JPH0760433A - Pouring device for casting - Google Patents

Abstract

PURPOSE:To simplify the ink mechanism in a ladle tilting device by using an electric motive actuator. CONSTITUTION:A bill-like pouring hole 11 is arranged in the ladle 1. A ladle supporting frame 2 for supporting the ladle 1 is fitted to a frame 3 freely rotatably. The link mechanism is formed so that this rotating center O23 point always coincides to the position of tip part of the pouring hole 11. The actuator 5 for tilting the ladle 1 is connected with the one end of the ladle supporting frame 2. This actuator 5 is composed of straight line movement mechanism for conversing the existing rotating movement into the straight line movement. The electric motor 6 for working the actuator 5 is provided. A truck 71 for loading these motor 6, actuator 5, frame 3, ladle supporting frame 2 and ladle 1 is provided. A self-running motor 7 is loaded on this truck 71 and the truck can be self-run on rails 8. The molten metal pouring operation is executed by remote-controlling this self-running motor 7 and the motor 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pouring device for casting, which is used when pouring the casting molten metal into a mold in a cast iron casting manufacturing process, and more particularly to tilting a tribute of the pouring device. The present invention relates to a device in which an electric actuator driven by an electric motor is adopted as the actuator.

[0002]

2. Description of the Related Art As a conventional pouring device, except for a manual type that is manually operated by an operator, it is difficult to use a hydraulic mechanism for a drive section because of heat countermeasures, so an electric type is adopted. Has been done. In this electric type, for example, as shown in FIG.
It is rotatably attached to the frame 30 via 10, and a sector gear 50 having a considerable size is provided in a part of the support frame 20, a pinion gear 550 for driving the sector gear 50 is provided, and the pinion gear 550 is further provided. An electric motor 60 for driving the vehicle is provided, and each of these devices is mounted on a carriage 70. In the pouring device having such a configuration, when pouring the casting metal into the injection port 91 of the mold 9, first, the electric motor 60 of FIG.
The pinion gear 550 is driven. As a result, the sector gear 50 is driven, and the tribe support frame 20 integrated with the sector gear 50 makes a rotary motion with the rotation shaft 210 provided between the sector gear 50 and the frame 30 as a fulcrum. Due to this rotational movement, the trolley 10 supported by the trolley support frame 20 is tilted. As a result, the casting molten metal stored in the ladles 10 flows out from the pouring port 110 of the ladles 10 and is poured into the injection port 91 of the mold 9. That is, the pouring work is performed by these series of operations.

[0003]

By the way, in the above-mentioned conventional apparatus, the sector gear 50, which is a device for tilting the tribe 10, and the like are large in size and heavy in weight (mass). Therefore, the electric motor 60 for driving the sector gear 50 also has to have a large capacity. In addition, there is a problem in that the entire device must be large. Further, since the position of the tip of the pouring port 110 is deviated from the position of the center of rotation of the rotary shaft 210, the pouring port 110 moves depending on the rotation angle (tilt angle) of the tribe 10, and the pouring port of the mold 9 is moved. There is a problem in that there is a positional shift with respect to 91. It is an object of the present invention to provide a casting pouring device, which solves such a problem, uses a lightweight, small-sized electric actuator, and has no misalignment between the pouring port and the mold pouring port. The object (problem) of the present invention.

[0004]

In order to solve the above problems, the present invention takes the following measures. That is, with respect to the pouring device of the casting hot water used in the manufacturing process of the casting for cast iron, the tribe in which the casting hot water is stored, the tribe support frame that supports the tribe, and the frame that rotatably supports the tribe support frame, An actuator that is connected to a part of the tribe support frame and that tilts the tribe support frame and the tribe, an electric motor that operates the actuator, and an electric motor, an actuator, a frame, and a tribe support frame, and further the tribe support. It was decided to adopt a configuration in which a trolley supported by a frame is mounted and a trolley that is self-propelled on a rail by a self-propelled motor.

[0005]

With the above construction, the following actions are exhibited in the present invention. That is, as shown in FIG. 1, when pouring the molten metal into the pouring port 91 of the mold 9, it is necessary to first move the pouring port 11 of the tribe 1 onto a predetermined pouring port 91. For that purpose, first, the self-propelled motor 7 is operated by remote control or the like, and the carriage 7
1 is run on the rail 8 and moved to a predetermined position. In such a state, next, the electric motor 6 for tilting the tribe 1 is also operated by remote control or the like. By the operation of the electric motor 6, the driving force is transmitted to the actuator 5 via the gear box 4. By the way, since the actuator 5 is composed of an existing linear motion mechanism that converts a ball-screw-nut type rotary motion into a linear motion, the rotary motion of the electric motor 6 is converted into the linear motion of the actuator 5. , The rotary support frame 2 connected to one end of the actuator 5 is rotated about the point O _23, which is the attachment point to the frame 3. That is, as shown in FIG. 1, the trolley support frame 2 and the trolley 1 supported by the trolley support frame 2 are tilted (tilted). As a result, the casting metal flows out of the pouring port 11 provided in the upper portion of the trowel 1 and is poured into the pouring port 91 provided in the mold 9.

