JP5063081B2 - Die casting machine - Google Patents

Description

  The present invention relates to a die casting machine in which a molten metal is injected and filled into a mold by advancing an injection plunger, and more particularly to a die casting machine using an electric servo motor as an injection drive source.

  A die casting machine that obtains a product by injecting and filling a molten metal material into a mold cavity is well known. In this die casting machine, a metal material melted in a melting furnace (for example, Al alloy, Mg alloy, etc.) Each shot is weighed and pumped with a ladle, and the molten metal (molten metal material) is poured into the injection sleeve, and this is injected and filled into the mold cavity by the forward movement of the injection plunger. Yes.

  As shown in FIG. 9, the casting process by the die casting machine includes an injection process including a low-speed injection process and a subsequent high-speed injection process, and a pressure increasing process subsequent to the high-speed injection process. Since a higher injection speed is required than plastic injection molding and a large pressure increase is required in the pressure increasing process, as a driving source for injection / pressure increasing, it has been generally a relatively large size. Since the injection drive source is used as the hydraulic drive source in this way, the hydraulic die casting machine using the hydraulic drive source as the drive source for mold opening and closing and casting product extrusion is conventionally used. It was the mainstream of die casting machines. However, hydraulic die casting machines have a risk of fouling by oil, so the demand for clean electric die casting machines is increasing recently, and the development of such electric die casting machines is advancing. is there.

  FIG. 10 is a simplified and partially broken explanatory view mainly showing a configuration of an injection system of a conventional electric die casting machine. In FIG. 10, 101 is a base member, 102 is a fixed die plate disposed on the base member 101, 103 is a fixed mold attached to the fixed die plate 102, and 104 is a mold opening / closing drive (not shown). A movable die plate that is driven forward and backward with respect to the fixed die plate 102 by a source and a mold opening / closing mechanism, 105 is a movable side mold attached to the movable die plate 104, and 106 is both molds 103 in a clamped state , 105 is a mold runner (such as a sprue / gate) that leads to the cavity 106.

  Reference numeral 108 denotes a holding plate disposed on the base member 101 so as to face the fixed die plate 102, 109 denotes a connecting shaft spanned between the fixed die plate 102 and the holding plate 108, and 110 denotes A rail member 111 laid on the base member 101 is a linear motion guide 112 that is linearly movable on the rail member 110, a linear motion body having a lower portion fixed thereto, and 113 is an injection unit mounted on a holding plate 108. The electric servo motor 114 is a drive pulley fixed to the output shaft of the electric servo motor 113, 115 is a ball screw mechanism that converts the rotation of the electric servo motor 113 into a linear motion, and 116 is rotatably held by the holding plate 108. The nut body 117 of the ball screw mechanism 115 thus formed is screwed into the nut body 116 and directly rotated by the rotation of the nut body 116. A threaded shaft 118 of the ball screw mechanism 115 to be transferred is fixed to the nut body 116, and a driven pulley 119 that transmits the rotation of the electric servo motor 113 via a driving pulley and a timing belt (not shown) is an end thereof. The injection sleeve is fixed to the fixed mold 103, and the inside thereof communicates with the mold runner 107, 120 is a pouring hole drilled in the injection sleeve 119, and 121 is a linearly moving body 111. This is an injection plunger that is fixed to and can move forward and backward in the injection sleeve 119.

  The rotation of the electric servo motor 113 is transmitted to the nut body 116 of the ball screw mechanism 115 via the driven pulley 114, a timing belt (not shown), and the driven pulley 118, and the nut body 116 is rotated to rotate the screw of the ball screw mechanism 115. The shaft 117 is linearly driven, whereby the linear moving body 111 and the injection plunger 121 are linearly driven integrally with the screw shaft 117.

  In the configuration shown in FIG. 10, when the molten metal 122 is poured into the injection plunger 119 from the pouring port 120 by a ladle (not shown) in the mold-clamping state, a low-speed injection process is started immediately after that, and the injection plunger 121 is The metal is moved forward in accordance with the set speed in the low-speed injection process, so that the molten metal 122 in the injection sleeve 119 is filled up to the mold runner 107, and the gas in the mold cavity 106 is vented. Is called. As soon as the low-speed injection process is completed, the process proceeds to the high-speed injection process, and the injection plunger 121 is driven forward according to the set speed in the high-speed injection process, whereby the molten metal 122 is rapidly injected into the cavity 106 of the mold. -Filled. As soon as the high-speed injection process is completed, the process proceeds to the pressure-increasing process. According to the set pressure in the pressure-increasing process, the injection plunger 121 applies an increased pressure to the metal in the cavity 106. Such a speed transition in the low-speed injection process and the high-speed injection process and a pressure transition in the pressure increasing process are as shown in FIG. 9, for example.

