JP6673472B2 - Weight placing equipment and weight placing method in blanking molding line - Google Patents

Description

  The present disclosure relates to a weight placing facility and a weight placing method for placing a weight on a mold of a blanking molding line.

  In the blanking molding method in which casting is performed using a sand mold without a flask, a tapered jacket is placed over the outer periphery of the mold and a weight is placed on the mold in order to prevent the mold from floating due to the poured molten metal. A weight is placed. After the melt has solidified, the jacket and weight are removed from the mold and the cast product is removed.

  Patent Document 1 discloses a weight jacket transfer device in a blanking molding line. In the weight jacket transfer device described in Patent Document 1, the weight is removed from the mold on the cooling line, and the weight is placed on the mold on the pouring line. Then, the jacket is removed from the mold on the cooling line, and the jacket is put on the mold on the pouring line.

  The pouring line and the cooling line described in Patent Literature 1 are arranged in parallel, and the weight jacket transfer device is arranged across the pouring line and the cooling line. For this reason, the space required for transferring the weight and the jacket can be reduced.

  However, the descent speed of the weight from when the weight starts to descend until it is placed on the mold should be such that the mold does not collapse due to the impact when the weight is placed on the mold. Is set. Since this speed is low, the cycle time from when the weight starts to descend until it is placed on the mold becomes long.

JP 2013-018033

  In view of the above problems, an object of the present disclosure is to provide a weight placing facility and a weight placing method in a blanking molding line.

  In order to achieve the above object, one embodiment of the present disclosure is a weight placing equipment that places a weight on a mold on a blanking molding line, wherein the weight is lowered and the weight is placed on the mold. And a deceleration position determining device that determines a deceleration position of the weight in the descending direction of the weight in the weight lifting device, wherein the weight lifting device is mounted on the weight lifting device. The descending speed includes a first descending speed from the start of descending to reaching the deceleration position, and a second descending speed from being placed on the mold from the decelerated position, The second descending speed is lower than the first descending speed.

  The deceleration position determination device determines a deceleration position of the weight lifting device in the descending direction of the weight. The weight is lowered by the weight lifting device to be placed on the mold. At this time, the descending speed of the weight is divided into a section from the start of descending to reaching the deceleration position (first section) and a section from the deceleration position to being placed on the mold (second section). Are set differently. The descent speed of the weight in the second section (second descent speed) is set to such a speed that the mold does not collapse due to an impact when the weight is placed. That is, the descending speed (first descending speed) of the weight in the first section is set at a speed higher than the second descending speed.

  According to the present embodiment, by setting the section in which the weight is lowered at the first lowering speed, it is possible to shorten the time for lowering the weight at the second lowering speed. Therefore, according to the present embodiment, the cycle time from the start of the lowering of the weight to the mounting of the weight on the mold can be shortened.

  In one embodiment, the weight placing equipment may further include a jacket elevating device that is disposed upstream of the weight elevating device and covers a side surface of the mold with a jacket. The deceleration position determining device may be provided in the jacket elevating device. According to this aspect, the deceleration position determination device operates when the jacket lifting device provided upstream of the weight lifting device operates, and determines the deceleration position of the weight in the downward direction of the weight in the weight lifting device. can do.

  In one embodiment, the deceleration position determining device may include a light measuring unit that is provided in the weight lifting device and measures a distance to an upper surface of the mold by light. The light measuring means may be arranged such that light emitted from the light measuring means is perpendicular to the upper surface of the mold. In this case, the distance from the weight lifting device to the upper surface of the mold is measured by the optical measuring means provided in the weight lifting device. Then, the deceleration position is determined by the deceleration position determination device based on the measured distance. According to this aspect, the measurement of the distance to the upper surface of the mold and the determination of the deceleration position of the weight can be performed by one device called an optical measurement unit.

  In one embodiment, the deceleration position determination device includes a first detector that can move up and down relative to the jacket elevating device, and a first detector that moves up and down together with the jacket elevating device to detect the first detector. And a proximity switch. The first proximity switch may include a plurality of proximity switches corresponding to different mold heights.

  In one embodiment, the weight lifting device may include a deceleration position detection device that detects the deceleration position. The deceleration position detection device, a second detector that moves up and down with the lifting operation of the weight lifting device, and a second proximity switch that is attached to the weight lifting device and detects the second detection object, You may have. The second proximity switch may include a plurality of proximity switches corresponding to different mold heights. Since the proximity switch is easy to replace, it is possible to quickly respond to a failure such as breakage. Therefore, according to this embodiment, the weight placing equipment is excellent in maintainability.

  In one embodiment, the deceleration position determining device may further include a bar member extending in a height direction of the mold. The first detection body may be disposed at an upper end of the rod member, and a lower end of the rod member may be disposed so as to be in contact with a flange formed on the jacket. According to this embodiment, the deceleration position can be determined with a simple structure.

  In one embodiment, the first detection body may extend in a height direction of the mold, and may have a cylindrical shape whose lower end is open. If the shape of the first detection body is a cylindrical shape having an open upper end, molding sand enters the inside of the first detection body. In addition, if the shape of the first detection body is a column shape, the material cost of the first detection body becomes high. According to this aspect, the first detection body can be configured such that casting sand does not enter therein and material cost can be reduced.

  Another embodiment of the present disclosure is a method of placing a weight on a mold on the blanking molding line described above, wherein the jacket elevating device lowers the jacket to cover the side surface of the mold. A deceleration position determination step of determining the deceleration position of the weight lifting device in the descending direction of the weight by the deceleration position determination device, and the weight lifting device moving the weight to the deceleration position. A first weight lowering step of lowering at the first lowering speed, and the weight lowering device lowers the weight at the second lowering speed until the weight is placed on the mold from the deceleration position. A second double weight lowering step. In this weight mounting method, the deceleration position of the weight is determined by the first detection body and the first proximity switch, and the descent speed of the weight is reduced at the deceleration position, and the weight is mounted on the mold. Is done. Therefore, according to the weight placing method, the weight can be placed on a mold having an arbitrary height. In addition, in this weight mounting method, each step may be performed sequentially, or two or more steps may be performed simultaneously.

