This application claims priority to Japanese Patent Application No. 2020-031294 filed on Feb. 27, 2020, incorporated herein by reference in its entirety.
The disclosure relates to a die casting method and a die casting device.
In die casting, after molten metal is supplied to a cylindrical plunger sleeve, a plunger tip is advanced at a high speed in the plunger sleeve, so as to inject the molten metal into a cavity of dies, as disclosed in Japanese Unexamined Patent Application Publication No. 2018-176192 (JP 2018-176192 A).
The inventor of this disclosure found a problem as follows, in relation to the die casting method and die casting device. In die casting as disclosed in JP 2018-176192 A, after molten metal is poured into the plunger sleeve, the plunger tip needs to be advanced at a low speed, so as to settle down waves at a surface of the molten metal, and prevent the molten metal from becoming turbulence and trapping air during injection.
Thus, the temperature of the molten metal in the plunger sleeve is reduced while the plunger tip is advanced, which may result in a problem, such as generation of a fractured chilled layer, or cold flakes, in a cast article produced. The cold flakes, which are casting defects, are generated when initially solidified pieces of molten metal formed on the inner surface of the plunger sleeve are fractured, peeled off, and mixed into the cast article as the plunger tip is advanced.
The disclosure provides die casting method and die casting device, which can curb temperature reduction of molten metal in a plunger sleeve.
A die casting method according to a first aspect of the disclosure includes: supplying molten metal to a plunger sleeve, and advancing a plunger in the plunger sleeve, to inject the molten metal into dies. When the molten metal is injected into the dies, the plunger is once retracted before being advanced, and the plunger is kept accelerated until the plunger reaches a target maximum speed when the plunger retracted is advanced.
In the die casting method according to the first aspect of the disclosure, the plunger is once retracted before it is advanced, instead of providing a low-speed section, so that molten metal is prevented from becoming turbulence and trapping air during injection. As a result, waves generated at a surface of molten metal due to pouring of the metal settle down; therefore, when the plunger thus retracted is advanced, the plunger can be kept accelerated until it reaches the target maximum speed. Consequently, it is possible to reduce the time required for the injection process, and curb temperature reduction of the molten metal in the plunger sleeve, while preventing air from being trapped.
In the first aspect, after the molten metal is supplied from a supply port provided in the plunger sleeve, the supply port may be closed before the plunger is advanced. With this arrangement, when the plunger is advanced, the molten metal is less likely or unlikely to overflow from the supply port of the plunger sleeve.
In the first aspect, when the plunger is advanced, the plunger may be kept accelerated until the plunger reaches the target maximum speed, at a maximum acceleration which a die casting device is able to exhibit. With this arrangement, reduction of the molten metal temperature can be further curbed.
In the first aspect, when the plunger is once retracted, the plunger may be hydraulically driven with a servo pump. With this arrangement, movement of the plunger can be controlled with high accuracy, and electric power consumption can be reduced.
A die casting device according to a second aspect of the disclosure includes a plunger sleeve configured to be supplied with molten metal via a supply port, dies that communicate with the plunger sleeve, a plunger configured to inject the molten metal supplied to the plunger sleeve, into the dies, and a controller configured to control operation of the plunger. When the plunger is advanced to inject the molten metal into the dies, the controller is configured to once retract the plunger before advancing the plunger, and keep the plunger accelerated until the plunger reaches a target maximum speed when the plunger retracted is advanced.
In the die casting device according to the second aspect of the disclosure, the plunger is once retracted before it is advanced, instead of providing the low-speed section, so that molten metal is prevented from becoming turbulence and trapping air during injection. Then, when the plunger thus retracted is advanced, the plunger is kept accelerated until it reaches the target maximum speed. Thus, it is possible to reduce the time required for the injection process, and curb temperature reduction of the molten metal in the plunger sleeve.
In the second aspect, the die casting device may further include a lid portion configured to open and close the supply port. With this arrangement, when the plunger is advanced, the supply port of the plunger sleeve can be closed with the lid portion, and the molten metal can be prevented from overflowing from the supply port.
In the second aspect, when the plunger is advanced, the controller may be configured to keep the plunger accelerated until the plunger reaches the target maximum speed, at a maximum acceleration which the die casting device is able to exhibit. With this arrangement, reduction of the molten metal temperature can be further curbed.
In the second embodiment, the die casting device may further include a servo pump configured to hydraulically drive the plunger, when the plunger is once retracted. With this arrangement, movement of the plunger can be controlled with high accuracy, and power consumption can be reduced.
