JP5033395B2 - Metal melt supply equipment - Google Patents

Description

  The present invention relates to a technique related to a molten metal supply device used in a cold chamber type die casting machine.

  In a molten metal supply apparatus that pumps a predetermined amount of molten metal from a melting furnace with a ladle, transports the ladle to the upper part of the hot water inlet of the injection sleeve, and pours the molten metal in the ladle into the injection sleeve from the hot water inlet. In many cases, the ladle is transported by a ladle transporting link mechanism, and the ladle is rotated (tilted) by a rotation transmission mechanism for ladle rotation.

  Japanese Patent Application Laid-Open No. 09-108815 (Patent Document 1) discloses a molten metal supply device in a die-casting machine having the above-described configuration. Rotational transmission for ladle rotation consisting of a parallel link mechanism (parallelogram link mechanism) by one link (link holding the ladle rotatably at its tip) and three links other than the ladle transport link mechanism The mechanism is configured so that when the ladle is transported by the ladle transporting link mechanism, the posture of the ladle is kept horizontal by the parallel link mechanism and the ladle rotation motor.

  By the way, in the technique disclosed in Patent Document 1, a ladle rotation motor is mounted on a link of a ladle transporting link mechanism that rotatably holds a ladle at the tip thereof. The ladle transport link mechanism supports a heavy member such as a gear train and a reduction gear train, and the ladle transport link mechanism increases in weight, and the ladle transport motor also requires a large motor with high power. There's a problem. Further, since the parallel link mechanism as the rotation transmission mechanism for rotating the ladle is exposed outside the link mechanism for transporting the ladle, there is room for improvement in terms of appearance.

  Accordingly, the inventors of the present application mount a ladle rotation motor on a fixed support frame, and use a ladle rotation rotation transmission mechanism driven by the ladle rotation motor for a ladle conveyance mechanism including a five-bar link mechanism. Of the five links of the link mechanism, one end of the link mechanism is rotatably connected to the other end of the first link, and the other end of the first link is rotatably connected to the other of the first link. A rotation transmission mechanism for rotation of the ladle is provided in the second link that rotatably holds the spindle having the base end portion of the ladle fixed to the end side, and the rotation transmission mechanism for rotation of the ladle is provided as the first link. It consists of a rotation transmission system with a sprocket (chain wheel) and a chain located inside, and a rotation transmission system with a sprocket (chain wheel) and a chain located in the second link. The supply device molten metal was manufactured prior to recall the present invention. In this molten metal supply device, the rotation transmission system (rotation transmission mechanism for ladle rotation) of two sprockets / chains can have a posture maintaining function equivalent to that of a parallel link mechanism (parallel quadrilateral link mechanism). Therefore, the ladle can be maintained in a predetermined posture (predetermined transfer posture) regardless of the operation posture of the ladle transport link mechanism during the ladle transport. Moreover, since the ladle rotation motor is mounted on the support frame, there is no need for the ladle conveyance link mechanism to support heavy components such as the ladle rotation motor and the reduction gear train, and the ladle conveyance link mechanism is relatively Further, by providing the rotation transmission mechanism for rotating the ladle in a predetermined link of the ladle transporting link mechanism, the appearance can be improved.

Japanese Patent Laid-Open No. 2002-254156 (Patent Document 2) discloses a rotation transmission mechanism for rotation of a ladle that is mounted on a fixed support frame and is driven by the motor for rotation of the ladle. Of the five links of the ladle transport link mechanism composed of a five-bar linkage mechanism, a first link whose one end is rotatably held around the output shaft for ladle rotation (corresponding to the fourth arm in Patent Document 2) And a second link in which one end thereof is rotatably connected to the other end of the first link, and a pivot having a base end of a ladle fixed to the other end is rotatably held (in Patent Document 2, a first link is provided). (Equivalent to 5 arms) is provided with a rotation transmission mechanism for ladle rotation, and this rotation transmission mechanism for rotation of the ladle is rotated by a pulley (toothed pulley) located in the first link and a toothed belt. And it reaches system was constructed by the rotation transmission system according to the chain sprocket (the chain wheel) located in the second link, feeder of molten metal is disclosed. In the molten metal supply apparatus disclosed in Patent Document 2, a parallel link mechanism (rotary transmission mechanism for ladle rotation) is also included in the rotation transmission system of the toothed pulley / toothed belt and the rotation transmission system of the sprocket / chain (rotation transmission mechanism for ladle rotation). A posture maintaining function equivalent to that of the parallelogram link mechanism) can be provided. Further, there is no need for the ladle transport link mechanism to support a heavy member such as a ladle rotation motor or a reduction gear train, and the ladle transport link mechanism can be made relatively light, and a rotation transmission mechanism for ladle rotation. Is provided in a predetermined link of the ladle transport link mechanism, so that the appearance can be improved.
JP 09-108815 A JP 2002-254156 A

  By the way, the second link that pivotally supports the ladle at the end thereof is heated by heat conduction from the ladle that pumps up the molten metal or heat radiation from the molten metal in the melting furnace, and 200 ° C. in the portion near the ladle of the second link High temperature around. Therefore, a toothed pulley / toothed belt rotation transmission system inferior in heat resistance cannot be adopted as the rotation transmission system disposed in the second link. If anything, the rotation transmission system of the toothed pulley / toothed belt uses a toothed belt (timing belt) in which rubber is included in a part of its constituent material, and the rubber deteriorates and hardens due to heat. This is because the usable temperature is about 100 ° C. at most. Therefore, in the technique disclosed in Patent Document 2, a toothed pulley / toothed belt rotation transmission system is disposed in the first link that is not so hot away from the ladle.

