JP2006315421A - Injection molding machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To realize a stable molding. <P>SOLUTION: The molding machine comprises an injection frame, a stator, a rotor and a rotary slide member movably in an axial direction radially inward of the rotor. A first lubricant storage room is provided in a space between the molding frame and the rotary slide member, and a second lubricant storage room is provided in communication with the 1st lubricant storage room, and a lubricant is supplied into the 2nd lubricant storage room from the 1st lubricant storage room. A material to be injected can be gone ahead smoothly, whereby injection can be well conducted. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an injection apparatus.

  2. Description of the Related Art Conventionally, in an injection molding machine, a screw is disposed in a heating cylinder of an injection device so as to be rotatable and movable back and forth, and the screw can be rotated or moved forward and backward by driving a drive unit. It can be done. In the metering step, when the screw is rotated, the resin supplied from the hopper into the heating cylinder is heated, melted, advanced, and stored in front of the screw head attached to the front end of the screw. . Further, when the screw is advanced in the injection process, the resin stored in front of the screw head is injected from the injection nozzle and filled in the cavity space of the mold apparatus.

  FIG. 2 is a conceptual diagram of a conventional injection apparatus.

  In the figure, reference numeral 11 denotes a heating cylinder, and a screw 12 is disposed in the heating cylinder 11 so as to be rotatable and to advance and retreat (movable in the left and right direction in the figure). Further, an injection nozzle (not shown) is formed at the front end (left end in the figure) of the heating cylinder 11, and a nozzle port is formed in the injection nozzle.

  A rear end (right end in the figure) of the heating cylinder 11 is attached to a front injection support 61, and a rear injection support 62 is disposed at a predetermined distance from the front injection support 61. The front injection support 61 includes a box-shaped main body 61a and a cover 61b. A rod 63 is installed between the front injection support 61 and the rear injection support 62, and a predetermined distance is maintained between the front injection support 61 and the rear injection support 62 by the rod 63. The front injection support 61, the rear injection support 62, and the rod 63 constitute an injection frame.

  A connecting body 64 having a circular shape is integrally attached to the rear end of the screw 12 via a coupler 59, and a cylindrical support body 65 is attached to the connecting body 64 via a bolt bt1. . The connecting body 64 and the support body 65 constitute a rotary sliding member 68 that is rotated or moved integrally with the screw 12. A male spline 92 is formed on the outer peripheral surface of the rear end of the support 65.

  In order to transmit the rotation to the rotary sliding member 68, a cylindrical rotary member 78 surrounds the rotary sliding member 68 so as to be slidable, and is opposed to the outer peripheral surface of the rotary sliding member 68. A female spline 93 having a length corresponding to the stroke of the screw 12 in the axial direction is formed on the inner peripheral surface of the rotating member 78. The rotating member 78 is rotatably supported by the front injection support 61 by bearings b1 and b2.

  An electric metering motor 70 is arranged, and the metering motor 70 is driven in the metering process to rotate the rotary sliding member 68, and the restraint generated by the metering motor 70 in the injection process. The rotation of the rotary sliding member 68 is stopped by the force (reverse torque). The metering motor 70 is attached to a stator (not shown), a rotor (not shown) disposed radially inward of the stator, an output shaft 74, and the output shaft 74, and detects the rotational speed of the metering motor 70. Encoder 70a is provided. The stator and the rotor are each provided with a core and a coil wound around the core.

  An output gear 75, a counter drive gear 76, a counter driven gear 77, and the rotating member 78 are disposed between the measuring motor 70 and the rotary sliding member 68, and the output gear 75 is connected to the output shaft 74. Then, the output gear 75 and the counter drive gear 76 are engaged with each other, the counter drive gear 76 and the counter driven gear 77 are engaged with each other, and the counter driven gear 77 is attached to the rotating member 78 with the bolt bt3.

  The output gear 75, the counter drive gear 76, the counter driven gear 77, and the rotating member 78 transmit the rotation generated by driving the measuring motor 70 to the rotating sliding member 68. For this purpose, the rotary sliding member 68 is disposed so as not to rotate with respect to the rotating member 78 and to be movable in the axial direction. Are slidably contacted. That is, the female spline 93 and the male spline 92 are slidably engaged with each other.

