CN116984468B - Ultra-thin metal polar plate ultrasonic auxiliary accurate forming device - Google Patents

Abstract

The invention discloses an ultra-thin metal polar plate ultrasonic auxiliary accurate forming device, which comprises a press, a hydraulic source, a hydraulic pipeline, an air pressure source and an air pressure pipeline, wherein a lower die holder is fixedly arranged on a working table surface of the press; at least one liquid filling port is formed in the upper die. According to the invention, by adopting the liquid filling preforming, hard die shaping and ultrasonic control type composite forming device, liquid filling preforming, hard die shaping and ultrasonic control type are realized on the same device, repeated positioning of the plate is avoided, the shape accuracy control is more accurate, and the forming efficiency is higher.

Description

Ultra-thin metal polar plate ultrasonic auxiliary accurate forming device

Technical Field

The invention relates to the technical field of stamping forming of metal plates, in particular to an ultrasonic-assisted precise forming device for an ultrathin metal plate.

Background

The hydrogen fuel cell directly converts hydrogen energy into electric energy through electrochemical reaction, has the advantages of cleanness, high efficiency, wide fuel source and the like, can be widely applied to the fields of traffic, industry, construction, energy storage and the like, and has important significance for realizing carbon peak and carbon neutralization. The polar plate is a key component in the hydrogen fuel cell, plays a plurality of roles of supporting a membrane electrode, separating hydrogen and oxygen, collecting electrons, conducting heat, providing a hydrogen and oxygen channel, discharging water generated by reaction, providing a cooling liquid flow channel and the like, and is a core component for guaranteeing the performance of the fuel cell stack. According to different materials, the polar plates are divided into a graphite polar plate, a composite polar plate and a metal polar plate, wherein the metal polar plate is easy for mass production, has the advantages of small volume, high power density, good vibration resistance, quick cold start and the like, and becomes an important direction of fuel cell technology development.

Along with the application of the hydrogen fuel cell in the fields of heavy commercial vehicles, ships and the like, the power requirement of the hydrogen fuel cell is increased to more than 200kW, the continuous improvement of the light-weight requirement is achieved, and the plate width of the polar plate is increased (more than or equal to 600 cm) ² ) The thickness reduction (less than or equal to 0.1 mm) is a higher requirement. The performance and life indexes of the hydrogen fuel cell put stringent requirements on geometric characteristics and dimensional accuracy of a polar plate runner, particularly on micro-scale forming of a complex runner structure, and the requirements reach the precision level of ultra-precise machining, which exceeds the theoretical limit of the forming precision of the traditional plate, and are the technological problems of leading edge science and commonality in the global fuel cell industry.

The structure of the metal polar plate in the prior art is shown in fig. 1 and 2, and the metal polar plate is formed by stamping a thin plate, so that the fine runner characteristic can be formed, but the initial plate thickness is 0.075-0.1 mm, and the rebound of a deformation area is serious due to the release of residual stress after forming, so that the dimensional accuracy of the runner is poor; and because of the large-scale dense flow channel distribution, the warping is serious after stamping. In order to control the precision of the runner, two-step stamping forming or three-step stamping forming is adopted at present, the dimensional precision and the warping degree of the runner are controlled through multi-pass stamping, but an excessive thinning area appears at the contact part of the runner and a convex die fillet in the multi-step stamping forming process, the uniformity of the wall thickness is poor, and the forming limit is low.

Disclosure of Invention

The technical problems to be solved by the invention are as follows: aiming at the defects existing in the prior art, the invention provides an ultra-thin metal polar plate ultrasonic auxiliary precise forming device, which realizes liquid filling preforming, hard die shaping and ultrasonic control forming on the same device by adopting a liquid filling preforming, hard die shaping and ultrasonic control forming device, thereby avoiding repeated positioning of the plate, ensuring more accurate shape precision control and higher forming efficiency.

