This application claims priority to Chinese application number 201710731644.1, filed 23 Aug. 2017, with a title of METHOD FOR QUICK GAS BULGING FORMING OF HOT METAL SHEET. The above-mentioned patent application is incorporated herein by reference in its entirety.
The present invention relates to a technology for forming a metal sheet part, and in particular to a method capable of realizing quick gas bulging forming of a hot metal sheet.
The manufacture of a metal sheet member is mainly achieved by plastically deforming a blank via an externally applied load, depending on the plastic deformation capability of a metal material. For different metal materials, different forming processes and forming conditions should be adopted.
Since an aluminum alloy, a magnesium alloy, a titanium alloy, and the like materials have low density and high specific strength, and a part of the same mass made from them can provide higher carrying capacity, such a material is referred to as a lightweight material. A common disadvantage of such materials is poor plasticity at room temperature, making it difficult for the materials to manufacture a complex part at room temperature. Currently, a hot forming method is mainly adopted for shaping such materials. That is, a blank to be shaped is heated to an appropriate temperature and then shaped. According to different deformation speeds of the material during forming, the hot forming can be divided into a slow type and a quick type. For example, superplastic forming is a typical slow forming, and high-pressure gas bulging forming is a typical quick forming. The superplastic forming utilizes a relatively low gas pressure (typically lower than 10 atmospheres, i.e., 1.0 MPa) to deform a blank under a high-temperature at a very slow rate, typically at a strain rate lower than 10−2/s. Since a person cannot operate in a high-temperature environment, or a part is stuck to a mold under a high temperature, it should remove the part only after the mold and the part are cooled to a lower temperature upon forming. Therefore, it often takes several hours or even longer to superplastic form a single part. This disadvantage significantly limits application of the superplastic forming in mass production. High-pressure gas bulging forming is achieved by increasing the gas pressure (for example, reaching 10 MPa or even higher) to deform the blank in a relatively short period of time. Since the entire process of the high-pressure gas bulging forming is very quick and the forming cycle of a single part requires only tens of seconds or even shorter, the high-pressure gas bulging forming becomes an advanced technology for mass production using the aforementioned lightweight metal materials. During the high-pressure gas bulging forming, currently a sheet blank is deformed mainly by quickly inflating the cavity of a mold through inflation holes partially disposed on the mold. Since during gas bulging forming both the sheet blank and the mold are at a relatively high temperature, while the introduced gas is in a state of room temperature and high pressure, the temperature of a local region on the blank will be significantly reduced to form a non-uniform temperature field due to the air flow and pressure drop during the inflation process. For a part having a simple shape such as an axisymmetric cylindrical part, the inflation hole often just faces the central position of the sheet blank, such that it can be substantially ensured that the part is deformed in a symmetrical manner. However, for a complicated metal sheet part, if the position of the inflation hole is not set properly, an unreasonable temperature field distribution will be formed on the sheet blank. On the other hand, since the gas is introduced into an enclosed space formed by the sheet blank and the mold cavity through the locally-positioned inflation holes during quick inflation, there may be a certain degree of non-uniformity in the gas pressure within a short period of inflation. Deformation of the metal sheet blank is co-determined by the temperature distribution on the sheet blank and the gas pressure acting on the sheet blank. When the temperature distribution and pressure distribution are unreasonable, it will be difficult to obtain the desired final part.
In order to realize precise and quick forming of a thin-walled metal sheet part having a relatively thin wall thickness and a complex shape, it is necessary to develop a forming technology which can ensure that the blank is deformed under a reasonable temperature condition and a reasonable gas-pressure condition.
An objective of the present invention is to solve the problem that the existing hot metal sheet forming technology cannot ensure that a blank is deformed under reasonable temperature and pressure conditions, thereby failing to realize precise and quick forming of a complex metal sheet part, especially a thin-walled part. Therefore, a method for quick gas bulging forming of a hot metal sheet is further provided.
The method for quick gas bulging forming of a hot metal sheet is implemented according to the following steps:
step one, placing a metal sheet blank to be formed on a forming mold, and closing a sealing mold to form enclosed cavities on upper and lower surfaces of a metal sheet blank;
step two, introducing high-pressure gases with equal pressures simultaneously into upper and lower enclosed cavities respectively formed by the metal sheet blank and the sealing mold, and the metal sheet blank and the forming mold;
step three, heating the metal sheet blank to a preset forming temperature condition;
step four, quickly releasing the high-pressure gas from the enclosed cavity formed by the metal sheet blank and the forming mold, such that the metal sheet blank bulges quickly under the action of the high-pressure gas at the other side and thus fits into the mold cavity of the forming mold; and
step five, discharging the gas from the cavity formed by the metal sheet blank and the sealing mold, and opening the sealing mold to obtain a formed metal sheet part.