  Therefore, in the molten metal supply device (hot water heater) manufactured before the present inventors conceived the present invention by the inventors of the present application and the hot water supply device disclosed in Patent Document 2, the rotation transmission of the sprocket / chain is transmitted in the second link. A system is arranged. As described above, the second link that pivotally supports the ladle at the end thereof is heated by heat conduction from the ladle that pumps up the molten metal or heat radiation from the molten metal in the melting furnace, and the sprocket / chain in the second link. When the rotation transmission system is installed, the chain in the second link is at a high temperature of about 200 ° C. near the ladle, but the chain has much better heat resistance than the timing belt and is around 200 ° C. Can be used even at high temperatures. By the way, both the chain and the link (second link) are made of steel and both have the same linear expansion coefficient. However, in the case of a chain connected by several tens of links (several tens of rings), the apparent linear expansion coefficient is It is several times larger than that. Therefore, when the chain is adjusted to an appropriate tension at room temperature, the chain extends at a high temperature. On the other hand, if the chain is adjusted to an appropriate tension in a high temperature state, the chain contracts and breaks the mechanism when the molten metal supply device (water heater) stops operating and the chain drops to room temperature. Therefore, the chain must be adjusted to an appropriate tension at room temperature. In this case, the chain is stretched due to a high temperature when the apparatus is in operation, and looseness occurs. In other words, in the case of the ladle, there is a phenomenon that the ladle rattles and it becomes difficult to perform precise rotation attitude control (tilt angle control) of the ladle, that is, precise control of the pumping amount by the ladle. There is. Furthermore, since the chain is heated to a high temperature, a high-temperature heat-resistant lubricant is necessary, the number of times of application thereof is large, and there is a problem that maintenance is complicated.

  The rotation transmission system of the toothed pulley / toothed belt can be reduced in weight as is well known, and the toothed belt is very little stretched. Rotational transmission accuracy is high because there is no slippage and slippage unlike the belt transmission with no rotation. Further, since the rotation transmission system of the toothed pulley / toothed belt is generally provided with a belt tension adjusting member for adjusting the belt tension by eliminating the looseness of the belt, there is almost no backlash. Even if a rotation transmission system of a toothed pulley / toothed belt is used as a part of the rotation transmission mechanism for rotating the ladle, there is no rattling of the ladle caused by the rotation transmission system of the toothed pulley / toothed belt. If a rotation transmission system of a toothed pulley / toothed belt is used as a part of a rotation transmission mechanism for ladle rotation, the rotation transmission system of the toothed pulley / toothed belt has no restriction / restriction of the rotation angle. Can be. However, if a toothed pulley / toothed belt rotation transmission system is used as a part of the rotation transmission mechanism for ladle rotation, the linear expansion coefficient of the toothed belt is smaller than that of steel, so a little tension is applied at room temperature. It is necessary to loosen, and in this way, when the device is in operation, the link or toothed pulley containing the toothed pulley / toothed belt rotation transmission system expands, so that the toothed belt has the proper tension. It becomes a state. Therefore, a rotation transmission system of a toothed pulley / toothed belt, which is part of a rotation transmission mechanism for ladle rotation, is arranged in the first link whose one end is rotatably held around the output shaft for ladle rotation. There is no practical hindrance to installation.

  The present invention has been made in view of the above points, and an object of the present invention is to mount a ladle rotation motor on the support frame side and to provide a rotation transmission mechanism for rotation of the ladle within a predetermined link of the link mechanism for ladle conveyance. Of the rotation transmission mechanism for rotating the ladle, which is disposed in the second link in which the ladle is pivotally supported at the end of the link of the link mechanism for the ladle conveyance. By making the rotation transmission system excellent in heat resistance and rotation transmission accuracy, it is possible to perform precise rotation posture control (tilt angle control) of the ladle.