In order to solve the technical problems, the invention adopts a technical scheme that:

the ultrasonic auxiliary precise forming device for the ultrathin metal polar plate comprises a press, a hydraulic source, a hydraulic pipeline, an air pressure source and an air pressure pipeline, wherein a lower die holder is fixedly arranged on a working table surface of the press, a lower die is arranged in the top of the lower die holder, an ultrasonic assembly is fixedly arranged in the working table of the press, an energy output end of the ultrasonic assembly is fixedly connected with the bottom surface of the lower die, a bag-type sealing element connected with the output end of the air pressure pipeline is fixedly connected to one side of the top surface of the lower die holder, after the air pressure source blows air into the bag-type sealing element, the bag-type sealing element expands and is positioned above the top surface of the lower die, and after the air pressure source withdraws the air in the bag-type sealing element, the bag-type sealing element contracts and is tightly positioned at one side of the lower die;

the power end of the press is fixedly provided with an upper die holder right above the lower die holder, the bottom of the upper die holder is fixedly provided with an upper die, when the bag-type sealing element is in an expanded state, the press drives the upper die holder and the upper die to move downwards, the bottom surface of the upper die is tightly contacted with the top surface of the bag-type sealing element, the bottom surface of the bag-type sealing element is tightly contacted with the top surface of the lower die, and a sealing cavity is formed by encircling the upper die and the lower die;

at least one liquid filling port is formed in the upper die, the inner side end of the liquid filling port is communicated with the sealing cavity, and the outer side end of the liquid filling port is connected with the output end of the hydraulic pipeline.

Further, the inside of the bag type sealing piece is integrally provided with a plurality of sealing strips which are distributed in a crisscross mode and are mutually communicated in the inside, and the sealing strips divide the internal space of the bag type sealing piece into a plurality of block liquid filling cavities.

Further, a liquid filling port is arranged in the top area of the bottom surface of the upper die, which corresponds to the liquid filling cavity of each block.

Furthermore, the output end of the hydraulic pipeline is provided with a plurality of liquid filling branch pipes which are respectively connected with each liquid filling port, and each liquid filling branch pipe is provided with a control valve.

Further, a wave-isolating piece is arranged between the lower die and the lower die holder.

Further, a plurality of longitudinally and transversely staggered wave-insulating grooves are formed in the bottom surface of the lower die, and divide the bottom surface of the lower die into a plurality of uniformly distributed block ultrasonic resonance areas.

Furthermore, a plurality of wave-insulating strips which are inserted with the wave-insulating grooves are integrally arranged in the wave-insulating piece, and the wave-insulating strips divide the internal space of the wave-insulating piece into block ultrasonic resonance cavities corresponding to the block ultrasonic resonance areas.

Further, the ultrasonic assembly comprises a plurality of ultrasonic generators, and an ultrasonic generator is arranged below the ultrasonic resonance area of each block.

Further, the lower die is made of Ti-6Al-4V.

Also provided is an ultrasonic-assisted precise forming method of an ultrathin metal polar plate, comprising the following steps:

s1: placing a plate blank to be formed in a preassembled position in a lower die;

s2: starting an air pressure source to work, blowing air into the bag type sealing element, and expanding and unfolding the bag type sealing element and being positioned above the top surface of the lower die;

s3: starting the press machine to work and controlling the power end stroke of the press machine, so that the press machine drives the upper die to descend to a preformed position, and the bag-type sealing element surrounds the upper die and the lower die to form a sealing cavity;

s4: starting a hydraulic source to work, so that high-pressure liquid is injected into the sealing cavity, and the high-pressure liquid is matched with the lower die to finish the preforming of the surface of the slab;

s5: closing a hydraulic source, starting a press machine to work, driving an upper die to ascend and reset, starting an air pressure source to work, and extracting air in the bag type sealing element to enable the bag type sealing element to shrink and tightly close to one side of a lower die;

s6: starting the press again to work and controlling the stroke of the power end, wherein the press drives the upper die to move downwards and to be matched with the lower die, and the upper die is matched with the lower die to finish the stamping and fine shaping of the preformed plate;

s7: maintaining the die assembly state of the upper die and the lower die, starting the ultrasonic assembly to work, enabling the lower die and the plate after stamping and fine shaping to synchronously perform ultrasonic resonance, and completing ultrasonic stress relaxation of a plate deformation area;

s8: after the forming is finished, the ultrasonic assembly is closed, the press is started to work, the press drives the upper die to reset upwards, and the formed piece is taken out.