In this way, when a predetermined amount of casting metal is poured from the pouring port 11 to the predetermined pouring port 91,
The electric motor 6 is rotationally driven in the opposite direction by remote control or the like to restore the tilt of the tribe 1 to the original state. This completes the pouring work. In such a state, the self-propelled motor 7 is further driven by remote control or the like in order to pour the molten metal into the next mold 9 ′. As a result, the tribe 1 is moved to the position where the next mold 9'is placed. At this position, the electric motor 6 is driven and the actuator 5 is operated by remote control as in the previous case. by this,
The ladle support frame 2 and the ladle 1 rotate about the O ₂₃ point, and the ladle 1 is tilted. As a result, the casting metal stored in the trowel 1 is poured into the injection port 91 'of the mold 9'through the pouring port 11 as in the previous case. By repeating such operations in sequence, the molten metal is sequentially poured into a predetermined number of molds.

In such a pouring operation, the pouring device of the present invention, in particular, the pouring port 11 of the ladle 1, the ladle support frame 2, the frame 3 and the like are shown in FIG. 2 and FIG. It is as shown in 3. That is, at one end O _{23 of the} frame 3 formed in the inverted L shape, the tribe support frame 2 is attached.
Is rotatably attached, and the tip of the pouring port 11 provided in the upper portion of the trowel 1 is formed so as to substantially coincide with this O ₂₃ point. The tribe support frame 2 includes a T-shaped support portion 21 and a bottom plate 22 provided below the support portion 21.
One end of the character-shaped support portion 21 is connected to the frame 3 at the O ₂₃ point, and the other end is connected to the rod 51 of the actuator 5 at the O ₂₁ point.

Therefore, by the operation of the electric motor 6,
When the actuator 5 is driven and the trolley support frame 2 is rotationally driven, the trolley 1 itself tilts, and as a result, as shown in FIG. 2, casting metal flows out from the pouring port 11,
It will be injected toward the injection port 91. By the way, in this case, the inclination angle of the trolley 1 changes depending on the remaining amount of the molten metal in the trolley 1. For example, when there is a large amount of casting hot water in the trolley 1, it is not necessary to tilt the trolley 1 too much. .

As described above, the inclination angle of the trowel 1 is set according to the remaining amount of the casting molten metal in the ladle 1, but in the present invention, the position of the tip of the pouring port 11 is set to the rivet 1. 1 and the center of rotation O ₂₃ of the tribe support frame 2 are set to substantially coincide with each other.
The position of the pouring spout 11 remains almost unchanged regardless of the inclination angle. As a result, no matter what state the pouring work is performed, there is almost no difference in the positional relationship between the pouring port 11 and the injection port 91. Therefore, as shown in FIG. 1, when the pouring work is sequentially performed for each of the molds 9, 9 ′, 9 ″, in the pouring work for the injection ports 91, 91 ′, 91 ″, a so-called target deviation ( There will be no problem such as failure of the target), and there will be no problem such as damage to the sand mold.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT An embodiment of the present invention will be described with reference to FIGS. As shown in FIG. 1, the structure of the present embodiment is such that a casting ladle 1 for storing casting metal and a supporting ladle 1 are provided.
Also, a tribe support frame 2 for tilting the tribe 1, a frame 3 having an inverted L-shape for rotatably supporting the tribe support frame 2, an actuator 5 for tilting the tribe support frame 2 and the tribe 1. And an electric motor 6 for operating the actuator 5 via the gear box 4.
And the electric motor 6, the actuator 5, the frame 3, the trolley support frame 2, the trolley 1, and the like, and
Basically, it consists of a carriage 71 which is self-propelled on the rail 8 by a self-propelled motor 7.