In order to achieve the above-mentioned object, the present invention pumps up a predetermined amount of molten metal from a melting furnace with a ladle, conveys the ladle to the upper part of the hot water inlet of the injection sleeve, and passes the molten metal in the ladle from the hot water inlet. in the supply device of the molten metal which is adapted poured into the injection sleeve, the plurality of links constituting the ladle transport link mechanism for transporting the ladle, can rotate one end around the ladle rotating output shaft A first link held on the other end of the first link rotatably connected to the other end of the first link, and a second link rotatably holding a support shaft having the base end of the ladle secured to the other end. In the first link and the second link, the ladle is driven via a ladle rotation output shaft by a ladle rotation motor mounted on a support frame. Rotation transmitting mechanism for ladle rotation for rotating is provided the rotation transmitting mechanism consists toothed belt passed over between the two toothed pulleys and the two toothed pulleys, in said first link a rotation transmission system of housed toothed pulley / toothed belt, Ri Do two rotating bodies and the parallel link mechanism having a bar-shaped link pair respectively mounted to both ends of the two to the rotating body, the first It is constituted by a parallel link rotation transmission system housed in two links, and at least one end portion of the bar-like link constituting the parallel link mechanism rotates integrally with each of the two rotating bodies. In order to avoid interference with the shaft member, it has a curved shape and is housed in the second link.

  In the present invention, a ladle rotation motor is mounted on the support frame side, and a rotation transmission mechanism for ladle rotation is disposed in a predetermined link of the ladle conveyance link mechanism. In a metal melt supply apparatus that can be reduced in weight and excellent in appearance, a rotation transmission mechanism for ladle rotation is provided with two toothed pulleys disposed in the first link of the links of the ladle conveyance link mechanism And a rotation transmission system of a toothed pulley / toothed belt comprising a toothed belt stretched between the two toothed pulleys and a second link of the links of the ladle conveying link mechanism. The two rotating bodies and both ends thereof are configured by a parallel link rotation transmission system including a parallel link mechanism having a pair of bar-like links attached to the two rotating bodies. The rotation transmission system by the parallel link rotation transmission system consisting of a parallel link mechanism with a pair of bar-shaped links is a rigid body made of steel, and has excellent heat resistance and durability, and its linear expansion coefficient is Since it is the same as the second link, the parallel link mechanism (parallel link rotation transmission system) and the second link are in the same expansion / contraction state both at room temperature and at a high temperature when the device is operating, and its operation function is stable. Thus, there is no risk of rattling of the ladle as in a rotation transmission system using a chain. Moreover, the toothed pulley / toothed belt rotation transmission system disposed in the first link is excellent in rotation transmission accuracy as described above. Therefore, the entire rotation transmission mechanism for rotating the ladle is excellent in rotation transmission accuracy. Therefore, a molten metal supply device capable of performing precise rotation attitude control (tilt angle control) of the ladle is provided. realizable.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 to 12 relate to a molten metal supply apparatus used in a cold chamber type die casting machine according to an embodiment of the present invention (hereinafter referred to as the present embodiment), and FIG. 1 illustrates a molten metal supply apparatus. FIG. 2 is a partially broken plan view, FIG. 2 is a front view of a molten metal supply device when the ladle is in the melting furnace, and FIG. 3 shows a rotation transmission mechanism for rotating the ladle when in the state of FIG. 4 is an explanatory view showing a state in which the ladle has been rotated (tilted) to draw the molten metal from the state of FIG. 3, and FIG. 5 is a view of the rotation of the ladle when the ladle is in the process of being conveyed. FIG. 6 is an explanatory view showing a rotation transmission mechanism for use, FIG. 6 is an explanatory view showing a state in which the ladle is rotated (tilted) from the state shown in FIG. Rotation for rotation of the ladle when it is above the injection sleeve Explanatory view showing a transmission mechanism, FIG. 8 is an explanatory view showing a state where the rotation (tilting) was for pouring the ladle from the state of FIG. 7 of the molten metal.

  1 to 8, 1 is a support frame fixedly installed at a site where a die casting machine is installed, 2 is a link mechanism for ladle conveyance comprising a five-bar linkage mechanism provided on the support frame 1, and 3 is a ladle conveyance A ladle 4 is transported between a melting furnace (not shown) and an injection sleeve (not shown) by the link mechanism 2 for ladle transport mounted on the support frame 1 to drive the link mechanism 2 for ladle transport. A motor 6 is a ladle rotating motor mounted on the support frame 1 to rotate (tilt) the ladle 3. The ladle conveying motor 4 and the ladle rotating motor 6 include a reduction mechanism (reduction gear). A geared motor with an integrated column is used, and a ladle transport motor 4 is connected to a ladle transport output shaft 5 (hereinafter simply referred to as an output shaft 5) via a reduction gear train. Is rolling, ladle rotating motor 6 ladle rotating output shaft 7 via a reduction gear train (hereinafter, simply referred to as the output shaft 7) is adapted to rotate the.

