KR20110074095A - Device for casting ladle - Google Patents

Abstract

PURPOSE: A ladle device for transporting molten metals is provided to enhance working efficiency by optimally determining the positions of a ladle and an insulating furnace and prevent product failure due to a lack of molten metals by supplying of a fixed amount of metal metals to a casting machine through accurate ladling when the molten metals are supplied to the casting machine or are moved. CONSTITUTION: A ladle device for transporting molten metals comprises an insulating furnace(20), an arm(30), a body frame(40), a horizontal guide frame(50), a die block(60) and a crank block(70). The insulating furnace stores molten metals. The arm is formed to be lift and rotated on one side of the insulating furnace. The body frame is vertically installed around the insulating furnace to guide the vertical movement of the arm. The horizontal guide frame is horizontally installed on the upper end of the body frame. The die block is mounted on the horizontal guide frame and horizontally moves along the horizontal guide frame. The crank block is mounted on the die block and rotates.

Description

Device for casting ladle {Device for casting ladle}

      The present invention relates to a molten ladle device for transporting molten metal, in particular, when supplying molten metal to a casting machine or transferring the molten metal in a high pressure die casting process, as necessary, to position the position of the ladle and the location of the heating furnace to improve the working efficiency. It relates to a molten ladle device for conveying molten metal.

      In the high pressure casting die casting method, a cold chamber system using a ladle, which is a container containing the molten metal, is mainly used when the aluminum molten metal is transferred to the casting machine or supplied into the casting machine. In some cases, the hot chamber type device, which is a method in which the heating furnace itself is vacuum-sealed and the molten metal is injected into the casting machine through a connecting pipe, is expensive but difficult to maintain. Many are not widely used.

      In the cold chamber type molten ladle device, as shown in FIG. 1, the molten metal contained in the thermal furnace 10 is poured into the ladle 12 mounted on the ladle arm 11 to the inlet 14 of the casting machine 13. It is supposed to be poured.

      In the molten ladle in this manner, as the casting process continues, the amount of molten metal decreases, thereby lowering the height of the molten surface. Accordingly, the ladle arm 11 in order to make the amount of molten metal contained in the ladle 12 constant. It is necessary to change the moving position of the molten metal according to the changing molten surface.The thermocouple capable of sensing the temperature is attached to the ladle arm 11 to sense the height of the molten surface by using the temperature sensing signal from the thermocouple, and at the detected height. There is known a structure for controlling the amount of molten metal contained at an angle to the ladle (see Republic of Korea Patent Publication No. 10-2008-0053577).

      In addition, when the molten metal contained in the thermal furnace 10 is transferred to the casting machine 13 through the ladle 12 or fed into the casting machine 13, the position of the thermal furnace 10 and the ladle 12 and the ladle 12 and the casting machine It is preferable that the position of (13) be freely changed.

      However, the conventional molten ladle lagging apparatus has a structure in which the heat retainer 10 and the ladle 12 are immovably coupled to each other, and when the molten aluminum in the heat retainer 10 is supplied into the casting machine 13 or the heat retainer, (10) There were many restrictions in moving the molten metal through the ladle 12, and in particular, the working radius of the ladle 12 was limited so that it could not adequately cope with the positional movement of the casting machine 13, etc. There was a problem that can not adequately respond to this interruption or deformation of the working radius.

      In addition, during the casting process, the surface of the molten metal is exposed to air to be oxidized and cooled, thereby forming a solidified oxide layer having a constant surface height. Accordingly, a difference occurs in the amount of molten metal contained in the ladle 12, thereby causing a defect in molding the product. Since the amount of molten ladle is mainly small and the molten metal is insufficiently supplied into the casting machine, the shape of the product is not completely formed.

      In addition, the solid oxide layer resulting from the rapid oxidation reaction between the aluminum molten metal and the atmosphere is supplied together with the molten metal into the casting machine mold and molded, so that an oxide layer lump is re-dissolved inside the product and not mixed with the molten metal. Deterioration occurs and defects occur because the oxide layer material is exposed and dropped during cutting.

