class joint prosthesis part curved surface turbulent flow polissoir
Thermostatically-controlled equipment, including glass restraint component, electromagnetic wave heating matrix, supporting rack and electromagnetism wave controller, the glass is about
Beam component is sleeved on outside class joint prosthesis part, the curved surface shape of the inner surface and class joint prosthesis part of the glass restraint component
At profiling runner in homogeneous thickness, the glass restraint component is made of the identical glass material of wall thickness, the glass restraint structure
The both ends of part are respectively equipped with profiling flow channel entry point and profiling runner exit;The electromagnetic wave heating matrix is mounted on the glass about
The side of beam component, the electromagnetic wave heating matrix include multiple wave heaters, the shape of multiple wave heater distributions
Shape is identical as projection of shape of the profiling runner on class joint prosthesis part side, and each wave heater is installed in supporting rack
On, and profiling runner described in the equal face of each wave heater;Each electromagnetic wave heating in the electromagnetic wave heating matrix
Device is electrically connected with electromagnetism wave controller, and electromagnetism wave controller adjusts all wave heaters in the electromagnetic wave heating matrix
Electromagnetic intensity.
Further, the wave heater includes heat source, concavees lens and convex lens, each equal face one of heating source
Concavees lens and convex lens, the electromagnetic wave that heating source is sent out are emitted in profiling runner after convex lens and concavees lens successively.
Further, the wave heater is in the densely distributed of profiling runner most recess and most convex.
Further, further include temperature-detecting device, glass restraint component is used in combination described in the temperature-detecting device face
It is electrically connected with electromagnetism wave controller in profiling temperatures, the temperature-detecting device in detection profiling runner.
Further, each heating source is electrically connected with electromagnetism wave controller and by electricity in the electromagnetic wave heating matrix
The independent control of magnetic wave controller.
The constant-temperature control method of one type joint prosthesis part curved surface turbulent flow polissoir, by the way that glass restraint component to be set with
Outside class joint prosthesis part, it is equal that thickness is formed between the inner surface and the curved surface of class joint prosthesis part of glass restraint component
The both ends of even profiling runner, glass restraint component are equipped with profiling flow channel entry point and profiling runner exit, by abrasive Flow with turbulent flow
State is sent into profiling runner by profiling flow channel entry point, then is flowed out by profiling runner exit, and abrasive Flow in profiling runner is passed through
The disordered motion of middle abrasive grain realizes micro- power micro cutting of class joint prosthesis part curved surface, during the cutting process using being arranged in glass
The electromagnetic wave heating matrix of profiling runner described in the face of glass confining part side heats the abrasive Flow in profiling runner, electricity
Magnetic wave heats matrix along the distribution of profiling runner but distribution density difference, according to actual needs to profiling runner side arrangement difference number
The wave heater of amount to carry out temperature-compensating to the abrasive Flow of different location in profiling runner, and then controls profiling stream
The tubulence energy of different location abrasive Flow in road, to control the polishing effect of profiling runner different location.
Further, electromagnetic wave heating matrix is all different the heated condition of different location in profiling runner, compensation temperature
Degree sets the wavelength of designated position wave heater to realize by electromagnetism wave controller.
The beneficial effects of the present invention are:
1, the present invention establishes glass restraint component, glass restraint component and class by the profiling of class joint prosthesis part curved surface
The controlled profiling runner of abrasive Flow in homogeneous thickness is formed between joint prosthesis part, the processed curved surface of class joint prosthesis part becomes imitative
A part for shape runner wall surface, makes lapping liquid enter in profiling runner with turbulence state, passes through the unordered fortune of abrasive grain in abrasive Flow
It moves to realize micro- power micro cutting on surface, reaches minute surface grade surface roughness, polishing precision is high.
There are linear loss and head loss when 2, being moved in profiling runner due to abrasive Flow, especially larger in curvature
Loss is the most serious at runner, therefore results in class joint prosthesis part finishes and be distributed in compartmentalization.Due to abrasive Flow
The relationship cut between fluid viscosity and temperature is in secondary relational expression, and temperature is higher, and abrasive Flow cutting fluid viscosity is smaller, and mobility is got over
Good, the abrasive grain energy of flow and speed are higher, and Turbulent Kinetic is higher, and processing effect is more apparent, therefore temperature is to influence abrasive Flow
The most important factor of processing effect.The present invention is increased by placing electromagnetic wave heating matrix in the side of glass restraint component
The tubulence energy and speed of abrasive Flow cutting fluid compensate the linear loss of abrasive Flow and head loss in profiling runner, so as to improve
The effect of overall processing, the temperature of abrasive Flow is kept constant in making during overall processing, so that the class joint prosthesis part surface is added
Working medium amount is more uniform.
