This invention relates to a method for controlling an automatic pouring device (hereafter, a pouring control) with a tilting-type ladle that tilts the ladle filled with molten metal to pour it into a mold. Also, the invention relates to a storage medium for storing programs for causing a computer to work as a pouring control means.
Some methods for controlling an automatic pouring device with a tilting-type ladle are proposed. One of them controls the position on which molten metal that runs out of a pouring ladle falls (hereafter, the falling position), by using a feed forward control (PTL 1). Another one has a feedback control so that it can correct any difference that occurs as a result of a control of the falling position of molten metal by using a feed forward control (PTL 2). Another one controls a movement of a mold so that the molten metal that runs out of a pouring ladle is accurately filled in the mold (PTL 3), etc.
(PTL 1)
Japanese Patent Laid-open Publication No. 2008-272802
(PTL 2)
Japanese Patent Laid-open Publication No. 2011-224631
(PTL 3)
Japanese Patent Laid-open Publication No. 2012-16708
By the technology disclosed by PTL 1, the position on which molten metal that runs out of a pouring ladle falls is controlled by using a feed-forward control. By the technology disclosed by PTL 2, if the falling position differs from a target position, and even if the position is controlled by the falling position control disclosed by PTL 1, a pouring ladle will go forward or backward so as to eliminate the difference. However, by the technologies disclosed by PTL 1 and PTL 2, a lip of a pouring ladle does not vertically get closer to a sprue of a mold. Thus, the pouring of molten metal may be carried out from a high position. Therefore, the temperature of the molten metal may decrease, because the free-fall time of the molten metal that runs out of the pouring ladle can be long. Also, the molten metal can be scattered when it contacts the sprue of the mold, because the velocity of the metal that runs out of the ladle can be high when the metal reaches the sprue. A pouring ladle should be moved vertically so as to cause the vertical distance between the lip of the pouring ladle and the sprue of the mold to become shorter. If the ladle is moved vertically, it can strike a mold or a pedestal of a device such as a device for pouring molten metal. Also, by the technology disclosed by PTL 3, since it uses a device for moving a mold, new equipment is needed. Also, it does not ensure that the ladle will not strike any pedestal located around the mold.
The invention of this application aims to provide a pouring control method and a storage medium for controlling an automatic pouring device with a tilting-type ladle. By the method, a lip of a pouring ladle approaches a sprue of a mold without striking a mold and any object located within the range of its movement. Also, by the method, the molten metal that runs out of the ladle can accurately fill the mold.
The present invention was made to accomplish these aims. The invention of claim 1 uses a technical means, i.e., it is a pouring control method for an automatic pouring device with a tilting-type pouring ladle. The device can control the movements of the ladle in the back and forth and up and down directions, and can also control its tilting. The method comprises the steps of setting a target flow rate of molten metal to be poured, generating a voltage to input it to a motor that tilts the ladle (hereafter, the tilting motor) so as to reach the target flow rate of the molten metal, based on an inverse model of a mathematical model of molten metal that runs out of a pouring ladle and an inverse model of the tilting motor, estimating the flow rate of the molten metal that runs out of the ladle, estimating the falling position and getting the estimated falling position to be a target position, and generating a trajectory for the movement of the pouring ladle wherein the trajectory causes the height of the lip of the pouring ladle above the level of a sprue of a mold to decrease and causes the ladle not to strike any object located within the range of its movement, controlling the movement of the pouring ladle and pouring the molten metal into the mold so that the height of the lip of the pouring ladle above the level of the sprue of the mold decreases and so that the ladle does not strike the object when the molten metal is being poured into the mold.
