JP2008062446A - Injection molding machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the operational reliability and durability of a crank mechanism in an injection molding machine equipped with the crank mechanism in which its power part is rotated/driven by the torque of a mold clamping servomotor. <P>SOLUTION: The constitution is provided with a pair of first arms which are held rotatably by respective tailstocks each on one end side and arranged coaxially and second arms which keep one end side are connected relatively rotatably to the other end side of each of the pair of the first arms, respectively, and the other end side connected relatively rotatably to the holding part of a movable die plate. The rotation of the mold clamping servomotor is transmitted simultaneously to the one end side of a pair of the first arms. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an injection molding machine including a crank mechanism (a mold clamping mechanism) in which a driving portion thereof is rotationally driven by a rotational force of a servo motor for mold clamping.

  A mold clamping mechanism comprising a crank mechanism capable of performing crank motion by rotationally driving the driving portion and transmitting the force to an action point is known. The mold clamping mechanism including the crank mechanism is configured to open and close the mold by converting the rotation of the servo motor for mold clamping into a linear motion once by the ball screw mechanism and driving the toggle link mechanism by the linear motion portion of the ball screw mechanism. Compared to the configuration, the maximum clamping force is small, but the structure is much simpler.

  FIG. 6 is a simplified cross-sectional side view of a principal part, omitting a part, showing a conventional crank mechanism (clamping mechanism) and a decelerating rotation transmission system for transmitting rotation thereto.

  In FIG. 6, reference numeral 101 denotes a tail stock. In FIG. 6, the tail stock 101 is depicted as being separated on the left and right, but in reality, the tail stock 101 is a structure in which the whole is integrally connected. Yes. Reference numerals 102A and 102B denote a pair of first rotation shafts rotatably held on the tailstock 101 via bearings 103. The first rotation shafts 102A and 102B forming a pair have their rotation centers on the same line. Has been placed. One end sides of the first arms 104A and 104B are fixed to the first rotating shafts 102A and 102B, respectively, and the other end sides of the pair of first arms 104A and 104B are integrated with each other. The connecting shaft 105 that is coupled to is fixed. One end side of the second arm 106 is rotatably held at the intermediate portion of the connecting shaft 105 via the bearing 103, and the other end side of the second arm 106 is not shown, but the movable side mold Is fixed to a second rotating shaft that is rotatably held via a bearing on a movable die plate. A pair of first arms 104A and 104B, a single second arm 106, and their rotation shaft support portions constitute a crank mechanism. As described above, one pair of first arms 104A and 104B is provided with one end of one second arm 106 held and coupled to the other end of the pair of first arms 104A and 104B. In order to make the mechanism for supporting the force well balanced and excellent in mechanical strength, the extension line of the rotation center of the first rotation shafts 102A and 102B is formed on the second arm 106. The two first rotation axes are independent of each other for convenience of overlapping with the rotation locus.

  In FIG. 6, 107 is a mold clamping servomotor (mold opening / closing servomotor) mounted on the tailstock 101, 108 is a small-diameter drive pulley fixed to the output shaft of the mold clamping servomotor 107, Reference numeral 109 denotes a large-diameter driven pulley that is fixed to one first rotating shaft 102A and that transmits the rotation of the driving pulley 108 (the mold clamping servomotor 107) via a timing belt (not shown). The drive pulley 108, the timing belt (not shown), and the driven pulley 109 constitute a reduced rotation transmission system.

  In the configuration shown in FIG. 6, the rotation of the mold clamping servo motor 107 is decelerated by a decelerating rotation transmission system including a driving pulley 108, a timing belt (not shown), and a driven pulley 109, and transmitted to one first rotating shaft 102 </ b> A. Then, the first arm 104A, whose one end is fixed to the one first rotating shaft 102A, is rotationally driven with its one end as the center of rotation. As a result, the second arm 106 follows the rotation of one of the first arms 104A to perform a cooperative follow-up operation (the second arm 106 linearly moves the other end side that is pivotally coupled to the movable die plate. The first arm 104B follows the rotation of the first arm 104A and follows the rotation of the first arm 104A. Integrally rotate with one end side as the center of rotation. By such an operation, a movable die plate (not shown) is driven forward or backward to perform mold closing / clamping or mold opening.