Further, in step S3, the sealing cavity includes a plurality of block forming areas symmetrically distributed in the left, right, front and rear directions and independent of each other, each block filling cavity is provided with a filling port therein, and the plurality of filling cavities divide the slab surface into a plurality of block forming areas correspondingly.

Further, in step S4, the liquid injection in each block forming area is completed in a manner that the distribution positions of each block forming area are from outside to inside, diagonally paired, and two sides alternate, and the liquid filling pre-forming is completed in each block forming area, and then the pressure is maintained.

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

according to the invention, by adopting the liquid filling preforming, hard die shaping and ultrasonic control type composite forming device, various processing technologies of liquid filling preforming, hard die shaping and ultrasonic control type are realized on the same device, repeated positioning of the plate can be avoided, so that the shape accuracy control of a formed part is more accurate, and the forming efficiency is higher;

according to the invention, the bag-type sealing element is arranged at the bottom of the upper die, a soft sealing structure can be formed between the upper die and the lower die by inflating the bag-type sealing element, and isostatic high-pressure liquid is filled in the soft sealing structure, so that the stress on each part of the surface of a plate blank is uniform, the thickness is reduced uniformly in the plate blank forming process, the wall thickness is uniformly distributed after the pre-forming, an excessive reduction area is not existed, and the forming limit can be improved;

according to the invention, the forming of fine features such as fine runners and the like which cannot be finished by liquid filling forming is realized through the hard die stamping, the precise shaping is finished, and the soft and hard die composite drawing forming method is adopted, so that liquid filling preforming is firstly carried out, then the hard die shaping is carried out, the conventional hard die stamping forming pass is reduced, and further the damage to the surface quality of a plate by the hard die drawing is reduced;

according to the invention, the ultrasonic assembly is integrated at the bottom of the lower die, and the ultrasonic vibration is applied to the punched plate under a certain mold clamping force, so that the residual stress in the plate forming area is relaxed and removed in time, thereby effectively improving the rebound resilience of the flow passage of the plate, reducing the warping degree of the whole plate, and further enabling the shape and size accuracy control of the plate to be more accurate.

According to the invention, by arranging a plurality of block forming areas, multi-cavity local loading can be realized, and space-time coupling in the forming process of each block forming area is realized through local filling of each cavity, sequential design of loading of each cavity, forming pressure regulation and control of each cavity and pressure maintaining duration control of each cavity, so that forming pressure can be effectively reduced, and warping is relieved; meanwhile, a plate can be formed in each block forming area, so that the processing mode of a plurality of pieces can be realized on the premise of not increasing the filling pressure, and the processing efficiency and the equipment performance utilization rate are improved.

Drawings

FIG. 1 is a schematic top view of a prior art plate;

FIG. 2 is a schematic side sectional view of a prior art pole plate;

FIG. 3 is a schematic perspective view of an ultra-thin metal plate ultrasound-assisted precision forming apparatus according to the present invention;

FIG. 4 is a schematic perspective view of a forming mold according to the present invention;

FIG. 5 is a schematic perspective view of the lower mold;

FIG. 6 is a second schematic perspective view of the lower mold;

FIG. 7 is a schematic perspective view of the balloon seal in an inflated and deployed state;

FIG. 8 is a schematic perspective view of the bladder seal in a contracted and tightened state;

FIG. 9 is a schematic diagram of a three-dimensional structure of the upper die holder and the upper die;

fig. 10 is a schematic perspective view of the connection state of the ultrasonic generator and the lower die;

FIG. 11 is a schematic perspective view of the wave barrier;

FIG. 12 is a schematic perspective view showing the assembled state of the lower die holder and the components therein;

FIG. 13 is a process flow diagram of an ultra-thin metal plate ultrasound-assisted precision forming method employing the present invention.

