CN212894814U - Bipolar electrode-twin coil pulse electromagnetic coupling strengthens metallic material device - Google Patents

Abstract

The utility model discloses a double-electrode and double-coil pulse electromagnetic coupling reinforced metal material device, which comprises a mounting component and an electromagnetic coupling processing component arranged on the mounting component; the mounting assembly comprises a workbench, a transverse slide rail and a longitudinal slide rail, the transverse slide rail and the longitudinal slide rail are arranged on the workbench, a transverse electrode seat and an electromagnetic seat are arranged on the transverse slide rail in a sliding manner, and a longitudinal electrode seat is arranged on the longitudinal slide rail in a sliding manner; the electromagnetic coupling processing assembly comprises an electric field processing assembly and a magnetic field processing assembly, wherein the electric field processing assembly comprises a transverse electrode column arranged on a transverse electrode seat and a longitudinal electrode column arranged on a longitudinal electrode seat; the magnetic field processing assembly comprises a magnetic field generating coil arranged on the electromagnetic seat, and a moving assembly is arranged at the bottom of the workbench. The metal material can receive various processing modes such as single-pulse electric field, single-pulse magnetic field, pulse electric field-pulse magnetic field coaxial processing or orthogonal processing, and meanwhile, the design of the slide rail is adopted, so that the processing space of the metal material is enlarged, and the application range is widened.

Description

Bipolar electrode-twin coil pulse electromagnetic coupling strengthens metallic material device

Technical Field

The utility model belongs to the technical field of the material processing, relate to metal material and strengthen handling, especially relate to a metal material device is strengthened to bipolar electrode-twin coil pulse electromagnetic coupling.

Background

The method utilizes external field technologies such as a pulse coupling electromagnetic field and the like to carry out micro modification on the metal material, reduces the residual stress of the material, reduces and even repairs micro cracks of the material, improves the physical properties (such as hardness, plasticity, wear resistance and the like) of the metal material, prolongs the service life of a workpiece, is a new research direction in the field of material treatment, and is immature in the prior art.

Compared with other chemical methods for treating metal materials, the electromagnetic treatment method for the metal materials has the advantages of short treatment time, obvious improvement effect and the like, can reduce chemical pollution by external field treatment, is a metal material modification method which is quicker, efficient and environment-friendly, and has wide application prospect.

The existing electromagnetic strengthening treatment device mainly comprises an electromagnetic treatment box and a cooling machine matched with the electromagnetic treatment box, wherein the electromagnetic treatment box comprises an electrode and a magnetic field coil which are coaxially arranged, a magnetic field treatment space is formed in the magnetic field coil, a workpiece to be treated is fixed in the magnetic field coil by clamping a movable electrode and a fixed electrode, and an electric field is applied to the workpiece to be treated; in addition, the electromagnetic treatment cavity in the electromagnetic treatment box is cooled through the cooler, so that the normal operation of the device is ensured. Because the electrode and the magnetic field coil are coaxial, the defect of single electromagnetic field coupling exists, and the requirement of multi-mode processing cannot be met. Meanwhile, the processing space of the existing electromagnetic strengthening processing device has limitation, the processing of metal materials with different shapes and sizes cannot be met, and the application range is small.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a bipolar electrode-twin coil pulsed electromagnetic coupling reinforces metal material device, the fine above-mentioned problem of having solved, it makes metal material can accept multiple intensive processing mode such as monopulse electric field, monopulse magnetic field, pulse electric field-coaxial processing in pulse magnetic field or pulse electric field-pulse magnetic field orthogonal processing, and the processing mode is nimble various, adopts the design of slide rail simultaneously, has increaseed metal material's processing space, has improved its application scope.