The beneficial effects of the present invention are:
(1) the inflation process is independent and controllable: high-pressure gases on both sides of the metal sheet blank are introduced at the same time, and since the gas pressures on both sides of the sheet blank are maintained equal or substantially equal, the upper and lower surfaces of the metal sheet blank are in an equilibrium state and thus will not be deformed due to bulging (see
(2) the inflation process is conducted in advance: after the metal sheet blank is placed into the mold and the mold is closed to achieve sealing, high-pressure gases can be immediately introduced into cavities on both sides of the sheet blank (see
(3) the temperature of the sheet blank is not affected: at the time of gas bulging forming, the blank is already under a reasonable temperature condition (the temperature on the sheet blank can be either isothermally or non-isothermally distributed), and during forming no external gas is directly blown onto the sheet blank to change the temperature condition, thereby avoiding the problem that the conventional direct introducing of high-pressure gases may cause an unreasonable temperature change on the sheet blank and thus affect the bulging deformation of the sheet blank;
(4) the quick forming performance is excellent: when bulging deformation occurs, the gas between the sheet blank and the forming mold is quickly discharged in a short time, and a certain numerical pressure difference will be quickly formed between two sides of the sheet blank, and when the numerical value of the pressure difference is large, the metal sheet blank will bulge in a very short time (see
(5) the distribution of pressure difference is controllable: during gas bulging forming the gas pressure in the cavity between the sealing mold and the metal sheet blank is maintained uniform or substantially uniform, and the numerical value of the gas pressure does not change significantly during the gas bulging forming process; on the other side of the sheet blank, different pressure distributions can be formed on the lower surface of the sheet blank by opening vent holes at different positions on the forming mold and controlling the deflation speeds at the different positions (see
(6) the temperature distribution during forming is controllable: the heating of the metal sheet blank can be done by either preheating it outside the mold before putting it into the mold, or heating it through a hot mold after it is placed into the mold, or heating can be done directly by connecting a power electrode at both ends of the sheet blank; in practice, different heating methods can also be combined to obtain a required specific temperature distribution condition; since the inflation process is completed before the temperature adjustment, and the formation of pressure difference on the sheet blank through quick deflation is completed in a very short time, this indicates the temperature distribution condition on the metal sheet blank during the gas bulging forming is stable, which provides the possibility for reasonably using the temperature distribution to obtain the required bulging deformation;
(7) the forming accuracy is high: since the gas bulging forming of the metal sheet blank is completed in a few seconds or even shorter time, and the time period since the bulging start of the metal sheet blank to complete fit of it into the mold is very short, the temperature of the sheet blank will not be significantly decreased due to contact with the forming mold, and thus the adopted forming mold may be at a warm state or even a state of room temperature, which means that the shape and dimensional accuracy of the final part is completely determined by the forming mold, thereby avoiding the problem that the conventional use of a hot mold may affect the dimensional accuracy of the mold cavity due to thermal expansion and contraction; and
(8) the forming efficiency is high: since the inflation pressurizing process and the deflation pressure-difference building process are both completed in a very short time, this solves the problem that during the conventional quick gas bulging forming the inflation speed is forced to be reduced for avoiding the possible adverse effect of quick inflation pressurizing on the temperature distribution and pressure distribution on the sheet blank, and thus can achieve quick gas bulging forming of a complicated part.
wherein, 1 refers to a metal sheet blank, 2 refers to a sealing mold, 3 refers to a gas bulging forming mold, 4 refers to an inflation hole of the sealing mold, 5 refers to an inflation hole of the gas bulging forming mold, and 6 refers to a vent hole of the gas bulging forming mold;
wherein, t1 is a time used for gas pressurization (inflation) in the solution adopted by the present invention, t2 is a time used for quickly decreasing the gas pressure on the back face of the metal sheet blank (deflation), t3 is a bulging time after the gas pressure on the back face of the metal sheet blank is completely eliminated, t4 is a time used for holding and releasing the pressure after the metal sheet blank bulges and fits in to the mold, P1 is a gas pressure in the cavity formed by the sealing mold and the metal sheet blank, and P2 is a gas pressure in the cavity formed by the gas bulging forming mold and the metal sheet blank, wherein the unit for time is second, and the unit for pressure is MPa;
wherein, 7 refers to a hot steel plate, 8 refers to a vent hole, 9 refers to a gas regulating valve, and 10 refers to a power electrode;
The technical solutions of the present invention will be further described below through the detailed description in connection with the accompanying drawings.