In the figure: the ultrasonic wave generator comprises a press 1, a hydraulic source 2, a hydraulic pipeline 201, a control valve 202, a liquid filling branch pipe 203, a pneumatic source 3, a hydraulic pipeline 301, a lower die holder 4, an upper die holder 5, a side port 501, a lower die 6, a wave isolating groove 601, a lower molding cavity 602, an upper die 7, a liquid filling port 701, an upper molding cavity 702, an 8-bag type sealing element, a sealing strip 801, a wave isolating element 9, a wave isolating strip 901 and an ultrasonic wave generator 10.

Detailed Description

The preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings so that the advantages and features of the present invention can be more easily understood by those skilled in the art, thereby making clear and defining the scope of the present invention.

Referring to fig. 3 to 13, an ultra-thin metal plate ultrasonic-assisted precise forming device comprises a press 1, a hydraulic pressure source 2, a hydraulic pressure pipeline 201 connected with the hydraulic pressure source 2, an air pressure source 3 and an air pressure pipeline 301 connected with the air pressure source 3. The hydraulic press 1 adopts a general portal frame vertical type hydraulic press for outputting pressure downwards, the hydraulic source 2 adopts an oil supply system of the press 1 or adopts a general hydraulic supply device for independent control and power output, the pneumatic source 3 adopts a general pneumatic supply device with high-pressure gas output and vacuum extraction functions, and the above devices are all in the prior art and are not described in detail herein.

The working table of the press 1 is fixedly provided with a lower die holder 4, the lower die holder 4 is of a rectangular groove structure with an open top, and the bottom surface of the lower die holder 4 is fixedly connected to the working table of the press 1 through bolts. A lower die 6 is arranged in the top of the lower die holder 4. As shown in fig. 5, the lower die 6 has a cubic plate-like structure as a whole, and a lower molding cavity 602 for forming the bottom surface of the slab is provided on the top surface thereof, and is a forming work area of the lower die 6. The lower die 6 is embedded in the groove of the lower die holder 4, the bottom surface and/or the side surface are fixedly connected with the lower die holder 4 through bolts, and the top surface of the lower die 6 protrudes above the top surface of the lower die holder 4.

As shown in fig. 7 and 8, a side plate which is vertically arranged is integrally arranged on one side of the top surface of the lower die holder 4, an air inlet end of the bag type sealing element 8 is fixedly bonded on the side surface of the side plate, and an air outlet end of the air pressure pipeline 301 penetrates through the side plate and is connected with the air inlet end of the bag type sealing element 8. After the air pressure source 3 blows air into the bag-type sealing element 8, the bag-type sealing element 8 expands and is positioned above the top surface of the lower die 6, and after the air pressure source 3 pumps the air in the bag-type sealing element 8, the bag-type sealing element 8 contracts and is tightly positioned at one side of the lower die 6.

An upper die holder 5 positioned right above the lower die holder 4 is fixedly arranged at the power end of the press machine 1, and an upper die 7 is fixedly arranged at the bottom of the upper die holder 5. As shown in fig. 9, the upper die holder 5 has a rectangular groove structure with an opening bottom, the length and the width of the upper die holder are the same as those of the lower die holder 4, and the top surface of the upper die holder is fixedly connected to the power output end of the press 1 through bolts, so that the upper die holder 5 can be driven to vertically lift at fixed intervals through the power output end of the press 1; the upper die 7 has a cubic plate-like structure as a whole, and an upper molding cavity 702 for forming the top surface of the slab is provided on the bottom surface thereof, and the length and width dimensions of the upper die 7 are the same as those of the lower die 4. The upper die 7 is embedded in a groove of the upper die holder 5, the top surface and/or the side surface are/is fixedly connected with the upper die holder 5 through bolts, and the bottom surface of the upper die 7 is inwards concave above the bottom surface of the upper die holder 5.

When the bag type sealing element 8 is in an expanded state, the power output end of the press 1 drives the upper die holder 5 and the upper die 7 to descend to a preset height, the side wall of the upper die holder 5 is buckled on the outer side of the bag type sealing element 8, the bottom surface of the upper die 7 is tightly contacted with the top surface of the bag type sealing element 8, the bag type sealing element 8 is pressed down, the bottom surface of the bag type sealing element 8 is tightly contacted with the top surface of the lower die 6, the outer side surface of the bag type sealing element 8 is tightly contacted with the inner wall of the upper die holder 5, a sealing cavity is formed by encircling the bag type sealing element 8 between the upper die 7 and the lower die 6, and a plate blank to be formed is completely positioned in the sealing cavity. For this purpose, as shown in fig. 9, a side opening 501 is provided on the bottom surface side of the upper die holder 5 above the air inlet end of the bag-type seal 8 for accommodating the air inlet end of the bag-type seal 8.

