ARRAY-SPRAYING ADDITIVE MANUFACTURING APPARATUS AND METHOD FOR MANUFACTURING LARGE-SIZED EQUIAXED CRYSTAL ALUMINUM ALLOY INGOT

Abstract

An array-spraying additive manufacturing apparatus and method for manufacturing a large-sized equiaxed crystal aluminum alloy ingot, comprising: a liquid aluminum spraying mechanism having array nozzles disposed in an atmospheric pressure chamber, a movable condensing mechanism disposed in the atmospheric pressure chamber below the liquid aluminum spraying mechanism, and a control mechanism. The control mechanism sends an upward guiding command to a release mechanism and issues a three-dimensional movement command to the movable condensing mechanism, such that liquid aluminum in the liquid aluminum spraying mechanism is sprayed at the surface of the movable condensing mechanism in a continuous array of liquid flows according to a preset path and is rapidly condensed to form an ingot. Also disclosed is an additive manufacturing method employing the apparatus.

Claims

1. An array-spraying additive manufacturing apparatus for a large-sized equiaxed crystal aluminum alloy ingot, comprising: a liquid aluminum spraying mechanism having array nozzles and disposed in an atmospheric pressure chamber, and a movable condensing mechanism and a control mechanism which are disposed in the atmospheric pressure chamber and below the liquid aluminum spraying mechanism, wherein the control mechanism is configured to send an upward guiding command to a release mechanism and issue a three-dimensional movement command to the movable condensing mechanism respectively, such that liquid aluminum in the liquid aluminum spraying mechanism is sprayed to a surface of the movable condensing mechanism in a form of a continuous array of liquid flows according to a preset path, and is rapidly condensed to form the ingot; and the liquid aluminum spraying mechanism comprises: the release mechanism, a liquid aluminum chamber, and array nozzles, wherein the array nozzles are disposed at a bottom of the liquid aluminum chamber, and the release mechanism is connected with the control mechanism to control a spraying speed of the liquid aluminum; a nozzle row spacing and a nozzle column spacing of the array nozzles are less than 300 mm, and a nozzle aperture is 0.2 mm-30 mm; and a single-pass movement length of a single nozzle is equal to the nozzle column spacing, and a total width of movement of the single nozzle is equal to the nozzle row spacing; the movable condensing mechanism comprises: a condensing table disposed right facing the array nozzles, a two-dimensional movable mechanism which is vertically movable and disposed under the condensing table, and a downward guiding device, wherein the two-dimensional movable mechanism and the downward guiding device are respectively connected to the control mechanism, and configured to receive two-dimensional movement command and vertical movement command so as to realize three-dimensional movement; and combined control is adopted for geometric arrangement of the array nozzles, cooling capacity of the condensing mechanism and a two-dimensional movement path, to make the liquid aluminum spread in a large area and be continuously kept in a semi-solid state at a printing interface, thereby achieving metallurgical combination of a printing area corresponding to each nozzle.

2. The apparatus according to claim 1, wherein the atmospheric pressure chamber is provided with a vacuum pump connected to the control mechanism, such that internal air pressure is further adjusted through the vacuum pump; and the atmospheric pressure chamber is connected with an inert gas source to provide inert gas protection for inside of the chamber.

3. The apparatus according to claim 1, wherein the release mechanism comprises an upward guiding device and a plug pole, wherein the plug pole is matched with the array nozzles, and the upward guiding device is respectively connected with the plug pole and the control mechanism in order to receive a release command and control the plug pole to lift upward to release the array nozzles.

4. (canceled)

5. The apparatus according to claim 1, wherein in-chamber heaters which are connected with the control mechanism are further disposed inside the liquid aluminum chamber.

6. The apparatus according to claim 1, wherein nozzle heaters are further disposed outside of the array nozzles.

7. The apparatus according to claim 1, wherein a cooling liquid flow channel is disposed inside the condensing table.

8. The apparatus according to claim 1, wherein the control mechanism comprises: a movement control unit and a general control unit, wherein the movement control unit is connected to the general control unit and configured to transmit movement information of the movable condensing mechanism, and the general control unit is connected with the release mechanism and the vacuum pump respectively, and configured to transmit information of movement of the release mechanism and information of opening and closing of the vacuum pump, is connected with the two-dimensional movable mechanism and configured to transmit movement information of the two-dimensional movable mechanism, is connected with the downward guiding device and configured to transmit movement information of the downward guiding device.