     When the oxide layer is formed, the worker directly removes the work, which is likely to cause a safety accident. In order to solve this problem, it is preferable to move the position of the ladle and the heating furnace as necessary to determine the position. However, the conventional ladle and the heating furnace are not integrated with each other and cannot be detached to determine the optimum molten metal transport position. It may cause work efficiency to fall.

      The present invention was created to solve the above problems, when supplying the molten metal to the casting machine in the high pressure die casting process or when the position of the ladle and the location of the heat retaining furnace as needed to optimize the work efficiency It is an object of the present invention to provide a molten ladle device for carrying molten metal.

      Another object of the present invention, by supplying the molten metal to the casting machine or when transferring the molten metal by supplying a certain amount of molten metal to the casting machine through accurate ladling to prevent product defects due to the lack of molten metal, and removes the oxide layer on the surface of the molten metal It is an object of the present invention to provide a molten ladle device for transporting the molten metal which can prevent product defects in advance by preventing the oxide layer mass from being supplied to the casting machine together with the molten metal.

       The molten ladle carrying device according to the present invention for achieving this object,

      An insulation furnace for storing molten molten metal, a ladle arm that is lifted and rotated in one side of the insulation furnace, and a ladle body frame installed in a vertical direction at one periphery of the insulation furnace to guide the vertical movement of the ladle arm; And a horizontal guide frame installed in a horizontal direction at an upper end of the ladle body frame, a ladle die block mounted on the horizontal guide frame to move horizontally along a horizontal guide frame, and a ladle crank block mounted on the ladle die block to rotate. And a link arm connected to the ladle crank block and a basket connected to one end of the link arm to spread the molten metal.

      A moving wheel installed at a bottom of the heat retaining path and supporting the heat retaining path to be movable;

      A moving wheel installed at the bottom of the ladle body frame and supporting the entire ladle body frame to be movable on the floor;

      A support bracket mounted to a side portion of the ladle body frame to support the ladle body frame without flow on the bottom surface;

      A ladle body frame support bolt mounted on the support bracket to fix the ladle body frame in a vertical state to the floor;

      The side portion of the thermal insulation furnace is characterized in that it comprises a support bracket 84 is mounted to the support bracket and is fixed to the support bracket for fixing the thermal insulation in a horizontal state.

      The warming furnace and the ladle body frame is characterized in that it is detachably coupled to the support bracket.

     The ladle body frame is provided with a lift rail guide and a lift rail, and the lift cylinder is mounted on the vertical axis at the center thereof.

      The lower side of the ladle body frame is characterized in that the frame ribs for installing the support bracket and the support bolt is symmetrically installed on both sides.

       The horizontal guide frame is characterized in that the ladle operation cylinder for horizontally moving the ladle die block along the horizontal guide frame is mounted.

      The present invention has the effect of improving the efficiency of work by positioning the position of the ladle and the position of the heating furnace in the optimum state as needed when supplying the molten metal to the casting machine in the high pressure die casting process. In addition, when supplying molten metal to the casting machine or transferring the molten metal, it supplies accurate quantity of molten metal to the casting machine through accurate ladling to prevent product defects due to the lack of molten metal. By preventing the supply of the molten metal to the casting machine is effective in reducing the casting product defects.

      Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

      Figure 2 is a molten ladle for carrying molten material according to an embodiment of the present invention, (a) is a front view and (b) is a side view. 3 is an explanatory view of a molten ladle device for carrying out according to an embodiment of the present invention. Figure 4 is a schematic view of the operation and installation of the molten ladle laminating apparatus according to an embodiment of the present invention.

     2 to 4 according to an embodiment of the present invention, as shown in Figures 2 to 4, the molten molten metal is stored in the heating furnace 20, and can be elevated in one side in the heating furnace 20 and rotated in the upper portion Ladle body 30 and the ladle body frame 40, which is installed in a vertical direction on the periphery of one side of the heating path 20 to guide the vertical movement of the ladle arm 30, and ladle body frame 40 Horizontal guide frame 50 installed in the horizontal direction at the upper end of the), the ladle die block 60 mounted on the horizontal guide frame 50 to move horizontally along the horizontal guide frame 50, and ladle die block 60 It consists of a ladle crank block 70 is mounted to the rotation and the link arm 71 connected to the ladle crank block 70 and a basket 72 connected to one end of the link arm 71 to transport the molten metal.