  That is, as described above, in the mold clamping mechanism including the conventional crank mechanism, only one of the paired first rotating shaft and the paired first arm (the first rotating shaft 102A and the first arm 104A) is used. A one-side drive type (single-axis drive type) crank mechanism that rotationally drives and rotationally drives the other first arm 104B and the first rotary shaft 102B from one first arm 104A via the connecting shaft 105 was adopted. .

In addition, as a prior art regarding the injection molding machine having the above-described one-side drive type crank mechanism, there is a technique disclosed in JP-A-1-280521 (Patent Document 1). However, in this patent document 1, the structure which directly connected the rotor of the servomotor to one 1st rotating shaft is taken.
JP-A-1-280521

  Incidentally, in the prior art shown in FIG. 6 and the prior art disclosed in Patent Document 1, as described above, only one of the paired first rotating shaft and the paired first arm is rotationally driven. And the structure of the crank mechanism of the one side drive system (single axis drive system) which rotationally drives the other 1st arm and the 1st rotating shaft via the connecting shaft from one 1st arm is taken. However, in such a one-side drive type crank mechanism, the other first arm or the first rotating shaft is not driven directly, but rotates following it, so that a minute clearance within the tolerance of the rotating shaft support portion is obtained. Unnecessary component force is likely to be generated due to, etc., and the transmission of force to the second arm is unbalanced. In addition, there is a problem in terms of durability.

  In the prior art shown in FIG. 6, the rotation of the servo motor for opening and closing the mold is transmitted to the driving part of the crank mechanism via the speed reduction rotation transmission system composed of the pulley and the timing belt. Since the transmission system is simply configured to perform one-stage deceleration, there is a limit to performing a larger deceleration, and there is a limit to using a lower torque mold opening / closing servomotor.

  The present invention has been made in view of the above points. An object of the present invention is to provide an injection molding machine including a crank mechanism (clamping mechanism) in which a driving portion thereof is rotationally driven by the rotational force of a mold clamping servomotor. Is to improve the operational reliability and durability of the crank mechanism.

In order to achieve the above-described object, the present invention provides a pair of first arms that are rotatably held on the tailstock with one end side as a rotation center, and are arranged so that the rotation centers are on the same line. The one end side is coupled to the other end side of the pair of first arms so as to be relatively rotatable, and the other end side is coupled to the holding portion of the movable die plate so as to be relatively rotatable. In the configuration provided with the second arm, the rotation of the servomotor for clamping is simultaneously transmitted to one end side of the pair of first arms.
Further, the rotation of the mold clamping servomotor is simultaneously transmitted to one end side of the pair of first arms via a deceleration rotation transmission system including a pulley and a timing belt, and the deceleration rotation transmission system performs two-stage deceleration. Configure as follows.

In the present invention, a pair of first arms that are rotatably held on the tailstock with the one end side as a rotation center, and arranged so that the rotation centers are on the same line, and one end side is a pair of A second arm coupled to the other end of the first arm so as to be relatively rotatable, and a second arm coupled to the other end of the first arm so as to be relatively rotatable. In the configuration, the rotation of the servomotor for clamping is simultaneously transmitted to one end of the pair of first arms, that is, one end of each first arm that is the center of rotation of the paired first arms. The drive mechanism of the crank mechanism of the twin drive system (both shaft drive system), in which each part is directly rotated and driven simultaneously by the mold clamping servo motor via the reduced speed rotation transmission system, so one side drive method Compared to the conventional crank mechanism, the force can be transmitted to the second arm evenly from the transmission path of the two forces. Compared with the conventional mechanism, there is a possibility that uneven wear or looseness may occur in the rotating shaft support. Therefore, a crank mechanism having excellent operational reliability and durability can be realized.
In addition, since the rotation of the mold clamping motor is decelerated by the deceleration rotation transmission system that performs two-stage deceleration, the rotation of the mold clamping motor is less than that of the deceleration rotation transmission system that performs one-stage deceleration. Thus, it is possible to use a high-rotation low-torque motor that is much cheaper than a low-rotation high-torque motor.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 to 4 relate to an electric injection molding machine according to an embodiment of the present invention (hereinafter referred to as the present embodiment), and FIG. 1 is a simplified and partial view of the injection molding machine of the present embodiment. It is the front view which cut | disconnected.

