CN113399764A - Electrolytic machining method - Google Patents

Abstract

The invention discloses an electrolytic machining method, which adopts a negative pressure adsorption structure to adsorb an electrolytic machining device on a workpiece to be machined; injecting pulsating electrolyte into a processing gap between the cathode and a workpiece to be processed through an electrolyte cavity arranged in the cathode; the electrode is used for carrying out electrolytic machining on the machined part of the workpiece; in the process of processing the workpiece, pulsating electrolyte with periodically changed pressure is injected into the processing gap through a channel to impact, stir and mix the electrolyte at the processing gap, turbulent flow is generated in the process that two strands of electrolyte are converged, the product of the electrolytic processing workpiece at the processing gap can be stirred, and the electrolytic processing product is prevented from flocculating and precipitating at the processing gap. The method can effectively improve the electrolytic machining efficiency.

Description

Electrolytic machining method

Technical Field

The invention belongs to the technical field of electrolytic machining, and particularly relates to an electrolytic machining method.

Background

During the electrolytic machining, when the workpiece is machined in a mode that the electrolyte passes through the cavity in the cathode, the cathode is generally in a vertically downward direction, the workpiece to be machined is positioned right below the cathode, the electrolyte flowing out of the cavity of the cathode fills a machining gap between the cathode and the workpiece, and a conductive path is formed between the cathode and the workpiece, so that the workpiece serving as an anode is dissolved. With the continuous feeding of the cathode relative to the workpiece, the metal of the workpiece is continuously electrolyzed, the electrolysis product is continuously washed away by the electrolyte, finally, gaps among the cathode and the workpiece tend to be consistent, and the surface of the workpiece is formed into a shape basically similar to the working surface of the cathode.

When a workpiece with an arc surface or an inclined plane is electrolytically machined, the cathode is in the inclined position after corresponding to the machining position on the arc surface or the inclined plane of the workpiece, and at the moment, electrolyte flowing out of a cavity in the cathode can flow downwards along the arc surface or the inclined plane of the workpiece under the influence of gravity, so that the electrolyte on the upper part of the end surface of the cathode corresponding to the workpiece is less than that on the lower part, namely the electrolyte filled in a gap between the workpiece and the cathode is not uniform, and the machining speed of the lower end surface of the cathode facing the workpiece is higher than that of the upper end surface of the cathode facing the workpiece; when the cathode is continuously fed, the upper end face of the cathode is directly contacted with a workpiece, short circuit occurs, the cathode and the workpiece are burnt, and the cathode and the workpiece are lost; and the electrolyte discharged through the internal cavity of the electrode has slow flowing speed, the discharge efficiency of electrolytic products is low, and the electrolyte is easy to accumulate at the electrolytic part of the workpiece, so that the electrolytic effect and the electrolytic progress are influenced. Therefore, the structure of the existing electrolysis device is optimized and improved to solve the existing technical problems.

Disclosure of Invention

The present invention has been made in view of the above problems, and an object thereof is to provide an electrolytic processing method.

In order to achieve the purpose, the invention provides the following technical scheme: an electrolytic processing method, comprising the steps of: A) adsorbing the electrolytic machining device on a workpiece to be machined by adopting a negative pressure adsorption structure; B) injecting pulsating electrolyte into a processing gap between the cathode and a workpiece to be processed through an electrolyte cavity arranged in the cathode; the electrode is used for carrying out electrolytic machining on the machined part of the workpiece; C) in the process of processing a workpiece, pulsating electrolyte with periodically changed pressure is injected into a processing gap through a channel to impact, stir and mix the electrolyte at the processing gap, turbulent flow is generated in the process of converging the two electrolyte flows, the product of the electrolytic processing workpiece at the processing gap can be stirred, and the electrolytic processing product is prevented from flocculating and precipitating at the processing gap; D) in the process of processing the workpiece, the waste gas is recovered and processed by a waste gas collecting and processing device in the electrolyte processing system.