  Yet another form of the present disclosure is a method of placing a weight on a mold on the above-described molding frame forming line, wherein the light measuring means measures a distance from the light measuring means to the upper surface of the mold. Measuring step, based on the distance measured in the measuring step, a deceleration position determining step of determining a deceleration position of the weight in the descending direction of the weight in the weight elevating device, the deceleration by the weight elevating device A first weight lowering step of lowering the weight at the first lowering speed to a position, and the weight lifting device, the weight is placed on the mold from the deceleration position until the weight is placed on the mold. A second double weight lowering step of lowering at a second lowering speed. In this weight placing method, the deceleration position of the weight is determined based on the distance measured by the optical measurement unit, and the descent speed of the weight is reduced at the deceleration position, and the weight is placed on the mold. You. Therefore, according to the weight placing method, the weight can be placed on a mold having an arbitrary height. In addition, in this weight mounting method, each step may be performed sequentially, or two or more steps may be performed simultaneously.

  According to various aspects and embodiments of the present disclosure, when the weight is lowered by the weight lifting device, a first section that descends at the first descending speed and a second section that descends at the second descending speed are set. Therefore, the cycle time from the start of the lowering of the weight to the mounting of the weight on the mold can be shortened as compared with the case where the entire section is lowered at the second lowering speed.

It is a schematic diagram which shows the blank molding line in 1st embodiment. It is a top view of the weight placing equipment in a first embodiment. It is a mimetic diagram showing the structure of the weight placing equipment in a first embodiment. It is a front view of the weight placing equipment in the pouring line of the first embodiment. FIG. 2 is a schematic diagram illustrating a deceleration position determination device according to the first embodiment. It is a schematic diagram which shows the jacket lifting / lowering device when the jacket lifting / lowering claw reaches the descent limit position in the first embodiment. It is a schematic diagram showing a deceleration position detection device in the first embodiment. It is an enlarged view of a deceleration position determining device in a first embodiment. FIG. 4 is a schematic diagram illustrating a positional relationship between the jacket elevating device and the jacket when a jacket elevating claw of the jacket elevating device reaches a descent limit position in the first embodiment. 9A is a schematic diagram when the height of the mold is H, FIG. 9B is a schematic diagram when the height of the mold is N, and FIG. FIG. 9D is a schematic diagram in the case of L, and FIG. 9D is a schematic diagram in the case where there is no template. It is a mimetic diagram showing a deceleration position of a weight lifting device in a first embodiment. It is a mimetic diagram showing a weight lifting device in a second embodiment.

  An example of an embodiment of a weight placing facility will be described with reference to the drawings. In the following description, up, down, left and right directions refer to directions in the drawings unless otherwise specified. Note that the present invention is not limited to the configuration of the present embodiment, and can be appropriately changed as needed. In addition, the mold in each embodiment refers to a mold made of molding sand and combining an upper frame and a lower frame unless otherwise specified.

(First embodiment)
FIG. 1 shows the overall configuration of a blanking molding line 1 according to the first embodiment. As shown in FIG. 1, a pouring line 2 and a cooling line 3 are arranged in parallel along the X-axis direction in the figure, and platen carrier transfer equipment (a pusher device, a cushion device, and a traverser) 4 is provided at both ends thereof. Be placed. As a result, the trolley 9 carrying the mold 8 can be circulated. The blanking molding line 1 is configured by a conveyor that feeds the platen carrier 9 at regular intervals. The blanking molding machine 10 is arranged so that the mold 8 molded by the blanking molding machine 10 can be carried into the pouring line 2 from the carry-in position 11. The weight placing equipment 7 including the jacket elevating device 5 and the weight elevating device 6 is arranged so as to straddle the pouring line 2 and the cooling line 3. The arrows shown in FIG. 1 indicate the traveling directions of the base plate carrier 9 and the mold 8 placed on the surface plate carrier 9.

  FIG. 2 shows a plan view of the weight placing equipment 7 in the first embodiment. An equipment frame 20 of the weight placing equipment 7 is arranged so as to straddle the pouring line 2 and the cooling line 3. In the equipment frame 20, a cylinder 21 and a connection frame 22 are arranged. The connection frame 22 fixes the jacket lifting device 5 and the weight lifting device 6 so as to be integrated. The jacket lifting device 5 and the weight lifting device 6 fixed by the connecting frame 22 move along the equipment frame 20 by the operation of the cylinder 21 (Y-axis direction in the figure). And it is comprised so that it can stop on the pouring line 2 and the cooling line 3.

  FIG. 3 shows the structure of the weight placing equipment 7 in the first embodiment. More specifically, a structure is shown in which the jacket lifting / lowering device 5 when located on the pouring line 2 and the weight lifting / lowering device 6 when located on the cooling line 3 are viewed from the right side.

  The jacket lifting device 5 includes a lifting cylinder 14, a frame 15, and a jacket lifting claw 16. The lifting cylinder 14 is connected to the frame 15. The jacket raising / lowering claw 16 is provided on the frame 15. The frame 15 of the jacket elevating device 5 and the jacket elevating claw 16 can be moved vertically by the elevating cylinder 14 (the Z-axis direction in the figure). The jacket 12 has a flange 12a. When the jacket 12 is lifted, the jacket raising / lowering claw 16 engages with the collar portion 12a and rises in the engaged state. Thereby, the jacket lifting / lowering device 5 can lift the jacket 12 covered by the mold 8 on the cooling line 3. Then, the jacket lifting / lowering device 5 is moved in the Y-axis direction in the figure by the operation of the cylinder 21, and the jacket 12 raised by the cooling line 3 can be lowered and covered on the mold 8 on the pouring line 2.