At least one liquid filling port 701 is formed in the upper die 7, the inner side end of the liquid filling port 701 is communicated with the sealing cavity, and the outer side end of the liquid filling port 701 is connected with the output end of the hydraulic pipeline 201. After the sealing cavity is formed, the hydraulic source 2 is started to work, high-pressure liquid (such as general hydraulic oil, an oil layer can be formed on the surface of the plate blank) is injected into the sealing cavity by the hydraulic source 2 through the hydraulic pipeline 201 and the liquid filling port 701, and the high-pressure liquid is isostatic, so that the stress on the surface of the plate blank is uniform, the thickness of the plate blank is reduced uniformly in the forming process of the plate blank, the wall thickness is uniformly distributed after the pre-forming, an excessive thinning area does not exist, and the forming limit can be improved. After the high-pressure liquid is maintained for a certain time, the hydraulic source 2 is closed, the upper die 7 is lifted and reset through the press 1, the bag-type sealing element 8 is in a loose state, the air pressure source 3 is started to work, air in the bag-type sealing element 8 is extracted, the bag-type sealing element 8 is contracted and is tightly positioned on one side of the lower die 6, the high-pressure liquid naturally flows downwards in the contraction process of the bag-type sealing element 8, flows into the table surface of the working table of the press 1 through the groove body and/or the outer wall of the lower die holder 4, the oil leakage hole is formed in the table surface of the working table, and the infusion tube is arranged below the oil leakage hole, so that the high-pressure liquid can be recovered.

After the bag-type sealing element 8 is contracted and tightened, the power output end of the press 1 drives the upper die holder 5 and the upper die 7 to descend to a preset height again, die assembly between the upper die 7 and the lower die 6 is completed, forming of fine features such as fine runners which cannot be completed by liquid filling forming is realized through hard die stamping, and precise shaping is completed. By adopting the soft and hard die composite drawing forming method, liquid filling preforming is performed firstly, and then the hard die is shaped, so that the conventional hard die stamping forming pass is reduced, and further the damage to the surface quality of the plate by the hard die drawing is reduced.

An ultrasonic assembly is fixedly arranged in a workbench of the press 1, and an energy output end of the ultrasonic assembly is fixedly connected with the bottom surface of the lower die 6 (as shown in fig. 10). The ultrasonic assembly includes at least one ultrasonic generator 10, the ultrasonic generator 10 being commercially available. After finishing the hard die shaping, the upper die 7 and the lower die 6 are kept in a die-closing state, an ultrasonic assembly is started to work, the ultrasonic assembly acts on the lower die 6, so that the lower die 6 and a plate blank synchronously resonate, the residual stress of a plate forming area is relaxed through ultrasonic vibration, the residual stress is removed in time, the rebound resilience of a flow passage of a plate can be effectively improved, the warping degree of the whole plate is reduced, and the shape and the size precision of the plate are controlled more accurately.

Preferably, the lower die 6 is made of Ti-6Al-4V, heat treatment is not needed, and ultrasonic resonance is easier to realize. Further preferably, a wave-blocking member 9 is provided between the lower die 6 and the lower die holder 4. As shown in fig. 11, the wave-insulating member 9 is a box structure with an open top and is made of a nonmetallic material, the length and width dimensions of the inner cavity of the wave-insulating member are matched with those of the lower die 6, and the outer length and width dimensions of the inner cavity of the wave-insulating member are matched with those of the inner side of the groove of the lower die holder 4, so that the wave-insulating member 9 is fixedly embedded at the bottom of the groove of the lower die holder 4, the lower die 6 is embedded in the wave-insulating member 9, and the wave-insulating member 9 is arranged between the lower die 6 and the lower die holder 4, so that the ultrasonic wave received by the lower die 6 is limited in the cavity of the wave-insulating member 9, the ultrasonic energy is concentrated, the stress relaxation effect of a plate is improved, the wave energy loss is reduced, and the energy utilization rate is improved.