According to this disclosure, the die casting method that can curb temperature reduction of molten metal in the plunger sleeve is provided.
Features, advantages, and technical and industrial significance of exemplary embodiments of the disclosure will be described below with reference to the accompanying drawings, in which like signs denote like elements, and wherein:
One specific embodiment of the disclosure will be described in detail with reference to the drawings. It is, however, to be understood that the disclosure is not limited to the following embodiment. Also, the following description and the drawings are simplified as needed, so as to make description clear.
Referring first to
As shown in
The movable die 10 is driven by a drive source (not shown), and is able to slide in the x-axis direction. On the other hand, the fixed die 20 is fixed to the die casting device. When the movable die 10 moves in the x-axis positive direction, and abuts against the fixed die 20, a cavity C that conforms with the shape of a product to be cast between the movable die 10 and the fixed die 20 is formed, as shown in
As shown in
As shown in
The plunger sleeve 30 is a cylindrical member having a central axis parallel to the x-axis. As described above, the plunger sleeve 30 is fitted in the through-hole of the fixed die 20. The molten metal M is poured into the plunger sleeve 30. The plunger sleeve 30 is formed of alloy tool steel for hot dies, for example.
A supply port 31 through which the molten metal M is poured into the plunger sleeve 30 is formed in the upper surface of the plunger sleeve 30 in the vicinity of its rear end portion (facing in the x-axis positive direction). For example, the molten metal M is poured from the supply port 31 into the plunger sleeve 30, using a ladle (not shown), for example. The method of feeding the molten metal is not limited to any method, but electromagnetic feeding or pneumatic feeding of molten metal, or the like, may be employed, in place of the feeding with the ladle.
Further, the plunger sleeve 30 is provided with a lid portion 32 that can open and close the supply port 31. When the plunger 40 ejects the molten metal M, the lid portion 32 can prevent the molten metal M from overflowing from the supply port 31. While the opening and closing actions of the lid portion 32 are not limited to any manner, the lid portion 32 can open and close the supply port 31, by moving in the z-axis direction by means of a drive source (not shown), in this embodiment. The opening and closing actions of the lid portion 32 are controlled by the controller 60, for example. In the example shown in
In the die casting device according to this embodiment, when the molten metal M is injected by the plunger 40, the plunger 40 is once retracted, and then advanced, as will be described later in detail. Thus, if the lid portion 32 is not provided, the molten metal M is likely to overflow from the supply port 31. Namely, the lid portion 32 can prevent the molten metal M from overflowing from the supply port 31. However, the lid portion 32 is not essential. If a sealed type electromagnetic feeding of molten metal, or the like, is employed, with the supply port 31 provided in a bottom portion of the plunger sleeve 30, for example, the lid portion 32 will not be needed.
The plunger 40 includes a plunger tip 41 and a plunger rod 42. The plunger tip 41 is a solid, cylindrical member that directly contacts the molten metal M in the plunger sleeve 30. The plunger tip 41 is connected to the plunger drive source 50, via the plunger rod 42 as a rod-like member having a central axis parallel to the x-axis, and can slide in the x-axis direction in the plunger sleeve 30. As shown in
The plunger drive source 50 drives the plunger 40 in the x-axis direction. The plunger drive source 50 includes a hydraulic pump (so-called servo pump) driven by a servomotor, for example. The specific structure and operation of the plunger drive source 50 will be described in detail later. The plunger drive source 50 is not particularly limited, but may drive the plunger 40 only by use of a servomotor, without using any hydraulic pump, for example.
The controller 60 controls movements of the plunger 40. Namely, as shown in
Although not illustrated in the drawings, the controller 60 functions as a computer, and includes a computing unit, such as a central processing unit (CPU), and a storage unit, such as a random access memory (RAM) and a read-only memory (ROM), in which various control programs, data, etc. are stored.
Summary of Die Casting Method
Referring next to
Then, as shown in
Then, as shown in
The runner portion A2 is a portion in which the molten metal M solidified in the runner R. The biscuit portion A3 is a portion in which the molten metal M surrounded by a front end face of the plunger tip 41 and the dies (movable die 10 and fixed die 20) solidified. The runner portion A2 and the biscuit portion A3 are eventually removed, and the product portion A1 is used as a product.
Details of Injection Process
Referring next to
Initially, the injection process of the die casting method according to the comparative example indicated by the broken line in
Then, the plunger tip 41 is kept accelerated until it reaches a target maximum speed at a given acceleration. The acceleration is suitably determined according to the product (for example, the cast article A in
In the comparative example, since the low-speed section is provided, a period of time for which the plunger tip 41 is advanced is long, namely, it takes a long time from pouring of the molten metal to completion of injection. Thus, the temperature of the molten metal M may be reduced in the plunger sleeve 30 after pouring of the metal, and a fractured chilled layer, or cold flakes, may be generated.