By the invention of claim 1, since the falling position of the molten metal is controlled, the molten metal that runs out of the ladle can be accurately poured into the sprue of the mold. Namely, a trajectory for the movement of the pouring ladle is generated so that the trajectory causes the ladle not to strike any object located within the range of its movement. Based on the trajectory, the movement of the pouring ladle is controlled so that the height of the lip of the pouring ladle above the level of a sprue of a mold decreases, and so that the molten metal is poured into the mold. Thus the free-fall time of the molten metal poured from the pouring ladle can be shortened, compared to that of a conventional pouring control method in which no lip of a pouring ladle is controlled to have it approach a sprue of a mold. Also, any decrease in the temperature of the molten metal can be restricted. Further, the velocity of the molten metal when the metal reaches the sprue can be lowered, and so scattering of the metal can be restricted.
The invention of claim 2 uses a technical means that includes steps that are carried out after the step of generating a trajectory for the movement of the pouring ladle in the method of claim 1. Namely, the trajectory is generated based on the mode in which the pouring ladle is going to strike the object (hereafter, the striking mode), which mode is previously set, and based on the conditions for changing the movement of the ladle, which conditions are decided based on the striking mode.
By the invention of claim 2, when the trajectory of the movement is generated, the shape of the pouring ladle, the relationship between the locations of the ladle and the object that is positioned within the range of its movement, etc., is considered, and then the trajectory can be generated based on the striking mode, in which the pouring ladle is going to strike the object, which mode is previously set, and based on the conditions for changing the movement of the ladle, which conditions are based on the striking mode.
The invention of claim 3 uses a technical means, i.e., it is a pouring control method for an automatic pouring device with a tilting-type pouring ladle. The device can control the movement of the ladle in the back and forth and up and down directions, and also can control its tilting. The method comprises the steps of setting a target flow rate of molten metal to be poured, generating a voltage to be input to a tilting motor so as to reach the target flow rate of the molten metal based on an inverse model of a mathematical model of the molten metal that runs out of a pouring ladle and an inverse model of the tilting motor that tilts the ladle, estimating the flow rate of the molten metal that runs out of the ladle, estimating the falling position of the molten metal and getting the falling position to be a target position, setting a hypothetical axis at the lip of the ladle, generating a second trajectory for the movement of the pouring ladle wherein the trajectory causes the ladle not to strike any object located within the range of its movement and minimizes the height of the lip of the pouring ladle above the level of a sprue of a mold, controlling the movement of the pouring ladle so that the ladle does not strike the object when the molten metal is being poured into the mold, and pouring the molten metal into the mold by turning the ladle around the hypothetical axis set at the lip of the ladle.
By the invention of claim 1, since the falling position of the molten metal is controlled, the molten metal that runs out of the ladle can be accurately poured into the sprue of the mold. Namely, a trajectory for the movement of the pouring ladle is generated so that the trajectory causes the ladle not to strike any object located within the range of its movement and minimizes the height of the lip of the ladle above the level of the sprue of the mold. Based on the trajectory, the movement of the pouring ladle is controlled so that the ladle turns around a hypothetical axis and the molten metal is poured into the mold. Thus, the free-fall time of the molten metal poured from the pouring ladle can be shortened. Also, the decrease in the temperature of the molten metal can be restricted. Further, the velocity of the molten metal when the metal reaches the sprue of the mold can be lowered and scattering of the metal can be restricted. Since the height of the lip of the ladle is constant when the molten metal is being poured, the pouring can be less affected by an external disturbance. Also, the electric power necessary to move the pouring ladle can be less.
The invention of claim 4 uses a technical means that includes steps that are carried out after the step of generating a second trajectory for the movement of the pouring ladle in the method of claim 3. Namely, at that step, the second trajectory decides the location of the ladle based on the striking mode, which mode is previously set.
By the invention of claim 4, when the second trajectory of the movement is generated, the shape of the pouring ladle, the relationship between the locations of the ladle and the object that is positioned within the range of its movement, etc., is considered, and then the location of the ladle can be decided based on the striking mode, which mode is previously set.