  The ladle transporting link mechanism 2 has a first link that is rotatably supported by the output shaft 7 on the side of the ladle rotation motor 6 via a rolling bearing so that one end of the link mechanism 2 is rotatable about the output shaft 7 as a rotation center. 8 and a first support shaft 10 key-coupled to a sleeve 9 rotatably held via a rolling bearing at the other end of the first link 8, one end of which is rotatably held via a rolling bearing. One end of the second link 11 and the output shaft 5 on the side of the ladle transport motor 4 are inserted and fixed, and the first link 11 is rotationally driven around the one end by the rotation of the ladle transport motor 4. A third link 12, one end of which is rotatably connected to an intermediate portion of the second link 11, a fourth link 13 whose other end of the third link 12 is rotatably connected to the intermediate portion, and one end thereof The part is coaxial with the output shaft 7 The other end portion of the fourth link 13 is rotatably connected to the support frame 1 via a rotation holding means as appropriate, and the other end portion of the fourth link 13 is rotatably connected. As will be described later, the base end portion of the ladle 3 is rotatably held at the other end portion of the second link 11.

  In the ladle transporting link mechanism 2 having the above-described structure, the third link 12 as the driving node is rotationally driven by the output shaft 5 via the speed reduction mechanism by the ladle transporting motor 4 so that the other four links. 8, 11, 13, and 14 perform a coordinated movement, whereby the base end portion (the rotation center of the ladle 3) of the ladle 3 is moved along a predetermined movement locus.

  In FIGS. 1 and 3 to 8, 15 is a rotation transmission system of a toothed pulley / toothed belt built in the first link 8, and 16 is a parallel link mechanism built in the second link 11. The rotation transmission system 15 of the toothed pulley / toothed belt and the parallel link rotation transmission system 16 constitute a rotation transmission mechanism for ladle rotation that rotates (tilts) the ladle 3. Yes. When the output shaft 7 is rotationally driven by the rotation of the ladle rotation motor 6, the rotation transmission mechanism (toothed pulley / toothed belt rotation transmission system 15 and parallel link rotation transmission system 16) is rotated by a mechanism described later. ) Is driven, and the ladle 3 rotates about its base end as the center of rotation, thereby allowing the ladle 3 to assume a desired rotational position (rotational posture).

  The toothed pulley / toothed belt rotation transmission system 15 is housed in one end portion of the first link 8 and is rotatably held at one end portion of the first link 8 via a rolling bearing. The first toothed pulley (timing pulley) 17 fixed to the output shaft 7 on the rotation motor 6 side and the other end of the first link 8 are accommodated in the other end of the first link 8 and are connected to the sleeve 9. By being key-coupled, the first support shaft 10 (the first support shaft 10 is rotatably held at one end of the second link 11 via a rolling bearing) via the sleeve 9 is fixed. The second toothed pulley (timing pulley) 18 and the toothed belt (timing belt) housed in the first link 8 and spanned between the first toothed pulley 17 and the second toothed pulley 18 It is composed of 19This toothed pulley / toothed belt rotation transmission system 15 is provided with a belt tension adjusting mechanism 20 provided in the first link 8, and a toothed belt 19 of a tension adjusting pulley of the belt tension adjusting mechanism 20. The tension applied to the toothed belt 19 is adjusted by appropriately adjusting the pressing force against the toothed belt 19. That is, as described above, the tension of the toothed belt 19 is slightly loosened at room temperature, and the first link 8 and the first and second toothed pulleys 17 and 18 are heated during operation of the apparatus. Thus, adjustment is performed so that the toothed belt 19 is in an appropriate tension state by being expanded.

  The parallel link rotation transmission system 16 is housed in one end portion of the second link 11 and is fixed to the first support shaft 10 so as to be rotatably held at one end portion of the second link 11. In addition, the first rotating body 21 that rotates integrally with the second toothed pulley 18, and the first rotating body 21 that is housed in the second link 11 and one end portion of which is rotatably connected to the first rotating body 21. A pair of parallel bars (a pair of parallel links) 22A and 22B and the other end of the second link 11 are housed in the other end of the second link 11 and rotated via a rolling bearing. By being fixed to the second support shaft 23 held so as to be able to be held, it is rotatably held at the other end of the second link 11, and the other end of the pair of second bar links 22A, 22B is The second rotating body 24 is rotatably connected to each other. To have.

  Further, the base end portion of the ladle 3 is fixed to the second support shaft 23 rotatably held at the other end portion of the second link 11, and the ladle 3 has the base end portion as a center of rotation. The two support shafts 23 and the second rotating body 24 are integrally rotated.

  In the present embodiment, the pair of bar-shaped links 22A and 22B is a rigid bar manufactured by cutting a metal plate. The pair of bar-shaped links 22A and 22B are attached to the first rotating body 21 and the second rotating body 24 with a phase shifted by 90 °. The reason why the paired parallel bar links are arranged with a 90 ° phase shift is to prevent dead points in the operation process of the bar links 22A and 22B. Thus, the operation of the parallel link rotation transmission system (parallel link mechanism) 16 can be made to have a high operation reliability without stagnation.