The technical scheme provided by the utility model is a double-electrode and double-coil pulse electromagnetic coupling reinforced metal material device, which comprises a mounting component and an electromagnetic coupling processing component arranged on the mounting component;

the mounting assembly comprises a workbench, a transverse slide rail and a longitudinal slide rail, the transverse slide rail and the longitudinal slide rail are arranged on the workbench, a transverse electrode seat and an electromagnetic seat are arranged on the transverse slide rail in a sliding manner, and a longitudinal electrode seat is arranged on the longitudinal slide rail in a sliding manner;

the electromagnetic coupling processing assembly comprises an electric field processing assembly and a magnetic field processing assembly; the electric field processing assembly comprises two transverse electrode columns arranged on two transverse electrode seats which are oppositely arranged and two longitudinal electrode columns arranged on two longitudinal electrode seats which are oppositely arranged, and each electrode column is provided with a detachable electrode chuck; the magnetic field processing assembly comprises two magnetic field generating coils which are arranged on two oppositely arranged electromagnetic seats;

the bottom of the workbench is provided with a moving assembly;

the metal material to be processed is clamped by two electrode chucks opposite to the two transverse electrode seats or the two longitudinal electrode seats, and meanwhile, the magnetic field generating coils on the two electromagnetic seats are symmetrically fixed at set positions, so that the metal material to be processed is positioned in a material processing cavity formed by an electric field and a magnetic field.

According to the bipolar electrode-twin coil pulse electromagnetic coupling reinforced metal material device, the workbench is a cross-shaped workbench, and the transverse slide rail and the longitudinal slide rail are respectively arranged on two cross-shaped vertical cross table tops of the cross-shaped workbench. The sample supporting table is arranged in the middle of the workbench, the moving assembly is universal wheels arranged at four corners of the bottom of the workbench, and lifting support columns are further arranged at the four corners of the bottom of the workbench.

According to the bipolar electrode-twin coil pulse electromagnetic coupling reinforced metal material device, the transverse slide rail and the longitudinal slide rail are perpendicular to each other, the transverse slide rail is provided with the transverse electrode seat and the electromagnetic seat in a sliding manner, and the longitudinal slide rail is provided with the longitudinal electrode seat in a sliding manner. The transverse electrode seat and the electromagnetic seat move on the transverse sliding rail in one or more driving modes of a screw rod, a motor, an air cylinder and a hydraulic cylinder, and the longitudinal electrode seat moves on the longitudinal sliding rail in one or more driving modes of the screw rod, the motor, the air cylinder and the hydraulic cylinder. The transverse electrode seat, the electromagnetic seat and the transverse sliding rail and the longitudinal electrode seat and the longitudinal sliding rail can be in driving connection in a gear and rack mode. Specifically, the bottom of the transverse electrode holder and the bottom of the electromagnetic holder can be in sliding connection with the transverse sliding rail through a sliding bearing or a sliding block, or the transverse electrode holder, the electromagnetic holder and the sliding bearing or the sliding block are integrally manufactured and in sliding connection with the transverse sliding rail, the transverse electrode holder and the electromagnetic holder can move on the transverse sliding rail through the driving of a screw rod, a motor, an air cylinder, a hydraulic cylinder and the like, and when the driving of the screw rod, the motor, the air cylinder and the hydraulic cylinder is stopped, certain constraint force is achieved, so that the transverse electrode holder and the electromagnetic holder can be stably fixed on the transverse sliding rail without sliding. Of course, the connection relationship and driving mode principle of the longitudinal electrode seat and the longitudinal slide rail are the same as those of the transverse electrode seat, the electromagnetic seat and the transverse slide rail.

Furthermore, the bottom of the transverse electrode seat and the bottom of the electromagnetic seat are in sliding connection with the transverse sliding rail through sliding bearings fixedly connected with the transverse electrode seat and the bottom of the longitudinal electrode seat is in sliding connection with the longitudinal sliding rail through sliding bearings fixedly connected with the longitudinal electrode seat. The two relative electromagnetic seats are provided with racks, the workbench is provided with gears which are meshed with the two racks simultaneously, the gears are connected with a driving motor, the two electromagnetic seats are driven by the gears to synchronously move along a transverse sliding rail, and the two relative transverse electrode seats or the two relative longitudinal electrode seats are identical to the electromagnetic seats in movement realization mode.

In the double-electrode double-coil pulse electromagnetic coupling reinforced metal material device, the axial leads of the transverse electrode column, the longitudinal electrode column and the magnetic field generating coil are positioned on the same plane so as to ensure the uniformity of treatment.