A medium invention uses a technical means, i.e., it is a medium that is readable by a computer in which a program is stored. The program causes the computer to carry out pouring control processes for an automatic pouring device with a tilting-type pouring ladle. The device can control the movement of the ladle in the back and forth and up and down directions, and also can control its tilting. The processes comprise setting a target flow rate of molten metal to be poured, generating a voltage to be input to a tilting motor so as to reach the target flow rate of the molten metal, based on an inverse model of a mathematical model of molten metal that runs out of a pouring ladle and an inverse model of the tilting motor, estimating the flow rate of the molten metal that runs out of the ladle, estimating the falling position of the molten metal and getting the falling position to be a target position, and generating a trajectory for the movement of the pouring ladle wherein the trajectory causes the height of the lip of the pouring ladle above the level of a sprue of a mold to decrease and causes the ladle not to strike any object located within the range of its movement.
Another medium invention uses a technical means, i.e., it is a medium that is readable by a computer in which a program is stored. The program causes the computer to carry out pouring control processes for an automatic pouring device with a tilting-type pouring ladle. The device can control the movement of the ladle in the back and forth and up and down directions, and also can control its tilting. The processes comprise setting a target flow rate of molten metal to be poured, generating a voltage to be input to a tilting motor so as to reach the target flow rate of the molten metal based on an inverse model of a mathematical model of molten metal that runs out of a pouring ladle and based on an inverse model of the tilting motor, estimating the flow rate of the molten metal that runs out of the ladle, estimating the falling position of the molten metal and getting the falling position to be a target position, setting a hypothetical axis at the lip of the ladle, and generating a second trajectory for the movement of the pouring ladle wherein the trajectory causes the ladle not to strike any object located within the range of its movement and minimizes the height of the lip of the pouring ladle above the level of a sprue of a mold.
By the medium inventions, the pouring control method of the invention of this application is applied to a program for controlling the pouring of molten metal that can cause the computer to carry out the method and is also applied to a storage medium that is readable by a computer and in which the program is stored.
Now, based on drawings we discuss the pouring control method of the invention of this application.
Since the servomotors 11, 12, and 13 each have rotary encoders, the position and the angle of the tilting of the pouring ladle 10 can be determined. The servomotors 11, 12, and 13 are configured to be given a command signal from a computer. The “computer” in this disclosure denotes a motion controller such as a personal computer, a micro computer, a programmable logic controller (PLC), and a digital signal processor (DSP).
The automatic pouring device 1 can control the servomotors 11, 12, and 13 in the construction as described above and cause the pouring ladle 10 to move on a predetermined trajectory. Then it can discharge the molten metal from a lip 10a and pour it into a mold 20 through a sprue 20a of the mold 20.
In the automatic pouring device with a tilting-type ladle 1, a position control system for the pouring ladle is used. The control system can control the device so that the pouring ladle 10 does not strike the mold 20 or any object within the range of the movement of the ladle 10 such as the pedestal 14 of the automatic pouring device 1, and so that the lip 10a of the ladle 10 advances to the sprue 20a of the mold 20 and accurately pours the molten metal into the sprue 20a. Shown below is a mathematical model that includes a process starting with sending a control command signal to the servomotor to determine a falling position in the horizontal direction of the molten metal that runs out of a pouring ladle 10.
The Pf shown in
[Math.1]
Vr(t)+Vs(θ(t))=Vr(t+Δt)+Vs(θ(t+Δt))+q(t)Δt (1)
If equation (1) is rearranged to calculate the volume of the molten metal Vr [m3], and if Δt→0, then equation (2) will be obtained.
The angular speed ω [deg/s] of the pouring ladle 10 is represented as equation (3).
If equation (3) is substituted for equation (2), then equation (4) will be obtained.
The volume Vr [m3] of the molten metal of the part that is above the lip is represented as equation (5).
[Math.5]
Vr(t)=∫0h(t)As(θ(t),hs)dhs (5)
The symbol As [m2] denotes the horizontal area of the molten metal at the height hs [m] above the horizontal plane of the lip.