  As shown in FIG. 3, the jacket lifting / lowering device 5 includes a deceleration position determination device 30. FIG. 5 shows the structure of the deceleration position determination device 30. The deceleration position determination device 30 includes a rod member 31, a first detection body 32, and first proximity switches 33a, 33b, and 33c. A first frame 34 is disposed above the frame 15 in the jacket elevating device 5. In the first frame 34, first proximity switches 33a, 33b, 33c are arranged at different heights. The first proximity switches 33a, 33b, 33c are separated to such an extent that they do not affect each other. The three first proximity switches are arranged in the order of the first proximity switches 33a, 33b, 33c from the top.

  The bar member 31 is disposed so as to extend in the vertical direction of the jacket elevating device 5 (the height direction of the mold 8) (the Z-axis direction in the figure). A first detection body 32 is attached to one end of the rod member 31. The first detection body 32 has a cylindrical shape whose one end is open. As shown in FIG. 8, the first detection body 32 is attached to the rod member 31 so that the opening of the first detection body 32 faces downward. The width of the height of the first detector 32 (the length in the Z-axis direction in the figure) is set to be longer than the distance between the first proximity switches 33a and 33c. Then, when the jacket elevating device 5 is elevating and lowering the jacket 12, the other end of the rod member 31 and the flange portion 12a are in contact with each other.

  Each of the three first proximity switches sends a signal to a sequencer (not shown) when the first detector 32 is moved up and down to the same height.

  The operation of the deceleration position determining device 30 during the operation of the jacket elevating device 5 will be described below. First, the movement of the deceleration position determining device 30 from when the jacket elevating device 5 lifts the jacket 12 covered on the mold 8 on the cooling line 3 to when the jacket 12 is covered on the mold 8 on the pouring line 2 will be described. (See FIG. 5). Each of the three first proximity switches is disposed on the first frame 34. The first frame 34 is disposed on the frame 15 of the jacket elevating device 5. Therefore, the three first proximity switches move together with the jacket elevating device 5. The rod member 31 to which the first detection body 32 is attached is in contact with the jacket 12. The jacket 12 is lowered by the jacket lifting device 5. Therefore, the first detector 32 also moves together with the jacket elevating device 5. Therefore, the positional relationship between the three first proximity switches and the first detector 32 does not change. In this case, the first detection body 32 is located at a lower height than the three first proximity switches. Therefore, none of the three first proximity switches detects the first detection body 32.

  Next, the movement of the deceleration position determining device 30 from the time when the jacket elevating device 5 covers the casting mold 12 on the pouring line 2 with the jacket 12 to the time when it is completely lowered on the pouring line 2 will be described. The three first proximity switches move (fall) together with the jacket elevating device 5 as described above. On the other hand, the rod member 31 to which the first detection body 32 is attached is in contact with the jacket 12. The jacket 12 does not descend because it covers the mold 8. Therefore, the first detection body 32 does not move (fall) with the jacket elevating device 5. Therefore, when viewed from the three first proximity switches, the first detector 32 appears to have an increased height. Thus, the first detection body 32 can be moved up and down relatively to the jacket elevating device 5. Then, as shown in FIG. 6, when the jacket elevating claw 16 of the jacket elevating device 5 is completely lowered (when the jacket elevating claw 16 is located at the lower limit position), the height at which the first detection body 32 has moved from the initial position. In response to the distance A1, the three first proximity switches detect the first detection body 32 and transmit a signal to the sequencer. The height distance A1 of the first detector 32 is the distance from the lower end of the flange 12a to the upper surface of the jacket elevating claw 16 when the jacket elevating claw 16 of the jacket elevating device 5 is located at the descent limit position on the pouring line 2. It is equal to the distance to A2.

  In order for the first proximity switch to detect the first detection body 32, the first proximity switch and the first detection body 32 need to come closer to a certain distance. For this reason, the first proximity switch and the first detector 32 are arranged so that the first proximity switch has a distance at which the first detector 32 can be detected. In the present embodiment, the first detection body 32 has a cylindrical shape. For this reason, even if the first detection body 32 rotates about the rod member 31, the first detection body 32 does not contact the first proximity switch. Then, when the first detection body 32 is mounted on the rod member 31, the first detection body 32 is mounted such that the opening of the first detection body 32 faces downward. Therefore, impurities such as casting sand do not enter the first detection body 32. Further, a hole through which impurities such as foundry sand may pass may be provided above the first detection body 32. This can prevent impurities from accumulating on the first detection body 32.

  Further, in the present embodiment, the bar member 31 is provided with a stopper 35 so that the bar member 31 and the first detection body 32 do not unnecessarily lower with respect to the frame 15.

  As shown in FIG. 3, the weight lifting device 6 in the weight placing equipment 7 includes a lifting cylinder 17, a frame 18, and a weight lifting claw 19. The lifting cylinder 17 is connected to the frame 18. The weight lifting claw 19 is provided on the frame 18. The frame 18 and the weight lifting claw 19 of the weight lifting device 6 can be moved vertically by the lifting cylinder 17 (the Z-axis direction in the figure). When lifting the weight 13, the weight lifting claw 19 engages with the weight 13 and rises in the engaged state. Thereby, the weight lifting device 6 can lift the weight 13 placed on the upper surface of the mold 8 on the cooling line 3. The weight lifting device 6 moves in the Y-axis direction in the figure by the operation of the cylinder 21, and can place the weight 13 lifted by the cooling line 3 on the upper surface of the casting mold 8 on the pouring line 2. .

  As shown in FIG. 4, the weight lifting device 6 includes a deceleration position detecting device 37. FIG. 7 shows the structure of the deceleration position detecting device 37. The deceleration position detection device 37 includes a second detection body 38 and second proximity switches 36a, 36b, 36c, 36d. The second proximity switches 36a, 36b, 36c, 36d are arranged at different heights. The second proximity switches 36a, 36b, 36c, 36d are separated to such an extent that they do not affect each other. The four second proximity switches are arranged in the order of the second proximity switches 36a, 36b, 36c, 36d from the top. The four second proximity switches are provided on the second frame 39. The second frame 39 is disposed on the equipment frame 20, as shown in FIG. Thus, the second proximity switches 36a, 36b, 36c, 36d are mounted on the weight lifting device 6.