Embodiment 1: as illustrated referring to
step one, placing a metal sheet blank 1 to be formed on a forming mold 3, and closing a sealing mold 2 to form enclosed cavities on upper and lower surfaces of the metal sheet blank 1;
step two, introducing high-pressure gases with equal pressures simultaneously into upper and lower enclosed cavities respectively formed by the metal sheet blank 1 and the sealing mold 2, and the metal sheet blank 1 and the forming mold 3 through an upper inflation hole 4 and a lower inflation hole 5;
step three, heating the metal sheet blank 1 to a preset forming temperature condition;
step four, quickly releasing the high-pressure gas from the enclosed cavity formed by the metal sheet blank 1 and the forming mold 3 through the vent hole 6, such that the metal sheet blank 1 bulges quickly under the action of the high-pressure gas contained in the cavity formed by the metal sheet blank 1 and the sealing mold 2, and thus fits into the mold cavity of the forming mold 3; and
step five, discharging the gas from the cavity formed by the metal sheet blank 1 and the sealing mold 2, and opening the sealing mold 2 to obtain a formed metal sheet part.
In this embodiment, the high-pressure gases on the upper and lower sheet surfaces of the metal sheet blank are introduced at the same time and the gas pressure thereof are maintained equal or substantially equal, i.e., P1=P2, (see
Effect of gas pressure loading on the sheet temperature: during the hot quick gas bulging forming, a high-pressure gas is quickly introduced, and the gas is generally a high-pressure compressed gas at a temperature lower than room temperature. When the gas is filled quickly, it can easily affect the temperature of the hot sheet.
As shown in
As shown in
Embodiment 2: as illustrated with reference to
In this embodiment, the metal sheet blank 1 is heated in different manners in respect of different requirements for the forming temperature of the metal sheet blank 1. It not only can achieve an approximately uniform temperature distribution, but also can form a non-uniform temperature distribution on the metal sheet blank 1 by controlling the temperature distribution of the mold, the temperature distribution of the hot steel plate 7, and the like. This provides the possibility of effectively controlling the bulging deformation of the metal sheet blank 1 and thus obtaining a part with a complicated shape. The other steps are the same as those in Embodiment 1.
Embodiment 3: as illustrated with reference to
In this embodiment, when the enclosed cavity of the forming mold 3 is a complex asymmetric structure, by reasonably setting the number and positions of the vent holes 6, the high-pressure gas contained in the enclosed cavity formed by the metal sheet blank 1 and the forming mold 3 can be quickly released to an atmospheric pressure at almost the same speed, such that an approximately uniform pressure difference can be quickly formed on the upper and lower surfaces of the metal sheet blank 1. The distance from the second vent hole 6-2 to the first vent hole 6-1 is relatively longer, the second vent hole 6-2 and the third vent hole 6-3 are arranged close to each other, and the metal sheet blank 1 will be expanded quickly under a sufficiently high gas pressure. The other steps are the same as those in Embodiment 1 or 2.
Embodiment 4: as illustrated with reference to
In this embodiment, different gas pressure distributions will be generated in the cavity due to the rapid flow of high-pressure gas during quick deflation. By reasonably setting the number and positions of the vent holes 6 and adjusting the deflation speed of each vent hole, a non-uniform gas pressure will be formed in the cavity formed by the metal sheet blank 1 and the forming mold 3, such that different pressures will act on the lower surface of the metal sheet blank 1. Since the pressure on the upper surface of the metal sheet blank 1 is approximately uniform, the metal sheet blank 1 will be expanded quickly under the non-uniformly distributed pressure differential condition. By reasonably setting the non-uniformly distributed pressure difference, it is possible to reasonably control the deformation of different portions of the metal sheet blank 1 and thus to realize the formation of a part with a complicated shape. The other steps are the same as those in one of the Embodiments 1 to 3.
Embodiment 5: as illustrated with reference to
In this embodiment, the metal sheet blank 1, the sealing mold 2 and the forming mold 3 are all initially at the state of room temperature, and the removal, placing, transferring and the like of the metal sheet blank 1 can be realized by using conventional methods and apparatuses. In step two, there is no need to consider the possible effect of the inflation process on the temperature of the metal sheet blank 1, and in step three the heating of the metal sheet blank 1 can be completed within several seconds. Therefore, the inflation process and the heating process of the metal sheet blank 1 are independent from each other without causing mutual interference. This greatly simplifies the removal and placing of the blank and shortens the adjustment and control time of the mold temperature. Moreover, since the cavity of the forming mold 3 at room temperature is the shape of the final part, the problem of affecting the accuracy of the mold due to thermal expansion and contraction when the hot mold is used is avoided. This also provides the possibility of forming a part with a high requirement in precision. The other steps are the same as those in one of the Embodiments 1 to 4.
Number | Date | Country | Kind |
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2017 1 0731644 | Aug 2017 | CN | national |
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Number | Date | Country | |
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20190366409 A1 | Dec 2019 | US |
Number | Date | Country | |
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Parent | 15982042 | May 2018 | US |
Child | 16541583 | US |