If the area As [m2] is divided into area A [m2] and the incremental value of the area ΔAs [m2], then the volume of the molten metal Vr [m3] will be represented by the following equation (6).
[Math.6]
Vr(t)=∫0h(t)(A(θ(t))+ΔAs(θ(t),hs))dhs=A(θ(t))h(t)+∫0h(t)ΔAs(θ(t),hs)dhs (6)
As for a commonly used pouring ladle, the incremental value of the area ΔAs [m2] is very small compared to the area A [m2] of the horizontal plane of the lip. Thus, the following equation (7) is obtained.
[Math.7]
A(θ(t))h(t)>>∫0h(t)ΔAs(θ(t),hs)dhs (7)
Accordingly, equation (6) can be represented by equation (8).
[Math.8]
Vr(t)≈A(θ(t))h(t) (8)
Therefore, equation (9) is obtained from equation (8).
Equation (10) is obtained from equation (9).
By using Bernoulli's theorem, the flow rate of the molten metal q [m3/s] is represented by equation (11) at the height h [m] of the molten metal above the lip 10a.
The symbol hb [m] denotes the depth of the molten metal in the pouring ladle from its surface as in
From the above, the process Pf of pouring molten metal is represented by equations (10) and (11).
The symbol Pm shown in
The symbol ω [deg/s] is an angular speed of tilting, u [V] is an input voltage, T [s] is a time constant, and K [deg/s/V] is a gain constant.
Now we discuss a method for estimating the falling position of the molten metal when it is being poured.
In a model of a process of an outflow of molten metal, the length of the drop of molten metal in the horizontal direction Sv [m] can be obtained by the product of a velocity of the outflow vf [m/s] times the falling time Tf [s], and the length can be represented by an equation using vf [m/s] and a height Sw [m], which height is the position where the molten metal reaches. The outflow velocity vf [m/s] is represented by a primary expression, considering the effect of its contraction, wherein the result obtained by dividing the flow rate q [m3/s] of a molten metal by a cross sectional area Ap [m2] of the molten metal at the lip 10a is used.
The symbol vf0 [m/s] denotes a flow rate of the molten metal when it flows into the guide of the lip 10b as in
The symbol θn [deg] in equations (15)-(18) denotes the angle of the tilting of the lip 10a at its end to the horizontal plane. Suppose that the angle of the tilting of the end of the lip 10a is φ [deg], wherein the pouring ladle 10 is vertical. If the angle of the tilting of the pouring ladle is θ [deg], then the angle will be represented by the following equation.
[Math.19]
θa(t)=θ(t)+ϕ (19)
Lg [m] is the length of the guide of the lip 10b, v [m/s] is the velocity of the molten metal when it runs out of the guide 10b, vf [m/s] is the horizontal component of the velocity of the molten metal when it runs out of the guide 10b, and Tf [S] is the free-fall time of the molten metal that runs out of the guide 10b. As in
Based on that mathematical model, a control system is constructed, wherein the control system estimates the position on which the molten metal falls and controls the position. By using the equation (11), the height href [m] of the molten metal above the lip can be obtained by the following equation. From that height href [m], a target flow rate qref [m3/s] of molten metal that is being poured will be reached.
[Math.20]
href(t)=f−1(qref(t)) (20)
If equation (4) is replaced by equations (9) and (20) and rearranged, the tilting angular speed ωref [deg/s] of tilting the pouring ladle will be represented by the following equation, and an inverse model of the process for pouring molten metal will be obtained. By using that angular speed ωref [deg/s], the height lire [m] of the molten metal above the lip will be reached.
The input voltage u [V] that is to be input to a servomotor is derived from the inverse model Pm−1 of the dynamic characteristics of a servomotor that tilts a pouring ladle 10. The voltage causes the servomotor to let the flow of the molten metal that is being poured reach the target flow rate qref [m3/s]. The model Pm−1 is derived from equation (12) as in the following equation.