  The second detector 38 is disposed above the weight-side guide pin 40 that moves up and down in accordance with the lifting and lowering of the weight 13 by the weight lifting device 6. Each of the four second proximity switches transmits a signal to a sequencer (not shown) when the second detection body 38 moves up and down and is positioned at the same height.

  Next, an example of a weight mounting method by the weight mounting equipment 7 of the first embodiment will be described with reference to the drawings. In the present embodiment, the heights of the upper frame and the lower frame in the mold 8 are the same. The outer peripheral lower part of the upper frame and the outer peripheral upper part of the lower frame are both tapered, and the outer peripheral center of the mold 8 becomes one tapered shape by combining the upper frame and the lower frame.

(Step 1: Jacket covering step)
The jacket 12 previously placed on the mold 8 on the cooling line 3 is removed by the jacket elevating device 5 and moved onto the mold 8 on the pouring line 2. The jacket 12 that has moved onto the casting mold 8 on the pouring line 2 descends while the flange 12 a of the jacket 12 and the jacket lifting claw 16 of the jacket lifting device 5 are engaged, and is put on the casting mold 8. . In this jacket covering step, the three first proximity switches and the first detector 32 are moved together with the jacket elevating device 5, so that the positional relationship does not change. In the present embodiment, the inner periphery of the jacket 12 is tapered, and the outer periphery of the mold 8 and the inner periphery of the jacket 12 match, so that the jacket 12 covers the mold 8. When the jacket 12 is put on the mold 8, the center of the height of the jacket 12 is located on the mating surface of the upper frame and the lower frame in the mold 8.

(Step 2: deceleration position determination step)
After the jacket 12 is covered on the mold 8 by the jacket elevating device 5, the jacket elevating claw 16 is separated from the flange portion 12a and continues to descend to the lower limit position. Here, the lowering limit position indicates a position when the jacket raising / lowering claw 16 of the jacket lifting / lowering device 5 is completely lowered. Until the jacket raising / lowering claw 16 is disengaged from the flange portion 12a and reaches the lower limit position, the three first proximity switches continue to move down together with the jacket lifting / lowering device 5. On the other hand, the first detection body 32 is not displaced because it is in contact with the jacket 12 covered on the mold 8 via the rod member 31. Therefore, when the first detector 32 is observed from the three first proximity switches, the first detector 32 appears to rise.

  FIG. 8 is an enlarged view of the deceleration position determination device 30. The height of the upper end of the first detection body 32 before the jacket 12 covers the mold 8 is referred to as height β. In the present embodiment, the first proximity switches 33a, 33b, 33c are located at distances from the height β by distances Da, Db, Dc, respectively. When the jacket raising / lowering claw 16 of the jacket lifting / lowering device 5 reaches the lower limit position, when the three first proximity switches 33a, 33b, 33c and the first detector 32 are located at the same height, Send the signal to the sequencer. In the present embodiment, distance Da> distance Db> distance Dc.

  FIG. 9 shows the positional relationship between the jacket elevating device 5 and the jacket 12 in a state where the jacket elevating claw 16 of the jacket elevating device 5 has reached the lower limit position. Based on FIG. 9, a method of determining the deceleration position of the weight 13 in the descending direction in the weight lifting device 6 will be described. Here, the method of determining the deceleration position of the weight 13 when the weight 13 is placed on the molds 8H, 8N, and 8L having three different heights, heights H, N, and L, will be described. I do. A method of determining the deceleration position of the weight 13 when the mold 8 is not placed on the surface plate carrier 9 will also be described. The deceleration position is a position where the weight 13 descending at the first descending speed starts deceleration. In FIG. 9, the upper surface height of the jacket lifting / lowering claw 16 at the lower limit is defined as the lower limit height α. The three different heights are set lower in the order of height H> N> L.

  First, the operation of the jacket lifting / lowering device 5 and the deceleration position determination device 30 in the deceleration position determination step when the weight 13 is placed on the mold 8H shown in FIG. 9A will be described. The jacket raising / lowering claw 16 descends by a distance h from when it comes off the flange 12a to when it reaches the lower limit position. On the other hand, when the first detector 32 is observed from the three first proximity switches, it rises from the height β by the distance h, similarly to the jacket lifting / lowering claw 16. Here, the distance h is longer than the distance Da in FIG. That is, the upper end of the first detector 32 is located above the first proximity switch 33a when the jacket lifting claw 16 of the jacket lifting device 5 reaches the lower limit position.

  When the first detector 32 rises by a distance h from the height β with respect to the three first proximity switches, the heights of the three first proximity switches 33a, 33b, and 33c are all equal to the upper end of the first detector 32. And within the range of the lower end. When the jacket elevating claw 16 of the jacket elevating device 5 reaches the lower limit position, each of the three first proximity switches 33a, 33b, 33c detects the first detector 32 and transmits a signal to the sequencer. By transmitting the signal to the sequencer as described above, the deceleration position of the weight 13 when the weight 13 is placed on the mold 8H is determined.

  Next, the operation of the jacket lifting / lowering device 5 and the deceleration position determination device 30 in the deceleration position determination step when the weight 13 is placed on the mold 8N shown in FIG. 9B will be described. During the period from when the jacket lifting / lowering claw 16 is disengaged from the flange portion 12a to when it reaches the lower limit position, the first detection body 32 has a height β when observed from the three first proximity switches, as described in the mold 8H. From a distance n. Here, the distance n is longer than the distance Db in FIG. 8 and shorter than the distance Da. That is, the upper end of the first detector 32 is located between the first proximity switches 33a and 33b.

  When the first detector 32 rises by a distance n from the height β with respect to the three first proximity switches, the heights of the two first proximity switches 33b and 33c are changed to the upper and lower ends of the first detector 32. It is located within the range. Therefore, when the jacket raising / lowering claw 16 of the jacket lifting / lowering device 5 reaches the lower limit position, the two first proximity switches 33b and 33c respectively detect the first detector 32 and transmit a signal to the sequencer. By transmitting the signal to the sequencer as described above, the deceleration position of the weight 13 when the weight 13 is placed on the mold 8N is determined.