  The rotation transmission mechanism (rotation transmission system 15 and toothed belt rotation transmission system 15 and parallel link rotation transmission system 16 of the toothed pulley / toothed belt) having the above-described structure is output by the rotation of the ladle rotation motor 6 being decelerated. 7 is rotated, and the first toothed pulley 17 fixed to the output shaft 7 is driven to rotate integrally with the output shaft 7, whereby the second toothed pulley 18 via the toothed belt 19, The first rotating shaft 10 rotates, whereby the first rotating body 21 rotates integrally with the first supporting shaft 10, so that the second rotating body 24 and the pair of bar-shaped links 22A and 22B are paired. As the second support shaft 23 rotates and the second support shaft 23 rotates, the ladle 3 rotates together with the second support shaft 23. Accordingly, by rotating the ladle rotating motor 6 in an appropriate direction by an appropriate amount of rotation, the ladle 3 can take the posture of drawing the molten metal in the melting furnace, or can take the posture of transfer during conveyance, or the injection sleeve. The pouring posture of the molten metal into the can be taken.

  Next, supplementation will be made about the holding posture of the ladle 3 by the rotation transmission mechanism for rotation of the ladle (the toothed pulley / toothed belt rotation transmission system 15 and the parallel link rotation transmission system 16) during the conveyance of the ladle 3. When the ladle 3 is transported, the first link 8 rotates (swings) about the output shaft 7 on the one side of the ladle rotation motor 6 as the rotation center, and the second link 11 is the other end of the first link 8. The first support shaft 10 provided on the side (which is also one end side of the second link 11) is rotated (oscillated) about the rotation center. At this time, if the rotation of the output shaft 7 is kept in the locked state, regardless of the rotation (swing) angle of the first link 8 and the second link 11, that is, the inclined posture of the first link 8 and the second link 11. Regardless of the case, the posture of the ladle 3 is maintained at the posture corresponding to the rotation stop position of the output shaft 7 at that time. In the state where the output shaft 7 is locked, the rotation transmission system 15 of the toothed pulley / toothed belt locks the first toothed pulley 17 on the driving side, and the first link 8 rotates ( When the inclination angle of the toothed belt 19 is changed without the belt rotation, the second toothed pulley 18 rotates with respect to the toothed belt 19. Since the parallel link rotation transmission system 16 is configured as a parallelogram link, the second toothed pulley 18 rotates by an angle corresponding to the rotation (swing) of the first link 8 and the second link 11. This is because the first rotating body 21 and the second rotating body 24 are rotated along with this to cancel the angular displacement, thereby keeping the posture of the ladle 3 constant. In the case of the present embodiment, when the ladle 3 is transported, the first link 8 rotates (swings) up to 150 ° about the output shaft 7 as a rotation center. Therefore, as described above, the first toothed pulley 17 rotates relative to the first link 8 by a maximum of 150 °.

  Subsequently, the rotation (tilting) of the ladle 3 will be supplemented. The ladle 3 is shown in FIG. 4 at the transfer position of FIGS. 2 and 3 when the molten metal in the melting furnace is drawn on the basis of the transfer posture (the postures of FIGS. 2, 3, 5, and 7). Thus, it is necessary to take a posture rotated (tilted) by a maximum of 60 ° to the right, and when pouring the molten metal into the injection sleeve, as shown in FIG. ° It is necessary to take a pouring position that rotates. In other words, the rotation (tilting) of the ladle 3 needs to rotate by 150 ° in total. Further, at the time of trial operation adjustment, the ladle 3 needs to be able to rotate (tilt) by 150 ° at any conveyance position.

  Therefore, the rotation transmission system 15 of the toothed pulley / toothed belt has a rotation angle of 150 ° necessary for maintaining the posture during the transport of the ladle 3 as described above and a rotation angle 150 necessary for the rotation (tilting) of the ladle 3. It is necessary to have a configuration corresponding to a rotation of 300 °, which is a total of °.

  Further, the second link 11 rotates (swings) up to 80 ° around the first support shaft 10 when the ladle 3 is transported. Therefore, the first rotating body 21 and the second rotating body 24 rotate up to 80 ° relative to the second link 11. Therefore, the parallel link rotation transmission system 16 is a total of the rotation angle 80 ° necessary for maintaining the posture during the transport of the ladle 3 and the necessary 150 ° necessary for the rotation (swing) of the ladle 3 as described above. It is necessary to make the configuration corresponding to the rotation of 230 °, and in the case of the present embodiment, it is configured to be able to cope with the rotation of 240 ° with a margin.

  In this embodiment, a toothed pulley / toothed belt rotation transmission system 15 and a parallel link rotation transmission system 16 are used for maintaining and rotating the ladle posture. The reason why this is done will be described below. In the rotation transmission system 15 of the toothed pulley / toothed belt, as is well known, since there is no restriction or limitation of the rotation angle, the rotation of 300 ° as described above can be further increased. It's easy to do. However, the rotation transmission system 15 of the toothed pulley / toothed belt has a limitation on the operating temperature. In the operating state of the apparatus, the part A (near the second support shaft 23) in FIG. 2 is about 260 ° C., the part B (intermediate part of the second link 11) in FIG. The temperature of part C (the connecting part of the second link 11 and the first link 8) may rise to about 60 ° C., and the part D (near the rotation center of the first link 8) in FIG. This has been confirmed by the inventors. Since the usable temperature of the toothed belt is 100 ° C. or less as described above, the toothed pulley / toothed belt rotation transmission system 15 cannot be disposed on the second link 11. The first link 8 can be disposed. Therefore, in the present embodiment, the toothed pulley / toothed belt rotation transmission system 15 is provided on the first link 8 for which the temperature rise is not so high, for reasons such as to easily cope with a large rotation angle of 300 °. It is what is arranged.