3, the present invention uses glass as the manufacture material of confining part, can effectively solve the problem that electromagnetic wave cannot penetrate non-glass
Glass confining part problem, and glass material is transparent, is conducive to observing to abrasive Flow cutting fluid flow regime.
4, its intensity of wave heater matrix of the present invention is adjustable, and can come by adjusting the position of concavees lens and convex lens
The spotlight effect for adjusting electromagnetic wave, can easily adjust its intensity, penetrate abrasive Flow cutting fluid, without excessive effect of flood periphery
Processing environment.
5, wave heater matrix is manufactured into profiling flow channel shape by the present invention, can effectively avoid manually closing class
Part heating is saved, class joint prosthesis part processing effect is influenced.Because class joint prosthesis part surface temperature rises, the abrasive Flow on surface
Meeting ascending motion after cutting fluid heat absorption expansion, hinders the abrasive Flow cutting fluid on upper layer to decline, and blocking abrasive grain is to class joint prosthesis part
The collision on surface is cut.
6, from the most convex of profiling runner to most recess it is linear loss region when abrasive Flow flows in profiling runner, most
Recess is local losses region, and most recess to most convex is linear loss region, and linear loss region and local loss area domain
The speed of energy loss differs, by hydrodynamics it is found that aqueous fluid viscosity is inversely proportional with temperature quadratic relation formula, Reynolds number
With viscosity inversely formula, and tubulence energy with Reynolds number at certain relationship, pass through and heat profiling runner abrasive Flow fluid and reduce
Abrasive Flow fluid viscosity can compensate abrasive Flow Hydrodynamic turbulence energy and speed, reduce linear loss and local losses and imitated to processing
The influence of fruit.The Temperature Distribution compensated needed for each region can be estimated by above-mentioned relation formula, it can be found that in local damage
It is most fast that mistake area's energy loss at most loses rate;According to amount of power loss and loss late, heating source is from dredging to close again from close to thin
Distribution is heated using wave heater distribution, is regulated and controled respectively into trip temperature to each region, is improved the uniformity of processing.
7, the present invention uses multiple independent wave heaters, and is carried out to it using individual concavees lens and convex lens
Light-ray condensing, it is not only easy to use, each wave heater can be adjusted according to actual conditions, and convex lens is recessed
Lens use common concavees lens and convex lens, need not go to customize special convex lens and concavees lens, reduce reality
Cost.
Description of the drawings
Fig. 1 is the structural schematic diagram of entire processing unit (plant) in the embodiment of the present invention.
Fig. 2 is the structural schematic diagram of the thermostatically-controlled equipment of class joint prosthesis part curved surface turbulent flow polissoir of the present invention.
Fig. 3 is the structural schematic diagram of class joint prosthesis part profiling runner of the present invention.
Fig. 4 is the structural schematic diagram of electromagnetic wave heating matrix of the present invention.
Fig. 5 is the working state schematic representation of single wave heater of the invention.
In figure, 1- electromagnetism wave controller, 2- glass restraints component, 3- electromagnetic wave heatings matrix, 4- supporting racks, 5- air films
Pump, 6- blenders, 7- profilings runner, 8- profilings runner exit, 9- class joint prosthesises part, 10- profilings flow channel entry point, 11- electromagnetism
Wave heater, 12- convex lenses, 13- concavees lens.
Specific implementation mode
The invention will be further described below in conjunction with the accompanying drawings:
As shown in Fig. 1 ~ 5, the thermostatically-controlled equipment of class joint prosthesis part curved surface turbulent flow polissoir, including glass restraint structure
Part 2, electromagnetic wave heating matrix 3, supporting rack 4 and electromagnetism wave controller 1, the glass restraint component 2 are sleeved on class joint prosthesis
Outside part 9, the inner surface of the glass restraint component 2 forms profiling stream in homogeneous thickness with the curved surface of class joint prosthesis part 9
Road 7, the glass restraint component 2 are made of the identical glass material of wall thickness, and the both ends of the glass restraint component 2 are respectively equipped with
Profiling flow channel entry point 10 and profiling runner exit 8;The electromagnetic wave heating matrix 3 is mounted on the one of the glass restraint component 2
Side, the electromagnetic wave heating matrix 3 include multiple wave heaters 11, the shape and imitate that multiple wave heaters 11 are distributed
Projection of shape of the shape runner 7 on 9 side of class joint prosthesis part is identical, and each wave heater 11 is installed in supporting rack 4
On, and profiling runner 7 described in 11 equal face of each wave heater;Each electromagnetic wave in the electromagnetic wave heating matrix 3
Heater 11 is electrically connected with electromagnetism wave controller 1, and electromagnetism wave controller 1 adjusts all electricity in the electromagnetic wave heating matrix 3
The electromagnetic intensity of magnetic wave heater 11.