The double-electrode double-coil pulse electromagnetic coupling reinforced metal material device is characterized in that the electrode chucks are arranged at the opposite ends of the two transverse electrode columns and the opposite ends of the two longitudinal electrode columns. The electrode chuck is connected with the transverse electrode column or the longitudinal electrode column through detachable connection modes such as threads or buckles. The electrode chuck is mainly used for clamping metal materials to be processed, and different electrode chucks are selected according to metal materials in different shapes, so that clamping is more stable. The specific shape of the electrode cartridge may be variously designed and selected according to the shape or size of the metal material actually processed. In the utility model, the electrode clamp is made of copper material.

The double-electrode and double-coil pulse electromagnetic coupling strengthened metal material device further comprises a power supply assembly, wherein the power supply assembly comprises an electric field generation power supply and a magnetic field generation power supply, the electric field generation power supply is electrically connected with the transverse electrode column and the longitudinal electrode column, and the magnetic field generation power supply is electrically connected with the magnetic field generation coil.

The bipolar electrode-twin coil pulse electromagnetic coupling reinforced metal material device further comprises a cooling assembly, wherein the cooling assembly comprises a first cooling pipeline and a second cooling pipeline which are arranged on the two magnetic field generating coils, and a first cooler and a second cooler which are respectively communicated with the first cooling pipeline and the second cooling pipeline and provide cooling liquid for the first cooling pipeline and the second cooling pipeline.

The utility model provides a metal material device is reinforceed to bipolar electrode-twin coil pulse electromagnetic coupling, compare with prior art, have following beneficial effect:

1. the utility model discloses set up horizontal electrode post, vertical electrode post and magnetic field generating coil on same workstation, form the electromagnetic coupling processing structure of bipolar electrode, twin coil, make metal material can accept on a device multiple intensive processing modes such as monopulse electric field, monopulse magnetic field, pulse electric field-pulse magnetic field coaxial processing or pulse electric field-pulse magnetic field orthogonal processing, the processing mode is nimble various, has brought powerful support for the problem such as treatment effect that the research different processing modes brought;

2. the utility model adopts the design of the slide rail, so that the transverse electrode column, the longitudinal electrode column and the magnetic field generating coil can move on the workbench, and the space between the two magnetic field coils forms a metal material processing cavity, thereby enlarging the processing space of the metal material, improving the application range and processing the metal materials with different sizes and shapes;

3. the utility model adopts the design that two electrode columns clamp the metal material through the electrode chuck, and simultaneously adopts the detachable electrode chuck, so that different electrode chucks can be selected according to the different shapes and sizes of the metal material, and the clamping is more stable;

4. the utility model discloses based on bipolar electrode-twin coil pulse electromagnetic coupling's structure, can also study hall effect to metal material's influence.

Drawings

Fig. 1 is a schematic perspective view of a bipolar electrode-twin coil pulse electromagnetic coupling reinforced metal material device provided in an embodiment of the present invention;

fig. 2 is a front view of a bipolar electrode-dual coil pulse electromagnetic coupling reinforced metal material device provided in an embodiment of the present invention;

fig. 3 is a side view of a dual-electrode-dual-coil pulse electromagnetic coupling reinforced metal material device according to an embodiment of the present invention;

fig. 4 is a top view of a dual-electrode-dual-coil pulse electromagnetic coupling reinforced metal material device provided in an embodiment of the present invention;

FIG. 5 is an enlarged view of portion A of FIG. 4;

in the figure: 1-a workbench; 11-a sample support table; 2-transverse sliding rails; 21-a transverse electrode holder; 211-transverse electrode column; 22-an electromagnetic base; 221-a magnetic field generating coil; 23. 23' -a rack; 24-a gear; 3-longitudinal sliding rail; 31-longitudinal electrode holder; 311-longitudinal electrode column; 4-a sliding bearing; 5-electrode holder; 6-power supply components; 61-electric field generating power supply; 62-a magnetic field generating power supply; 7-a cooling assembly; 71-a first chiller; 72-second cooler.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the accompanying drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", etc. indicate the position or positional relationship based on the position or positional relationship shown in the drawings, or the position or positional relationship which is usually placed when the utility model is used, and are only for convenience of description and simplification of the description, but do not indicate or imply that the device or element referred to must have a specific position, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The bipolar electrode-double coil pulse electromagnetic coupling reinforced metal material device provided by the embodiment comprises a mounting assembly, and an electromagnetic coupling processing assembly and a cooling assembly which are arranged on the mounting assembly.