  Therefore, when the output shaft 74 is rotated by driving the metering motor 70, the rotation is transmitted to the rotary sliding member 68 via the output gear 75, the counter drive gear 76, the counter driven gear 77 and the rotating member 78. The rotary sliding member 68 is rotated in the forward direction or in the reverse direction as necessary, and the screw 12 is rotated. Further, when the driving of the measuring motor 70 is stopped and the output shaft 74 is stopped by the restraining force of the measuring motor 70, the rotation of the rotary sliding member 68 is stopped and the rotation of the screw 12 is also stopped.

  In addition, the ball nut 82 and the ball nut 82 are screwed together behind the front injection support 61 (rightward in the figure), and are rotatable with respect to the ball nut 82 and in the axial direction. A ball screw 83 including a ball screw shaft 81 that is movably supported is disposed. The ball screw shaft 81 includes a small-diameter shaft portion 84, a large-diameter screw portion 85, a connecting portion connected to the electric injection motor 90, and the like sequentially formed from the front end to the rear end. An annular flange member 89 is externally fitted to the step portion of the shaft portion 84 and the screw portion 85.

  The injection motor 90 is fixed to the rear injection support 62 via the load cell 96 and is driven in the injection process, and the rotation generated along with this is transmitted to the ball screw shaft 81. The ball screw 83 converts the rotational motion generated by the rotation of the injection motor 90 into a rectilinear motion associated with the rotation, that is, a rotational rectilinear motion, and the rotational rectilinear motion is transferred to the rotary sliding member 68. introduce.

  Therefore, the ball screw shaft 81 is supported at the front end portion (left end portion in the drawing) by bearings b7 and b8 so as to be rotatable with respect to the rotary sliding member 68 and so as not to move in the axial direction. The ball nut 82 is rotatably screwed and supported. That is, the rotary sliding member 68 is disposed so as to be rotatable with respect to the ball screw 83 and not movable in the axial direction. Further, a male screw (not shown) is formed at the front end portion of the shaft portion 84, and a bearing nut 80 is disposed by screwing with the male screw. The bearing nut 80 positions the bearing b7 together with the protrusion 65a formed on the inner peripheral surface of the support body 65. The ball nut 82 is fixed to the rear injection support 62 via the load cell 96.

  Therefore, when the rotational force generated by driving the injection motor 90 in the forward direction and the reverse direction is transmitted to the ball screw shaft 81 via the connecting portion, the ball screw shaft 81 is Since 85 and the ball nut 82 are screwed together, they are advanced and retracted while rotating.

  In the injection process or the like, the rotation of the rotary sliding member 68 is stopped by stopping the driving of the metering motor 70. When the injection motor 90 is driven in this state, the rotary sliding member 68 is moved. It can be moved forward (moved leftward in the figure) in the axial direction without rotating. As a result, the linear movement is transmitted to the screw 12 attached to the rotary sliding member 68, and the screw 12 can be advanced.

  Next, a method for driving the injection apparatus having the above configuration will be described.

  First, when the weighing motor 70 is driven during the weighing process, the rotation generated in the output shaft 74 is transmitted via the output gear 75, the counter drive gear 76, the counter driven gear 77, the rotating member 78, and the rotating sliding member 68. Is transmitted to the screw 12 to rotate the screw 12 in the forward direction.

  Along with this, a resin (not shown) dropped from a hopper (not shown) disposed in the heating cylinder 11 is advanced in a groove (not shown) formed on the outer peripheral surface of the screw 12, and the screw 12 moves backward (right in the figure). The resin is stored in front of a screw head (not shown) attached to the front end of the screw 12. At this time, the rotating sliding member 68 is moved relative to the rotating member 78 and retracted along with the retreating force generated in the screw 12. As the rotary sliding member 68 moves backward, the ball screw shaft 81 is also moved backward while rotating.

  Next, during the injection process, the injection motor 90 is driven. At this time, the rotation generated by the rotor (not shown) of the injection motor 90 is transmitted to the ball screw shaft 81 through the connecting portion, and the ball screw The rotary motion is converted into a rotationally straight motion by 83. As a result, the ball screw shaft 81 is advanced while rotating. When the rotary sliding member 68 is stopped by the metering motor 70, the screw 12 is integrally attached to the rotary sliding member 68, so that the screw 12 is advanced without rotating.

  However, in the conventional injection device, the female spline 93 and the male spline 92 are slidably engaged with each other. However, it is possible to reliably lubricate between the female spline 93 and the male spline 92. It is not possible to perform stable molding.