  Next, the operation of the jacket lifting / lowering device 5 and the deceleration position determination device 30 in the deceleration position determination step when the weight 13 is placed on the mold 8L shown in FIG. 9C will be described. During the period from when the jacket lifting / lowering claw 16 is disengaged from the flange portion 12a to when it reaches the lower limit position, the first detection body 32 has a height β when observed from the three first proximity switches, as described in the mold 8H. From a distance l. Here, the distance 1 is longer than the distance Dc in FIG. 8 and shorter than the distance Db. That is, the upper end of the first detector 32 is located between the first proximity switches 33b and 33c.

  When the first detector 32 rises by a distance 1 from the height β with respect to the three first proximity switches, the height of one first proximity switch 33c falls within the range between the upper end and the lower end of the first detector 32. Located to fit in. Therefore, when the jacket raising / lowering claw 16 of the jacket lifting / lowering device 5 reaches the lower limit position, one first proximity switch 33c detects the first detector 32 and transmits a signal to the sequencer. By transmitting the signal to the sequencer as described above, the deceleration position of the weight 13 when the weight 13 is placed on the mold 8L is determined.

  Finally, the operation of the jacket lifting / lowering device 5 and the deceleration position determination device 30 in the deceleration position determination step when the mold 8 does not exist on the surface plate carrier 9 shown in FIG. 9D will be described. During the period from when the jacket lifting / lowering claw 16 is disengaged from the flange portion 12a to when it reaches the lower limit position, the first detection body 32 has a height β when observed from the three first proximity switches, as described in the mold 8H. From the distance e. Here, the distance e is shorter than the distance Dc. That is, the upper end of the first detection body 32 is located below the first proximity switch 33c.

  For the three first proximity switches, even if the first detector 32 rises by the distance e from the height β, the heights of the three first proximity switches are all higher than the upper end of the first detector 43. Located in a high position. Therefore, when the jacket raising / lowering claw 16 of the jacket lifting / lowering device 5 reaches the lower limit position, none of the three first proximity switches detects the first detection body 32 and does not transmit a signal to the sequencer. In the deceleration position determination step, the deceleration position of the weight 13 is determined by not transmitting a signal from the first proximity switch to the sequencer. In addition, when the mold 8 does not exist on the trolley 9, the jacket 12 is directly mounted on the trolley 9 as shown in FIG.

  After the jacket raising / lowering claw 16 of the jacket lifting / lowering device 5 reaches the lowering limit, the jacket lifting / lowering device 5 is raised again so as not to contact the mold 8 or the jacket 12. Thereafter, the jacket elevating device 5 is moved onto the cooling line 3 by the cylinder 21. Then, the molds 8 placed on the platen carrier 9 are intermittently transported by the platen carrier transfer equipment 4 by one pitch (one mold) in a continuous mold group state. Note that the four different distances become shorter in the order of distances h> n> l> e. When the jacket raising / lowering claw 16 of the jacket lifting / lowering device 5 reaches the lower limit position, the jacket lifting / lowering claw 16 and the flange portion 12a do not contact in any of the above cases.

(Step 3: First weight descending step)
The weight lifting device 6 lifts the weight 13 placed on the mold 8 on the cooling line 3 and moves the weight 13 onto the mold 8 on the pouring line 2. Thereafter, the weight 13 descends toward the mold 8. The descending speed of the weight lifting device 6 at this time is defined as a first descending speed. The first descending speed is higher than a second descending speed described later. The first descending speed is set in consideration of the load on the weight lifting device 6 and the time from when the weight 13 descends to when the weight 13 decelerates to the second descending speed. When the weight 13 is moved up and down by the weight lifting device 6, the weight 13 and the second detector 38 are moved up and down together.

(Step 4: second double weight descending step)
The deceleration position of the weight lifting device 6 is set by signals transmitted to the sequencer by the three first proximity switches. In the present embodiment, the flow of setting the deceleration position for the molds 8H, 8N, 8L having three different heights, heights H, N, L, will be described. The flow of setting the deceleration position when the mold 8 is not placed on the surface plate carrier 9 (when only the jacket 12 is placed) will be described. The height of the second detector 38 before the weight lifting device 6 lowers the weight 13 is referred to as a height γ. The second proximity switches 36a, 36b, 36c, 36d are positions where the second detection body 38 can be detected, and the second detection body 38 is at the same height as the second proximity switches 36a, 36b, 36c, 36d. The positions are referred to as positions P1, P2, P3, and P4, respectively.

  FIG. 10 shows the deceleration position of the weight lifting device 6. Table 1 shows the relationship between the signal transmitted by the first proximity switch and the position of the second detector 38 in the first embodiment. The “presence / absence of a signal transmitted by the first proximity switch” column in Table 1 indicates whether the three first proximity switches 33a, 33b, and 33c transmit signals to the sequencer in the deceleration position determination step. It is described for each type (mold height). Here, “○” indicates that a signal has been transmitted in the deceleration position determination step, and “×” indicates that no signal has been transmitted. The “position of the second detector” column indicates the position of the second detector 38 when the weight lifting device 6 starts decelerating.

  As shown in Table 1, the type of signal transmitted from the first proximity switch to the sequencer differs depending on the mold height, and the deceleration position of the second detector 38 corresponding to the type of signal is set in advance. I have. Specifically, when the three first proximity switches 33a, 33b, and 33c transmit signals to the sequencer, when the second proximity switch 36a detects the second detector 38 (the second detector 38 moves to the position P1). Then, the weight lifting device 6 starts to decelerate. When the two first proximity switches 33b and 33c transmit signals to the sequencer, when the second proximity switch 36b detects the second detection body 38 (when the second detection body 38 is located at the position P2), the weight is moved up and down. The device 6 is decelerated. When one of the first proximity switches 33c transmits a signal to the sequencer, when the second proximity switch 36c detects the second detector 38 (when the second detector 38 is located at the position P3), the weight is raised and lowered. The device 6 starts to decelerate. When the first proximity switch does not transmit a signal to the sequencer in the deceleration position determination step, when the second proximity switch 36d detects the second detection body 38 (when the second detection body 38 is located at the position P4), the weight moves up and down. The device 6 starts to decelerate. The deceleration position is set to a higher position in the order of P1> P2> P3> P4. As the deceleration position is set to a higher position, the section that descends at the first descending speed becomes shorter.