Referring to fig. 13, an ultrasonic-assisted precise forming method of an ultrathin metal plate includes the following steps:

s1: placing a plate blank to be formed in a preassembled position in a lower die 6;

s2: starting the air pressure source 3 to work, blowing air into the bag-type sealing element 8, and expanding and unfolding the bag-type sealing element 8 and being positioned above the top surface of the lower die 6;

s3: starting the press 1 to work and controlling the power end stroke of the press 1 to enable the press 1 to drive the upper die 7 to descend to a preformed position; in this position, the bottom surface of the upper die 7 is in close contact with the top surface of the bladder seal 8, and the bladder seal 8 is pressed down so that the bottom surface of the bladder seal 8 is in close contact with the top surface of the lower die 6, the outer side surface of the bladder seal 8 is in close contact with the inner wall of the upper die holder 5, the bladder seal 8 surrounds between the upper die 7 and the lower die 6 to form a seal cavity, and the slab to be formed is entirely within the seal cavity.

S4: starting the hydraulic source 2 to work, so that high-pressure liquid is injected into the sealing cavity, the high-pressure liquid forms uniformly distributed hydraulic pressure on the top surface of the slab, the hydraulic pressure acts on the surface of the slab, and the preforming of the surface of the slab is completed through the cooperation of static pressure and the lower molding cavity 602 on the surface of the lower mold 6;

s5: closing the hydraulic pressure source 2, starting the press 1 to work, driving the upper die 7 to ascend and reset, starting the air pressure source 3 to work, and extracting the air in the bag-type sealing element 8 to enable the bag-type sealing element 8 to shrink and tightly close to one side of the lower die 6;

s6: starting the press 1 to work again and controlling the stroke of a power end, wherein the press 1 drives the upper die 7 to move downwards and to be matched with the lower die 6, the upper die 7 applies punching force to the surface of a plate blank, and the upper molding cavity 702 on the bottom surface of the upper die 7 is matched with the lower molding cavity 602 on the top surface of the lower die 6 to finish the punching and fine shaping of the preformed plate;

s7: maintaining the die assembly state of the upper die 7 and the lower die 6, starting an ultrasonic assembly to work, enabling the ultrasonic assembly to act on the lower die 6, enabling the lower die 6 and the punched and precisely shaped plate to synchronously perform ultrasonic resonance, and completing ultrasonic stress relaxation of a plate deformation area;

s8: after the forming is finished, the ultrasonic assembly is closed, the press 1 is started to work, the press 1 drives the upper die 7 to reset upwards, the formed piece is taken out, and the whole forming process is finished.

The overall structure and operation of this embodiment are substantially the same as those of embodiment 1, and only the differences will be described in detail.

The inside of the bag type sealing member 8 is integrally provided with a plurality of sealing strips 801 which are distributed in a crisscross mode and are mutually communicated in the inside, and the sealing strips 801 divide the internal space of the bag type sealing member 8 into a plurality of block liquid filling cavities. In this embodiment, as shown in fig. 7, the internal space of the balloon-type sealing member 8 is divided into 6 block filling cavities by a sealing strip 801 arranged transversely and two sealing strips 801 arranged longitudinally, and for convenience of description, the 6 block filling cavities of two rows are sequentially named as filling cavity I, filling cavity II, filling cavity III, filling cavity IV, filling cavity V and filling cavity VI from left to right. Correspondingly, a liquid filling port 701 is arranged on the bottom surface of the upper die 7 in the top area corresponding to each block liquid filling cavity. The output end of the hydraulic pipeline 201 is provided with 6 liquid filling branch pipes 203 which are respectively connected with each liquid filling port 701, each liquid filling branch pipe 203 is provided with a control valve 202, and the on-off of liquid in the corresponding liquid filling branch pipe 203 is controlled through the control valve 202. The sealing cavity comprises 6 block forming areas which are symmetrically distributed in the left, right, front and back and are independent of each other, each block forming area is internally provided with a liquid filling port, and the surface of the slab is correspondingly divided into 6 block forming areas by the 6 liquid filling cavities.

