JP2006110922A - Nozzle for injection molding machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a nozzle for an injection molding machine constituted so as not to contaminate a material. <P>SOLUTION: The nozzle 12 is constituted of a nozzle body 14 and the valve core guide 17 being in contact with the rear end 14b of the nozzle body 14. A first valve core housing hole 19, the material inflow port 20 piercing the first valve core housing hole 19 from the outside of the nozzle body 14 and an injection hole 18 provided so as to pierce the first valve core housing hole 19 and the contour of the leading end part of the nozzle body 14 are provided to the nozzle body 14. A second valve core housing hole 17b communicating with the first valve core housing hole 19 of the nozzle body 14 on the same center axis is provided to the valve core guide 17. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a nozzle for an injection molding machine, and more particularly to a nozzle for injecting a low-viscosity material such as LIM (Liquid Injection Molding).

  Conventionally, the injection molding machine by patent document 1 is disclosed as an injection molding machine which uses this kind of low-viscosity material.

JP 2000-158498 A

  FIG. 11 shows a cross-sectional view of a nozzle used in an injection molding machine like Patent Document 1.

The nozzle used in the conventional injection molding machine shown in FIG. 11 includes a nozzle tip 102 provided with a first valve core housing hole 107a on the inner side, a cylinder 101 provided with a second valve core housing hole 107b on the inner side, The first and second valve core housing holes 107a and 107b are slidably received by the same central shaft and are slidably received in the second valve core housing hole 107b. The material communicates with the valve core housing hole 107b. The material inlet 106 is supplied, and a gap between the valve core 103 and the valve core accommodating holes 107a and 107b is used as an injection path, and a nozzle hole 108 is provided as a material injection port.
Slide rings 105 a and 105 b are provided between the second valve core housing hole 107 b and the valve core 103 as means for preventing contact between the valve core 103 and the valve core housing holes 107 a and 107 b.
Further, in order to prevent the material from leaking from the rear end side of the cylinder 101, a packing 104 is provided between the second valve core housing hole 107 b and the valve core 103.

  However, since the slide rings 105a and 105b are arranged closer to the material inlet 106 than the packing 104, the slide rings 105a and 105b are always exposed to the material. The dust generated when 105a and 105b slide with the inner wall of the injection hole 107 contaminates the material, leaving a problem that the contaminated material is injected.

  The present invention has been made to solve such problems, and an object of the present invention is to provide a nozzle for injection molding in which the material is not contaminated.

In order to achieve such an object, the present invention provides a valve core housing hole provided inside a nozzle, and an injection provided through the valve core housing hole and an outer periphery of a tip portion of the nozzle body. A hole, a material inflow port penetrating from the outside of the nozzle into the valve core housing hole, a valve core housed in the valve core housing hole so as to be able to advance and retreat, and a sliding contact between the valve core housing hole and the valve core. A packing and a slide ring which are arranged in a possible manner are provided, and the packing is arranged closer to the material inlet than the slide ring.
The nozzle is composed of a nozzle body and a valve core guide in contact with the rear end of the nozzle body. The nozzle body has a first valve core housing hole, and the first valve core housing hole penetrates from the outside of the nozzle body. A material inlet, a first valve core receiving hole, and an injection hole provided through the outer periphery of the tip of the nozzle body, and the valve core guide has the same center as the valve core receiving hole of the nozzle body A second valve core housing hole communicating with the shaft is provided, and the slide ring is disposed so as to be slidable between the second valve core housing hole provided in the valve core guide and the valve core. The collar is housed in a collar that surrounds the outer peripheral side of the nozzle body, and the collar is disposed between the rear end of the nozzle body and the valve core guide.
The collar may be accommodated in the rear end portion of the nozzle body or the valve core guide front end portion.

  ADVANTAGE OF THE INVENTION According to this invention, it came to be able to provide the nozzle for injection molding in which material is not contaminated with the waste powder of a slide ring.