Preferably, the electrolytic machining device comprises a cathode and a workpiece, a sliding chute is arranged on the side wall of the cathode, a sliding assembly is hermetically and slidably arranged in the sliding chute, the sliding assembly comprises an upper cavity part and a lower adsorption part, and the cavity part is communicated with the adsorption part through a communication valve; the cavity part is provided with a first cavity and a second cavity which are independent of each other, a sliding cavity which is matched with the cathode to slide up and down is arranged between the first cavity and the second cavity, and the first cavity is communicated with the second cavity through a first channel, the sliding cavity and a second channel; the first chamber is connected with an external electrolyte treatment system and a negative pressure system through a third channel; the second chamber is connected with an external electrolyte supply system through a fourth channel; the cavity part is provided with a sealing sliding block matched with the sliding groove; the adsorption part comprises a sucker, an elastic sealing block is arranged inside the sucker, and the top of the elastic sealing block is connected with the cavity part.

Preferably, an electrolyte cavity is formed in the cathode, and pulsating electrolyte flows in the electrolyte cavity; the electrolyte cavity is connected with an external electrolyte supply system through a pipeline and a first electromagnetic valve; the cathode is connected with a feeding mechanism on the electrolytic processing device.

Preferably, the outer surface of the workpiece is a smooth surface, the sucker is extruded on the outer surface of the workpiece and is used for extracting air in the sucker, and the sucker is adsorbed on the outer surface of the workpiece.

Preferably, the sliding assembly is provided with various shapes and specifications, and a sucker on the sliding assembly is adaptive to the outer surface of the workpiece; and the sealing slide block on the sliding assembly is adaptive to the shape of the cathode.

Preferably, the communication valve comprises a supporting block and a through hole which are arranged below the cavity part, the supporting block is connected with a compression spring, and the compression spring is connected with a blocking block; the blocking block is clamped in the through hole, and the cavity part is not communicated with the inside of the sucker.

Preferably, the third channel is communicated with the electrolyte treatment system through one channel of the three-way pipe, the second electromagnetic valve and a pipeline; and the third channel is communicated with the negative pressure system through the other channel of the three-way pipe, the third electromagnetic valve and a pipeline.

Preferably, the electrolyte treatment system comprises an electrolyte filtering device and an exhaust gas collecting and treating device; the fourth channel is communicated with the electrolyte supply system through a fourth electromagnetic valve and a pipeline.

Preferably, when the air in the sucking disc is extracted to enable the sucking disc to be adsorbed on the outer surface of the workpiece, the elastic sealing block is pressed to seal the part to be machined of the workpiece, so that the inside of the sucking disc is separated from the part to be machined of the workpiece.

Preferably, the cathode is clamped into the sliding cavity through the sliding groove and the sealing slide block, the elastic sealing block is extruded and then seals the part to be processed of the workpiece, and the first cavity, the first channel, the gap between the cathode and the sliding cavity, the machining gap between the cathode and the workpiece, the second channel and the second cavity form an electrolyte flowing channel.

Compared with the prior art, the invention has at least the following beneficial effects:

1. the electrolyte cavity is arranged in the cathode, and the pulsating electrolyte flows in the electrolyte cavity; forming pulsating electrolyte with periodically changed pressure by a booster pump of an electrolyte supply system, wherein the pulsating electrolyte flows to a machining gap between a cathode and a workpiece from an electrolyte cavity and is used for performing electrolytic machining on a machining part of the workpiece by an electrode; on the other hand, in the process of processing the workpiece, the pulsating electrolyte with periodically changed pressure impacts, stirs and mixes the electrolyte flowing into the processing gap from the second chamber and the second channel, and turbulence is generated in the process of converging the two electrolyte streams, so that a product of electrolytically processing the workpiece at the processing gap can be stirred, and the electrolytic processed product is prevented from flocculating and precipitating at the processing gap to influence the subsequent electrolytic effect and efficiency; the electrolytic machining product stirred and disturbed by the turbulent flow is taken away by new electrolyte flowing in subsequently, and the effect and the efficiency of the subsequent electrolytic machining are improved.