  On the other hand, the rotation transmission system 15 of the toothed pulley / toothed belt having inferior heat resistance cannot be arranged on the second link 11 in which the temperature rises significantly when the apparatus is in operation. Therefore, in the molten metal supply device (hot water supply device) manufactured before the present inventors conceived the present invention by the inventors of the present application and the hot water supply device disclosed in Patent Document 2, the second link also described above. As mentioned above, a sprocket / chain rotation transmission system is arranged. However, when a rotation transmission system using a chain is used, it is undeniable that the rotation transmission accuracy is lowered due to the rattling as described above. In this embodiment, the rotation of 240 ° as described above is enabled by the parallel link rotation transmission system 16 using the bar-shaped links 22A and 22B that are not stretched or bent. In order to secure the required rotation angle and achieve a compact mechanism by using such a rigid bar-shaped link, in this embodiment, a parallel link is formed by a rigid rotating body and a rigid bar-shaped link. The mechanism is built. Furthermore, by devising the shape of the end of the bar-shaped link, the required rotation angle can be ensured while achieving compactness.

  Subsequently, the end shape of the pair of bar-shaped links 22A and 22B and the mounting structure thereof will be described in detail. As shown in FIG. 9, one end of the bar-shaped link 22A and the bar-shaped link 22B (the end on the first rotating body 21 side) is a position inside the end surface of the first support shaft 10 (the first end than the end surface). 1), the end of each of the bar-shaped link 22A and the bar-shaped link 22B is simply formed in a linear shape. Then, it interferes with the first support shaft 10. Therefore, one end of the bar-shaped link 22A and the bar-shaped link 22B is formed in a curved shape with a radius of curvature larger than the outer diameter of the first support shaft 10 in order to avoid interference with the first support shaft 10. is there. Further, the other end portions of the bar-shaped link 22A and the bar-shaped link 22B (the end portion on the second rotating body 24 side) are positions inside the end surfaces of the second support shafts 23 as shown in FIG. It is attached to the second rotating body 24 so as to be rotatable by a pin and a bearing. For this reason, if the other end portions of the bar-shaped link 22A and the bar-shaped link 22B are simply linear, they interfere with the second support shaft 23. To do. Therefore, the other ends of the bar-shaped link 22A and the bar-shaped link 22B are respectively formed in a curved shape with a radius of curvature larger than the outer diameter of the second support shaft 23 in order to avoid interference with the second support shaft 23. It is. 9 and 10 are perspective views showing only the end shapes of the pair of bar-like links 22A and 22B and their mounting structures, with some members removed for the sake of illustration.

  A parallel link mechanism (parallel link rotation transmission system 16) employing a bar-shaped link made of a rigid body that is not bent and deformed by adopting the end shape of the bar-shaped links 22A and 22B and its mounting structure as described above. In addition, it is possible to realize the operating range and functions required for this type of molten metal supply device.

  FIG. 11 is a cross-sectional view of the main part in a state where both the links 8 and 11 are separated, showing a connection structure between the other end of the first link 8 and one end of the second link 11. FIG. 12 is a cross-sectional view of the principal part in a direction orthogonal to FIG. 11, showing a coupling structure between the sleeve 9 on the other end side of the first link 8 and the second toothed pulley 18. As shown in FIGS. 11 and 12, a key groove 9 a is formed in the inner peripheral surface of the sleeve 9 that is rotatably held at the other end of the first link 8 via a rolling bearing. Further, a key that is partly fitted on the outer peripheral surface of the first support shaft 10 on the outer peripheral surface of the first support shaft 10 that is rotatably held on one end side of the second link 11 via a rolling bearing. 10a is provided. Then, by inserting the key 10a of the first support shaft 10 into the key groove 9a of the sleeve 9 and key-connecting the sleeve 9 and the first support shaft 10, the pulley 18 with the second tooth, the sleeve 9 and the first support shaft 10 are connected. The shaft 10 is coupled so as to rotate integrally, and the second link 11 is connected to the first link 8 so as to be rotatable relative to the first support shaft 10 as a rotation center. Therefore, the first link 8 and the second link 11 can be easily separated simply by releasing the key coupling between the key groove 9a and the key 10a, and are highly convenient and easy to maintain at the time of repair. It is excellent.