By sequentially calculating the solutions of equations (20)-(22), the input voltage u [V] that causes the servomotor to let the flow reach the target flow rate qref [m3/s] of molten metal can be obtained.
Now, we discuss the block for generating a trajectory for the movement of a pouring ladle. In this block Dyz, the position on which the molten metal falls is estimated and the position is set as a target position. The trajectory causes the lip 10a of the ladle 10 to approach the sprue 20a of the mold 20 and the molten metal is accurately poured into the sprue of the mold without the pouring ladle 10 striking the mold 20 or a pedestal 14 or other objects. In this embodiment, we discuss a case in which a box-shaped pouring ladle is used.
A feed forward control system that uses an inverse model of the flow rate Pf−1Pm−1 for controlling the flow rate of molten metal that is to be poured causes the actual flow of molten metal to follow a pattern of a target flow. Thus it causes the actual flow to correspond to the target flow rate qref [m3/s] of the molten metal. The position on which the molten metal falls (the falling position) can be estimated by using the target flow rate qref [m3/s] and the flow rate of the molten metal that is estimated in the block for estimating the flow rate Ef. Then a control for the falling position is carried out by moving the pouring ladle 10 to the place from which, if the molten metal is poured, the estimated falling position will be the target position, i.e., the position just on the sprue 20a of the mold 20.
The relative falling position Sv [m] is the horizontal distance between the position on which the molten metal falls and the end of the lip 10a. The absolute falling position Sy [m] is the horizontal distance between the position on which the molten metal falls and the origin of a coordinate system. The origin is the center of the sprue 20a on the surface of a mold 20.
The positions of objects are shown in
About the changes of the position of the pouring ladle 10 when it approaches the mold 20 or the pedestal 14, the ways to approach it can be divided into the following three modes, as in
Each mode follows the following conditions, which are determined based on the relative positions of the pouring ladle 10, the mold 20, the pedestal 14, etc. The movement of the pouring ladle 10 is changed corresponding to each mode and the position [yf,zf] of the pouring ladle is calculated so that the ladle does not strike the mold 20 or the pedestal 14 or other objects and so that the molten metal is accurately poured into the sprue of the mold. The indices 1-3 respectively correspond to modes 1-3. The conditions in equation (23) are those in which a box-shaped pouring ladle is used. These are set corresponding to the shape of the front lateral part of the pouring ladle.
The symbols df and dp are represented as follows.
[Math.24]
df=Sv(θ,v,Ls cos(γ+θ)+ε) (24)
[Math.25]
dp=Ls sin(γ+θ) (25)
The position of the pouring ladle in each mode is derived as follows.
<Mode 1>
In mode 1, a pouring ladle is moved so that the distance c between its end P and the top surface of a mold 20 is kept constant. The position Z in the vertical direction and the position Y in the back and forth directions of the pouring ladle are obtained as follows.
[Math.26]
zf1=Ls cos(θ+γ)+ε (26)
[Math.27]
yf1=Sv(θ,v,zf1) (27)
<Mode 2>
In mode 2, a pouring ladle is moved so that the height of its end P continuously changes in correspondence to its tilting. Namely, when the position of the end P is lower than the origin of the coordinate system, the ladle is moved so that the end of the lip 10a is kept lower. The position of the pouring ladle in the vertical direction can be obtained by calculating the following equation for zf.
[Math.28]
Sv(θ,v,zf)+zf tan(θ+γ)=dm (28)
The numerical solution of equation (28) can be obtained by using a method for obtaining a numerical solution such as the Newton-Raphson method. In certain cases, in which the pouring ladle has a certain shape, an analytical solution can be obtained. Here we discuss a process to derive the vertical position of the pouring ladle by using the Newton-Raphson method. If equation (28) is replaced with equations (17)-(19), then the following equation will be obtained.
If equation (29) is differentiated with respect to zf, it will be as follows.
Therefore, the zin will be obtained by repeatedly using the following equation.