2. When air in the sucker is extracted to enable the sucker to be adsorbed on the outer surface of a workpiece, the elastic sealing block is extruded to seal the part to be processed of the workpiece, so that the inside of the sucker is isolated from the part to be processed of the workpiece, on one hand, the sucker enables the sliding assembly to be adsorbed on the workpiece, the processing position of the workpiece can be positioned, and the cathode is supported; on the other hand, a sealing slide block matched with the sliding groove is arranged on the cavity part, the cathode is clamped into the sliding cavity through the sliding groove and the sealing slide block, and after the elastic sealing block is extruded to seal a part to be processed of the workpiece, the first cavity, the first channel, the gap between the cathode and the sliding cavity, the processing gap between the cathode and the workpiece, the second channel and the second cavity form an electrolyte flow channel, so that the electrolyte can normally flow in the electrolyte flow channel in the processing process, and the processing part of the workpiece can be normally processed; the third aspect, because the negative pole passes through the spout and seals the slider and form seal structure, can guarantee that the clearance of slip cavity and negative pole forms airtight space with second cavity, first cavity, in the waste gas that produces flows to electrolyte processing system along with used electrolyte among the electrolytic machining process, the waste gas collection processing apparatus in the rethread electrolyte processing system retrieves and handles, prevents the polluted environment, endangers staff's health, creates healthy operational environment for the staff.

3. When the arc-shaped surface or the inclined surface of the workpiece is electrolytically machined, after the cathode corresponds to the part to be machined of the workpiece, when the cathode is in an inclined position, the horizontal height of the first channel on the first chamber is higher than the height of the second channel on the second chamber, electrolyte entering from the second channel fills the second chamber, fills the machining gap between the cathode and the workpiece, and then flows out from the first channel, so that the machining gap between the cathode and the workpiece can be kept full of the electrolyte, and the problems that the cathode and the workpiece are short-circuited and the cathode is burnt due to the fact that the electrolyte cannot be filled in the machining gap under the influence of gravity when the cathode is inclined under the condition that the electrolyte only flows into the machining gap from the electrolyte cavity of the cathode are solved.

4. When the cathode of the invention is used for processing a deeper cavity on a workpiece, the cathode is in sealed sliding connection with the cavity part through the chute and the sealing slide block above the cathode, and the lower part of the cavity part is connected with the sucker; simultaneously in the process of sucking the inside air of sucking disc messenger sucking disc and adsorbing on the surface of work piece, the elasticity sealing block is treated the processing position to the work piece after being extrudeed and is formed the sealed back, because the elasticity sealing block is in compression state, also can play effectual korea towards, absorbing effect to the vibration of negative pole, sucking disc and elasticity sealing block combined action, the low-cathode is because vibrations cause and take place the risk of short circuit with work piece direct contact, improve the life of negative pole, guarantee going on smoothly of electrolytic machining effect.

Drawings

FIG. 1 is a schematic view of a cathode and a slide assembly and a workpiece assembly according to the present invention;

FIG. 2 is a schematic view of the structure of the cavity and the chute of the cathode of the present invention;

FIG. 3 is a schematic view of the structure of the sliding assembly of the present invention;

FIG. 4 is an enlarged view of a portion A of FIG. 3 according to the present invention;

FIG. 5 is a schematic view of a cathode and a sliding assembly according to the present invention;

FIG. 6 is a schematic view showing the flow path of an electrolyte during the electrolytic processing according to the present invention.

In the figure: 1. a cathode; 101. an electrolyte cavity; 2. a workpiece; 3. a chute; 4. a sliding assembly;

41. a cavity portion; 4101. a first chamber; 4102. a second chamber; 4103. a sliding chamber; 4104. a first channel; 4105. a second channel; 4106. a third channel; 4107. a fourth channel; 42. an adsorption part; 4201. a suction cup; 4202. an elastic sealing block; 43. sealing the sliding block; 5. a communication valve; 501. a support block; 502. a through hole; 503. a compression spring; 504. and (7) blocking.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1 to 6, the present invention provides an electrolytic machining apparatus, comprising a cathode 1 and a workpiece 2, wherein the cathode 1 is used for performing electrolytic machining on the workpiece 2, and an insulating layer is coated on the outer side of the cathode 1 to prevent secondary electrolysis of the machined hole wall; an electrolyte cavity 101 is formed in the cathode 1, and pulsating electrolyte flows in the electrolyte cavity 101; a pulsating electrolyte with periodically changed pressure is formed by a booster pump of the electrolyte supply system, and the pulsating electrolyte flows into a machining gap between the cathode 1 and the workpiece 2 from the electrolyte cavity 101 and is used for performing electrolytic machining on a machining part of the workpiece 2 by the electrode 1; on the other hand, during the processing of the workpiece 2, the pulsating electrolyte with periodically changing pressure impacts, stirs and mixes the electrolyte flowing into the processing gap from the second chamber 4102 and the second channel 4105, and turbulence is generated during the joining of the two electrolytes, so that the product of electrolytic processing of the workpiece 2 at the processing gap can be stirred, and the product of electrolytic processing, such as fe (oh), can be prevented₂、Fe（OH）₃、Fe₂O₃The subsequent electrolysis effect and efficiency are influenced by flocculation and precipitation at the processing clearance; the electrolytic machining product stirred and disturbed by the turbulent flow is taken away by new electrolyte flowing in subsequently, and the effect and the efficiency of the subsequent electrolytic machining are improved. The electrolyte cavity 101 is connected with an external electrolyte supply system through a pipeline and a first electromagnetic valve; the processing device is used for controlling the first electromagnetic valve to be opened or closed, and then controlling the external electrolyte supply system to timely supply the pulsating electrolyte so as to meet the requirements of the processing process.