      Also. It is provided on the bottom of the heat retainer 20 has a moving wheel 80 for supporting the heat retainer 20 to be movable, is installed on the bottom of the ladle body frame 40, the entire ladle body frame 40 It is provided with a moving wheel 81 for supporting the movable to the bottom surface, the support bracket 82 is provided on the side of the ladle body frame 40 to support the ladle body frame 40 without flow on the bottom surface It is configured to be mounted, the ladle bar deframe supporting bolts 83 are mounted to the support bracket 82 to fix the ladle body frame 40 in a vertical state on the bottom surface, and the thermal insulation furnace 20 The side portion of the support bracket 84 is mounted and is mounted to the support bracket 84 is composed of a heat retention furnace support bolt 85 for fixing the heat retention path 20 in a horizontal state.

      In addition, the thermal insulation furnace 20 and the ladle body frame 40 is configured to be detachably coupled to each other by the support brackets 82 and 84.

     In addition, a lift rail guide 41 and a lift rail 42 are installed in the ladle body frame 40, and a lift cylinder 43 is mounted on the vertical axis to be mounted at the center thereof to form a horizontal guide frame 50. It is configured to move up and down.

     In addition, the lower side of the ladle body frame 40, the frame ribs 86 for installing the support bracket 82 and the support bolt 83 is configured to be symmetrically installed on both sides.

      In addition, the horizontal guide frame 50 is equipped with a ladle operation cylinder 51 for horizontally moving the ladle die block 60 along the horizontal guide frame 50.

       Here, reference numeral 91 is a ladle motor, 92 is a central arm chain, 93 is a pouring motor, 94 is a vertical arm chain, 95 is an electric box.

Referring to Figures 3 and 4 the specific operation of the molten ladle carrying apparatus according to the invention configured as described above are as follows.

The thermal furnace 20 has a space 21 for keeping aluminum or a similar material in a molten state or maintaining a molten state and storing a molten metal.

As shown in FIG. 4, when the molten metal stored in the heat retaining furnace 20 is transported or supplied to the casting machine 90, the space 21 of the heat retaining furnace 20 is used by using a basket 72. The molten metal contained in the molten state is spread and supplied to the casting machine 90.

4 is a schematic diagram showing a state in which the ladle device according to the present invention is installed at the periphery of the continuous casting machine 90 to transport and supply the molten metal contained in the space 21 of the heating furnace 20 to the casting machine 90 side. .

In order to move the molten metal contained in the heating furnace 20 to the basket 72, a mechanical device capable of moving like a robot arm is required.

     Usually, in the molten ladle apparatus, a mechanism consisting of a lifting mechanism, a link, and an arm is used.

     In the present invention, a ladle carrying device for carrying molten metal may include a ladle arm 30 and a ladle arm 30 configured to be lifted and rotated on one side in the thermal furnace 20 and the thermal furnace 20 in which the molten molten metal is stored. In order to guide the vertical movement of the ladle body frame 40 is installed in a vertical direction on the periphery of one side of the heating furnace 20, the horizontal guide frame 50 is installed in the horizontal direction on the upper end of the ladle body frame 40, A ladle crank block 70 mounted on the horizontal guide frame 50 and horizontally moved along the horizontal guide frame 50, a ladle crank block 70 mounted on the ladle diblock 60, and a ladle crank block ( Link arm 71 connected to 70 and one end of the link arm 71 is connected to the basket 72 for carrying the molten metal.