In such a basic structure, the above-mentioned tribe 1 is basically based on a ladle for storing casting metal, and a bird's beak-shaped pouring port 11 is provided in the upper part thereof. It is composed of Tribe 1 like this
The tribe support frame 2 that supports the T-shaped support portion 21 (T-shaped portion) and a bottom plate 22 that is provided below the T-shaped portion 21 and mainly supports the tribe 1. It is basically composed of Then, one end of the T-shaped portion 21 having such a configuration, as shown in FIGS. 2 and 3, is rotatably connected to the frame 3 by O ₂₃ points, and the O ₂₃ points as a fulcrum the The tribe support frame 2 is rotatably attached. The other end of the T-shaped portion 21 is connected to the tip of the rod 51 of the actuator 5 at a point O ₂₁ . Therefore, the actuator 5
There activated, when the rod 51 drives the O ₂₁ points the T-shaped portion 21, the ladle support frame 2 is adapted to rotary motion by the connecting points O ₂₃ of the frame 3 as a fulcrum, the The trolley 1 is inclined with the rotational movement of the trolley support frame 2.

In addition, in such a mounting structure, as shown in FIG.
Further, as shown in FIG. 3, the tip of the pouring port 11 of the ladle 1 is formed so as to substantially coincide with the O ₂₃ point which is the center of rotation of the ladle support frame 2. Further, the frame 3 to which the tribe support frame 2 having the above-mentioned structure is connected via the rotation center O ₂₃ has an inverted L-shape, and the lower end thereof is on the carriage 71 by welding means or the like. It is composed of a fixed structure. Then, the position of the point O _23, which is the connection point of the frame 3 with the tribe support frame 2, that is, the tip of the pouring port 11 of the tribe 1 is projected onto the work line where the mold 9 or the like is installed. It is formed in.

Next, the actuator 5 for tilting the tribe support frame 2 is formed by an existing linear motion mechanism that converts a rotary motion of a ball, a screw, a nut, etc. into a linear motion. As shown in FIG. 4, the linear motion mechanism has the lower part set on the carriage 71, and
The upper portion is configured to be rotatably connected to the rotary shaft 25 of the tribe support frame 2 via a rod 51. In this embodiment, such actuators 5 are provided on both the left and right sides of the tribe support frame 2 as shown in FIG.
The inclination of the tribe 1 is such that no imbalance occurs on both its left and right sides. The actuators 5 provided on both sides are connected to each other by the gear box 4, the coupling 55, the drive shaft 56, etc., and are connected to the electric motor 6 via the coupling 55. Has become. With these configurations, the driving force from the electric motor 6 is evenly distributed to the left and right actuators 5 and the both actuators 5 operate in synchronization.

The trolley 1, the trolley support frame 2, the frame 3, the actuator 5, the electric motor 6 and the like having these configurations are mounted on a carriage 71. As shown in FIG. 1, the carriage 71 has a self-propelled motor 7
Is installed, and by the operation of this self-propelled motor 7,
The carriage 71 can be freely moved on the rail 8. The control of the self-propelled motor 7 and the control of the electric motor 6 are performed by remote control (remote operation) or the like from a control room (not shown) provided at a distant position.

The operation mode and the like of this embodiment having these configurations will be described. First, when pouring the molten metal into the pouring port 91 of the mold 9, it is necessary to move the pouring port 11 of the trowel 1 to a predetermined pouring port 91 as shown in FIG. For that purpose, first, the self-propelled motor 7 is operated by remote control or the like to move the carriage 71 on the rail 8 to move it to a predetermined position. In such a state, next, the electric motor 6 for tilting the tribe 1 is also operated by remote control or the like. By the operation of the electric motor 6, the driving force is transmitted to the actuator 5 via the gear box 4. By the way, the actuator 5 is composed of a linear motion mechanism that converts a ball-screw-nut type rotary motion into a linear motion.
Is converted into a linear motion of the actuator 5, and the tribe support frame 2 connected to one end of the actuator 5 is rotated about an O ₂₃ point that is an attachment point to the frame 3. That is, as shown in FIG. 1 and FIG. 2, the trolley support frame 2 and the trolley 1 supported by the trolley support frame 2 are tilted (tilted). As a result, the pouring port 1 provided in the upper part of the trolley 1
The casting water flows out of the casting mold 1, and the injection port 9 provided in the mold 9
Injected into 1.

In this way, when a predetermined amount of casting metal is poured from the pouring port 91, it is again operated by remote control or the like.
The electric motor 6 is rotationally driven in the opposite direction to restore the inclination of the tribe 1 to the original state. This completes the pouring work. In such a state, the self-propelled motor 7 is further driven by remote control or the like in order to pour the molten metal into the next mold 9 ′.
As a result, the tribe 1 is moved to the position where the next mold 9'is placed. At this position, the electric motor 6 is driven and the actuator 5 is operated by remote control as in the previous case. As a result, the trolley support frame 2 and the trolley 1 rotate about the O ₂₃ point, and the trolley 1
Can be tilted. As a result, the casting metal stored in the trowel 1 is poured into the casting port 91 'of the mold 9'through the pouring port 11 as in the previous case. By repeating such an operation in sequence, the molten metal is sequentially poured into a predetermined number of molds.