The cathode 1 is connected with a feeding mechanism on the electrolytic machining device, the feeding mechanism drives the cathode 1 to feed downwards to machine the workpiece 2, and can drive the cathode 1 to move upwards, and the cathode 1 retreats within a pulse current interval period, so that the machining gap between the electrode 1 and the workpiece 2 is increased, and the flowing and updating of electrolyte at the machining gap are promoted.

The outer surface of the workpiece 2 is a smooth surface and can be obtained by preliminary processing; the suction portion 42 includes a suction cup 4201; after the cathode 1 is inserted into the slide chamber 4103 through the chute 3 and the sealing slide 43, the negative pressure system sucks air in the chuck 4201 through the third passage 4106, the first chamber 4101, the second chamber 4102, the slide chamber 4103, and the communication valve 5, forms negative pressure in the chuck 4201 by pressing the chuck 4201 against the outer surface of the workpiece 2 and sucking air in the chuck 4201, the chuck 4201 is attracted to the outer surface of the workpiece 2, and the slide assembly 4 is fixed to the outer surface of the workpiece 2 by the chuck 4201, ready for processing the workpiece 2.

The side wall of the cathode 1 is provided with a chute 3, a sliding component 4 is hermetically and slidably arranged in the chute 3, after the sliding component 4 is fixed on the outer surface of the workpiece 2, the cathode 1 is hermetically and slidably connected in a sliding chamber 4103 through a sealing sliding block 43 on the chute 3 and the sliding component 4, and the part to be processed of the workpiece 2 is ensured to be isolated from the outside. The sliding component 4 is provided with various shapes and specifications, and the suction cups 4201 on the sliding component 4 are adapted to the outer surface of the workpiece 2, so as to ensure that the sliding component 4 is smoothly sucked on the outer surface of the workpiece through the suction cups 4201. The sealing slide block 43 on the sliding component 4 is adapted to the shape of the cathode 1, so as to ensure that the sliding component 4 can adapt to cathodes 1 of different shapes, and further ensure that the cathode 1 can process workpieces 1 into different shapes.

The slide module 4 includes an upper cavity portion 41 and a lower suction portion 42, the cavity portion 41 communicating with the suction portion 42 through the communication valve 5; the communication valve 5 comprises a supporting block 501 and a through hole 502 which are arranged below the cavity part 41, the supporting block 501 is connected with a compression spring 503, and the compression spring 503 is connected with a blocking block 504; after the air in the suction cup 4201 is extracted by the negative pressure system to make the suction cup 4201 adhere to the workpiece 1, further extracting the air in the suction cup 4201, at this time, under the action of the negative pressure, the compression spring 503 is compressed by the block 504, after the compression spring 504 is compressed to a certain degree, the block 504 is clamped in the through hole 502, and the cavity portion 41 is not communicated with the inside of the suction cup 4201; at this time, the suction cup 4201 is fixed to the slide module 4, and the electrolytic solution can be injected into the cavity 4 to electrolyze the portion of the workpiece 1 to be processed by the cathode 1 without affecting the operation of the suction cup 4201.