      Inserting or removing the basket 72 into the space 21 of the heat retaining furnace 20 can be removed by inserting the basket 72 into the heat retaining furnace 20 using a conventional lifting mechanism, and moving the basket 720 to another position. The ladle arm 30 is rotated and moved, that is, the ladle crank block 70 rotates according to the operation of the ladle die block 60, and the link arm 71 operates in conjunction with the rotation to supply molten metal as shown in FIG. The molten metal can be supplied to the casting machine 90 side which becomes a target part.

      Here, the ladle body frame 40 supports the horizontal guide frame 50 in a horizontal state, and at the same time to raise and lower the entire horizontal guide frame 50 through the lift cylinder (43). For this purpose, the lift rail guide 41 and the lift rail 42 are installed in the ladle body frame 40 to guide the lifting and lowering operation, and the position of the lift cylinder 43 rod becomes the height of the horizontal guide frame 40. .

       The horizontal guide frame 50 supports the ladle diblock 60 in a horizontal state and simultaneously seats and supports the ladle diblock 60 to determine the position of the ladle diblock 60 through the ladle actuating cylinder 51. . That is, as shown in Figure 3, when inserting the basket 72 to the heat retainer 20 side pulls the roller of the ladle operation cylinder 60 in order to move the ladle die block 60 to the heat retainer 20 side, on the contrary As described above, when the ladle arm 30 is rotated to pour molten metal on the casting machine 90 side, the rod is pushed to position the ladle die block 60 so as to be located close to the casting machine 90 side. For this purpose, the ladle diblock 60 is mounted on the rod of the ladle actuating cylinder 60.

      Rotation of the basket 72 in a state in which the basket 72 is lowered to the molten surface after the position adjustment of the ladle die block 60 is completed, the molten metal is contained in the basket 72 and moved upward through the ladle arm 30 again. Drives the drive motor to rotate the ladle crank block 70, the link arm 71 is interlocked by the rotation of the ladle crank block 70 to transport the molten metal to the casting machine 90 side located on the opposite side as shown in FIG. Supply.

      On the other hand, the position of the casting machine in high-pressure casting die casting is typically difficult to move or overall repositioning. Typically, ladle arms and insulation furnaces, including casting machines, are placed on the periphery of the casting machine. Furthermore, relocation by weight requires equipment and time-consuming precise positioning.

      According to the present invention, when the molten metal contained in the heating furnace 20 is transferred to the casting machine 90 through the ladle arm 30 or supplied into the casting machine 90, the position of the heating furnace 20 and the ladle arm 30 and the ladle arm 30 are provided. The positions of the 30 and the casting machine 90 can be freely changed and positioned.

      That is, the heat retaining furnace 20 and the ladle body frame 40 are detachably coupled to each other by the support brackets 82 and 84 so as to independently position the warming temperature 20 and the ladle body frame 40 by positioning them. It is supposed to be.

     In the related art, since all of them are integrated, it is impossible to independently adjust or determine the position of the optimum state corresponding to the supply position of the molten metal. However, the insulation furnace 20 and the ladle body frame 40 may be detachably attached. By combining, the independent movement and positioning of the thermal insulation furnace 20 and the ladle body frame 40 is possible.

     At the bottom of the heat retainer 20, a moving wheel 80 supporting the heat retainer 20 to be movable is installed, and the position of the heat retainer 20 can be easily adjusted, and the bottom of the ladle body frame 40 is provided. In addition, since the moving wheel 81 for supporting the entire ladle body frame 40 to be movable on the bottom surface is installed, the entire positioning and adjustment of the ladle arm 30 is possible. In addition, the ladle body frame 40 is a support bracket 82 is installed and the support bracket 82, the ladle body frame support bolt 83 is mounted to determine the position of the ladle body frame 40 and then support Rotating the lower bolt 83 to contact the bottom surface can be installed in a solid state in the vertical direction to the bottom ladle body frame 40.

     Similarly, when the heat retaining support bolts 85 are mounted on the side support brackets 84 of the heat retaining furnace 20, and the support bolts 85 touch the floor after adjusting the position of the heat retaining furnace 20. By turning down to settle the position of the thermal insulation furnace 20 in a solid state.