  Further, a key groove 18 a is formed in the inner peripheral surface of the second toothed pulley 18, and a key 9 b in which a part thereof is fitted in the outer peripheral surface of the sleeve 9 is provided in the outer peripheral surface of the sleeve 9. ing. Then, by inserting the key 9b of the sleeve 9 into the key groove 18a of the second toothed pulley 18 and key-connecting the sleeve 9 and the second toothed pulley 18, the sleeve 9 and the second toothed pulley 18 are connected. They are connected so as to rotate together. Accordingly, the sleeve 9 is taken out only by releasing the key connection between the key 9b and the key groove 18a in a state where the first link 8 and the second link 11 are separated and the bearing of the sleeve 9 is removed. Then, the second toothed pulley 18 can be taken out. Also in this respect, it is highly convenient and easy to maintain at the time of repair.

  As described above, in this embodiment, the ladle rotation motor 6 is mounted on the support frame 1 side, and the rotation transmission mechanism for rotation of the ladle is arranged in the first and second links 8 and 11 of the link mechanism 2 for ladle conveyance. In the molten metal supply apparatus having a configuration in which the ladle transport link mechanism can be made relatively light in weight and excellent in appearance, a rotation transmission mechanism for ladle rotation is provided in the teeth disposed on the first link 8. The rotation transmission system 15 of the pulley with teeth / toothed belt and the parallel link rotation transmission system 16 disposed on the second link 11 are combined. Here, the rotation transmission system by the parallel link rotation transmission system 16 composed of a parallel link mechanism having a pair of bar-shaped links disposed in the second link 11 that becomes high temperature when the apparatus is in operation has its constituent elements. Since it is a rigid body made of steel and has excellent heat resistance and durability, and its linear expansion coefficient is the same as that of the second link 11, it is a parallel link rotation transmission system even at room temperature and at high temperatures during operation of the apparatus. 16 and the second link 11 are in the same expansion / contraction state, and their operation functions are stabilized, and there is no possibility of causing rattling in the ladle 3 as in a rotation transmission system using a chain. In addition, by providing a toothed pulley / toothed belt rotation transmission system 15 in the first link 8 that does not reach a high temperature even when the apparatus is in operation, there is no concern about heat resistance. The toothed pulley / toothed belt rotation transmission system 15 that is excellent in transmission accuracy and can be reduced in weight can be suitably arranged. Therefore, the entire rotation transmission mechanism for rotating the ladle is excellent in rotation transmission accuracy, and therefore, a molten metal supply device capable of performing precise rotation posture control (tilt angle control) of the ladle 3. Can be realized. Further, since the pair of bar-shaped links 22A and 22B are attached to the first rotating body 21 and the second rotation 24 with a phase shifted by 90 °, they are dead in the parallel link mechanism (parallel link rotation transmission system 16). No point is generated, and the operation of the parallel link rotation transmission system 16 can be performed without delay and with high operation reliability. Further, the end portions of the pair of bar-shaped links 22A and 22B are curved in order to avoid interference with the first support shaft 10 and the second support shaft 23, so that each bar-shaped link 22A and 22B can be displaced without any problem. Therefore, the operation range and functions required for this type of molten metal supply device can be reliably realized.

It is the principal part top view which fractured | ruptured partially the supply apparatus of the molten metal which concerns on one Embodiment of this invention. It is a principal part front view in case the ladle is in a melting furnace in the molten metal supply apparatus which concerns on one Embodiment of this invention. It is explanatory drawing which shows the rotation transmission mechanism for the ladle rotation in the state of FIG. FIG. 4 is an explanatory view showing a state in which a ladle is rotated (tilted) to draw a molten metal from the state of FIG. 3. It is explanatory drawing which shows the rotation transmission mechanism for the ladle rotation, etc. in the middle of the ladle being conveyed. FIG. 6 is an explanatory diagram showing a state in which the ladle is rotated (tilted) to a molten metal pouring posture from the state of FIG. It is explanatory drawing which shows the rotation transmission mechanism for a ladle rotation, etc. when a ladle is above an injection sleeve. It is explanatory drawing which shows the state which the ladle rotated (inclined) for pouring of the molten metal from the state of FIG. It is the principal part perspective view which omitted the one part member which shows the edge part shape of the one side of a pair of bar-shaped link, and its attachment structure in the molten metal supply apparatus which concerns on one Embodiment of this invention. . It is the principal part perspective view which omitted the one part member which shows the edge part shape of the other side of a pair of bar-shaped link, and its attachment structure in the molten metal supply apparatus which concerns on one Embodiment of this invention. . It is principal part sectional drawing of the state which cut | disconnected both links which shows the connection structure of the other end part of a 1st link, and the one end part of a 2nd link in the molten metal supply apparatus which concerns on one Embodiment of this invention. FIG. 11 is a cross-sectional view of a main part in a direction orthogonal to FIG. 11, showing a coupling structure between the sleeve on the other end side of the first link and the second toothed pulley in the molten metal supply device according to the embodiment of the present invention. is there.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Support frame 2 Link mechanism for ladle conveyance 3 Ladle 4 Ladle conveyance motor 5 Ladle conveyance output shaft (output shaft)
6 Ladle rotation motor 7 Ladle rotation output shaft (output shaft)
8 1st link 9 Sleeve 9a Keyway 9b Key 10 1st spindle 10a Key 11 2nd link 12 3rd link 13 4th link 14 5th link 15 Rotation transmission system of toothed pulley / toothed belt 16 Parallel link mechanism Parallel link rotation transmission system consisting of 17 pulley with first tooth (timing pulley)
18 Second toothed pulley (timing pulley)
18a Keyway 19 Toothed belt (timing belt)
20 Belt tension adjusting mechanism 21 First rotating body 22A, 22B Bar-shaped link 23 Second support shaft 24 Second rotating body