  In the prior art shown in FIG. 10, as described above, the rotation of the electric servo motor 113 is converted into a linear motion by the ball screw mechanism 115, and the injection plunger 121 is linearly driven by the linear motion portion of the ball screw mechanism 115. Yes. However, in the high-speed injection process, it is necessary to rapidly increase the forward speed of the injection plunger 121. Therefore, in the high-speed injection process, the electric servo motor 113 is rapidly rotated at a high speed. Is inherently limited by motor performance alone. Further, in the pressure increasing process, it is necessary to quickly increase the pressure increase (pressing force) by the injection plunger 121 to a high pressure. However, the transient response to increase to a high pressure is naturally limited only by the motor performance, and a large pressure increase. In order to obtain this, an expensive motor with a large capacity (high torque output) is required, which leads to a problem of cost increase.

  In a plastic injection molding machine, a crank mechanism is used as a technique to perform an injection operation by a link mechanism that is driven by the rotational force of an electric servo motor and whose force expansion rate and speed change according to the operating position. A technique for performing an injection operation is disclosed in Japanese Patent Laid-Open No. 3-146320, and a technique for performing an injection operation by a double toggle link mechanism is disclosed in Japanese Patent Laid-Open No. 2003-25368. However, the technologies of these prior application publications are not applied to a die casting machine, and do not disclose the use of link operating characteristics according to a high speed injection process or a pressure increasing process inherent to the die casting machine.

  An object of the present invention is to improve the performance of rapid startup to a high speed in a high-speed injection process and the performance of rapid startup to a high pressure in a pressure-increasing process in a die casting machine using an electric servo motor as an injection drive source. It is possible to obtain a large pressure increase easily even if a relatively small capacity motor is used.

In order to achieve the above-described object, the present invention uses an electric servo motor as an injection drive source, and in the product casting process, follows an injection process comprising a low-speed injection process and a subsequent high-speed injection process, and a high-speed injection process. A die casting machine that drives and controls the electric servo motor so that a pressure increasing step is performed, wherein a driving shaft is rotationally driven at a constant speed by the electric servo motor, and an operating position of a link member connected to the driving shaft Is the ratio of the force expansion ratio, which is the ratio of the force acting on the input end of the link member and the force acting on the output end, and the ratio of the moving speed of the input end of the link member to the moving speed of the output end. a link mechanism speed ratio and changes, and a injection plunger which is linearly driven in the injection sleeve by the link mechanism, the high-speed injection step, movement of the link mechanism Running in the region speed ratio in the region is greater than "1", the pressure increasing step, the magnification of the force in the operation area of the link mechanism and to execute in a region above the "1".
Moreover, the distance between the fixed die plate and the force input end of the link mechanism is variably set according to the injection filling condition of the molten metal.
Further, a holding block that is disposed opposite to the fixed die plate and can be variably set with respect to the fixed die plate, and the fixed die plate and the holding block are connected to each other, and a holding block is formed on a screw portion formed on the side penetrating the holding plate A plurality of connecting shafts in which geared nuts that are rotatably held are screwed together, a holding block position adjusting motor that is mounted on the holding block and that rotates the geared nuts via a transmission gear train, is linearly driven by a link mechanism, the example Bei a linear motion block which is linearly transported a injection plunger integral with the link mechanism includes a rotatably retained original shaft to the holding block-side, one end A first arm that rotates integrally with the driving shaft about the driving shaft as a rotation center, and one end of the first arm connected to the other end of the first arm so as to be relatively rotatable. , With a second arm whose other end is relatively rotatably connected to the linear motion block side, constituted by the crank mechanism.

In the present invention, in the configuration in which the injection plunger is linearly driven by a link mechanism that is driven by the rotational force of the electric servomotor for injection and whose force enlargement rate and speed change according to the operating position, the high-speed injection process is performed in the link Since the speed increase process is executed in an area where the force expansion rate is large in the operation area of the link mechanism, the link mechanism functions as a speed increase mechanism in the high speed injection area. This makes it possible to quickly start up to a high speed, and the link mechanism functions as a force expansion mechanism (ie, a pressure increasing mechanism) in the pressure increasing process, which makes it easy to quickly increase to a high pressure. Moreover, even if a relatively small capacity motor is used, a large pressure increase can be easily obtained.
In addition, since the distance between the fixed die plate and the force input end of the link mechanism is variably set according to the injection filling condition of the molten metal such as the mold shape, injection at the start of the low-speed injection process prior to the high-speed injection process The position of the plunger can be set to an arbitrary position, whereby the advance stroke of the injection plunger from the start time of the low speed injection process to the time of disclosure of the high speed injection process can be arbitrarily variably set, that is, at the start time of the high speed injection process. By setting the operation posture of the link mechanism to a desired state, the high-speed injection process can be started from a desired position on the speed ratio characteristic line of the link mechanism. Therefore, since it becomes possible to start the high-speed injection process from a desired position of the speed ratio characteristic line in the link mechanism according to the injection filling condition of the molten metal such as the mold shape, it is preferable according to the injection filling condition of the molten metal. Casting can be performed adaptively.
The link mechanism includes a driving shaft that is an input end of a force rotatably held on the holding block side, a first arm whose one end rotates integrally with the driving shaft with the driving shaft as a rotation center, and one end thereof Is constituted by a crank mechanism having a second arm connected to the other end of the first arm so as to be relatively rotatable and a second arm having the other end connected to the linear motion block so as to be relatively rotatable. The injection mechanism is configured to perform injection by once converting the rotation of the electric servo motor into a linear motion by the ball screw mechanism and driving a toggle link mechanism such as a double toggle link mechanism by the linear motion part of the ball screw mechanism. In comparison, the structure is much simpler.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 to 8 relate to an electric die casting machine according to an embodiment of the present invention (hereinafter referred to as the present embodiment), and FIG. 1 is a simplified diagram mainly showing a configuration of an injection system of the die casting machine of the present embodiment. It is explanatory drawing which cut and partly fractured.