The cavity part 41 is provided with a first chamber 4101 and a second chamber 4102 which are independent of each other, a sliding chamber 4103 which is matched with the cathode 1 to slide up and down is arranged between the first chamber 4101 and the second chamber 4102, and the first chamber 4101 is communicated with the second chamber 4102 through a first channel 4104, the sliding chamber 4102 and a second channel 4105; after the cavity 41 and the chuck 4201 are not connected to each other, the electrolyte introduced from the second chamber 4102 can reach the first chamber 4101 through the second channel 4105, the slide chamber 4102, and the first channel 4104, and the slide chamber 4102 can be filled with the electrolyte when the electrolyte flows, so that the gap between the cathode 1 and the workpiece 1 is filled with the electrolyte, and the electrolytic operation can be performed smoothly.

The second chamber 4102 is connected to an external electrolyte supply system through a fourth passage 4107; the fourth passage 4107 is connected to an electrolyte supply system via a fourth solenoid valve and a pipe. When the air in the suction cup 4201 is pumped out, the fourth electromagnetic valve is closed, and the air in the second chamber 4102 can be pumped out through the negative pressure system, so that the corresponding communication valve 5 is closed to prepare for flowing the electrolyte in the second chamber 4102; when it is desired to flow electrolyte through the second chamber 4102, the fourth solenoid valve may be opened and new electrolyte may be continuously supplied through the fourth passage 4107 and the electrolyte supply system. The first chamber 4101 is connected to an external electrolyte treatment system and a negative pressure system through a third channel 4106. The third channel 4106 is communicated with the electrolyte treatment system through one channel of the three-way pipe, the second electromagnetic valve and a pipeline; the third channel 4016 is communicated with the negative pressure system through the other channel of the three-way pipe, a third electromagnetic valve and a pipeline; after the cathode 1 slides into the sliding chamber 4103 of the sliding assembly 4 through the chute 3, when the negative pressure system draws air in the suction cup 4201 through the third channel 4106, the three-way pipe, the third electromagnetic valve and the pipeline, the first electromagnetic valve is closed, the second electromagnetic valve is closed, the fourth electromagnetic valve is closed, and when the negative pressure system draws air in the suction cup 4201 to a certain degree, the corresponding communication valves 5 in the first chamber 4101 and the second chamber 4102 are closed under the action of negative pressure, the cavity 41 is not communicated with the inside of the suction cup 4201, and at this time, the third electromagnetic valve is not communicated with the inside of the suction cup 4201 any moreClosing the system, generating a pressure larger than that of a negative pressure system by the electrolyte treatment system, then sequentially opening a fourth electromagnetic valve, a first electromagnetic valve and a second electromagnetic valve, enabling the electrolyte of the electrolyte supply system to enter a gap between the sliding chamber 4103 and the cathode 1 through the fourth electromagnetic valve and the second chamber 4102, enabling the electrolyte to mutually impact and merge with pulsating electrolyte entering from the first electromagnetic valve and the electrolyte cavity 101, enabling the merged electrolyte to enter the first chamber 4101 through a first channel 4104, and enabling the electrolyte used in the processing gap to enter the electrolyte treatment system through the second electromagnetic valve and a pipeline; the electrolyte treatment system comprises an electrolyte filtering device and a waste gas collecting and treating device, wherein the electrolyte filtering device is mainly used for filtering and recovering Fe (OH) in used electrolyte₂、Fe（OH）₃、Fe₂O₃Floccules and other electrolysis products are used for preventing environmental pollution; the waste gas collecting and treating device is mainly used for collecting waste gas such as Cl generated in the electrolytic machining process₂、Br₂Etc., the specific gas type is related to the material of the workpiece 2 to be processed; the suction cup 4201 is provided therein with an elastic sealing block 4202, and the top of the elastic sealing block 4202 is connected to the cavity portion 41. When air in the suction cup 4201 is pumped to enable the suction cup 4201 to be adsorbed on the outer surface of the workpiece 2, the elastic sealing block 4202 is squeezed to seal a to-be-machined part of the workpiece 2, and the inside of the suction cup 4201 is isolated from the to-be-machined part of the workpiece 2; on one hand, the slide assembly 4 can be ensured to be adsorbed on the workpiece 2 through the sucking disc 4201, the processing position of the workpiece 2 can be positioned, and the cathode 1 can be supported; on the other hand, the cavity 41 is provided with a sealing slider 43 matching with the chute 3, the cathode 1 is clamped into the sliding cavity 4103 through the chute 3 and the sealing slider 43, and after the elastic sealing block 4202 is pressed to seal the to-be-processed part of the workpiece 2, the first cavity 4102, the first channel 4105, the gap between the cathode 1 and the sliding cavity 4103, the processing gap between the cathode 1 and the workpiece 2, the second channel 4106 and the second cavity 4103 form an electrolyte flow channel, so that the electrolyte can normally flow in the electrolyte flow channel in the processing process, the electrolyte cannot enter the suction cup 4201 to cause the falling of the suction cup 4201 under the sealing action of the elastic sealing block 4202, and further, the processing part of the workpiece 2 is ensured to be normally added with the sealing slider 43Working; in the third aspect, because the cathode 1 forms a sealing structure through the chute 3 and the sealing slide block 43, a processing gap between the sliding chamber 4103 and the cathode 1, the second chamber 4102 and the first chamber 4101 can form a closed space, waste gas generated in the electrolytic processing process flows into the electrolyte treatment system along with used electrolyte, and is recovered and treated by a waste gas collecting and treating device in the electrolyte treatment system, so that the environment pollution and the physical health of workers are prevented, and a healthy working environment is created for the workers.