Claims (4)

A molten metal of a predetermined amount is melted from a melting furnace by a ladle, the ladle is transported to the upper part of the hot water inlet of the injection sleeve, and the molten metal in the ladle is poured into the injection sleeve from the hot water inlet. In the supply device ,
The plurality of links constituting the ladle transport link mechanism for transporting the ladle have a first link whose one end is rotatably held around the output shaft for ladle rotation, and one end thereof is the first link. A second link that is rotatably connected to the other end of the frame, and that rotatably supports a spindle having a base end portion of the ladle fixed to the other end. The second link is included in the first link and the second link. And a rotation transmission mechanism for rotating the ladle that is driven by the ladle rotation motor mounted on the support frame through the output shaft for rotation of the ladle and rotates the ladle .
The rotation transmission mechanism consists subjected passed toothed belt between the two toothed pulleys and the two toothed pulleys, rotation transmission toothed pulley / toothed belt housed in said first link and the system, the two rotating bodies and Ri Do a parallel link mechanism having a bar-shaped link pair respectively mounted on the ends of two rotating bodies, the parallel link rotation transmission system housed within the second link and Composed by
At least one end portion of the bar-shaped link constituting the parallel link mechanism has a curved shape in order to avoid interference with a shaft member that rotates integrally with each of the two rotating bodies, An apparatus for supplying molten metal, which is housed in a second link . In the molten metal supply device according to claim 1,
A pair of the bar-shaped links is attached to each of the rotating bodies described above with a 90 ° phase shift. A molten metal of a predetermined amount is melted from a melting furnace by a ladle, the ladle is transported to the upper part of the hot water inlet of the injection sleeve, and the molten metal in the ladle is poured into the injection sleeve from the hot water inlet. In the supply device ,
A ladle transport motor mounted on the support frame, a ladle transport output shaft that decelerates and outputs the rotation of the ladle transport motor, a ladle rotation motor mounted on the support frame, and the ladle rotation motor A ladle rotation output shaft that decelerates and outputs rotation, a first link whose one end is rotatably held around the ladle rotation output shaft, and is rotatable at the other end of the first link A first support shaft provided; a second link whose one end is rotatably held by the first support shaft; a third link whose one end is fixed to the output shaft for ladle conveyance; and A fourth link having one end portion rotatably connected to an intermediate portion of the second link, and the other end portion of the third link being rotatably connected to the intermediate portion, and one end portion thereof being the output for rotating the ladle Is held rotatably around the axis A fifth link having the other end rotatably connected to the other end of the fourth link, and a pulley with a first tooth housed in one end of the first link and fixed to the output shaft for ladle rotation A second toothed pulley rotatably accommodated in the other end of the first link and fixed to the first support shaft, and a first toothed pulley housed in the first link, A toothed belt stretched between the second toothed pulleys, a first rotating body housed in one end of the second link and fixed to the first support shaft, and the second link A second rotating body housed in the end portion and fixed to a second support shaft rotatably held at the other end portion of the second link; and at least one end portion of the second support shaft or the second link In order to avoid interference with the second spindle, the shape is curved, and both ends thereof are the first rotating body and 2 respectively mounted to the rotating body, and the pair bar-shaped link housed in the second link, and a ladle that its proximal end is fixed to the second support shaft, has,
By driving the five-bar linkage mechanism composed of the first, second, third, fourth, and fifth links by the rotation of the ladle transport motor, the ladle is transported,
Toothed pulley / toothed belt rotation transmission system comprising the first toothed pulley, the toothed belt, and the second toothed pulley, the first rotating body and the pair of bar links, and A parallel link rotation transmission system composed of a parallel link mechanism composed of a second rotating body is driven by rotation of the ladle rotation motor to rotate the ladle,
When the ladle rotation motor is stopped, the toothed pulley / toothed belt rotation transmission system and the parallel link rotation transmission system can take any action posture of the 5-joint link mechanism. An apparatus for supplying molten metal characterized by maintaining a predetermined position of a ladle. The apparatus for supplying molten metal according to claim 3,
The pair of bar-shaped links are attached to the first rotating body and the second rotating body with a 90 ° phase shift, and are provided with a molten metal supply device.

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