  In FIG. 1, 1 is a base member fixed on a main frame (not shown), 2 is a fixed die plate fixed on the base member 1, and 3 is a fixed-side mold attached to the fixed die plate 2. 4 is a movable die plate that is driven forward and backward with respect to the fixed die plate 2 by a mold opening / closing drive source and a mold opening / closing mechanism (not shown), and 5 is a movable side mold attached to the movable die plate 4. Reference numeral 6 denotes a cavity formed by the molds 3 and 5 in a clamped state, and reference numeral 7 denotes a mold runner (such as a sprue gate) that leads to the cavity 6.

  8 is a rail member laid on the base member 1, 9 is a holding block whose lower part is fixed to a linear motion guide 10 that can move linearly on the rail member 8, and is maintained at a fixed position during casting operation, 11 A plurality of connecting shafts 12, which are bridged between the fixed die plate 2 and the holding block 9 and connect the two plates 2, 9, are linearly moved on the rail member 8 and are linearly moved to the linear guide 13. 1 is a crank mechanism that is driven by the rotational force of the injection electric servo motor (not shown in FIG. 1) mounted on the holding block 9 (driven by the rotational force of the injection electric servo motor). The crank mechanism, which is a link mechanism in which the force expansion rate and speed change according to the operating position), 15 connects and fixes the holding piece 16 at the force output end of the crank mechanism 14 and the linear motion block 12. An end of the cell unit 17 is fixed to the fixed mold 3 and an inside thereof is an injection sleeve communicating with the mold runner 7. An injection hole 18 is formed in the injection sleeve 17. An injection plunger 20 whose end is fixed to the linear motion body 12 and can move back and forth in the injection sleeve 17 is a position sensor that detects the position of the injection plunger 19.

  21 is a holding block position adjusting motor mounted on the holding block 9, 22 is a drive gear fixed to the output shaft of the holding block position adjusting motor 21, and 23 is rotatably held by the holding block 9. The intermediate gear 24, to which the rotation of the drive gear 22 is transmitted, is screwed into a screw portion formed at the end of each connecting shaft 11 passing through the holding block 9, and is rotatably held by the holding block 9. Thus, it is a nut with a gear to which the rotation of the intermediate gear 23 is transmitted.

  In FIG. 1 and FIGS. 4 and 5 described later, reference numeral 25 denotes a molten metal (molten metal) or a metal that has started to solidify.

  The crank mechanism 14 will be described with reference to FIGS. 1 and 2. FIG. 2 is an explanatory view showing a configuration of the crank mechanism 14 viewed from a direction orthogonal to FIG. 1 and a drive system of the crank mechanism 14. In FIG. 2, the holding block 9 is drawn separately on the left and right. However, in practice, the holding block 9 is a structure that is integrally connected as a whole.

  1 and 2, reference numeral 31 denotes a pair of driving shafts rotatably held by a holding block 9 via a bearing (not shown). The pair of driving shafts 31 have their rotational centers on the same line. Is arranged. The driving shaft 31 is an input end of the force of the crank mechanism 14. One end side of the first arm 32 is fixed to one end side of each driving shaft 31, and the other end side of the pair of first arms 32 is connected to the other end side integrally. 33 is fixed. One end side of the second arm 34 is rotatably held at an intermediate portion of the connecting shaft 33 via a bearing (not shown). The other end side of the second arm 34 is fixed to a rotating shaft 35 rotatably held via a bearing (not shown) on a holding piece 16 attached to the linear motion body 12 via a load cell unit 15. The rotary shaft 35 is an output end of the force of the crank mechanism 14.