The vertical position of the pouring ladle is used as an initial value zf0 for the repeated usage of the equation (31). The vertical position, as the initial value, has been obtained by solving equation (31) with respect to the value that is obtained before one sampling period. The calculated vertical position of the ladle is assigned to the following equation as a vertical position of the ladle zf2, and then the position Y in the back and forth directions of the pouring ladle is obtained.
[Math.32]
yf2=Sv(θ,v,zf2) (32)
<Mode 3>
In mode 3, a pouring ladle is moved so that the distance c from its end P to the top surface of a pedestal 14 is kept constant. The position of the pouring ladle in the vertical direction is obtained, using the result in mode 2, as follows.
[Math.33]
zf3=Ls cos(θ+α)+ε−dh (33)
The position yf3 of the pouring ladle in the back and forth directions can be obtained by putting the vertical position of the ladle zf3 in the following equation.
[Math.34]
yf3=Sv(θ,v,zf3) (34)
The yf and zf that are obtained by the equations (23)-(34) are respectively changed to yref and zref, and input into the system Gy for moving the pouring ladle in the back and forth directions and the control system Gz for moving the pouring ladle in the vertical direction. Thus, a method is realized wherein by the method the lip 10a of the ladle 10 is caused to advance to the sprue 20a of the mold 20 and the molten metal is caused to be accurately poured into the sprue of the mold without the pouring ladle 10 striking the mold 20 or a pedestal 14 or other objects.
The pouring control method of the invention of this application is applied to a program for controlling the pouring of molten metal that can cause the computer to carry out the method. The method is also applied to a storage medium that is readable by a computer and in which the program is stored. Namely, the program causes the computer to carry out pouring control processes for an automatic pouring device with a tilting-type pouring ladle. The device can control the movement of the ladle in the back and forth and up and down directions, and can also control its tilting. The processes comprise setting a target flow rate of molten metal to be poured, generating a voltage to be input to a tilting motor so as to reach the target flow rate of the molten metal based on an inverse model of a mathematical model of molten metal that runs out of a pouring ladle and based on an inverse model of the tilting motor, estimating the flow rate of the molten metal that runs out of the ladle, estimating the falling position of the molten metal and getting the falling position to be a target position, and generating a trajectory for the movement of the pouring ladle wherein the trajectory causes the height of the lip of the pouring ladle above the level of a sprue of a mold to decrease and causes the ladle not to strike any object located within the range of its movement.
(Example of Modification)
In addition to a feed forward control, a feedback control can correct an error of a falling position of molten metal and can accurately control the position. For example, a video camera is placed by a side of the automatic pouring device with a tilting-type ladle 1. The falling position of the molten metal that runs out of the lip 10a of a pouring ladle 10 is determined by the camera. A target position is defined in a coordinate system around the camera. The difference between the target position and the falling position is determined. At the block for generating a trajectory for the movement of a pouring ladle Dyz, a feedback control is carried out so as to eliminate the difference. Then the pouring ladle 10 is moved. By this control, even if the estimation of the falling position has an error, since the error is minimized by the feedback control, the falling position can be accurately controlled.
Effects of the First Embodiment
By the pouring control method of the invention of this application, since a falling position of molten metal is controlled, the molten metal that runs out of the ladle 10 can be accurately poured into the sprue 20a of a mold. Namely, a trajectory for the movement of the pouring ladle is generated so that the trajectory causes the ladle not to strike any object located within the range of its movement and so that the height of the lip 10a of the pouring ladle 10 above the level of the sprue 20a of the mold decreases. Based on the trajectory, the movement of the pouring ladle is controlled and the molten metal is poured into the mold 20. Thus the free-fall time of the molten metal poured from the pouring ladle 10 can be shortened, compared to that of a conventional pouring control method in which no lip 10a of a pouring ladle 10 is controlled to have it approach a sprue 20a of a mold. Also, any decrease in the temperature of the molten metal can be restricted. Further, the velocity of the molten metal when the metal reaches the mold 20 can be lowered, and so scattering of the metal can be restricted.