  In FIG. 1, 1 is a main frame member, 2 is an injection system mechanism disposed on the right side when viewed from the front on the main frame member 1, and 3 is a mold disposed on the left side when viewed from the front on the main frame 1. It is an open / close system mechanism.

  In the injection system mechanism 2, 4 is fixed to the main frame member 1 via an appropriate base member, and the rail member 5 that supports the entire injection system mechanism 2 so as to be able to move forward and backward is provided on the rail member 4. The head stock 7 fixed on the linear guide 6 slidably interposed is fixed on the linear guide 8 slidably mounted on the rail member 4, and the load cell block 9 The holding block 10 fixed to the head stock 5 is fixed on a linear motion guide 11 slidably mounted on the rail member 4 so as to be able to move forward and backward with respect to the head stock 5. The moving block 12 is a heating cylinder whose rear end is fixed to the headstock 5, 13 is a nozzle fixed to the leading end of the heating cylinder 12, and 14 is rotated and moved forward in the heating cylinder 12. The screw 15, which can be moved forward, fixes the rear end of the screw 14, and the rotating body 16 rotatably held by the linear motion block 10. The rotation of a measuring servo motor (not shown) mounted on the block 10 is transmitted via a drive pulley (not shown) and a timing belt, 17 is a driven pulley, 17 is an injection servo motor mounted on the holding block 7, 18 Is a drive pulley fixed to the output shaft of the injection servo motor 17, 19 is a driven pulley that transmits the rotation of the injection servo motor 17 via a drive pulley 18, a timing belt (not shown), and 20 is a driven pulley. A ball screw mechanism 20a for converting the rotation of the pulley 19 into a linear motion is rotatably held by the holding block 7, and a bolt having a driven pulley 19 fixed to the end thereof. Threaded shaft of ball screw mechanism 20, 20b, together with the screwed to the screw shaft 20a, a nut of the ball screw mechanism 20 fixed to the linear motion block 10.

  In the injection system mechanism 2 shown in FIG. 1, during the molding operation, the nozzle 13 at the tip of the heating cylinder 12 is fixed to a fixed die plate 21 described later by a nozzle touch / back motor and a nozzle touch / back mechanism (not shown). It is pressed with a predetermined force around the resin inlet of a fixed mold (not shown). In such a nozzle touch state, at the time of the metering process, the screw 14 is rotationally driven by a metering servo motor (not shown), whereby the raw material resin supplied to the base side of the screw 14 is kneaded and plasticized. The screw 14 is transferred to the head side of the screw 14 by the screw feeding action, and the screw 14 moves backward as the molten resin is accumulated before the head of the screw 14 (first). When the screw 14 is retracted, the injection servomotor 17 is subjected to pressure feedback control to control the back pressure, and when a predetermined amount of molten resin is accumulated (before) the head of the screw 14. The screw rotation is stopped. Further, at the time of injection, the injection servomotor 17 is rotationally driven, so that the nut body 20b of the ball screw mechanism 20 is driven forward, whereby the screw 14 is driven forward integrally with the linear motion block 10, Molten resin stored prior to the head of the screw 14 is injected and filled into the mold.

  In the mold opening / closing system mechanism 3 shown in FIG. 1, 21 is fixed to the main frame member 1 through an appropriate base member, and a fixed die plate on which a fixed mold (not shown) is mounted, The rail member 23 fixed on the frame member 1 via an appropriate base member is fixed on a linear motion guide 24 slidably mounted on the rail member 22, and the fixed position is maintained during the molding operation. The tail stock 25 is fixed to a plurality of tie bars fixed at both ends to the fixed die plate 21 and the tail stock 23, and 26 is fixed to a linear guide 27 slidably mounted on the rail member 22. The movable die that is inserted and guided by the tie bar 25 and can be moved back and forth between the fixed die plate 21 and the tailstock 23, and is mounted with a movable mold (not shown). 28, a mold clamping servomotor (mold opening / closing servomotor) mounted on the tailstock 23, and 29 a rotational drive of the driving portion by the rotational force of the mold clamping servomotor 28. This is a crank mechanism that drives the movable die plate 26 forward and backward.