  In FIG. 2, reference numeral 36 denotes an injection electric servomotor mounted on the holding block 9, and the rotation of the injection electric servomotor 36 is, for example, a deceleration rotation transmission mechanism 37 using a pulley and a timing bell. Is transmitted in synchronization with a pair of driving shafts 31. Reference numeral 38 denotes a system controller that controls the entire die casting machine. The system controller 38 drives and controls the electric servomotor 36 for injection via a servo amplifier 39. S1 is a detection output (position detection information) of the position sensor 20, S2 is a detection output (pressure detection information) of the strain sensor of the load cell unit 15, and the system controller 38 monitors these detection outputs S1 and S2. On the other hand, in the low-speed injection process and the high-speed injection process, the injection electric servomotor 36 is driven and controlled by speed feedback control along the position axis, and in the pressure increase process, the injection electric servomotor is controlled by pressure feedback control along the time axis. 36 is driven and controlled.

  In the crank mechanism 14 and its drive system, when the injection electric servomotor 36 is rotationally driven in a predetermined direction, the rotation of the injection electric servomotor 36 is paired with a driving shaft that forms a pair via a deceleration rotation transmission mechanism 37. 31 is transmitted synchronously. The reason why the reduction rotation transmission mechanism 37 is used is to transmit a rotational torque of a certain level or more to the driving shaft 31 even if the injection electric servomotor 36 is small. Depending on the performance of the motor 36, the drive shaft 31 may be directly driven by the electric servomotor 36 for injection. As described above, when the paired prime shafts 31 are rotationally driven, the paired first arms 32 are simultaneously rotationally driven in a predetermined direction with the prime shaft 31 as a rotational center. Accordingly, the second arm 34 follows a predetermined cooperative tracking operation (following the rotation of the first arm 32 so that the second arm 34 linearly moves the other end fixed to the rotating shaft 35). The movement of the second arm 34 causes the linear motion body 12 to be linearly driven, so that the injection plunger 19 is linearly driven integrally with the linear motion body 12.

  Here, in the crank mechanism 14 of the present embodiment, the twin driving shaft 31 and the paired first arm 32 are simultaneously rotated by the injection electric servomotor 36 via the reduction rotation transmission mechanism 37, respectively. The drive mechanism (double-axis drive system) crank mechanism is used. For this reason, the number of the driving shaft 31 to which the rotation is transmitted is one, and the other driving shaft that is paired with the driving shaft 31 disposed so that the center of rotation is collinear with the driving shaft 31 is driven. Compared with a crank mechanism of a general single-side drive system (single-axis drive system) that uses a shaft, the force can be transmitted to the second arm 34 equally from the two force transmission paths. Therefore, it is possible to reduce the possibility of occurrence of uneven wear and backlash as much as possible. Therefore, the crank mechanism 14 having excellent operational reliability and durability can be realized. In order to simplify the configuration of the reduced speed rotation transmission mechanism 37, it is of course possible to adopt a crank mechanism of a single drive system (single shaft drive system) instead of a twin drive system (biaxial drive system). Is possible.

  FIG. 3 is a very schematic schematic characteristic diagram showing a change in speed at the output end of the force of the crank mechanism 14 and a change in the force expansion rate when the driving shaft 31 of the crank mechanism 14 is rotated at a constant speed. It is. 3, the horizontal axis indicates the position of the output end of the force of the crank mechanism 14, the vertical axis indicates the speed ratio (relative speed) and the power expansion rate, 41 is a speed ratio characteristic line, and 42 Is the characteristic line of force magnification.

  FIG. 3 shows the characteristics when the first arm 32 of the crank mechanism 14 is rotated 180 ° from the state shown in FIG. When the first arm 32 starts rotating from the state shown in FIG. 4, the speed of the output end of the force of the crank mechanism 14 starts to increase from the speed ratio (relative speed) “0” and the speed ratio (relative speed) “1”. After reaching the maximum speed, the speed starts to decrease. After the speed ratio (relative speed) “1” is decreased, the first arm 32 completes 180 ° rotation, The ratio (relative speed) is “0”. On the other hand, when the first arm 32 starts rotating from the state shown in FIG. 4, the expansion rate of the force output end of the crank mechanism 14 starts to decrease from infinity and falls below the expansion rate “1”. After reaching the minimum enlargement rate, the force enlargement rate starts to increase, and after exceeding the enlargement rate “1”, when the first arm 32 finishes rotating 180 °, the force increase The rate is infinite.

  In the present embodiment, in consideration of the characteristics of the speed ratio of the crank mechanism 14 and the characteristics of the force expansion rate, the high-speed injection process is performed in an area where the speed (speed ratio) in the operation area of the crank mechanism 14 is large. The pressure increasing step is executed in a region where the force expansion rate is large in the operating region of the link mechanism 14. Specifically, the high-speed injection process is performed in the operation region of the crank mechanism 14 exceeding the speed ratio “1”, and more preferably in the operation region of the crank mechanism 14 exceeding the speed ratio “1.5”. In addition, the pressure increasing step is performed in the operation region of the crank mechanism 14 exceeding the force expansion rate “1”, and more preferably, the crank mechanism 14 exceeding the force expansion rate “2”. This is performed in the operation area. Note that the characteristic lines 41 and 42 in FIG. 3 are very schematic outline characteristics as described above, and it is possible to obtain desired operation characteristics depending on the design of the crank mechanism 14. The size of the region used for the high-speed injection process and the size of the region used for the pressure-increasing process can be made wider or narrower.