As shown in fig. 1, the mounting assembly includes a work table 1, a lateral slide rail 2 and a longitudinal slide rail 3 provided on the work table 1. The workbench 1 is a cross-shaped workbench 1, and a sample support platform 11 is arranged in the middle of the workbench. The transverse slide rail 2 and the longitudinal slide rail 3 are respectively arranged on two crossed table-boards of the cross-shaped workbench 1. The cross-shaped workbench 1 reduces the occupied area of the workbench 1, improves the range of motion of an operator and is convenient to operate. The sample support platform 11 is located at the center of the workbench 1, and the sample support platform 11 can be a lifting platform, i.e. a support platform with lifting capability such as a hydraulic lifting rod, and can support the metal material placed on the support platform, so that the stability of the metal material is further ensured.

As shown in fig. 1 to 4, the transverse slide rails 2 and the longitudinal slide rails 3 are arranged perpendicular to each other. The transverse slide rail 2 is provided with a transverse electrode seat 21 and two electromagnetic seats 22 which meet the required quantity of the electromagnetic coupling processing assembly in a sliding manner, and the longitudinal slide rail 3 is provided with a longitudinal electrode seat 31 which meets the required quantity of the electromagnetic coupling processing assembly in a sliding manner. In this embodiment, the transverse slide rails 2 and the longitudinal slide rails 3 are both two, and are parallel to each other between the two transverse slide rails 2, and are parallel to each other between the two longitudinal slide rails 3, the transverse electrode base 21 and the electromagnetic base 22 are placed on the two transverse slide rails 2, and the longitudinal electrode base 31 is placed on the two longitudinal slide rails 3, so that the motor base and the electromagnetic base are installed and operated more stably. Specifically, the bottoms of the transverse electrode seat 21 and the electromagnetic seat 22 are connected with the transverse slide rail 2 in a sliding manner through a sliding bearing 4 fixedly connected with the transverse electrode seat, and the bottom of the longitudinal electrode seat is connected with the longitudinal slide rail in a sliding manner through a sliding bearing fixedly connected with the longitudinal electrode seat.

As shown in fig. 1 to 4, the electromagnetic coupling processing assembly includes an electric field processing assembly and a magnetic field processing assembly. The electric field treatment assembly comprises two transverse electrode columns 211 and two longitudinal electrode columns 311, each having a removable electrode cartridge 5 mounted on the end thereof. The two transverse electrode columns 211 are respectively installed on the two oppositely-arranged transverse electrode holders 21, the two longitudinal electrode columns 311 are respectively installed on the two oppositely-arranged longitudinal electrode holders 31, and the electrode chucks 5 are installed at opposite ends of the two transverse electrode columns 211 and opposite ends of the two longitudinal electrode columns 311. The two transverse electrode columns 211 and the two longitudinal electrode columns 311 constitute a dual electrode structure in mutually perpendicular directions. The magnetic field processing assembly comprises two magnetic field generating coils 221, the two magnetic field generating coils 221 are arranged on two oppositely arranged electromagnetic bases 22 to form a double-coil structure, the electromagnetic bases are arranged on the inner sides of the transverse electrode bases, and the transverse electrode columns 211 penetrate out of the magnetic field generating coils opposite to the transverse electrode columns. The axes of the transverse electrode column 211, the longitudinal electrode column 311, and the magnetic field generating coil 221 are located on the same plane, that is, the electric field generated by the transverse electrode column 211 is perpendicular to the electric field generated by the longitudinal electrode holder 311, the electric field generated by the transverse electrode column 211 is parallel to the magnetic field generated by the magnetic field generating coil 221, and the electric field generated by the longitudinal electrode holder 311 is perpendicular to the magnetic field generated by the magnetic field generating coil 221, so as to ensure the uniformity of the treatment.