  The weight lifting device 6 that has started decelerating thereafter continues to descend at the second descending speed until the weight 13 is placed on the mold 8 or the jacket 12. Here, the second descending speed is lower than the first descending speed. The second descending speed can be arbitrarily set as long as the speed is such that the mold 8 does not collapse due to an impact when the weight 13 is placed on the mold 8.

  After the weight lifting device 6 places the weight 13 on the mold 8 (or the jacket 12) while maintaining the second descending speed, the weight lifting device 6 lowers by a certain distance and stops. Then, the weight lifting device 6 moves up again so as not to contact the mold 8 and the weight 13. Thereafter, in order to repeat the above steps, the weight lifting device 6 is moved above the cooling line 3 by the cylinder 21.

  Next, a method of setting the height positions of the first proximity switches 33a, 33b, 33c and the second proximity switches 36a, 36b, 36c, 36d in the first embodiment will be described.

  In the present embodiment, the height of the upper frame and the lower frame in the mold 8 are the same, and the center of the height of the jacket 12 is located at the mating surface of the upper frame and the lower frame. As described above, the distance from the lower surface of the flange portion 12a to the lower limit height α is the same as the distance at which the first detector 32 rises from the height β in the deceleration position determination step. Therefore, in the deceleration position determination step, as the value of the height of the mold 8 increases, the distance from the lower surface of the flange 12a to the lower limit height α increases, and the distance at which the first detector 32 rises from the height β Is also longer.

  On the other hand, as the value of the height of the mold 8 increases, the deceleration position of the weight lifting device 6 needs to be higher. Based on the above, a method of setting the height positions of the first proximity switches 33a, 33b, 33c and the second proximity switches 36a, 36b, 36c, 36d will be described below. Note that the first proximity switches 33a, 33b, 33c and the second proximity switches 36a, 36b, 36c, 36d are all separated from each other to such an extent that they do not affect each other.

  First, a method of setting the height positions of the three first proximity switches will be described. In advance, among the molds that can be molded by the blanking molding machine 10, the deceleration position determination step is performed on the mold 8 M having the maximum height and the mold 8 m having the minimum height, and the upper end height position of the first detector 32 is confirmed. The upper end heights of these first detectors 32 are shown as PM and Pm in FIG. Then, the two first proximity switches 33a and 33b are arranged within the range of the upper end heights PM and Pm. In addition, the height of the mold 8M is set as H +, and the height of the mold 8m is set as L-.

  Also in the case where the jacket 12 is not covered by the mold 8 and is placed on the trolley 9, the deceleration position determination step is performed in the same manner, and the height position of the upper end of the first detector 32 is confirmed. The height of the upper end of the first detector 32 is indicated as Pn in FIG. Then, one first proximity switch 33c is arranged within the range between the upper end heights Pm and Pn. In the present embodiment, a first proximity switch 33b is arranged at an intermediate position between the first proximity switches 33a and 33c. However, the three first proximity switches 33a, 33b, 33c can be arranged at arbitrary positions within the above-described range. In the deceleration position determination step, the mold when the first detection body 32 rises by the distance Da is the mold 8Da having the mold height M +, and the mold when the first detection body 32 rises by the distance Db is the mold height. The mold 8Db has a length L +.

  Next, a method of setting the height positions of the four second proximity switches will be described. First, the position of the second proximity switch 36a is set so that the weight 13 can be placed at the second descending speed when the weight 13 is placed on the mold 8M. Specifically, from the position of the second detector 38 at the moment when the weight 13 is placed on the mold 8M having the mold height H +, the distance required to reduce the speed from the first descending speed to the second descending speed is used. The position of the second proximity switch 36a is set so that the upper position is the position P1.

  The position of the second proximity switch 36b is set so that the weight 13 can be placed at the second descending speed when the weight 13 is placed on the mold 8Da. Specifically, from the position of the second detector 38 at the moment when the weight 13 is placed on the mold 8Da having the mold height M +, a distance necessary for decelerating from the first descending speed to the second descending speed. The position of the second proximity switch 36b is set so that the upper position is the position P2.

  The position of the second proximity switch 36c is set so that the weight 13 can be placed at the second descending speed when the weight 13 is placed on the mold 8Db. Specifically, from the position of the second detector 38 at the moment when the weight 13 is placed on the mold 8Db having the mold height L +, a distance necessary for decelerating from the first descending speed to the second descending speed is used. The position of the second proximity switch 36c is set so that the upper position is the position P3.

  The position of the second proximity switch 36d is set so that the weight 13 can be mounted at the second descending speed when the weight 13 is mounted on the jacket 12. Specifically, the position above the position of the second detection body 38 at the moment when the weight 13 is placed on the jacket 12 by a distance necessary for decelerating from the first descending speed to the second descending speed is a position P4. The position of the second proximity switch 36d is set such that

  Table 1 summarizes the relationship between the mold height and the deceleration position of the second detector 38. Regarding the mold heights described in Table 1, the height H is in the range of heights M + to H +, the height M is in the range of heights L + to M +, and the height L is in the range of heights L- to L +. Are set within the range of. As described above, the deceleration position is determined in consideration of the height of the mold on which the weight 13 is placed. Further, the deceleration position may be determined in consideration of the mechanical load on the weight lifting device 6 when the lowering speed of the weight lifting device is reduced from the first lowering speed to the second lowering speed.

  In the present embodiment, the two first proximity switches 33a and 33b are arranged within the range of the upper end heights PM and Pm. However, the present invention is not limited to this, and one or three or more first proximity switches are arranged. You may. In this case, other than the above four second proximity switches may be arranged based on the method of setting the height position of the second proximity switch.