  Next, the low-speed injection process, the high-speed injection process, and the pressure increase process of this embodiment will be described. 4 is an explanatory diagram showing a state before the start of the low-speed injection process, and FIG. 5 is an explanatory diagram showing a state immediately after the high-speed injection process is started. FIG. 4 and FIG. Some of the constituent elements shown in FIG.

  When a predetermined amount of the molten metal 25 is poured into the injection sleeve 17 from the pouring port 18 by a ladle (not shown), the injection electric servomotor 36 is connected via the servo amplifier 39 based on a command from the system controller 38. The rotation shaft is driven to rotate in a predetermined direction and at a speed set in the low-speed injection process, whereby the driving shaft 31 of the crank mechanism 14 is rotationally driven via the reduction rotation transmission mechanism 37, so that it is integrated with the linear motion body 12. Thus, the injection plunger 19 is driven forward at a low speed. In the present embodiment, the speed setting of the low-speed injection process can be set in multiple stages along the position axis at the number of stages and speed desired by the user, and the electric servomotor 36 for injection is controlled based on this setting condition. It is designed to be feedback controlled. That is, in the low-speed injection process, the injection electric servomotor 36 is driven and controlled by speed feedback control along the position axis while monitoring the detection output S1 of the position sensor 20 that detects the position of the injection plunger 19. The low-speed injection process is executed, the molten metal 25 in the injection sleep 17 is filled up to the mold runner 7, and the gas in the cavity 6 is vented. Then, the system controller 38 recognizes the advance position of the injection plunger 19 based on the detection output S1 from the position sensor 20, and switches the injection process to the high-speed injection process at a timing advanced by a distance set in the low-speed injection process. . Note that when the low-speed injection process is completed, the operation posture of the crank mechanism 14 is higher than the speed ratio “1”, more preferably higher than the speed ratio “1.5”.

  At the start timing of the high-speed injection process, the electric servomotor for injection 36 is rotationally driven in a predetermined direction and at a speed set in the high-speed injection process via the servo amplifier 39 based on a command from the system controller 38. As a result, the driving shaft 31 of the crank mechanism 14 is rotationally driven via the deceleration rotation transmission mechanism 37, so that the injection plunger 19 is driven forward at a high speed integrally with the linear motion body 12. In the present embodiment, the speed setting in the high-speed injection process can be set to one or two stages along the position axis, and the electric servomotor for injection 36 is speed-feedback controlled based on this setting condition. It is like that. That is, in the high-speed injection process, the injection electric servomotor 36 is driven and controlled by speed feedback control along the position axis while monitoring the detection output S1 of the position sensor 20 that detects the position of the injection plunger 19. A high-speed injection process is performed, and the molten metal 25 is rapidly injected and filled into the cavity 6. FIG. 5 shows a state immediately after the high-speed injection process is started.

  In the above-described high-speed injection process, the operating range of the crank mechanism 14 is a region where the speed ratio exceeds “1”, and more preferably exceeds “1.5”. By functioning as a speed increasing mechanism, rapid start-up to a high speed can be easily achieved.

  Then, the system controller 38 recognizes the advance position of the injection plunger 19 based on the detection output S1 from the position sensor 20, and the timing at which the system controller 38 has advanced by the distance set in the high-speed injection process (that is, the injection to the start position of the pressure increasing process). At the timing when the plunger 19 moves forward), the high-speed injection process is completed, and the process is switched to the pressure increasing process. When the high-speed injection process is completed, the operation posture of the crank mechanism 14 is in a state where the force expansion rate exceeds “1”, more preferably the force expansion rate exceeds “2”.