Next, the injection process of the die casting method according to this embodiment indicated by the solid line in
Then, as in the comparative example, as the plunger tip 41 is kept advanced at the target maximum speed, the cavity C is filled with the molten metal M; as a result, the plunger tip 41 is not advanced any more, and stops. Needless to say, the plunger tip 41 may be forced to be decelerated, so that the plunger tip 41 stops at a predetermined position.
As shown in
In this manner, waves generated at the surface of the molten metal due to pouring settle down; therefore, when the retracted plunger tip 41 is advanced, the plunger tip 41 can be kept accelerated until it reaches the target maximum speed. Thus, in the injection process according to this embodiment, it is possible to reduce the time required for the injection process, as compared with the comparative example, while making air less likely or unlikely to be trapped in the molten metal M. Consequently, it is possible to curb temperature reduction of the molten metal M in the plunger sleeve 30, and curb generation of the cold flakes in the cast article A.
Also, since the time required for the injection process is short in the injection process according to this embodiment, the cycle time of die casting is shortened, and the production efficiency of cast articles A is improved, as compared with the comparative example. Further, as shown in
Referring to
Then, when the plunger tip 41 is once retracted in the x-axis positive direction as shown in the upper section of
Then, when the plunger tip 41 is advanced in the x-axis negative direction, as shown in the lower section of
Then, while the condition where the waves at the molten metal surface settle down, and the condition where the filling rate of the molten metal M on the side closer to the front end face of the plunger tip 41 is high, are maintained, the plunger tip 41 moves the molten metal M forward (in the x-axis negative direction). Thus, it is possible to inject the molten metal M while discharging air to the cavity C side, without trapping air.
As described above, in the injection process according to this embodiment, the plunger tip 41 is once retracted before being advanced, instead of providing the low-speed section, so that the molten metal M is prevented from becoming turbulence and trapping air during injection. As a result, the waves generated at the molten metal surface due to pouring settle down; therefore, when the plunger tip 41 once retracted is advanced, the plunger tip 41 can be kept accelerated until it reaches the target maximum speed.
Thus, it is possible to reduce the time required for the injection process, and curb temperature reduction of the molten metal M in the plunger sleeve 30, while preventing air from being trapped. Consequently, cold flakes are less likely or unlikely to be generated in the cast article A. Further, since the time required for the injection process is short, the cycle time of die casting is shortened, and the production efficiency of the cast articles A is improved.
Details of the Plunger Drive Source 50
Next, referring to
As shown in
Initially, referring to
As shown in
The hydraulic pump P is a bidirectional servo pump driven by the servomotor MT. One end of the hydraulic pump P is connected to the rear end portion of the injection cylinder 51 via the valve V2. The other end of the hydraulic pump P is connected to the front end portion of the injection cylinder 51, and is also connected to the oil tank OT via the valve V3. The rear end portion of the injection cylinder 51 is connected to the front end portion of the injection cylinder 51 via the valve V4, and is also connected to the oil tank OT via the valve V5.
Next, referring to
As shown in
Next,
As shown in
When the plunger tip 41 once retracted is advanced, the hydraulic pump P may be rotated in the reverse direction in
As shown in
As described above, the injection piston 52 is advanced at a high speed, due to the differential flow of the hydraulic oil. Meanwhile, a pressure loss appears due to the differential flow of the hydraulic oil. Thus, it is possible to raise the pressure with which the injection piston 52 (i.e., the plunger tip 41) is pressed, by shutting off the differential flow of the hydraulic oil.
More specifically, the hydraulic pump P sucks up the hydraulic oil from the oil tank OT, via the valve V3, and delivers the hydraulic oil to the rear end portion of the injection cylinder 51, via the valve V2. The hydraulic oil pushed out from the front end portion of the injection cylinder 51 is discharged to the oil tank OT via the valve V5, and stored. If the output of the hydraulic pump P is larger than that of the accumulator ACC, the pressure at which the injection piston 52 (i.e., the plunger tip 41) is pressed is further raised, as compared with that in the state of
It is to be understood that the disclosure is not limited to the above embodiment, but the embodiment may be modified as needed, without departing from the principle of the disclosure.
Number | Date | Country | Kind |
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JP2020-031294 | Feb 2020 | JP | national |
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Number | Date | Country | |
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20210268577 A1 | Sep 2021 | US |