Incidentally, in such a pouring operation, the positional relationship among the present pouring device, particularly the pouring port 11, the trolley support frame 2, the frame 3, etc., is as shown in FIGS. That is, the trolley support frame 2 is rotatably attached to one end O _{23 of the} frame 3 formed in the inverted L shape, and the tip of the pouring spout 11 provided in the upper portion of the trolley 1 has the O _23. It is formed so as to almost coincide with the points. In addition, the tribe support frame 2 includes a support portion (T-shaped portion).
21 and a bottom plate 2 provided below the T-shaped portion 21
2, and one end of the T-shaped portion 21 is
In addition to being connected to the frame 3 at the O ₂₃ point,
The other end is connected to the rod 51 of the actuator 5 and the O
It is connected at ₂₁ points.

Therefore, when the actuator 5 is driven by the operation of the electric motor 6 and the trolley support frame 2 is rotationally driven, the trolley 1 itself tilts, and as a result, the casting metal flows out from the pouring port 11. Then, the liquid is injected toward the injection port 91. By the way, in this case, depending on the remaining amount of the casting hot water in the trolley 1,
The tilt angle of varies. For example, when there is a large amount of casting hot water in the trolley 1, it is not necessary to tilt the trolley 1 too much. .

As described above, the inclination angle of the trowel 1 is set according to the remaining amount of the casting metal in the ladle 1, but in the present embodiment, the position of the tip of the pouring port 11 is set. Is set so as to substantially coincide with the rotation center O _{23 of} the trolley 1, the position of the pouring port 11 hardly changes regardless of the inclination angle of the trolley 1. As a result, no matter what state the pouring work is performed, there is almost no difference in the positional relationship between the pouring port 11 and the pouring port 91. Therefore, in FIG. When performing sequentially with the molds 9, 9 ', 9'', etc., the injection port 9
In the pouring work for 1, 91 ', 91'', etc., so-called target deviation (out-of-target) and the like are eliminated, and the problem of damaging the sand mold and the like is also eliminated.

[0020]

According to the present invention, with respect to a pouring device for casting molten metal used in the manufacturing process of castings for cast iron, a ladle for accumulating the molten molten metal, a ladle supporting frame for supporting the ladle, and the ladle supporting frame. A frame that rotatably supports the actuator, an actuator that is connected to a part of the tribe support frame and tilts the tribe support frame and the tribe, an electric motor that operates the actuator, and the electric motor, the actuator, the frame, and Since the configuration is made up of a trolley support frame, a trolley that is supported by the trolley support frame, and a trolley that is self-propelled on a rail by a self-propelled motor, the trolley and the tribe The actuator that tilts the support frame can be formed by a linear movement mechanism having a simple structure and a lightweight structure. , It has become possible to reduce the weight of the entire apparatus. In addition, since the actuator is formed by the existing linear motion mechanism, the link mechanism of the operating part is simplified, and maintenance including maintenance and inspection is facilitated. Further, along with downsizing of the electric motor, it has become possible to reduce the running cost.

[Brief description of drawings]

FIG. 1 is a perspective view showing an overall configuration of the present invention.

FIG. 2 is a skeleton diagram showing an operation mode of the present invention.

FIG. 3 is a skeleton structure diagram showing a link structure of the present invention.

FIG. 4 is a skeleton structure diagram showing a configuration of an actuator, an electric motor and the like which are main parts of the present invention.

FIG. 5 is a perspective view showing an overall configuration of a conventional example.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Tribe 11 Pouring spout 2 Tribe support frame 21 Support part (T-shaped part) 22 Bottom plate 25 Rotating shaft 3 Frame 4 Gear box 5 Actuator 51 Rod 55 Coupling 56 Drive shaft 6 Electric motor 7 Self-propelled motor 71 Cart 8 Rail 9 Mold 9'Mold 9 '' Mold 91 Inlet 91 'Inlet 91' 'Inlet

Claims (1)

[Claims] Claim: What is claimed is: 1. A ladle for storing casting metal, a ladle support frame for supporting the ladle, a frame for rotatably supporting the ladle support frame, and a portion of the ladle support frame for connecting the ladle support. An actuator that tilts the frame and the tribe, an electric motor that operates the actuator, an electric motor, an actuator, a frame, a tribe support frame, and a tribe supported by the tribe support frame are mounted, and A casting pouring device, characterized in that it comprises a trolley that runs on a rail by a traveling motor.