The wave heater 11 includes heating source, concavees lens 13 and convex lens 12, and each wave heater is just
To a concavees lens 13 and convex lens 12, the electromagnetic wave that heating source is sent out is emitted to after convex lens 12 and concavees lens 13 successively
In profiling runner 7.Each heating source is electrically connected with electromagnetism wave controller 1 and by electromagnetism in the electromagnetic wave heating matrix 3
The independent control of wave controller 1.
The wave heater 11 is densely distributed the most recess of profiling runner 7 and most convex.Wave heater 11
Distribution it is gradually thinning to both sides respectively from most recess and most convex so that the most recess of profiling runner 7 and most convex plus
Heat ratio is more, and carrying out excessive change without the wavelength to wave heater 11 just can realize temperature in entire profiling runner 7
Degree balance.
The thermostatically-controlled equipment of class joint prosthesis part curved surface turbulent flow polissoir further includes temperature-detecting device, the temperature
Glass restraint component 2 described in detection device face is simultaneously used to detect profiling temperatures in profiling runner 7, the temperature detection dress
It sets and is electrically connected with electromagnetism wave controller 1.The compensation temperature of the actual needs of each position in profiling runner 7 is by experiment
Preceding is calculated, and monitoring temperature is carried out during actual processing by temperature-detecting device, to in profiling runner 7
Different temperatures ensures the constant of temperature in profiling runner 7 into trip temperature second compensation.
The thermostatically-controlled equipment of the class joint prosthesis part curved surface turbulent flow polissoir of the present invention and 6 gentle membrane pump 5 of blender
An end to end abrasive particle flow circulating system is connected by pipeline, when processing starts, abrasive Flow cutting fluid enters blender 6
It is interior, abrasive Flow cutting fluid is stirred evenly by blender 6, then abrasive Flow cutting fluid is input to by profiling stream by air film pump 5
In road entrance 10, then flowed back into blender 6 from profiling runner exit 8 after profiling runner 7;At the same time, by electromagnetic wave
Add matrix 3 to be powered, the electromagnetism of each wave heater 11 in electromagnetic wave heating matrix 3 is adjusted by electromagnetism wave controller 1
Intensity of wave makes electromagnetic wave only be heated to the abrasive Flow cutting fluid in profiling runner 7 through glass restraint component 2.
The present invention carries out temperature controlled side using the thermostatic control of above-mentioned class joint prosthesis part curved surface turbulent flow polissoir
Method is as follows:By the way that glass restraint component 2 to be sleeved on outside class joint prosthesis part 9, in inner surface and the class people of glass restraint component 2
Profiling runner 7 in homogeneous thickness is formed between the curved surface of work joint piece 9, the both ends of glass restraint component 2 are equipped with profiling stream
Abrasive Flow is sent by profiling flow channel entry point 10 in profiling runner 7 by road entrance 10 and profiling runner exit 8 with turbulence state,
It is flowed out again by profiling runner exit 8, class joint prosthesis part is realized by the disordered motion of abrasive grain in abrasive Flow in profiling runner 7
Micro- power micro cutting of 9 curved surfaces utilizes setting profiling runner 7 described in 2 side face of glass restraint component during the cutting process
Electromagnetic wave heating matrix 3 abrasive Flow in profiling runner 7 is heated, electromagnetic wave heating matrix 3 along profiling runner 7 be distributed
But distribution density is different, according to actual needs to the wave heater 11 of 7 side arrangement different number of profiling runner, to right
The abrasive Flow of different location carries out temperature-compensating in profiling runner 7, and then controls the rapids of different location abrasive Flow in profiling runner 7
Kinetic energy, the polishing effect to control 7 different location of profiling runner keep uniform.
Electromagnetic wave heating matrix 3 is all different the heated condition of different location in profiling runner 7, and compensation temperature passes through electricity
Magnetic wave controller 1 sets the wavelength of designated position wave heater 11 to realize.
Above-described embodiment is presently preferred embodiments of the present invention, is not the limitation to technical solution of the present invention, as long as
Without the technical solution that creative work can be realized on the basis of the above embodiments, it is regarded as falling into patent of the present invention
Rights protection scope in.