The nozzle for an injection molding machine according to the present invention is characterized in that the packing is arranged closer to the material inlet than the slide ring, and the specific example of the nozzle for the injection molding machine according to the present invention is as follows. An example is shown.
Note that this embodiment is merely an example of the present invention, and is not construed as being limited thereto, and the design can be changed within the scope of the present invention.

  The nozzle 12 includes a nozzle main body 14, a packing portion 16 fitted on the rear end side of the nozzle main body 14, a valve core guide 17 provided integrally on the rear end side of the nozzle main body 14, and the nozzle main body 14. And the valve core guide 17 is connected to the valve core 15 so as to be movable forward and backward. (See Fig. 1, Fig. 2 and Fig. 3)

FIG. 3 is an exploded view of the nozzle 12, and FIGS. 1 and 2 are assembly views of the nozzle 12. The outer shape of the nozzle body 14 is a cylindrical shape having a tapered tip end, and the tip is formed in a hemispherical shape. Inside the nozzle body 14, a first valve core housing hole 19 having a circular shape in a cross-sectional view that is drilled to the rear end in the axial direction is provided, and the first valve core housing hole 19 and the tip of the nozzle body 14 are provided. Is provided with an injection hole 18 having a circular shape in cross-sectional view that passes through the same axis.
The injection hole 18 has a smaller diameter than that of the first valve core housing hole 19, and is formed with the same diameter from the tip opening 18 a to the communication port 19 a of the first valve core housing hole 19 in this embodiment. However, the present invention is not construed as being limited thereto. For example, the first valve core housing hole 19 is formed so that the diameter decreases from the communication port 19a toward the tip opening 18a. It can be changed.
In the present embodiment, the nozzle body 14 is provided with a material injection hole 20 penetrating from the outside of the body to the first valve core housing hole 19 in an orthogonal shape. As shown, the material injection hole 20 is connected to a material supply means via a flexible pipe or hose P, and the material is supplied from the material supply means.
Further, in this embodiment, a packing portion arrangement hole 14a that communicates coaxially with the first valve core housing hole 19 and a valve core guide fitting hole 14c are respectively provided in the rear end portion of the nozzle body 14. .
The packing portion arrangement hole 14 a is formed in a short cylindrical shape having a diameter larger than that of the first valve core housing hole 19, with the first valve core housing hole 19 provided at the approximate center of the inner bottom surface.
The valve core guide fitting hole 14c is formed in a short cylindrical shape having a larger diameter than the packing portion arrangement hole 14a, with the packing portion arrangement hole 14a provided substantially at the center of the inner bottom surface. In this embodiment, bolt holes 21c and 21d are formed on the inner bottom surface around the valve core guide fitting hole 14c.

The packing part 16 includes a collar 16a, a packing 16b, and an O-ring 16d.
The collar 16a is fitted into the packing portion arrangement hole 14a, and when fitted, the rear end surface of the collar 16a and the rear end surface 14b of the nozzle body 14 are formed in a cylindrical shape that can be accommodated on the same plane. A packing insertion hole 16c recessed with the same diameter inward from the end surface, a third valve core housing hole 16g provided in communication with the packing insertion hole 16c and opened at the front end surface, and a collar 16a The front end surface is constituted by an O-ring housing groove 16e provided around the opening of the third valve core housing hole 16g.
The third valve core housing hole 16g is formed to have a smaller diameter than the packing insertion hole 16c and the same inner diameter as the first valve core housing hole 19 of the nozzle body 14, and the packing insertion hole 16c. The third valve core housing hole 16g communicates coaxially with the first valve core housing hole 19 of the nozzle body 14.

The packing 16b is fitted into the packing insertion hole 16c. When the packing 16b is fitted and fixed in the packing insertion hole 16c, for example, the rear end face of the packing 16b and the rear end face of the collar 16a can be accommodated on the same plane. It is formed in a cylindrical shape, and has a cylindrical valve core sliding contact hole 16j having the same diameter from the front end portion toward the rear end portion.
The valve core slide contact hole 16j is formed to have a smaller diameter than the third valve core accommodation hole 16g of the collar 16a, and communicates coaxially with the first valve core accommodation hole 19 of the nozzle body 14.