The electrode clamp 5 is detachably connected with the transverse electrode column 211 or the longitudinal electrode column 311 through threads, and different electrode clamps 5 are selected according to different shapes of metal materials to be processed, so that clamping is more stable. The specific shape of the electrode holder can be designed and selected differently according to the shape or size of the actual metal material. Here, the electrode cartridge 5 is a copper material.

The bottom of the workbench 1 is provided with a moving assembly; the movable assembly is universal wheels arranged at four corners of the bottom of the workbench 1, and lifting support columns are further arranged at the four corners of the bottom of the workbench 1. The moving assembly can also be a device such as a roller and the like which can roll, and the moving assembly is mainly used for driving the workbench 1 to move, so that the flexibility of the workbench 1 is improved. And the lifting support column is arranged beside the moving assembly, is in threaded connection with the bottom of the workbench 1 through a threaded rod, and can be lifted by rotating the lifting support column to adjust the height of the lifting support column. When the workbench 1 does not need to move, the lifting support column is lowered to be in contact with the ground so as to support the workbench 1; when the workbench 1 needs to move, the lifting support column is lifted, so that the lifting support column is separated from the ground, and the universal wheels or the rollers are in contact with the ground, so that the workbench 1 has the rolling movement capacity.

In this embodiment, the metal material to be processed is clamped by the two electrode chucks 5 at the opposite ends of the two transverse electrode holders 21 or the two longitudinal electrode holders 31, and the magnetic field generating coils on the two electromagnetic holders 22 are symmetrically fixed at the set positions, so that the metal material to be processed is located in the material processing cavity formed by the electric field and the magnetic field. The two electrode chucks can simultaneously clamp metal materials, so that the clamping is more stable.

In this embodiment, the workpiece is clamped by controlling the transverse electrode holder 21 or the longitudinal electrode holder 31 to move on the transverse slide rail or the longitudinal slide rail respectively, in a preferred implementation manner, when the transverse electrode holder or the longitudinal electrode holder is stopped from being driven, a certain constraint force can be generated, so that the transverse electrode holder 21 and the electromagnetic holder 22 can be stably fixed on the transverse slide rail 2 without sliding, that is, when the transverse electrode holder 21 and the electromagnetic holder 22 are not used or work by clamping a metal material, the transverse electrode holder 21 and the electromagnetic holder 22 can be stably stopped on the transverse slide rail 2, thereby avoiding instability of the metal material, the electric field, or the magnetic field. Furthermore, in order to satisfy the real-time symmetry of the positions of the two opposite electrodes on the transverse slide rail or the longitudinal slide rail, it is necessary to be able to synchronously approach or synchronously separate the two opposite electrode holders on the transverse slide rail or the longitudinal slide rail. Similarly, the relative displacement between the two magnetic field generating coils on the transverse slide rail can be adjusted by controlling the electromagnetic seat 22 to move on the transverse slide rail, so as to realize the clamping of the metal material with longer size. Furthermore, in order to satisfy the real-time symmetry of the positions of the two opposite magnetic field generating coils on the transverse slide rail, it is necessary to be able to synchronously approach or synchronously separate the two opposite electromagnetic seats on the transverse slide rail.

In this embodiment, the driving modes of the two electromagnetic seats on the transverse slide rail, the driving modes of the two transverse electrode seats, and the driving modes of the two longitudinal electrode seats on the longitudinal slide rail are the same, and all the driving modes are the driving modes formed by the gear and the linear rack.