  When entering the pressure increasing process, the system controller 38 switches the control of the electric servomotor 36 for injection via the servo amplifier 39 from speed feedback control along the position axis to pressure feedback control along the time axis. The pressure increasing process in the die casting machine corresponds to a pressure holding process in plastic injection molding. In this pressure-increasing step, the injection electric servomotor 36 is driven by the pressure feedback control along the time axis via the servo amplifier 39 based on a command from the system controller 38. When the driving shaft 31 of the crank mechanism 14 is adaptively rotationally driven through 37, a large pressure increase is applied to the molten metal 25 or the metal 25 that has started to solidify by the injection plunger 19. In this embodiment, the pressure setting in the pressure-increasing step can be set in multiple stages along the time axis with the number of stages desired by the user and the pressure. It is designed to be feedback controlled. That is, in the pressure increasing step, the injection electric servomotor 36 is driven and controlled by pressure feedback control along the time axis while monitoring the detection output S2 from the strain sensor of the load cell unit 15 and monitoring, thereby increasing the pressure. The process is executed, and a pressure following the pressure setting along the time axis is output. In this pressure-increasing injection process, a large pressure is continuously applied to the metal 25 where the injection plunger 19 has started to solidify, and as the metal 25 solidifies and contracts, the injection plunger 19 is only a minute amount from the position at the time of completion of high-speed injection. Move forward slightly. And the system controller 38 will switch a process to a cooling process, if the completion timing of a pressure increase injection process is recognized based on time monitoring. FIG. 1 shows a completed state of the pressure increasing step. In FIG. 1, reference numeral 25a denotes a biscuit in the tip of the injection sleeve 17. In addition, the expansion rate of the force of the crank mechanism 14 in FIG. 1 is not infinite, but is an extremely large expansion rate.

  In the above-described pressure increasing process, the operating region of the crank mechanism 14 is a region where the power expansion rate exceeds “1”, more preferably exceeds “2”. Therefore, in the pressure increasing region, the crank mechanism 14 By functioning as a pressure-increasing mechanism, rapid start-up to a high pressure can be easily achieved. Further, even if the electric servomotor 36 for injection having a relatively small capacity is used, a large pressure increase can be easily obtained.

  Next, the holding block position adjusting mechanism will be described with reference to FIGS. 1 and 6. FIG. 6 is an explanatory view showing the configuration of the holding block position adjusting mechanism as viewed from the direction orthogonal to FIG. 1, and in FIG. 6, the holding block 9 is drawn separately on the left and right, Actually, the holding block 9 is a structure that is integrally connected as a whole. All the components shown in FIG. 6 are the components described above with reference to FIG.

  Prior to the casting operation, when the position of the holding block 9 is adjusted, the driving block 22 and the intermediate gear are rotated by rotating the holding block position adjusting motor 21 mounted on the holding block 9 by a predetermined amount of rotation in a predetermined direction. 23, the geared nuts 24 are rotated in a predetermined direction in synchronism with a predetermined rotation amount. As a result, the nuts with gears 24 screwed into the threaded portions of the connecting shafts 11 move in the axial direction with respect to the connecting shafts 11, and the holding blocks 9 that hold the nuts with gears 24 rotatably are placed. Move forward or backward by a fixed amount. When the holding block 9 moves forward or backward in this manner, the distance between the fixed die plate 2 and the holding block 9, that is, between the fixed die plate 2 and the driving shaft 31 that is the input end of the force of the crank mechanism 14. The distance will change. Such position adjustment of the holding block 9 is performed according to the injection filling condition of the molten metal such as a mold shape, and the distance between the fixed die plate 2 and the driving shaft 31 of the crank mechanism 14 is the injection of the molten metal. It is set to a suitable value according to the filling conditions.

  The significance of the position adjustment of the holding block 9 will be described with reference to FIGS. FIG. 7 shows the positions of the injection plunger 19 before the low-speed injection process and the injection plunger 19 before the high-speed injection process in three cases in which the distance between the fixed die plate 2 and the driving shaft 31 of the crank mechanism 14 is different. The left side of FIG. 7 shows the state before the low speed injection process, and the right side of FIG. 7 shows the state before the high speed injection process. In FIG. 7, the injection filling amount into the mold is assumed to be the same for the sake of simplicity of explanation.

  7A shows a case where the distance between the fixed die plate 2 and the driving shaft 31 of the crank mechanism 14 is longer than the reference value, and FIG. FIG. 7C shows the case where the distance between the driving shaft 31 of the crank mechanism 14 is a reference value, and FIG. 7C shows the distance between the fixed die plate 2 and the driving shaft 31 of the crank mechanism 14 being a reference value. The shorter case is shown.