  The crank mechanism 29 functions as a mold clamping mechanism, and the rotation of the mold clamping servo motor 28 is transmitted through a deceleration rotation transmission system. After the mold closing process, the movable die plate 26 is fixed to the fixed die. The force to advance toward the plate 21 side is expanded, and a clamping force of about 30 to 50 tons can be expressed in the clamping state.

  Hereinafter, the details of the crank mechanism 29 will be described. FIG. 2 is a simplified side cross-sectional view showing a crank mechanism 29 and a reduced rotation transmission system for transmitting rotation to the crank mechanism 29, and FIG. 3 is a reduced rotation for transmitting rotation to the crank mechanism 29. It is a principal part front view which shows a transmission system.

  2 and 3, reference numeral 23 a denotes a pair of support plate portions integrated with the tail stock 23. In FIG. 2, the tail stock 23 is drawn separately on the right and left sides. The tail stock 23 is a structure that is integrally connected as a whole. 31 is a pair of first rotating shafts rotatably supported on the tailstock 23 via a rolling bearing 32 containing a solid lubricant. The rotation centers of the paired first rotating shafts 31 are on the same line. Arranged to be. One end side of the first arm 33 is fixed to one end side of each first rotating shaft 31, and the other end sides of the pair of first arms 33 are integrally coupled to each other. The connecting shaft 34 is fixed. One end of the second arm 35 is rotatably held at the intermediate portion of the connecting shaft 34 via a rolling bearing 32 containing a solid lubricant, and the other end of the second arm 35 is connected to the movable die plate 26. The bulging portion 26a is fixed to a second rotary shaft 36 rotatably held via a rolling bearing 32 containing a solid lubricant. The pair of first arm 33, single second arm 35, and their rotation shaft support portions constitute a crank mechanism 29. Each rotation shaft support portion of the crank mechanism 29 (four rotation shaft support portions). The rolling bearing 32 containing a solid lubricant is used. The details of the rolling bearing 32 containing the solid lubricant will be described later.

  2 and 3, reference numeral 37 denotes a small-diameter drive pulley fixed to the output shaft of the above-described mold clamping servomotor 28 mounted on the tailstock 23. Reference numeral 38 denotes a rotating shaft rotatably supported on the tailstock 23 via a bearing 39. A first intermediate pulley 40 having a diameter larger than that of the drive pulley 37 is fixed to the rotating shaft 38. A timing belt 41 is wound around the intermediate pulley 40 and the drive pulley 37. Reference numeral 42 denotes a second intermediate pulley that is fixed to both ends of the rotary shaft 38 and forms a pair having a smaller diameter than the first intermediate pulley 40. Reference numeral 43 denotes the other end of the first rotary shaft 31 that forms the above pair. Timing belts 44 are respectively wound around second intermediate pulleys 42 and driven pulleys 43 corresponding to fixed large-diameter driven pulleys. The drive pulley 37, the timing belt 41, the first intermediate pulley 40, the rotary shaft 38, the second intermediate pulley 42, the timing belt 44, and the driven pulley 43 constitute a reduced rotation transmission system.

  In the mold opening / closing system mechanism 3 having the deceleration rotation transmission system and the crank mechanism 29 described above, the mold clamping servomotor 28 is driven to rotate in a predetermined direction during the mold closing / clamping process, and the rotation of the mold clamping servomotor 28 is performed. Is transmitted to the first intermediate pulley 40 via the drive pulley 37 and the timing belt 41, and the rotation of the first intermediate pulley 40 is driven via the rotary shaft 38, the second intermediate pulley 42, and the timing belt 44. Thus, the paired first rotating shafts 31 (the paired first rotating shafts 31 that are the driving shafts of the crank mechanism 29) are simultaneously driven to rotate. When the paired first rotating shafts 31 are rotationally driven, the paired first arms 33 are simultaneously rotated in a predetermined direction around the first rotating shaft 31, Accordingly, the second arm 35 follows a predetermined cooperative tracking operation (following the rotation of the first arm 33 so that the second arm 35 linearly moves the other end fixed to the second rotating shaft 36). With the movement of the second arm 35, the movable die plate 26 is driven forward in the direction toward the fixed die plate 21, and the mold touch is performed. Even after the mold is touched, the mold clamping servomotor 28 is rotationally driven in the same direction by a predetermined amount, and the crank mechanism 29 functions as a toggle mechanism, so that an enlarged force is applied to the mold, and the predetermined mold clamping is performed. When the force is generated, the rotation of the servomotor 28 for mold clamping is stopped and the mold clamping is completed. Further, during the mold opening process, the mold clamping servomotor 28 is driven to rotate in the direction opposite to the previous direction, and the rotation of the mold clamping servomotor 28 is paired via the same reduced rotation transmission system. This is transmitted to the shaft 31, whereby the crank mechanism 29 is driven in the opposite direction, and the movable die plate 26 is driven backward in the direction away from the fixed die plate 21.