  An object of the present invention is to solve the problems of the conventional injection device and to provide an injection device capable of performing stable molding.

  Therefore, in the injection apparatus of the present invention, an injection frame, a stator attached radially inward of the injection frame, a rotor disposed radially inward of the stator, and a radial direction of the rotor And a rotary sliding member that is moved back and forth in the axial direction.

  A first lubricant storage chamber is formed between the injection frame and the rotor. Further, a second lubricant accommodating chamber is formed between the rotor and the rotary sliding member so as to communicate with the first lubricant accommodating chamber. Then, the lubricant is supplied from the first lubricant accommodating chamber to the second lubricant accommodating chamber.

  According to the present invention, in an injection apparatus, an injection frame, a stator attached radially inward of the injection frame, a rotor disposed radially inward of the stator, and a radial direction of the rotor And a rotary sliding member that is moved forward and backward in the axial direction.

  A first lubricant storage chamber is formed between the injection frame and the rotor. Further, a second lubricant accommodating chamber is formed between the rotor and the rotary sliding member so as to communicate with the first lubricant accommodating chamber. Then, the lubricant is supplied from the first lubricant accommodating chamber to the second lubricant accommodating chamber.

  In this case, a first lubricant accommodating chamber is formed between the injection frame and the rotor, and the second lubricant is communicated with the first lubricant accommodating chamber between the rotor and the rotary sliding member. An agent storage chamber is formed, and the lubricant is supplied from the first lubricant storage chamber to the second lubricant storage chamber.

  Therefore, the injection member can be smoothly advanced and injection can be performed satisfactorily.

  Further, since the lubricant can be reliably supplied to the second lubricant storage chamber, the lubrication of the engaging portion is not interrupted and stable molding can be performed.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a conceptual diagram of an injection apparatus according to an embodiment of the present invention.

  In the figure, 11 is a heating cylinder as a cylinder member, and 12 is a screw as an injection member that is rotatably arranged in the heating cylinder 11 and can be moved back and forth (moved in the horizontal direction in the figure). An injection nozzle (not shown) is formed at the front end of the heating cylinder 11, and a nozzle port is formed in the injection nozzle.

  The screw 12 includes a screw body and a screw head (not shown) attached to the front end of the screw body. A flight (not shown) is formed in a spiral shape on the outer peripheral surface of the screw body, and a spiral groove is formed by the flight. Is done.

  The rear end (right end in the figure) of the heating cylinder 11 is attached to a front injection support 21 as a front support, and a rear injection support 62 as a rear support is arranged at a predetermined distance from the front injection support 21. Established. A rod 63 is installed between the front injection support 21 and the rear injection support 62, and a predetermined distance is maintained between the front injection support 21 and the rear injection support 62 by the rod 63. The front injection support 21, the rear injection support 62, and the rod 63 constitute an injection frame.

  A connecting body 64 having a circular shape is integrally attached to the rear end of the screw 12 via a coupler 59, and a cylindrical support body 65 is attached to the connecting body 64 via a bolt bt1. . The connecting body 64 and the support body 65 constitute a rotating sliding member 68 that is integrally attached to the screw 12 and rotated (or moved) together with the screw 12. The support 65 has a length corresponding to the stroke of the screw 12 in the axial direction, and a male spline 67 is formed on the outer peripheral surface.

  In order to transmit the rotation to the rotary sliding member 68, the first side is adjacent to the rear end of the front injection support 21, and integrally with the front injection support 21, and surrounds the rotary sliding member 68. An electric metering motor 22 as a driving unit and a rotational force restricting unit, and the metering motor 22 is placed in a first driving state in the metering step and in a second driving state in the injection step; The rotary sliding member 68 is rotated in the first driving state, and the rotation transmitted to the rotating sliding member 68 is restrained in the second driving state.

  The metering motor 22 is attached to a sleeve 23 fixed to the front injection support 21, a rear annular body 24 attached to the rear end of the sleeve 23, and a radially inner side of the front injection support 21 via the sleeve 23. And a cylindrical rotor 26 disposed opposite to the outer peripheral surface of the rotary sliding member 68 on the radially inner side of the stator 25, and a rear end that is a side surface of the rotor 26. A spline nut 27 as a rotation transmission part is attached to the bolt bt2.