As shown in fig. 6, when the workpiece 2 is processed by electrolysis, and the cathode 1 corresponds to the portion of the workpiece 2 to be processed, when the cathode 1 is in an inclined position, the horizontal height of the first channel 4104 on the first chamber 4101 is higher than the height of the second channel 4105 on the second chamber 4102, and the electrolyte entering from the second channel 4105 fills the second chamber 4102, fills the processing gap between the cathode 1 and the workpiece 2, and then flows out from the first channel 4104, so that the processing gap between the cathode 1 and the workpiece 2 can be ensured to be filled with the electrolyte, and the problem that the cathode 1 and the workpiece 2 are short-circuited and the cathode 1 is burned out due to the electrolyte being not filled with the electrolyte in the processing gap only from the electrolyte cavity 101 of the cathode 1 when the cathode 1 is inclined due to the influence of gravity is avoided.

When the cathode 1 is used for processing a deeper cavity on the workpiece 2, the depth of the cathode 1 entering the workpiece 2 is deeper, and when the feeding mechanism drives the cathode 1 to retreat to promote the electrolyte flow and update at the processing gap, the cathode 1 can vibrate, and because the distance between the inner walls formed after the cathode 1 and the workpiece 2 are processed is very small, the cathode 1 is easily in direct contact with the workpiece 2 to cause short circuit between the cathode 1 and the workpiece 2, so that the cathode 1 is burnt and damaged. In the invention, the cathode 1 is in sealed sliding connection with the cavity part 41 through the chute 3 and the sealing slide block 43 above the cathode 1, and the lower part of the cavity part 41 is connected with the sucker 4201, after partial air in the sucker 4201 is pumped away through a negative pressure system, a part of air still remains in the sucker 4201, and the part of air can effectively play a role in buffering and damping the vibration of the cathode 1 through the sucker 4201, the sealing slide block 43 and the chute 3 on the cavity part 41, so that the risk of short circuit caused by direct contact of the cathode 1 and the workpiece 2 due to vibration is reduced; meanwhile, in the process of sucking air in the sucker 4201 to enable the sucker 4201 to be adsorbed on the outer surface of the workpiece 2, after the elastic sealing block 4202 is pressed to seal the to-be-machined part of the workpiece 2, the elastic sealing block 4202 is in a compressed state, so that the vibration of the cathode 1 can be effectively buffered and damped, the risk of short circuit caused by direct contact of the cathode 1 and the workpiece 2 due to vibration is reduced, the service life of the cathode 1 is prolonged, and the electrolytic machining effect is guaranteed to be smoothly performed.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. An electrolytic processing method, characterized in that the method comprises the steps of:

A) adsorbing the electrolytic machining device on a workpiece to be machined by adopting a negative pressure adsorption structure;

B) injecting pulsating electrolyte into a processing gap between the cathode and a workpiece to be processed through an electrolyte cavity arranged in the cathode; the electrode is used for carrying out electrolytic machining on the machined part of the workpiece;

C) in the process of processing a workpiece, pulsating electrolyte with periodically changed pressure is injected into a processing gap through a channel to impact, stir and mix the electrolyte at the processing gap, turbulent flow is generated in the process of converging the two electrolyte flows, the product of the electrolytic processing workpiece at the processing gap can be stirred, and the electrolytic processing product is prevented from flocculating and precipitating at the processing gap;

D) in the process of processing the workpiece, the waste gas is recovered and processed by a waste gas collecting and processing device in the electrolyte processing system.