  Next, the structure of the rolling bearing 32 containing a solid lubricant used for each rotation shaft support portion (four rotation shaft support portions) of the crank mechanism 29 will be described. FIG. 4 is a cross-sectional view of the rolling bearing 32 containing a solid lubricant used in the present embodiment.

  As shown in FIG. 4, the rolling bearing 32 containing a solid lubricant includes an outer ring 51, a plurality of needle rollers (needle rollers) 52, and a solid lubricant 53. A plurality of needle rollers 52 are rotatably arranged so as to be embedded in a solid lubricant 53 deposited on the inner peripheral surface side with a uniform thickness. Only a part of each needle roller 52 is exposed from the solid lubricant 53, and the first rotating shaft 31, the connecting shaft 34, or the second rotating shaft 36 is in contact with the exposed portion of each needle roller 52. However, it is fitted into the rolling bearing 32 containing the solid lubricant. The solid lubricant 53 is formed by heat-treating a mixture of fine polymer polyolefin resin and lubricating oil (grease) and solidifying the needle roller 52 as the rotating member rotates. Therefore, the lubricating oil oozes out over a long period only by an appropriate amount (that is, so as to ensure smooth rotation and prevent oil leakage). Therefore, by using the rolling bearing 32 containing the solid lubricant for each rotating shaft support portion of the crank mechanism 29, the rotational motion can be stabilized without lubrication for a very long time (even under a very long continuous operation). It can be supported. In addition, it has excellent cleanliness and requires no refueling, so the running cost can be reduced.

  As described above, in the injection molding machine according to this embodiment, the paired first rotating shaft 31 and the paired first arm 33 are simultaneously and directly rotated by the mold clamping servomotor 28 via the reduction rotation transmission system. The drive mechanism of the twin drive system (both shaft drive system) crank mechanism is adopted. For this reason, compared with the crank mechanism of the one-side drive system (single-axis drive system), the transmission of force to the second arm 35 can be performed equally from the transmission path of the two forces, and the rotation shaft support portion can be compared with the conventional one. Therefore, it is possible to reduce the possibility of occurrence of uneven wear and backlash as much as possible, thereby realizing a crank mechanism having excellent operational reliability and durability.

  In this embodiment, the rotation of the mold clamping servomotor 28 is first decelerated by the first-stage decelerating system including the driving pulley 37, the timing belt 41, and the first intermediate pulley 40, and then the second intermediate pulley 42, the timing. The speed is further reduced by a second-stage reduction system comprising the belt 44 and the driven pulley 43, and the rotation of the mold clamping servomotor 28 can be greatly reduced by such a two-stage reduction. Therefore, it is possible to easily reduce the number of rotations to about 1/3 to 1/4 compared with a one-stage reduction system. However, it is possible to use a high rotation low torque motor which is much cheaper than a low rotation high torque motor.

  Note that the configuration of the twin drive system (both shaft drive system) crank mechanism of the above-described embodiment is one example, and various modifications are possible without departing from the spirit of the present invention. Needless to say, it is included in the scope of the present invention.

  For example, in the above-described embodiment, the other ends of the paired first arms 33 are integrally coupled by the connecting shaft 34, but the connecting shaft 34 is fixed to one end of the second arm 35. It may be. FIG. 5 is a view corresponding to FIG. 2 showing a modified example of the above-described embodiment. In FIG. 5, the same reference numerals are given to the components equivalent to the above-described embodiment. The configuration shown in FIG. 5 is different from the previous configuration in that the central portion of the connecting shaft 34 is fixed to one end side of the second arm 35, and both sides of the connecting shaft 34 form a pair of pairs. The other end of the first arm 33 is rotatably held via a rolling bearing 32 containing a solid lubricant, and other configurations are the same as those of the above-described embodiment.