In this embodiment, the steps of the ultrasonic-assisted precise forming method of the ultrathin metal plate are substantially similar to those of embodiment 1, and the main difference is that in step S4, the liquid injection in the liquid filling cavities of each block is completed in a mode that the distribution positions of the forming areas of each block are from outside to inside, diagonally paired, and two sides alternate, and each block forming area is pressurized after the liquid filling pre-forming is completed. Specifically, corresponding control valves 202 on the liquid filling cavity I and the liquid filling cavity VI are opened firstly, and liquid filling branch pipes 203 corresponding to high-pressure liquid static in a hydraulic pipeline 203 are simultaneously and equally filled into the liquid filling cavity I and the liquid filling cavity VI, so that the pre-deformation of the surface areas of cover plate blanks covered in the corresponding forming areas of the liquid filling cavity I and the liquid filling cavity VI is realized; after the pre-deformation operation in the forming areas of the two blocks is completed, closing the corresponding control valves 202 on the liquid filling cavity I and the liquid filling cavity VI to form a pressure maintaining cavity; the same mode is adopted, and the injection of high-pressure liquid in the liquid filling cavity III and the liquid filling cavity IV and the pre-deformation of the surface area of the cover plate blank covered in the corresponding forming area, namely the pressure maintaining after the deformation, are continuously completed; then adopting the same mode, continuously completing the injection of high-pressure liquid in the liquid filling cavity II and the liquid filling cavity V, and corresponding the pre-deformation of the surface area of the cover plate blank covered in the forming area, namely the pressure maintaining after deformation; after all the pre-deformations in the block forming zone are completed, all the control valves 202 are opened and the hydraulic source 2 is turned off, completing the pre-forming of the slab surface.

The space-time coupling of the preforming in the forming area of each block is realized through the partial filling of each cavity, the sequential design of loading of each cavity, the forming pressure regulation and control of each cavity and the pressure maintaining time control of each cavity, so that the forming pressure can be reduced, and the warping generated in the plate forming process can be relieved. Meanwhile, a plate can be formed in each block forming area, so that the processing mode of a plurality of pieces can be realized on the premise of not increasing the filling pressure, and the processing efficiency and the equipment performance utilization rate are improved.

The overall structure and operation of this embodiment are substantially the same as those of embodiment 1 or embodiment 2, and only the differences will be described in detail below.

A plurality of wave-insulating grooves 601 which are distributed in a criss-cross mode are formed in the bottom surface of the lower die 6, and the wave-insulating grooves 601 divide the bottom surface of the lower die 6 into a plurality of uniformly distributed block ultrasonic resonance areas. As shown in fig. 6, in the present embodiment, the bottom surface of the lower die 6 is equally divided into 6 block ultrasonic resonance regions by one transversely arranged wave-shielding groove 601 and two longitudinally arranged wave-shielding grooves 601. Correspondingly, the ultrasonic assembly comprises 6 ultrasonic generators 10, and one ultrasonic generator 10 is arranged below each ultrasonic resonance area of each block, as shown in fig. 10. Further, as shown in fig. 11, a notch 901 is integrally provided in the notch 9 and inserted into the notch 601, and the notch 901 divides the internal space of the notch 9 into a block ultrasonic resonant cavity corresponding to the block ultrasonic resonant region. After the lower die 6 is fitted in the wave-blocking member 9, the wave-blocking strips 901 are inserted into the wave-blocking grooves 601.

Through set up supersonic generator 10 alone respectively to every block ultrasonic resonance region, can make the ultrasonic wave that every supersonic generator 10 produced restrict respectively in the block ultrasonic resonance region who corresponds, further make ultrasonic energy more concentrated, promote the stress relaxation effect of plate more fast, high-efficient, reduce wave energy loss simultaneously, promote energy utilization.

The foregoing description is only illustrative of the present invention and is not intended to limit the scope of the invention, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present invention.