The above driving method is explained in detail by taking two electromagnetic seats on the transverse slide rail as an example. As shown in fig. 4 and 5, the electromagnetic base 22 is driven by a driving system including a gear 24 and linear racks (23, 23') to move along the lateral slide rail. The gear 24 is arranged on the workbench 1, and two opposite linear racks (23, 23') which are meshed with the gear and are parallel to the transverse sliding rail 2 are respectively arranged on two electromagnetic seat fixed supporting plates. One supporting plate is fixed on the outer side surface of one electromagnetic seat; the other supporting plate is in a long strip shape, one end of the other supporting plate is fixedly connected with the outer side surface of the other electromagnetic seat, and the other end of the other supporting plate penetrates through the lower part of the table top where the longitudinal sliding rail is located and is arranged on a rail parallel to the transverse sliding rail. The gear 24 is connected with a driving motor on the workbench 1, and the driving motor drives the gear 24 to rotate, so that the rack 23 and the rack 23' meshed with the gear 24 move along two opposite directions, and further drives the two electromagnetic seats to synchronously approach or leave on the transverse sliding rail 2. The electromagnetic seat 22 is moved on the transverse slide rail 2 by the driving mode of the gear 24 and the linear racks (23, 23'), so that the magnetic field generating coil 221 applies a pulse magnetic field to the metal material workpiece to a required processing position, and the requirements of coupling a strong magnetic field and a strong electric field on the reliability and the synchronism of equipment and the distribution of a mechanism on space are met.

When the driving mode of the two transverse electrode holders on the transverse slide rail is the same as that of the two longitudinal electrode holders on the longitudinal slide rail, the driving mode consisting of the gear and the linear rack is also adopted, so that the electromagnetic holders and the electrode holders are respectively controlled. In a preferred implementation, the mounting positions of the linear rack on the transverse electrode holder and the longitudinal electrode holder can be located inside two opposite transverse sliding rails or longitudinal sliding rails (as shown in fig. 1).

The above-mentioned electromagnetically coupled processing assembly further comprises a power supply assembly 6. The power supply module 6 includes an electric field generating power supply 61 electrically connected to the transverse electrode column 211 and the longitudinal electrode column 311, and a magnetic field generating power supply 62 electrically connected to the magnetic field generating coil 221. The electric field generating power source 61 supplies the transverse electrode column 211 and the longitudinal electrode column 311 with energy for generating electric fields, and the magnetic field generating power source 62 supplies the magnetic field generating coil 221 with energy for generating magnetic fields.

The cooling unit 7 includes first and second cooling circuits provided on the two magnetic field generating coils 221, and first and second coolers 71 and 72 that are respectively communicated with the first and second cooling circuits and supply cooling liquid thereto. The first cooler and the second cooler are conventional cooling devices in the field, such as an existing water cooling device or an existing oil cooling device, and may be composed of components including, but not limited to, a cooling power supply, a compressor, a condenser, an expansion valve, an evaporator, a water pump, a water tank, and the like, wherein the compressor, the condenser, and the expansion valve are sequentially connected between an outlet end and an inlet end of the evaporator, the evaporator and the water pump are all disposed in the water tank, a water outlet of the water pump is connected with a water inlet of the cooling pipeline through a circulating water inlet pipe, and a water outlet of the cooling pipeline is connected with a water inlet of the. The cooling assembly 7 is used for cooling the magnetic field generating coil 221, so that the normal operation of the magnetic field generating coil 221 is ensured.

In the device for reinforcing the metal material by the double-electrode and double-coil pulse electromagnetic coupling provided by the embodiment, when the electromagnetic coupling processing works, firstly, the metal material workpiece is placed between the two transverse electrode columns 211 or the two longitudinal electrode columns 311, then the transverse electrode holder 21 or the longitudinal electrode holder 31 is moved to enable the metal material to be positioned in the middle of the device, then the metal material workpiece is clamped and fixed by the electrode chuck 5, then the gear 24 rotates to drive the electromagnetic holder 22 to move on the transverse slide rail 2 to enable the magnetic field generating coil 221 to reach a required processing position, the electric field generating power source 61, the magnetic field generating power source 62 and the cooling assembly 7 are started, the effective coupling of the pulse magnetic field and the pulse electric field is simultaneously completed under the cooling effect of the cooling assembly 7, the electromagnetic coupling processing on the workpiece is completed, the internal microscopic defects of the metal material can be remarkably reduced, the residual stress is reduced, The fatigue strength is improved, and the service life of the metal material is greatly prolonged.