  According to the present embodiment, the steps from lowering the weight 13 by the weight lifting device 6 to placing the weight 13 on the mold 8 are the first weight lowering step of lowering the weight 13 at the first lowering speed. And a second double weight lowering step of lowering the weight 13 at the second lowering speed. With this configuration, the lowering speed of the weight 13 due to the second lowering speed, which is lower than the first lowering speed, is a speed at which the weight 13 is placed without disintegrating the mold 8 having an arbitrary height. Process time can be shortened.

  According to the present embodiment, the deceleration position determining device 30 determines the deceleration position, which is the position at which the first down speed is changed to the second down speed, for each mold 8 flowing into the pouring line 2. With this configuration, since the deceleration position is determined for each mold 8 flowing into the pouring line 2, even if molds having different heights flow into the pouring line 2, it can be handled. That is, according to the present embodiment, since the height of the mold on which the weight is placed can be set arbitrarily, it is possible to cope with a change in the height of the mold.

  According to the present embodiment, each of the deceleration position determination device 30 and the deceleration position detection device 37 includes a plurality of proximity switches. Since the proximity switch can be easily removed, when a problem such as breakage occurs, it is possible to promptly take measures such as replacement.

(Second embodiment)
Next, as an example of another type of weight mounting equipment, a weight mounting equipment including an optical measurement unit as a deceleration position determining device will be described as a second embodiment. In the following description, changes from the first embodiment will be described. In the present embodiment, a laser sensor is used as an optical measurement unit.

  In the second embodiment, the weight placing equipment 107 includes a weight lifting device 106, and is disposed so as to straddle a pouring line and a cooling line. On the upstream side of the pouring line as viewed from the weight elevating device 106, a jacket elevating device 105 is disposed so as to straddle the pouring line and the cooling line. The jacket lifting / lowering device 105 has the same configuration as the jacket lifting / lowering device 5 in the first embodiment, except that the jacket lifting / lowering device 105 is not provided with the deceleration position determining device 30.

  FIG. 11 shows a configuration of the weight lifting device 106 according to the second embodiment. The weight lifting device 106 includes a lifting cylinder (not shown), a frame 118, a weight lifting claw 119, and a frame 150. The frame 150 has a cylindrical shape, and the lifting cylinder is disposed so as to be surrounded by the frame 150. The lifting cylinder is connected to the frame 118. The weight lifting claw 119 is provided on the frame 118. The frame 118 of the weight lifting device 106 and the weight lifting claw 119 can be moved vertically by a lifting cylinder (the Z-axis direction in the figure). When lifting the weight 13, the weight lifting claw 119 engages with the lower surface of the weight 13 and rises in the engaged state. Thereby, the weight lifting device 106 can lift the weight 13 placed on the upper surface of the mold 8 on the cooling line. The weight lifting device 106 can place the weight 13 lifted by the cooling line on the upper surface of the mold 8 on the pouring line. The frame body 150 is integrated with the weight lifting device 106, and is moved in the vertical direction by the lifting cylinder together with the weight lifting device 106.

  As shown in FIG. 11, the weight lifting device 106 includes two laser sensors 130 as a deceleration position determining device. The two laser sensors 130 are attached to the frame 150, and are arranged so as to emit laser light perpendicularly to a horizontal plane (the upper surface of the mold). The laser sensor 130 can continuously measure the distance from the laser sensor 130 to the mold 8 by receiving the laser light reflected from the mold 8. Then, the measured distance is transmitted to a sequencer (not shown) as needed.

  Next, an example of a weight mounting method by the weight mounting equipment 107 of the second embodiment will be described with reference to the drawings. The jacket 12 is previously covered with the mold 8 on the pouring line by the jacket elevating device 105. The mold 8 covering the jacket 12 is located below the weight lifting device 106.

  The weight 13 placed on the mold 8 on the cooling line is lifted by the weight lifting device 106 and moved to the mold 8 on the pouring line. Thereafter, the weight 13 is lowered by the weight lifting device 106. Each of the two laser sensors 130 emits a laser beam vertically toward the upper surface of the mold 8 and starts measuring the distance from the laser sensor 130 to the upper surface of the mold 8 (measurement step). In this measurement step, the distance is continuously measured from the start of the lowering of the weight 13 by the weight lifting device 106 until the weight 13 is placed on the mold 8, and the measurement result is transmitted to the sequencer. I have. When the weight lifting device 106 is moving down the weight 13, the two laser sensors 130 are attached to the frame 150 and move together with the weight lifting device 106. On the other hand, the mold 8 is placed on a pouring line. Therefore, the laser sensor 130 approaches the mold 8 over time.

  The distance PS from the laser sensor 130 to the upper surface of the mold 8 when the weight lifting device 106 starts to decelerate from the first descending speed to the second descending speed is set in advance. While the weight 13 is being lowered by the weight lifting device 106, when the distance continuously measured by the laser sensor 130 becomes the distance PS, the deceleration position of the weight lifting device 106 is determined, and deceleration is started. (Deceleration position determination step). In addition, the step of lowering the weight 13 by the weight lifting device 106 includes a step of lowering the weight 13 at the first descent speed from the start of the descent to the deceleration position (first weight lowering step) and a step of moving the weight 13 from the deceleration position to the mold 8. Until it is placed, it is divided into a step of descending at the second descending speed (second double weight descending step). The distance PS in the second embodiment is arbitrarily set in consideration of the deceleration distance from the first descending speed to the second descending speed and the like.

  When the smaller value of the distances continuously measured by the two laser sensors 130 reaches the distance PS, the deceleration of the weight lifting device 106 is set to start. This is to consider a case where the laser light emitted from one of the laser sensors 130 hits the gate on the upper surface of the mold 8.

  When the mold 8 is not placed on the surface plate carrier (when only the jacket 12 is placed), the laser light emitted from the laser sensor 130 impinges on the surface plate carrier. In this case, the distance measured by the laser sensor 130 when the weight 13 starts descending is significantly longer than when the mold 8 is placed on the surface plate carriage. In this case, the sequencer determines that only the jacket 12 is mounted on the base plate carrier. Then, the deceleration position of the weight 13 is set to a position above the upper surface of the flange portion 12a of the jacket 12 by a distance necessary to reduce the speed from the first descending speed to the second descending speed.