Also, the invention of this application can be applied to a program for controlling the pouring of molten metal, which program can cause the computer to carry out the method. This invention is also applicable to a storage medium that is readable by a computer and in which the program is stored.
Second Embodiment
By the first embodiment, the movement of the pouring ladle 10 is controlled so that the height of its lip 10a above the level of the sprue 20a of the mold decreases. By the second embodiment, a trajectory is generated based on the striking mode, which mode exists between the pouring ladle 10 and the object located within the range of the movement of the ladle 10, and is previously set. The trajectory is generated so that the height of the lip 10a of the pouring ladle 10 above the level of a sprue 20a of the mold is minimized. When the molten metal is being poured, the pouring ladle 10 is moved so that it is tilted around a hypothetical axis set on the lip 10a without its height being changed.
By the first embodiment, a trajectory of the movement of a pouring ladle 10 is generated so that the height of the lip 10a of the pouring ladle 10 is minimized, under the dynamic condition in which the height of the lip 10a is varied when molten metal is being poured. By the second embodiment, under a static condition, a height of the pouring ladle 10 that does not cause the ladle 10 to strike any object around it and a trajectory of the movement of the pouring ladle 10 are determined. Then an initial position from which molten metal is poured is determined.
The steps for determining an initial position of a pouring ladle 10 from which the lip 10a of the pouring ladle 10 starts to approach the sprue 20a of the mold are as follows. First, the input voltage u[V] to a servomotor and the angle θ [deg] of the tilting of the pouring ladle are determined for a target flow rate qref of the molten metal to be poured, by using the equations (20)-(22). By assigning the determined input voltage u[V] and the angle θ [deg] of the tilting to equations (10)-(18), a relative falling position Sv [m], which is the horizontal distance between the position and the end of the lip 10a, is decided. Then a mode value Mo (Sv) of the relative falling position Sv [m] is obtained. By assigning these values to the elements of the trajectory of the movement of the pouring ladle, which elements are shown in equations (23)-(34), the initial position of the pouring ladle at the beginning of pouring molten metal is derived (corresponding to the step for generating a second trajectory for the movement of the pouring ladle in claim 3). When the molten metal is being poured, the pouring ladle 10 is tilted by turning the ladle around the hypothetical axis set at the end of the lip 10a. Therefore, since the ladle 10 will be retracted from the mold 20 and the pedestal 14 compared to the initial position of the ladle, there will be no possibility of striking either one. Accordingly, by using a simple control, the lip 10a of the pouring ladle 10 can advance to the sprue 20a of the mold 20 without striking the mold 20 or pedestal 14. Also, since the height of the lip 10a of the ladle is constant when the molten metal is being poured, the pouring can be less affected by an external disturbance. Also, the electric power necessary to move the pouring ladle can be less. By not assigning the mode value Mo (Se) of the relative falling position Sv [m], but by assigning a medium value or a mean value of the position Sv [m] to the elements of the trajectory of the movement of the pouring ladle, the position of a pouring ladle at the beginning of pouring molten metal is derived.
Also, the invention of this application can be applied to a program for controlling the pouring of molten metal that can cause the computer to carry out the method. This invention is also applied to a storage medium that is readable by a computer and in which the program is stored. Namely, the program causes the computer to carry out pouring control processes for an automatic pouring device with a tilting-type pouring ladle. The device can control the movement of the ladle in the back and forth and up and down directions, and also can control its tilting. The processes comprise setting a target flow rate of molten metal to be poured, generating a voltage to be input to a tilting motor so as to reach the target flow rate of the molten metal based on an inverse model of a mathematical model of molten metal that runs out of a pouring ladle and based on an inverse model of the tilting motor, estimating the flow rate of the molten metal that runs out of the ladle, estimating the falling position of the molten metal and getting the falling position to be a target position, setting a hypothetical axis at the lip of the ladle, and generating a second trajectory for the movement of the pouring ladle wherein the trajectory causes the ladle not to strike any object located within the range of its movement and minimizes the height of the lip of the pouring ladle above the level of a sprue of a mold.