The bipolar electrode-double coil pulse electromagnetic coupling reinforced metal material device provided by the embodiment has the following working modes:

(1) single-pulse electric field treatment, namely, when the two transverse electrode columns 211 or the two longitudinal electrode columns 311 clamp the metal material and only the clamped transverse electrode columns 211 or the longitudinal electrode columns 311 work to generate an electric field, the single-pulse electric field treatment is performed;

(2) single pulse magnetic field treatment, namely when the two transverse electrode columns 211 clamp the metal material, the magnetic field generating coils on the two electromagnetic seats 22 move to set positions, the two magnetic field generating coils are symmetrically arranged relative to the metal material, and single pulse magnetic field treatment is performed when only the two magnetic field generating coils 221 work;

(3) the pulse electric field-pulse magnetic field coaxial treatment is carried out, when the two transverse electrode columns 211 clamp the metal material, the magnetic field generating coils on the two electromagnetic seats 22 move to set positions, the two magnetic field generating coils are symmetrically arranged relative to the metal material, and the pulse electric field-pulse magnetic field coaxial treatment is carried out when the transverse electrode columns 211 and the magnetic field generating coils 221 work;

(4) and (3) performing pulse electric field-pulse magnetic field orthogonal treatment, namely, when the two longitudinal electrode columns 311 clamp the metal material, the magnetic field generating coils on the two electromagnetic seats 22 move to a set position, the two magnetic field generating coils are symmetrically arranged relative to the metal material, and the longitudinal electrode columns 311 and the magnetic field generating coils 221 work to perform pulse electric field-pulse magnetic field orthogonal treatment, so that the influence of the Hall effect on the metal material can be researched.

The utility model arranges the transverse electrode column 211, the longitudinal electrode column 311 and the magnetic field generating coil 221 on the same workbench 1, so that the metal material can receive various strengthening treatment modes such as monopulse electric field, monopulse magnetic field, pulse electric field-pulse magnetic field coaxial treatment or pulse electric field-pulse magnetic field orthogonal treatment on one device, the treatment modes are flexible and various, and powerful support is provided for researching the treatment effects and other problems brought by different treatment modes; meanwhile, the design of a sliding rail is adopted, so that the transverse electrode column 211, the longitudinal electrode column 311 and the magnetic field generating coil 221 can move on the workbench 1, the processing space of metal materials is enlarged, the application range is also improved, and the metal materials with different sizes and different shapes can be processed; the utility model discloses a two electrode posts pass through the design of 5 centre gripping metal materials of detachable electrode holder, can select different electrode holder 5 according to the difference such as metal material shape and size, and the centre gripping is more stable.

Compare with current electromagnetic coupling metal intensification device, the utility model discloses a processing space is bigger also more nimble, and the mode of processing is various, the utility model discloses a structure of bipolar electrode-twin coil pulse electromagnetic coupling can also study hall effect to metal material's influence, handles to electromagnetic coupling material and has very important meaning.

Of course, the present invention may have other embodiments, and those skilled in the art may make various corresponding changes and modifications according to the present invention without departing from the spirit and the essence of the present invention, and these corresponding changes and modifications should fall within the protection scope of the appended claims.

Claims (10)

1. A bipolar electrode-double coil pulse electromagnetic coupling reinforced metal material device is characterized in that: the electromagnetic coupling processing assembly comprises a mounting assembly and an electromagnetic coupling processing assembly arranged on the mounting assembly;

the mounting assembly comprises a workbench (1), a transverse slide rail (2) and a longitudinal slide rail (3), wherein the transverse slide rail (2) and the longitudinal slide rail (3) are arranged on the workbench (1), a transverse electrode seat (21) and an electromagnetic seat (22) are arranged on the transverse slide rail (2) in a sliding manner, and a longitudinal electrode seat (31) is arranged on the longitudinal slide rail (3) in a sliding manner;