  After placing the weight 13 on the mold 8 (or on the jacket 12), the weight lifting device 106 is lowered by a certain distance and stopped. Then, the weight lifting device 106 moves up so as not to contact the mold 8 and the weight 13. Thereafter, the weight lifting device 106 moves above the cooling line to repeat the process.

  According to the present embodiment, unlike the first embodiment, the deceleration position determination device is only the two laser sensors 130, and does not have the deceleration position detection device. Therefore, a simple facility configuration can be achieved.

  In the embodiment, the number of times the weight is decelerated by the weight lifting device is set to one time. However, the number of times of deceleration may be divided into two or more times, and the weight may be decelerated stepwise. Thereby, the mechanical load of the weight lifting device can be suppressed. For example, when the weight 13 is placed on the mold 8L in the first embodiment, when the second proximity switches 36a and 36c respectively detect the second detector 38, the weight lifting device 6 is set to be decelerated. You may.

DESCRIPTION OF SYMBOLS 1 ... Unframed molding line, 5, 105 ... Jacket elevating device, 6, 106 ... Weight elevating device, 7, 107 ... Weight placing equipment, 8 ... Mold, 12 ... Jacket, 12a ... Flange, 13 ... Heavy Weight, 30: deceleration position determining device, 31: rod member, 32: first detector, 33a, 33b, 33c: first proximity switch, 36a, 36b, 36c, 36d: second proximity switch, 37: deceleration position detection Device, 38: second detector, 106: weight lifting device, 130: laser sensor (optical measuring means).

Claims (9)

A weight placing equipment for placing a weight on a mold on a blanking molding line,
A weight lifting device for lowering the weight and placing the weight on the mold,
A deceleration position determination device that determines a deceleration position in the descending direction of the weight in the weight lifting device,
The descending speed of the weight in the weight lifting device is a first descending speed from when the descending is started to when the deceleration position is reached, and a first descending speed when the weight is placed on the mold from the decelerated position. And two descending speeds,
The weight placing equipment, wherein the second descending speed is set in advance as a speed at which the mold does not collapse due to an impact when the weight is placed on the mold, and is lower than the first descending speed. A weight placing equipment for placing a weight on a mold on a blanking molding line,
A weight lifting device for lowering the weight and placing the weight on the mold,
A deceleration position determining device that determines a deceleration position of the weight in the descending direction of the weight in the weight lifting device,
Wherein disposed upstream of the weight lifting device, has ingredients Bei a jacket lifting device covering the jacket side of the mold,
The descending speed of the weight in the weight lifting device is a first descending speed from when the descending is started to when the deceleration position is reached, and a first descending speed when the weight is placed on the mold from the decelerated position. And two descending speeds,
The second descending speed is lower than the first descending speed,
The weight placement equipment , wherein the deceleration position determining device is disposed in the jacket elevating device. A weight placing equipment for placing a weight on a mold on a blanking molding line,
A weight lifting device for lowering the weight and placing the weight on the mold,
A deceleration position determining device that determines a deceleration position of the weight in the descending direction of the weight in the weight lifting device,
The descending speed of the weight in the weight lifting device is a first descending speed from when the descending is started to when the deceleration position is reached, and a first descending speed when the weight is placed on the mold from the decelerated position. And two descending speeds,
The second descending speed is lower than the first descending speed,
The deceleration position determination device, disposed on the weight lifting device, comprises a light measuring means for measuring the distance to the upper surface of the mold by light,
The weight mounting equipment , wherein the light measuring means is disposed so that light emitted from the light measuring means is perpendicular to the upper surface of the mold. The deceleration position determination device,
A first detector that can be raised and lowered relatively to the jacket lifting device,
A first proximity switch that moves up and down together with the jacket elevating device and detects the first detection body,
The weight placing equipment according to claim 2, wherein the first proximity switch includes a plurality of proximity switches corresponding to different heights of the mold. The weight lifting device includes a deceleration position detection device that detects the deceleration position,
The deceleration position detection device,
A second detector that moves up and down with the lifting operation of the weight lifting device,
A second proximity switch attached to the weight lifting device and detecting the second detection body,
The weight placing equipment according to claim 4, wherein the second proximity switch includes a plurality of proximity switches corresponding to different heights of the mold. The deceleration position determination device further includes a rod member extending in the height direction of the mold,
At the upper end of the rod member, the first detection body is disposed,
The weight placing equipment according to claim 5, wherein a lower end of the bar member is arranged so as to be able to abut on a flange formed on the jacket.   The weight placing equipment according to claim 6, wherein the first detector extends in the height direction of the mold and has a cylindrical shape with an open lower end. A method of placing a weight on a mold on a frame making line using the weight placing equipment according to claim 2,
By the jacket elevating device, a jacket covering step of lowering the jacket and covering the side surface of the mold,
By the deceleration position determination device, a deceleration position determination step of determining the deceleration position in the descending direction of the weight in the weight lifting device,
A first weight lowering step of lowering the weight at the first lowering speed to the deceleration position by the weight lifting device;
By the weight lifting device, a second double weight lowering step of lowering the weight at the second lowering speed until the weight is placed on the mold from the deceleration position,
Weight mounting method having the following. A method of placing a weight on a mold on a molding line using the weight placing equipment according to claim 3,
A measuring step of measuring a distance from the light measuring means to the upper surface of the mold by the light measuring means,
A deceleration position determination step of determining a deceleration position of the weight in the descending direction of the weight in the weight lifting device based on the distance measured in the measurement step;
A first weight lowering step of lowering the weight at the first lowering speed to the deceleration position by the weight lifting device;
By the weight lifting device, a second double weight lowering step of lowering the weight at the second lowering speed until the weight is placed on the mold from the deceleration position,
Weight mounting method having the following.