Effects of the Second Embodiment
By the pouring control method of this embodiment, since the falling position of molten metal is controlled, the molten metal that runs out of the pouring ladle 10 can be accurately poured into the sprue 20a of the mold. Also, a trajectory for the movement of the pouring ladle 10 is generated so that the trajectory causes the ladle 10 not to strike any object located within the range of its movement and minimizes the height of the lip 10a of the ladle 10 above the level of the sprue 20a of the mold. Based on the trajectory, the movement of the pouring ladle 10 is controlled so that the ladle turns around a hypothetical axis, which is set at the lip 10a of the ladle, and the molten metal is poured into the mold 20. Thus, the free-fall time of the molten metal poured from the pouring ladle 10 can be shortened, compared to that of a conventional pouring control method in which no lip 10a of a pouring ladle 10 is controlled to have it approach a sprue 20a of a mold. Also, any decrease in the temperature of the molten metal can be restricted. Further, the velocity of the molten metal when the metal reaches the sprue of the mold 20 can be lowered and scattering of the metal can be restricted. Since the height of the lip 10a of the ladle is constant when the molten metal is being poured, the pouring can be less affected by an external disturbance. Also, the electric power necessary to move the pouring ladle 10 can be less.
Also, the invention of this application can be applied to a program for controlling the pouring of molten metal that can cause the computer to carry out the method. This invention is also applicable to a storage medium that is readable by a computer and in which the program is stored.
To clarify the availability of the invention of this application, the trajectory generated by the present invention was compared to the trajectory generated by a conventional method. In that method no lip of a pouring ladle was controlled to have it approach a sprue of a mold. As for the initial conditions, the initial angle of the tilting was θ0=20 [deg] and the initial distance between the center of the sprue of the mold and its side was dm=0.25 [m]. Also, the target flow was given by the shape of the bell in
1 an automatic pouring device with a tilting-type ladle
10 a pouring ladle
10
a a lip of the pouring ladle
10
b a guide of the lip
10
c a lateral side of a front part of the pouring ladle
11, 12, 13 servomotors
14 a pedestal
20 a mold
20
a a sprue of the mold
Number | Date | Country | Kind |
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2012-054827 | Mar 2012 | JP | national |
This is a division of application Ser. No. 14/369,836, § 371(c) date of Jun. 30, 2014, now U.S. Pat. No. 9,950,364, issued Apr. 24, 2018, which is the National Stage of PCT/JP2013/001023, filing date of Feb. 22, 2013, and claims foreign priority to JP 2012-054827, filed Mar. 12, 2012, all of which are incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
3818971 | Schutz | Jun 1974 | A |
6280499 | Koffron | Aug 2001 | B1 |
7308929 | Beale | Dec 2007 | B2 |
8062578 | Noda | Nov 2011 | B2 |
9248498 | Noda | Feb 2016 | B2 |
Number | Date | Country |
---|---|---|
2 140 955 | Jan 2010 | EP |
2 143 513 | Jan 2012 | EP |
2 143 514 | Jan 2012 | EP |
H09-001320 | Jan 1997 | JP |
2008-0272802 | Nov 2008 | JP |
2011-224631 | Nov 2011 | JP |
2012-016708 | Jan 2012 | JP |
Entry |
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English-language International Search Report from the Japanese Patent Office for International Application No. PCT/JP2013/001023, dated Aug. 7, 2013. |
Office Action for corresponding CN Application No. 102106887 dated Nov. 21, 2017. |
Number | Date | Country | |
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20180193907 A1 | Jul 2018 | US |
Number | Date | Country | |
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Parent | 14369836 | US | |
Child | 15917461 | US |