9. (canceled)

10. An array-spraying additive manufacturing method for manufacturing large-sized equiaxed crystal aluminum alloy ingot based on the apparatus according to claim 1, comprising following steps: Step 1: placing a plug pole in a lowest position to make the nozzles in a closed state; turning on in-chamber heaters for performing preheating to reach a liquid aluminum temperature and keeping the temperature; opening an inlet gate to allow the liquid aluminum to flow into the liquid aluminum chamber, and closing the inlet gate after the liquid aluminum is controlled by a liquid level meter to reach a preset height, turning on nozzle heaters to preheat the nozzles, sealing an airtight condensing chamber, and turning on the vacuum pump to vacuum the airtight condensing chamber; and turning off the vacuum pump when a vacuum degree meets a requirement, and introducing inert gas from an inert gas source to reach a preset pressure; Step 2: turning on cooling water, controlling a downward guiding device by a movement control unit so as to make a distance between the nozzles and a condensing table reach a preset distance, then turning on a two-dimensional movement device to enable the nozzles to move relative to the condensing table periodically and repeatedly; turning on an upward guiding device to lift upward the plug pole, so as to make the liquid aluminum enter the nozzles; turning on the vacuum pump to perform pumping to make a pressure of an airtight condensing chamber less than 1 atm, wherein the liquid aluminum in the liquid aluminum chamber above the airtight condensing chamber is sprayed out as stable liquid columns through the nozzles under above-mentioned negative pressure generated inside the airtight condensing chamber, and sprayed onto the condensing table to form the ingot; and controlling, after ingot preparation starts, the downward guiding device to move the condensing table downward, wherein during the ingot preparation process, with continuous consumption of the liquid aluminum, when a liquid level in the liquid aluminum chamber drops to a warning level, the inlet gate is opened to replenish the liquid aluminum until reaching a stable level, and then the inlet gate is closed; and Step 3: turning off, upon preparation of the ingots is completed, the plug pole to block flowing of the liquid aluminum out from the nozzles, turning off the two-dimensional movement device and the downward guiding device, turning off a heating power supply, and turning off the cooling water after the ingot is cooled, thus finishing the preparation process.

11. (canceled)

12. (canceled)

13. (canceled)

14. (canceled)

15. (canceled)

16. (canceled)

Description

BRIEF DESCRIPTION OF DRAWINGS

[0025] FIG. 1 is a schematic diagram of the structure of the present disclosure;

[0026] FIG. 2 is a schematic diagram of the structure of nozzles;

[0027] FIG. 3 is a schematic diagram of the movement path of a nozzle liquid column;

[0028] FIG. 4 and FIG. 5 are the metallographic photos of Example 1;

[0029] FIG. 6 and FIG. 7 are the metallographic photos of Example 2;

[0030] In the Figures: inlet gate 1; diversion trench 2; liquid aluminum 3; thermal insulation layer 4; gas inlet pipe 5; inert gas 6; nozzle heater 7; baffle plate 8; condensing table 9; two-dimensional movement device 10; guide rail 11; support table 12; upward guiding device 13; plug pole 14; in-chamber heater 15; liquid aluminum chamber 16; nozzle 17; liquid lever meter 18; ingot 19; cooling water tube 20; airtight condensing chamber 21; movement control unit 22; downward guiding device 23; vacuum pump 24; general control unit 25.

DETAILED DESCRIPTION OF EMBODIMENTS

Example 1

[0031] As indicated in FIG. 1, the example relates to an array-spraying additive manufacturing apparatus for manufacturing large-sized equiaxed crystal aluminum alloy ingot, comprising: an inlet gate 1, a diversion trench 2, liquid aluminum 3, a thermal insulation layer 4, a gas inlet pipe 5, inert gas 6, nozzle heaters 7, a baffle plate 8; a condensing table 9, a two-dimensional movement device 10, a guide rail 11, a support table 12, an upward guiding device 13, a plug pole 14, in-chamber heaters 15, a liquid aluminum chamber 16; nozzles 17, a liquid lever meter 18; an ingot 19, a cooling water tube 20, an airtight condensing chamber 21, a movement control unit 22, a downward guiding device 23, a vacuum pump 24, and a general control unit 25.

[0032] The pressure of the liquid aluminum chamber is kept at 1 atm, and the airtight condensing chamber is completely sealed. The pressure P can be adjusted by the vacuum pump 24 and the gas inlet pipe. During ingot preparation, the pressure P is less than 1 atm.

[0033] As shown in FIG. 2, the nozzles 17 are arranged in array, with the nozzles having row spacing of W (W<300 mm), the column spacing of L (L<300 mm), and the nozzle aperture of D (0.2 mm<D<30 mm).

[0034] The two-dimensional movement device 10 enables the translational movement of the condensing table in the horizontal X and Y directions, where the moving speed is v(v<1000 mm/s), and the maximum strokes in the two directions are X(X<1 m) and Y(Y<1 m) respectively. By movement, it is possible to allow the nozzle liquid column to move relative to the condensing table in a movement path similar to that shown in FIG. 3, whereas it is not limited to such movement path. The distance between adjacent passes is d(d<30 mm). As shown in FIG. 2 and FIG. 3, the single-pass movement length of a single nozzle is equal to the nozzle column spacing L, while the total width of the movement of a single nozzle is equal to the nozzle row spacing W.