Changing the distance between the fixed die plate 2 and the driving shaft 31 of the crank mechanism 14 means that the position of the injection plunger 19 relative to the injection sleeve 17 (tip position) before the low-speed injection process, as shown on the left side of FIG. In FIG. 7A, P _A1 indicates the tip position of the injection plunger 19 before the low speed injection process, and in FIG. 7B, P _S1 indicates the low speed injection process. The tip position of the previous injection plunger 19 is shown. In FIG. 7C, P _B1 shows the tip position of the injection plunger 19 before the low speed injection process. When the low-speed injection process is performed at the top, middle, and bottom of FIG. 7, the injection filling amount into the mold is all the same here, so that the low-speed viewed at the tip position of the injection plunger 19 with respect to the injection sleeve 17. The start position of the high-speed injection process viewed from the completion position of the injection process, that is, the tip position of the injection plunger 19 with respect to the injection sleeve 17 is the same position in the upper, middle and lower parts of FIG. That is, in (a) of FIG. 7, the start position _{P A2} next to high-speed injection step by the injection plunger 19 from the start position _{P A1} of the low-speed injection step distance _{L A} is advanced, in FIG. 7 (b), the low-speed The injection plunger 19 moves forward from the start position P _S1 of the injection process by the distance L _{S to} become the start position P _S2 of the high speed injection process. In FIG. 7C, the distance L _B from the start position P _B1 of the low speed injection process. Only when the injection plunger 19 moves forward, the start position P _B2 of the high-speed injection process is reached. When the high-speed injection process is performed at the top, middle, and bottom of FIG. 7, the injection filling amount into the mold is all the same here, so that the injection plunger 19 is seen at the tip position of the injection sleeve 17. The completion position of the high-speed injection process, that is, the start position of the pressure increasing process viewed from the tip position of the injection plunger 19 with respect to the injection sleeve 17 is the same position in the upper, middle and lower parts of FIG. That is, by moving forward by the same distance from the start positions P _A2 , P _{S2, and} P _{B2 of} the high-speed injection process, the pressure increase process start positions P _A3 , P _S3 , and P _B3 are obtained.

Here, in the upper, middle, and lower sides of FIG. 7, the start position of the high-speed injection process as viewed from the tip position of the injection plunger 19 with respect to the injection sleeve 17 is the same, but the start positions P _A2 , P _S2, The forward strokes of the injection plunger 19 up to P _B2 are different, and therefore the operation postures at the start of the high-speed injection process as seen by the crank mechanism 14 are different.

  FIG. 8 shows speed ratio characteristic lines drawn so as to correspond to (a), (b), and (c) of FIG. 7. In FIG. 8, the horizontal axis represents the tip of the injection plunger 19. The position (which corresponds to the position of the output end of the force of the crank mechanism 14) is shown, and the vertical axis shows the speed ratio. In FIG. 8, the speed ratio characteristic indicated by a one-dot chain line corresponds to (a) in FIG. 7, and the speed ratio characteristic indicated by a solid line corresponds to (b) in FIG. The ratio characteristic corresponds to (c) of FIG.

  As is clear from FIG. 8, in the case of FIG. 7A, the operating posture of the crank mechanism 14 at the start of the high-speed process injection is the largest, and the speed ratio of FIG. In this case, the operation posture of the crank mechanism 14 at the time of starting the high-speed injection process is smaller than that in the case of FIG. 7A, and in the case of FIG. As for the operation posture of the crank mechanism 14 at, the speed ratio is the smallest. Therefore, in (a), (b), and (c) of FIG. 7, it becomes easy to make a difference in characteristics at the time of starting the high-speed injection process, and the molten metal such as a mold shape is obtained. It is possible to perform a suitable high-speed injection process according to the injection filling conditions.

  FIGS. 7 and 8 are schematic views for helping understanding of the present invention, and the distance between the fixed die plate 2 and the force input end (the driving shaft 31) of the crank mechanism 14 is variably set. By doing so, it is possible to set the operation posture of the crank mechanism 14 at a desired time at the start of the high-speed injection process, that is, start the high-speed injection process from a desired position in the speed ratio characteristic line of the crank mechanism 14 It should be understood that it is possible to show that

As described above, in the present embodiment, the injection plunger 19 is linearly driven by the crank mechanism 14 that is driven by the rotational force of the electric servomotor 36 for injection and whose force expansion rate and speed change according to the operating position. In the high-speed injection region, the high-speed injection step is executed in a region where the speed in the operation region of the crank mechanism 14 is high, and the pressure-increasing step is executed in a region where the force expansion rate in the operation region of the crank mechanism 14 is large. Since the crank mechanism 14 functions as a speed increasing mechanism, rapid startup to a high speed can be easily performed, and the crank mechanism 14 functions as a force expanding mechanism (that is, a pressure increasing mechanism) in the pressure increasing process. This makes it possible to quickly start up to a high pressure easily and obtain a large pressure increase even with a relatively small capacity motor. Door is easily possible.
Further, since the distance between the fixed die plate 2 and the force input end (the driving shaft 31) of the crank mechanism 14 is variably set in accordance with the injection filling condition of the molten metal such as the mold shape, prior to the high-speed injection process. The position of the injection plunger 19 at the start of the low-speed injection process can be set to an arbitrary position, and thereby the advance stroke of the injection plunger 19 from the start of the low-speed injection process to the disclosure of the high-speed injection process can be arbitrarily variably set. That is, the high-speed injection process can be started from a desired position on the speed ratio characteristic line of the crank mechanism 14 by setting the operation posture of the crank mechanism 14 at the start time of the high-speed injection process to a desired state. Therefore, the high-speed injection process can be started from the desired position of the speed ratio characteristic line in the crank mechanism 14 in accordance with the injection filling condition of the molten metal such as the mold shape. Suitable casting can be performed adaptively.
Further, the injection mechanism by the crank mechanism 14 converts the rotation of the electric servo motor into a linear motion once by the ball screw mechanism, and drives the toggle link mechanism such as the double toggle link mechanism by the linear motion part of the ball screw mechanism, thereby The structure is much simpler than the configuration that performs the above.