  In the embodiment described above and the modification shown in FIG. 5, the other end of the second arm 35 is fixed to a second rotating shaft 36 that is rotatably held on the movable die plate 26 side. However, instead of the second rotating shaft 36, a fixed shaft fixed to the movable die plate 26 side is provided, and the other end side of the second arm 35 with respect to the fixed shaft is interposed via a rolling bearing 32 containing solid lubricant. And may be configured to be rotatable.

  In the above-described embodiment and the modification shown in FIG. 5, the first rotating shaft 31 and the first arm 33 are separate members, but the first rotating shaft 31 and the first arm 33 may be integrated. Similarly, the second arm 35 and the second rotation shaft 36 may be integrated as one unit instead of separate members. Alternatively, the connecting shaft 34 may be formed integrally with the first arm 33 or formed integrally with the second arm 35.

  Furthermore, as the bearing used for the rotating shaft support portion of the crank mechanism 29, any rolling bearing or sliding bearing can be used in addition to the rolling bearing 32 containing the solid lubricant.

It is the front view which simplified and partially cut off the injection molding machine which concerns on one Embodiment of this invention. It is the simplified principal part cutaway side view which omitted the part which shows the crank mechanism and the deceleration rotation transmission system which transmits rotation to it in the injection molding machine which concerns on one Embodiment of this invention. It is a principal part front view which shows the deceleration rotation transmission system etc. which transmit rotation to the crank mechanism in the injection molding machine which concerns on one Embodiment of this invention. In the injection molding machine which concerns on one Embodiment of this invention, it is sectional drawing of the rolling bearing containing a solid lubricant used for each rotating shaft support part of a crank mechanism. It is the simplified principal part cutaway side view which omits one part which shows the crank mechanism and the deceleration rotation transmission system which transmits rotation to it in the injection molding machine which concerns on the modification of one Embodiment of this invention. It is the simplified principal part section side view which omitted the one part which shows the crank mechanism by the prior art, and the deceleration rotation transmission system which transmits rotation to it.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Main frame member 2 Injection system mechanism 3 Type | mold opening / closing system mechanism 4 Rail member 5 Headstock 6 Linear motion guide 7 Holding block 8 Linear motion guide 9 Load cell block 10 Linear motion block 11 Linear motion guide 12 Heating cylinder 13 Nozzle 14 Screw 15 Rotation Body 16 Driven pulley 17 Injection servo motor 18 Drive pulley 19 Driven pulley 20 Ball screw mechanism 20a Screw shaft of ball screw mechanism 20b Nut body of ball screw mechanism 21 Fixed die plate 22 Rail member 23 Tail stock 23a Tail stock support plate 24 Direct motion Guide 25 Tie bar 26 Movable die plate 26a Swelling portion 27 Linear motion guide 28 Servo motor for mold clamping (servo motor for mold opening / closing)
DESCRIPTION OF SYMBOLS 29 Crank mechanism 31 1st rotating shaft 32 Rolling bearing containing solid lubricant 33 1st arm 34 Connection shaft 35 2nd arm 36 2nd rotating shaft 37 Drive pulley 38 Rotary shaft 39 Bearing 40 First intermediate pulley 41 Timing belt 42 First 2 intermediate pulley 43 driven pulley 44 timing belt 51 outer ring 52 needle roller (needle roller)
53 Solid lubricant

Claims (3)

In an injection molding machine equipped with a crank mechanism driven by the rotational force of a servo motor for mold clamping,
A pair of first arms that are rotatably held on the tailstock with the one end side as a rotation center, and arranged so that the rotation centers are on the same line;
The one end side is coupled to the other end side of the pair of first arms so as to be relatively rotatable, and the other end side is coupled to the holding portion of the movable die plate so as to be relatively rotatable. A second arm,
An injection molding machine characterized in that the rotation of the servo motor for clamping is simultaneously transmitted to one end side of the pair of first arms. The injection molding machine according to claim 1,
An injection molding machine characterized in that the rotation of the mold clamping servomotor is simultaneously transmitted to one end side of the pair of first arms via a deceleration rotation transmission system including a pulley and a timing belt. The injection molding machine according to claim 2,
The reduced-speed rotation transmission system performs two-stage deceleration, and is an injection molding machine.

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