Claims (8)

1. The utility model provides an ultra-thin metal polar plate supersound assists accurate forming device, includes press (1), hydraulic pressure source (2) and hydraulic pressure pipeline (201), atmospheric pressure source (3) and atmospheric pressure pipeline (301), its characterized in that: the working table of the press (1) is fixedly provided with a lower die holder (4), the top of the lower die holder (4) is internally provided with a lower die (6), the working table of the press (1) is internally fixedly provided with an ultrasonic assembly, the energy output end of the ultrasonic assembly is fixedly connected with the bottom surface of the lower die (6), one side of the top surface of the lower die holder (4) is fixedly connected with a bag-type sealing element (8) connected with the output end of an air pressure pipeline (301), after the air pressure source (3) blows air into the bag-type sealing element (8), the bag-type sealing element (8) expands and is positioned above the top surface of the lower die (6), and after the air pressure source (3) extracts the air in the bag-type sealing element (8), the bag-type sealing element (8) contracts and is tightly positioned at one side of the lower die (6);

the upper die holder (5) is fixedly arranged right above the lower die holder (4) at the power end of the press machine (1), the upper die (7) is fixedly arranged at the bottom of the upper die holder (5), when the bag-type sealing element (8) is in an expansion and unfolding state, the press machine (1) drives the upper die holder (5) and the upper die (7) to move downwards, the bottom surface of the upper die (7) is tightly contacted with the top surface of the bag-type sealing element (8), the bottom surface of the bag-type sealing element (8) is tightly contacted with the top surface of the lower die (6), and a sealing cavity is formed by encircling the bag-type sealing element (8) between the upper die (7) and the lower die (6);

at least one liquid filling port (701) is formed in the upper die (7), the inner side end of the liquid filling port (701) is communicated with the sealing cavity, and the outer side end of the liquid filling port is connected with the output end of the hydraulic pipeline (201);

the inside of bag formula sealing member (8) is provided with a plurality of criss-cross distribution and inside each other link up sealing strip (801) integratively, sealing strip (801) divide into a plurality of block liquid filling chamber with the interior space of bag formula sealing member (8).

2. The ultrasonic-assisted precise forming device for the ultrathin metal polar plate, as claimed in claim 1, is characterized in that: a liquid filling port (701) is arranged in the top area of the bottom surface of the upper die (7) corresponding to each block liquid filling cavity.

3. The ultrasonic-assisted precise forming device for the ultrathin metal polar plate, as claimed in claim 2, is characterized in that: the output end of the hydraulic pipeline is provided with a plurality of liquid filling branch pipes (203) which are respectively connected with each liquid filling port (701), and each liquid filling branch pipe (203) is provided with a control valve (202).

4. An ultra-thin metal plate ultrasound-assisted precision forming apparatus according to any one of claims 1 to 3, characterized in that: a wave-insulating piece (9) is arranged between the lower die (6) and the lower die holder (4).

5. The ultrasonic-assisted precise forming device for the ultrathin metal polar plate, as claimed in claim 4, is characterized in that: a plurality of wave-insulating grooves (601) which are distributed in a criss-cross mode are formed in the bottom surface of the lower die (6), and the wave-insulating grooves (601) divide the bottom surface of the lower die (6) into a plurality of uniformly distributed block ultrasonic resonance areas.

6. The ultrasonic-assisted precise forming device for the ultrathin metal polar plate, as claimed in claim 5, is characterized in that: the inside of the wave-insulating piece (9) is integrally provided with a plurality of wave-insulating strips (901) which are correspondingly inserted into the wave-insulating grooves (601), and the wave-insulating strips (901) divide the internal space of the wave-insulating piece (9) into block ultrasonic resonant cavities corresponding to the block ultrasonic resonant areas.

7. The ultrasonic-assisted precise forming device for the ultrathin metal polar plate according to claim 5 or 6, wherein the ultrasonic-assisted precise forming device comprises the following components: the ultrasonic assembly comprises a plurality of ultrasonic generators (10), and an ultrasonic generator (10) is arranged below the ultrasonic resonance area of each block.

8. The ultrasonic-assisted precise forming device for the ultrathin metal polar plate, as claimed in claim 1, is characterized in that: the lower die (6) is made of Ti-6Al-4V.