[0035] The downward guiding device 13 enables the movement of the condensing table in the vertical direction, where the moving speed is v.sub.1(v.sub.1<50 mm/s), and the total stroke is Z(Z<5 m).

[0036] The present example relates to an array-spraying additive manufacturing method for manufacturing large-sized equiaxed crystal aluminum alloy ingot, comprising the following steps:

[0037] Step 1: placing the plug pole at the lowest position to make the nozzles in a closed state; turning on the in-chamber heaters for performing preheating to reach a liquid aluminum temperature T.sub.1(T.sub.1>600° C.), and keeping the temperature, opening an inlet gate to allow the liquid aluminum to flow into the liquid aluminum chamber, and closing the inlet gate after the liquid aluminum is controlled by a liquid level meter to reach a preset height, turning on the nozzle heaters to preheat the nozzles, where the preheating temperature is T.sub.2(T.sub.2>500° C.), sealing the airtight condensing chamber, and turning on the vacuum pump to vacuum the airtight condensing chamber; and turning off the vacuum pump when the vacuum degree meets the requirement, and introducing the inert gas from the gas inert tube to reach the pressure P.sub.1(P.sub.1=1 atm);

[0038] Step 2: turning on the cooling water, controlling the downward guiding device by the movement control unit so as to make the distance between the nozzles and the condensing table reach H(H<50 cm), then turning on the two-dimensional movement device to enable the nozzles to move relative to the condensing table periodically and repeatedly as shown in FIG. 2, turning on the upward guiding device to lift the plug pole, so as to make the liquid aluminum enter the nozzles; turning on the vacuum pump to perform pumping to make the pressure of the airtight condensing chamber be P.sub.2(P.sub.2<1 atm), wherein the liquid aluminum is sprayed out as stable liquid columns through the nozzles under the above-mentioned negative pressure generated inside the airtight condensing chamber, and sprayed onto the condensing table to form an ingot; and controlling, after the ingot preparation starts, the downward guiding device to move the condensing table downward at the velocity of v.sub.1(v.sub.1<50 mm/s), such that the height of the nozzles relative to the surface of the ingot remains at height H. During the ingot preparation process, with continuous consumption of the liquid aluminum, when the liquid level in the liquid aluminum chamber drops to a warning level, the inlet gate is opened to replenish the liquid aluminum until it reaches stable level, and then the inlet gate is closed;

[0039] Step 3: turning off, upon preparation of the ingots is completed, the plug pole to block flowing of the liquid aluminum out from the nozzles, turning off the two-dimensional movement device and the downward guiding device, turning off the heating power supply, and turning off the cooling water after the ingots are cooled, thus finishing the preparation process.

[0040] When preparing a 7050 aluminum alloy ingot by the above-mentioned method, settings comprise: the liquid aluminum temperature being 680° C., the nozzle diameter being 8 mm, the horizontal moving speed of the condensing table being 300 mm/s, the spray area of the array nozzles being 2 m*5 m, and the thickness of the ingot being 0.5 m, and it takes 40 minutes to prepare a large-sized ingot of 2 m*5 m*0.5 m. The solidified structure of the ingot is dense, without macroscopic segregation, and is equiaxed crystal with an average grain size of 60-80 μm, as shown in FIG. 4. FIG. 5 shows the grain structure of the ingot prepared by semi-continuous casting. By comparison, the grain structure of the ingot prepared by the present method is significantly more refined.

Example 2

[0041] In this example, the same method as in Example 1 is applied to prepare Al-4.5Cu aluminum alloy ingot. The settings comprise: liquid aluminum temperature being 700° C., the nozzle diameter being 6 mm, the horizontal moving speed of the condensing table being 260 mm/s, and the spray area of the array nozzles being 2 m*5 m, and the thickness of the ingot being 0.8 m, and it takes 60 minutes to prepare a large-sized ingot of 2 m*5 m*0.8 m. The solidified structure of the ingot is dense, without macroscopic segregation, and is equiaxed crystal with an average grain size of 60-90 μm. The metallographic photos at ¼ and ½ along the center line of the cross section of the ingot are shown in FIG. 6 and FIG. 7, respectively.

[0042] The specific embodiments above may be partially adjusted by those skilled in the art in different ways without departing from the principle and purpose of the present disclosure. The protection scope of the present disclosure should be based on the claims and is not limited by the specific embodiments above. All implementation solutions within the scope thereof are bound by the present disclosure.