  The stator 25 includes a core 25a attached to the sleeve 23, and a coil 25b wound around the core 25a. The rotor 26 is a hollow cylindrical body as a rotating member that is disposed on the same axis as the rotating sliding member 68 and is relatively movable radially outward of the rotating sliding member 68. 29, and a permanent magnet 28 disposed at a location corresponding to the stator 25 on the outer peripheral surface of the cylindrical body 29. The cylindrical body 29 functions as an output shaft of the measuring motor 22, and the front The injection support 21 is rotatably supported by the bearing b1 and the rear annular body 24 by the bearing b2.

  In this case, the sleeve 23 and the rear annular body 24 constitute a case formed integrally with the front injection support 21. Therefore, since the front injection support 21 and the metering motor 22 can be integrated, the injection device can be reduced in size.

  The spline nut 27 transmits the rotation generated in the first driving state of the metering motor 22 to the rotary sliding member 68 while allowing the relative movement of the rotary sliding member 68 in the axial direction. Then, the restraining force generated in the second driving state of the measuring motor 22 is transmitted to the rotating sliding member 68 to restrain the rotating sliding member 68 from rotating. For this purpose, the rotary sliding member 68 is disposed so as not to rotate with respect to the spline nut 27 and to be movable in the axial direction with respect to the rotor 26 and the spline nut 27. And the inner peripheral surface of the rotor 26 are slidably brought into contact with each other. That is, at the front end (left end in the figure) of the cylindrical body 29, the outer peripheral surface of the connecting body 64 and the inner peripheral surface of the cylindrical body 29 are slidably contacted via the seal 30 as the first sealing device. At the rear end of the cylindrical body 29, the female spline formed on the inner peripheral surface of the spline nut 27 and the male spline 67 are slidably engaged with each other.

  A seal portion is formed by the seal 30 between the outer peripheral surface of the connecting body 64 and the inner peripheral surface of the cylindrical body 29, and an engaging portion is formed by the female spline and the male spline 67 of the spline nut 27. An annular groove for accommodating the seal 30 is formed at a front end of the rotary sliding member 68, for example, at a predetermined location on the outer peripheral surface of the coupling body 64. In the present embodiment, an annular groove is formed on the outer peripheral surface of the coupling body 64, and the seal 30 is accommodated in the annular groove, but at a predetermined location on the inner peripheral surface of the cylindrical body 29. An annular groove may be formed and a seal may be accommodated in the annular groove. The first transmission element is constituted by the female spline of the spline nut 27, and the second transmission element is constituted by the male spline 67.

  In this case, since the axial dimension of the spline nut 27 is small and the axial dimension of the male spline 67 is large, when the female spline of the spline nut 27 and the male spline 67 slide, A load is always applied to the inner peripheral surface, and the inner peripheral surface of the female spline of the spline nut 27 is faster to wear than the outer peripheral surface of the male spline 67. Since it is attached to the end of 22, that is, the rear end of the cylindrical body 29, the maintenance work for checking the progress of wear and replacing the spline nut 27 can be simplified.

  Further, if a spline is to be formed on the inner peripheral surface of the cylindrical body 29, the radial dimension of the cylindrical body 29 needs to be increased accordingly. In the present embodiment, the spline nut 27 is a cylindrical Since it is attached to the rear end of the cylindrical body 29, the radial dimension of the cylindrical body 29 can be reduced. Therefore, the diameter of the rotor 26 can be prevented from becoming larger than necessary, and the radial dimension of the measuring motor 22 can be reduced. As a result, the rod 63 can be disposed further inside, so that the injection device can be reduced in size.

  In addition, the ball screw 83 as the movement direction conversion unit is assembled into the injection device together with the support body 65 and the bearings b7 and b8 during assembly and maintenance of the injection device. First, the ball screw 83, the support body 65, and the bearings b7 and b8 are assembled into the injection device with the spline nut 27 removed, and then the female spline and the male spline 67 of the spline nut 27 are engaged. Subsequently, the spline nut 27 is attached to the rear end of the cylindrical body 29 with a bolt bt2.

  In this case, when the ball screw 83, the support body 65, and the bearings b7 and b8 are incorporated in the injection device, it is not necessary to incorporate the female spline and the male spline 67 in consideration of the engagement (engagement). Time can be shortened, and assemblability, maintainability, etc. can be improved.