      As described above, the present invention can easily determine the positions of the heating furnace 20, the ladle arm 30, and the ladle body frame 40 based on the position of the molten metal supply target, so that the molten metal is more precisely and quickly supplied. There is an advantage that can be carried to the target.

Accordingly, the present invention can improve the work efficiency by positioning the position of the ladle arm and the position of the heating furnace in the optimum state as needed when supplying the molten metal to the casting machine in the high-pressure die casting process or transfer the molten metal to the casting machine, Accurate ladling is applied to the casting machine through accurate ladling when supplying or transferring molten metal to prevent product defects due to lack of molten metal, and to remove the oxide layer on the surface of the molten metal to contribute to the safety of operation. It can be prevented from being fed to the casting machine to reduce casting product defects.

As such, the present invention has been described with reference to an embodiment of the present invention through the drawings and the specification. Those skilled in the art can make various modifications and equivalent implementations.

       1 is a schematic diagram for explaining a general ladle device.

      Figure 2 shows a ladle device according to an embodiment of the present invention, (a) is a front view, (b) is a side view.

       3 is a layout view of a ladle device according to an embodiment of the present invention.

      4 is a layout example of the ladle device according to an embodiment of the present invention and an operation diagram thereof.

       <Explanation of symbols for the main parts of the drawings>

      20: thermal insulation

      21: space

      30: ladle arm

      40: ladle body frame

      41: lift rail guide

      42: lift rail

      43: lift cylinder

      50: Number of evaluation guide frame

      51: ladle operation cylinder

      60: ladle die block

      70: ladle crank block

      71: link arm

      72: basket

      80.81: Moving wheels

      82.84: support bracket

      83.85: Supporting bolt

Claims (5)

       To guide the vertical movement of the ladle arm (30) and the ladle arm (30) configured to be elevated and rotated on one side in the thermal furnace (20), the molten molten metal is stored; Ladle body frame 40 is installed in a vertical direction on one side peripheral portion of the heating furnace 20, a horizontal guide frame 50 is installed in a horizontal direction on the upper end of the ladle body frame 40, and the horizontal guide frame The ladle crank block (70) and the ladle crank block (70) mounted on the ladle crank block (60) and horizontally moved along the horizontal guide frame (50) are mounted on the ladle diblock (60) and rotated. Link basket 71 is connected to one end and the basket 72 is connected to one end of the link arm 71 to carry the molten metal,       A moving wheel 80 installed at the bottom of the heat retaining furnace 20 to support the heat retaining furnace 20 to be movable;      A moving wheel 81 installed at the bottom of the ladle body frame 40 to support the entire ladle body frame 40 to be movable on the bottom surface;      A support bracket 82 mounted on a side portion of the ladle body frame 40 to support the ladle body frame 40 without flow on the bottom surface;      And a ladle body frame support bolt 83 mounted on the support bracket 82 to fix the ladle body frame 40 in a vertical state to the bottom surface;     A side surface of the heat retainer 20 includes a support bracket 84 mounted thereon and a heat retainer support bolt 85 mounted to the support bracket 84 to fix the heat retainer 20 in a horizontal state. A molten ladle device for carrying molten metal.       The method of claim 1,      The heating furnace 20 and the ladle body frame 40 is characterized in that the support bracket (82) (84) is detachably coupled to each other characterized in that the molten hauling device. The method of claim 1,       The ladle body frame 40 is provided with a lift rail guide 41 and a lift rail 42, the center of the lift cylinder 43 is mounted on the vertical axis is mounted to raise and lower the horizontal guide frame 50 A molten ladle device for carrying molten metal, characterized in that configured to be.       The method of claim 1,      The lower side of the ladle body frame 40, the support bracket 82 and the frame ribs (86) for installing the support bolts (83), characterized in that the symmetrical installation on both sides, characterized in that configured ladle apparatus for carrying.       The method of claim 1,      The horizontal guide frame 50 is ladle device for ladle transport characterized in that the ladle operation cylinder (51) for horizontal movement along the horizontal guide frame 50 is mounted to the ladle die block (60).

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