In the die-casting machine concerning one embodiment of the present invention, it is the explanatory view which simplified and showed a part fracture mainly showing the composition of the injection system. It is explanatory drawing which shows the structure which looked at the crank mechanism in the die-casting machine which concerns on one Embodiment of this invention from the direction orthogonal to FIG. 1, and the drive system of a crank mechanism. It is explanatory drawing which shows the outline of the characteristic of the speed ratio characteristic and the force expansion rate in the crank mechanism used with the die-casting machine which concerns on one Embodiment of this invention. In the die-casting machine concerning one embodiment of the present invention, it is the explanatory view which simplified and showed a part fracture mainly showing the composition of the injection system. In the die-casting machine concerning one embodiment of the present invention, it is the explanatory view which simplified and showed a part fracture mainly showing the composition of the injection system. It is explanatory drawing which shows the structure which looked at the position adjustment mechanism of the holding block in the die-casting machine which concerns on one Embodiment of this invention from the direction orthogonal to FIG. In the die-casting machine according to an embodiment of the present invention, the position of the injection plunger before the low-speed injection process and the injection before the high-speed injection process in three cases where the distances between the fixed die plate and the driving shaft of the crank mechanism are different. It is explanatory drawing which shows the position of a plunger. It is explanatory drawing which shows the outline | summary of the characteristic line of the speed ratio of a crank mechanism drawn corresponding to (a), (b), (c) of FIG. It is explanatory drawing which shows the example of control of the speed in a low-speed injection process, a high-speed injection process, and a pressure increase process in a die-casting machine. It is explanatory drawing which simplified and partly fractured | ruptured mainly showing the structure of the injection system in the conventional electric die-casting machine.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Base member 2 Fixed die plate 3 Fixed side metal mold | die 4 Movable die plate 5 Movable side metal mold | die 6 Cavity 7 Mold runner part (a sprue gate part etc.)
8 Rail member 9 Holding block 10 Linear motion guide 11 Connection shaft 12 Linear motion body 13 Linear motion guide 14 Crank mechanism (link mechanism)
15 Load Cell Unit 16 Holding Piece 17 Injection Sleeve 18 Pouring Port 19 Injection Plunger 20 Position Sensor 21 Holding Block Position Adjustment Motor 22 Drive Gear 23 Intermediate Gear 24 Geared Nut 25 Metal Molten Metal or Metal that has Begun to Solidify 25a Biscuit 31 Driving Shaft 32 First arm 33 Connecting shaft 34 Second arm 35 Rotating shaft 36 Electric servo motor for injection 37 Deceleration rotation transmission mechanism 38 System controller 39 Servo amplifier

Claims (3)

The electric servo motor is used as the drive source for injection, and the electric servo is used so that an injection process consisting of a low-speed injection process and a subsequent high-speed injection process and a pressure increasing process following the high-speed injection process are performed in the product casting process. A die-casting machine for driving and controlling a motor,
The ratio of the force acting on the input end of the link member and the force acting on the output end according to the operating position of the link member connected to the drive shaft is rotated at a constant speed by the electric servo motor. A link mechanism in which a force expansion ratio and a speed ratio that is a ratio of a moving speed of an input end and an output end of the link member change, and an injection that is linearly driven in the injection sleeve by the link mechanism A plunger,
The high-speed injection step is executed in a region where the speed ratio in the operation region of the link mechanism exceeds “1”, and the pressure increasing step is performed in a region where the force expansion rate in the operation region of the link mechanism exceeds “1”. Die-casting machine that is characterized by being executed in In the die casting machine according to claim 1,
A die casting machine characterized in that the distance between the fixed die plate and the force input end of the link mechanism is variably set according to the injection filling condition of the molten metal. In the die-casting machine according to claim 2,
A holding block that is disposed opposite to the fixed die plate and is capable of variably setting a position with respect to the fixed die plate;
A plurality of connecting shafts in which the fixed die plate and the holding block are connected, and a geared nut rotatably held by the holding block is screwed to a screw portion formed on a side penetrating the holding plate. When,
A holding block position adjusting motor mounted on the holding block and rotationally driving the geared nut via a transmission gear train;
A linear motion block that is linearly driven by the link mechanism and linearly transported integrally with the injection plunger;
Wherein the link mechanism includes a rotatably retained original shaft to the holding block-side, a first arm whose one end is rotated integrally with the driving shaft as the center of rotation of the driving shaft, one end is the first A die casting comprising a crank mechanism having a second arm connected to the other end of one arm so as to be relatively rotatable and having a second arm connected to the other side of the linear motion block so as to be relatively rotatable. Machine.

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