  When the rotor 26 is rotated by driving the metering motor 22 in the first driving state, the rotation is transmitted to the rotating sliding member 68 via the spline nut 27, and the rotating sliding member 68 is It is rotated in the forward direction or in the reverse direction as necessary. Further, when the measuring motor 22 is placed in the second driving state, a restraining force is generated and the rotor 26 is stopped, the rotation transmitted to the rotary sliding member 68 is restrained, and the rotation of the screw 12 is also restrained. The

  Further, the rear end of the inner peripheral surface of the rear annular body 24 and the outer peripheral surface of the spline nut 27 are slidably brought into contact with each other via a seal 31 as a second sealing device, and the seal 31 is disposed. Thus, a sealed first lubricant storage chamber 32 is formed between the rear annular body 24, the cylindrical body 29, the bearing b2, and the seal 31. For example, lubrication is performed in the first lubricant storage chamber 32. Grease (not shown) as an agent is filled. In addition, the said cylindrical body 29 can be extended back (right in a figure), and the cylindrical body 29 and the seal | sticker 31 can also be made to contact. In this case, the sealing performance between the cylindrical body 29 and the seal 31 can be improved.

  Then, a sealed second lubricant accommodating chamber 33 is formed between the cylindrical body 29, the rotary sliding member 68, the seal 30 and the engaging portion, and the second lubricant accommodating chamber 33 has, for example, The grease is filled. Further, a first lubricant supply path 34 is formed in the rear annular body 24 by communicating a lubricant supply source (not shown) with the first lubricant storage chamber 32, and the cylindrical body 29 has a first lubricant supply path 34. The second lubricant supply passage 35 is formed by communicating the first lubricant storage chamber 32 and the second lubricant storage chamber 32.

  In this case, when the female spline of the spline nut 27 and the male spline 67 are slid, the seal 30 is slid against the smooth inner peripheral surface of the cylindrical body 29. Therefore, since the second lubricant accommodating chamber 33 can be reliably sealed, it is possible to prevent grease from leaking out to the screw 12 side. Furthermore, since the seal 30 is disposed at one end of the cylindrical body 29, that is, the front end and the spline nut 27 is disposed at the rear end, the allowable capacity of the second lubricant accommodating chamber 33 can be increased. In addition, a sufficient amount of grease can be stored in the second lubricant storage chamber 33. Therefore, since the grease can be reliably supplied between the female spline and the male spline 67 of the spline nut 27, stable molding can be performed.

  Then, behind the front injection support 21, a ball nut 82 and a ball screw shaft screwed with the ball nut 82 and supported so as to be rotatable with respect to the ball nut 82 and movable in the axial direction are supported. The ball screw 83 made of 81 is disposed. The ball screw shaft 81 includes a small diameter shaft portion 84 formed in order from the front end to the rear end, a large diameter screw portion 85, a connecting portion connected to an electric injection motor 90 as a second drive portion, and the like. Become. An annular flange member 89 is externally fitted to the step portion between the shaft portion 84 and the screw portion 85.

  By the way, the rotation generated in the rotor (not shown) of the injection motor 90 by driving the injection motor 90 is transmitted to the ball screw shaft 81, but the ball screw 83 is transmitted to the ball screw shaft 81. Rotational motion due to the rotation is converted into rotational linear motion, and the ball screw shaft 81 is rotated and advanced and retracted.

  Therefore, the ball screw shaft 81 is supported at the front end by the bearings b7 and b8 so as to be rotatable with respect to the rotary sliding member 68 and immovable in the axial direction, and at the rear end with respect to the ball nut 82. It is supported by screwing it in a freely rotatable manner. That is, the rotary sliding member 68 is disposed so as to be rotatable with respect to the ball screw 83 and not movable in the axial direction. Further, a male screw (not shown) is formed at the front end portion (left end portion in the drawing) of the shaft portion 84, and a bearing nut 80 is disposed by screwing with the male screw. The bearing nut 80 positions the bearing b7 together with the protrusion 65a formed on the inner peripheral surface of the cylindrical body 65. The ball nut 82 is fixed to the rear injection support 62 via the load cell 96. The load cell 96 constitutes a pressure detection device that detects the pressure of the molten resin in the heating cylinder 11.

  Therefore, when the rotation generated by driving the injection motor 90 in the forward direction and the reverse direction is transmitted to the ball screw shaft 81 via the connecting portion, the ball screw shaft 81 is And the ball nut 82 are screwed together so that they can be advanced and retracted while rotating.