Claims (7)
1. the thermostatically-controlled equipment of class joint prosthesis part curved surface turbulent flow polissoir, it is characterised in that:Including glass restraint component
(2), electromagnetic wave heating matrix(3), supporting rack(4)With electromagnetism wave controller(1), the glass restraint component(2)It is sleeved on class
Joint prosthesis part(9)Outside, the glass restraint component(2)Inner surface and class joint prosthesis part(9)Curved surface form thickness
Spend uniform profiling runner(7), the glass restraint component(2)It is made of the identical glass material of wall thickness, the glass restraint
Component(2)Both ends be respectively equipped with profiling flow channel entry point(10)With profiling runner exit(8);The electromagnetic wave heating matrix(3)
Mounted on the glass restraint component(2)Side, the electromagnetic wave heating matrix(3)Including multiple wave heaters
(11), multiple wave heaters(11)The shape of distribution and profiling runner(7)In class joint prosthesis part(9)Projection on side
Shape is identical, each wave heater(11)It is installed in supporting rack(4)On, and each wave heater(11)Equal face
The profiling runner(7);The electromagnetic wave heating matrix(3)In each wave heater(11)With electromagnetism wave controller
(1)Electrical connection, electromagnetism wave controller(1)Adjust the electromagnetic wave heating matrix(3)In all wave heaters(11)Electricity
Magnetic wave intensity.
2. the thermostatically-controlled equipment of class joint prosthesis part curved surface turbulent flow polissoir according to claim 1, feature exist
In:The wave heater(11)Including heating source, concavees lens(13)And convex lens(12), each equal face one of heating source
Concavees lens(13)And convex lens(12), the electromagnetic wave that heating source is sent out is successively by convex lens(12)And concavees lens(13)After emit
To profiling runner(7)It is interior.
3. the thermostatically-controlled equipment of class joint prosthesis part curved surface turbulent flow polissoir according to claim 1, feature exist
In:The wave heater(11)In profiling runner(7)Most recess and most convex it is densely distributed.
4. the thermostatically-controlled equipment of class joint prosthesis part curved surface turbulent flow polissoir according to claim 1, feature exist
In:Further include temperature-detecting device, glass restraint component described in the temperature-detecting device face(2)And for detecting profiling stream
Road(7)Interior profiling temperatures, the temperature-detecting device and electromagnetism wave controller(1)Electrical connection.
5. the thermostatically-controlled equipment of class joint prosthesis part curved surface turbulent flow polissoir according to claim 2, feature exist
In:The electromagnetic wave heating matrix(3)Interior each heating source with electromagnetism wave controller(1)It is electrically connected and is controlled by electromagnetic wave
Device(1)Independent control.
6. the constant-temperature control method of class joint prosthesis part curved surface turbulent flow polissoir, it is characterised in that:By by glass restraint structure
Part(2)It is sleeved on class joint prosthesis part(9)Outside, in glass restraint component(2)Inner surface and class joint prosthesis part(9)Curved surface
Profiling runner in homogeneous thickness is formed between surface(7), glass restraint component(2)Both ends be equipped with profiling flow channel entry point(10)With
Profiling runner exit(8), abrasive Flow is passed through into profiling flow channel entry point with turbulence state(10)It is sent into profiling runner(7)In, then by
Profiling runner exit(8)Outflow, passes through profiling runner(7)The disordered motion of abrasive grain realizes class joint prosthesis part in interior abrasive Flow
(9)Micro- power micro cutting of curved surface, during the cutting process using setting in glass restraint component(2)Profiling stream described in the face of side
Road(7)Electromagnetic wave heating matrix(3)To profiling runner(7)Interior abrasive Flow is heated, electromagnetic wave heating matrix(3)Along imitative
Shape runner(7)Distribution but distribution density difference, according to actual needs to profiling runner(7)The electromagnetic wave of side arrangement different number
Heater(11), to profiling runner(7)The abrasive Flow of interior different location carries out temperature-compensating, and then controls profiling runner
(7)The tubulence energy of interior different location abrasive Flow, to control profiling runner(7)The polishing effect of different location.
7. the constant-temperature control method of class joint prosthesis part curved surface turbulent flow polissoir according to claim 6, feature exist
In:Electromagnetic wave heating matrix(3)To profiling runner(7)The heated condition of interior different location is all different, and compensation temperature passes through electricity
Magnetic wave controller(1)Set the wave heater of designated position(11)Wavelength realize.
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CN114102466B (en) * | 2021-11-22 | 2022-10-28 | 天津爱思达航天科技有限公司 | Tool convenient for assembly and used for machining honeycomb curved surface mold core and application |
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CN202825563U (en) * | 2012-07-25 | 2013-03-27 | 浙江工业大学 | Flexible abrasive flow machining device based on fuzzy control |
CN103612164A (en) * | 2013-12-03 | 2014-03-05 | 浙江工业大学 | Curved surface turbulence polishing device for performing eddy current heating on constraint component |
CN103846798A (en) * | 2014-03-28 | 2014-06-11 | 长春理工大学 | Variable caliber pipe abrasive flow ultra-precise polishing measurement and control system |
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