the electromagnetic coupling processing assembly comprises an electric field processing assembly and a magnetic field processing assembly, the electric field processing assembly comprises two transverse electrode columns (211) arranged on two transverse electrode seats (21) which are oppositely arranged and two longitudinal electrode columns (311) arranged on two longitudinal electrode seats (31) which are oppositely arranged, and each electrode column is provided with a detachable electrode chuck (5); the magnetic field processing assembly comprises magnetic field generating coils (221) arranged on two electromagnetic seats (22) which are oppositely arranged, and a material processing cavity (222) is arranged in the middle of each magnetic field generating coil (221);

the bottom of the workbench (1) is provided with a moving assembly;

the metal material to be processed is clamped by two electrode chucks opposite to the two transverse electrode seats or the two longitudinal electrode seats, and meanwhile, the magnetic field generating coils on the two electromagnetic seats (22) are symmetrically fixed at set positions, so that the metal material to be processed is positioned in a material processing cavity formed by an electric field and a magnetic field.

2. The bipolar electrode-twin coil pulsed electromagnetic coupling strengthened metallic material device of claim 1, wherein: workstation (1) is cross workstation (1), and install respectively on two cross vertically crossed's of cross workstation (1) mesa horizontal slide rail (2) and vertical slide rail (3), the universal wheel of removal subassembly for setting up in workstation (1) bottom four corners department, workstation (1) bottom four corners department still is provided with the lift support post.

3. The bipolar electrode-dual coil pulsed electromagnetic coupling enhanced metallic material device as set forth in claim 1 or 2, wherein: and a sample supporting table (11) is arranged in the middle of the workbench (1).

4. The bipolar electrode-twin coil pulsed electromagnetic coupling strengthened metallic material device of claim 1, wherein: the transverse slide rail (2) and the longitudinal slide rail (3) are arranged perpendicular to each other.

5. The bipolar electrode-twin coil pulsed electromagnetic coupling strengthened metallic material device of claim 1, wherein: the axial leads of the transverse electrode column (211), the longitudinal electrode column (311) and the magnetic field generating coil (221) are positioned on the same plane.

6. The bipolar electrode-twin coil pulsed electromagnetic coupling enhanced metallic material device as set forth in claim 1 or 5, wherein: the electrode chucks (5) are arranged at the opposite ends of the two transverse electrode columns (211) and the opposite ends of the two longitudinal electrode columns (311).

7. The bipolar electrode-twin coil pulsed electromagnetic coupling strengthened metallic material device of claim 1, wherein: the transverse electrode seat (21) and the electromagnetic seat (22) move on the transverse sliding rail (2) through one or more driving modes of a screw rod, a motor, an air cylinder and a hydraulic cylinder, and the longitudinal electrode seat (31) moves on the longitudinal sliding rail (3) through one or more driving modes of the screw rod, the motor, the air cylinder and the hydraulic cylinder.

8. The bipolar electrode-dual coil pulsed electromagnetic coupling enhanced metallic material device as recited in claim 1 or 7, wherein: the two relative electromagnetic seats (22) are provided with racks (23, 23 '), the workbench (1) is provided with a gear (24) which is simultaneously meshed with the racks (23, 23'), the gear (24) is connected with a driving motor, the two electromagnetic seats are driven by the gear to synchronously move along a transverse sliding rail, and the two relative transverse electrode seats or the two relative longitudinal electrode seats are identical in moving implementation mode with the electromagnetic seats.

9. The bipolar electrode-twin coil pulsed electromagnetic coupling strengthened metallic material device of claim 1, wherein: the power supply assembly (6) comprises an electric field generation power supply (61) electrically connected with the transverse electrode column (211) and the longitudinal electrode column (311) and a magnetic field generation power supply (62) electrically connected with the magnetic field generation coil (221).

10. The bipolar electrode-twin coil pulsed electromagnetic coupling strengthened metallic material device of claim 1, wherein: the cooling device is characterized by further comprising a cooling assembly (7), wherein the cooling assembly (7) comprises a first cooling pipeline and a second cooling pipeline which are arranged on the two magnetic field generating coils (221) and the magnetic field generating power supply (62), and a first cooler (71) and a second cooler (72) which are respectively communicated with the first cooling pipeline and the second cooling pipeline and provide cooling liquid for the first cooling pipeline and the second cooling pipeline.

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