  The motion component of the ball screw shaft 81 includes a linear motion component that causes the ball screw shaft 81 to advance and retreat, and a rotational motion component that rotates the ball screw shaft 81. The linear motion component and the rotational motion component include the bearing b7, It is transmitted to the rotary sliding member 68 via b8.

  In the injection process and the like, the metering motor 22 is transmitted to the rotary sliding member 68 by placing the metering motor 22 in the second drive state, that is, in the rotation restraint state, and placing the injection motor 90 in the drive state. The rotation is constrained and the rotary sliding member 68 can be moved in the axial direction without rotating. As a result, the linear movement is transmitted to the screw 12 integrally attached to the rotary sliding member 68, and the screw 12 can be moved forward (moved leftward in the figure).

  Next, a method for driving the injection apparatus having the above configuration will be described.

  First, during the weighing process, the weighing processing means of the control unit (not shown) performs the weighing process, and drives the weighing motor 22 in the first driving state. At this time, the rotational force generated in the rotor 26 is transmitted to the screw 12 through the spline nut 27 and the rotary sliding member 68, and the screw 12 is rotated in the forward direction.

  Along with this, resin supplied from a hopper (not shown) disposed in the heating cylinder 11 is advanced in the groove, and accordingly, the screw 12 is retracted (moved in the right direction in the figure), and the resin Is stored in front of the screw head. At this time, the rotary sliding member 68 is moved relative to the spline nut 27 in accordance with the retreating force generated in the screw 12. As the rotary sliding member 68 moves backward, the ball screw shaft 81 is also moved backward while rotating.

  Further, during the injection process, the injection processing means of the control unit performs the injection processing and drives the injection motor 90. At this time, the rotation generated by the injection motor 90 is transmitted to the ball screw shaft 81, and the ball screw 83 converts the rotary motion into a rotary linear motion. As a result, the ball screw shaft 81 is advanced while rotating. The injection processing means drives the metering motor 22 in a rotationally restrained state and generates a restraining force by controlling the rotational speed of the rotor 26 to 0 [rpm].

  The restraining force is transmitted to the rotary sliding member 68 via the spline nut 27, and the rotation transmitted to the rotary sliding member 68 via the ball screw shaft 81 is restrained. As a result, the screw 12 integrally attached to the rotary sliding member 68 is advanced without rotating.

  Thus, when the screw 12 is advanced, the resin stored in front of the screw head is injected from the injection nozzle and filled in the cavity space of the mold apparatus (not shown). At this time, a backflow prevention device (not shown) is disposed around the screw head so that the resin stored in front of the screw head does not flow back.

  Thus, since the second lubricant accommodating chamber 33 is formed between the rotary sliding member 68, the cylindrical body 29, the seal 30 and the engaging portion, sufficient lubrication is performed at the sealing portion and the engaging portion. Is called. Therefore, when the injection motor 90 is driven, the rotary sliding member 68 and the screw 12 can be smoothly advanced, and injection can be performed satisfactorily.

  In the present embodiment, the second lubricant containing chamber 33 is formed between the rotary sliding member 68, the cylindrical body 29, the seal 30 and the engaging portion. A lubricant accommodating chamber can be formed by disposing a seal between the member 78 (see FIG. 2) and the rotary sliding member 68.

  In addition, this invention is not limited to the said embodiment, It can change variously based on the meaning of this invention, and does not exclude them from the scope of the present invention.

It is a conceptual diagram of the injection device in the embodiment of the present invention. It is a conceptual diagram of the conventional injection device.

Explanation of symbols

21 Front injection support 25 Stator 26 Rotor 29 Cylindrical body 30, 31 Seal 32, 33 First and second lubricant accommodating chambers 62 Rear injection support 63 Rod 68 Rotating sliding member

Claims (2)

(A) an injection frame;
(B) a stator attached radially inward of the injection frame;
(C) a rotor disposed radially inward of the stator;
(D) having a rotary sliding member that is moved back and forth in the axial direction inside the rotor in the radial direction;
(E) a first lubricant containing chamber is formed between the injection frame and the rotor;
(F) a second lubricant accommodating chamber is formed between the rotor and the rotary sliding member in communication with the first lubricant accommodating chamber;
(G) An injection device in which a lubricant is supplied from the first lubricant storage chamber to the second lubricant storage chamber.   The injection device according to claim 1, wherein the first lubricant accommodating chamber is formed by disposing a sealing device between the injection frame and the rotation transmission unit.

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