2. The method according to claim 1, wherein the electrolytic machining device comprises a cathode (1) and a workpiece (2), a sliding groove (3) is formed in the side wall of the cathode (1), a sliding assembly (4) is hermetically and slidably arranged in the sliding groove (3), the sliding assembly (4) comprises an upper cavity part (41) and a lower adsorption part (42), and the cavity part (41) is communicated with the adsorption part (42) through a communication valve (5);

the cavity part (41) is provided with a first chamber (4101) and a second chamber (4102) which are independent of each other, a sliding chamber (4103) which is matched with the cathode (1) to slide up and down is arranged between the first chamber (4101) and the second chamber (4102), and the first chamber (4101) is communicated with the second chamber (4102) through a first channel (4104), the sliding chamber (4102) and a second channel (4105);

the first chamber (4101) is connected with an external electrolyte treatment system and a negative pressure system through a third channel (4106); the second chamber (4102) is connected with an external electrolyte supply system through a fourth channel (4107);

a sealing sliding block (43) matched with the sliding groove (3) is arranged on the cavity part (41);

the adsorption part (42) comprises a sucker (4201), an elastic sealing block (4202) is arranged inside the sucker (4201), and the top of the elastic sealing block (4202) is connected with the cavity part (41).

3. The method of claim 2, wherein: an electrolyte cavity (101) is formed in the cathode (1), and pulsating electrolyte flows in the electrolyte cavity (101); the electrolyte cavity (101) is connected with an external electrolyte supply system through a pipeline and a first electromagnetic valve; the cathode (1) is connected with a feeding mechanism on the electrolytic processing device.

4. The method of claim 3, wherein: the outer surface of the workpiece (2) is smooth, the sucker (4201) is pressed on the outer surface of the workpiece (2) and air inside the sucker (4201) is extracted, and the sucker (4201) is adsorbed on the outer surface of the workpiece (2).

5. The method of claim 4, wherein: the sliding assembly (4) is provided with various shapes and specifications, and a sucker (4201) on the sliding assembly (4) is adapted to the outer surface of the workpiece (2); the sealing slide block (43) on the sliding component (4) is adapted to the shape of the cathode (1).

6. The method of claim 5, wherein: the communication valve (5) comprises a supporting block (501) and a through hole (502) below the cavity part (41), the supporting block (501) is connected with a compression spring (503), and the compression spring (503) is connected with a blocking block (504); the block piece (504) is clamped in the through hole (502), and the cavity part (41) is not communicated with the inside of the sucker (4201).

7. The method of claim 6, wherein: the third channel (4106) is communicated with the electrolyte treatment system through one channel of the three-way pipe, the second electromagnetic valve and a pipeline; and the third channel (4016) is communicated with the negative pressure system through the other channel of the three-way pipe, a third electromagnetic valve and a pipeline.

8. The method of claim 7, wherein: the electrolyte treatment system comprises an electrolyte filtering device and a waste gas collecting and treating device.

9. The method of claim 8, wherein: the fourth channel (4107) is communicated with an electrolyte supply system through a fourth electromagnetic valve and a pipeline; when air in the sucker (4201) is extracted to enable the sucker (4201) to be adsorbed on the outer surface of the workpiece (2), the elastic sealing block (4202) is pressed to form a seal for the to-be-machined part of the workpiece (2), and the inside of the sucker (4201) is isolated from the to-be-machined part of the workpiece (2).

10. The method of claim 9, wherein: the cathode (1) is clamped into the sliding chamber (4103) through the chute (3) and the sealing slide block (43), and after the elastic sealing block (4202) is pressed to seal a to-be-processed part of the workpiece (2), the first chamber (4102), the first channel (4105), a gap between the cathode and the sliding chamber (4103), a processing gap between the cathode (1) and the workpiece (2), the second channel (4106) and the second chamber (4103) form an electrolyte flow channel.

Images