  The O-ring 16d is fitted in an O-ring receiving groove 16e formed in the collar 16a, and is not particularly limited, and has a well-known shape. When inserted, the gap between the injection hole 18 side and the collar 16a is separated in the circumferential direction to prevent the material of the injection hole 18 from leaking to the outer peripheral side.

  Further, in this embodiment, the collar 16a has a screw hole 16f on its rear end surface as shown in FIG. 3, and a drawing bolt 16h can be screwed into the screw hole. The pull-out bolt 16h is for pulling out the collar 16a fitted with the packing portion disposing hole 14a of the nozzle body 14 and the rear end face thereof being matched from the packing portion disposing hole 14a. Accordingly, as shown in FIGS. 1 and 2, the extraction bolt 16h is removed when the nozzle 12 is assembled and used.

  In this embodiment, the packing 16b is inserted into the packing insertion hole 16c from the rear end surface of the collar 16a. However, the packing insertion hole 16c may not be open to the rear end surface of the collar 16a. A circumferential groove may be provided on the inner diameter surface of the cylindrical through hole 16a, and the packing 16b may be fitted into the groove.

As shown in FIG. 3, the valve core guide 17 has a small-diameter cylindrical tip projection 17c that fits into the valve core guide fitting hole 14c of the nozzle body 14, and a larger diameter than the tip projection 17c. A large-diameter cylindrical flange portion 17d that is formed and abuts the rear end edge portion 14d of the nozzle body 14, and a second valve core housing hole 17b having a circular cross-sectional view is formed at the tip end of the shaft center. A hole is formed over the tip of the portion 17c and the rear end of the flange portion 17d. In FIG. 3, 17 e and 17 f are bolt holes provided in the valve core guide 17.
As shown in FIGS. 1 and 2, the valve core guide 17 is fitted with a tip protrusion 17 c in the valve core guide fitting hole 14 c of the nozzle body 14, and the tip surface of the protrusion 17 c is inserted into the valve core guide. After being brought into contact with the inner bottom surface of the fitting hole 14c, the assembly bolts 21a and 21b are fixed through the bolt holes 17e and 17f to be integrated with the nozzle body 14. In FIGS. 2 and 3, 17e and 17f are bolt holes provided in the valve core guide 17, and the assembled bolts 21a and 21b are fixed through the bolt holes 17e and 17f.

The valve core 15 is formed to be longer than at least the length of the nozzle 12, and the second valve core of the valve core guide 17 when the tip 15 e of the valve core 15 contacts the injection hole 18 of the nozzle body 14. It is an elongated cylindrical shape formed so that the rear end portion 15f of the valve core protrudes rearward from the rear end surface 17g of the housing hole 17b, and the front end portion 15e is conical and sharp.
Specifically, as shown in FIGS. 7 and 8, the rear end portion 15 f of the valve core 15 protruding from the rear end surface 17 g of the valve core guide 17 is below the nozzle base 11 through the through hole 11 b provided in the nozzle base 11. It shall have a length that projects to the side.
As shown in FIGS. 1 and 2, the outer diameter of the valve core 15 is such that the first valve core housing hole 19 of the nozzle body 14, the third valve core housing hole 16 g of the collar 16 a, and the second valve of the valve core guide 17. The diameter is smaller than the core receiving hole 17b, and is the same diameter as the diameter of the valve core sliding contact hole 16j of the packing 16b of the packing portion 16, or slightly larger than the valve core sliding contact hole 16j.

Further, as shown in FIG. 3, grooves 15 a and 15 b are provided in the valve core 15 in the circumferential direction at a predetermined position on the outer periphery of the valve core 15. As shown in FIGS. 1 and 3, slide rings 15 c and 15 d are fitted into the protrusions in the grooves 15 a and 15 b, respectively.
The outer diameters of the slide rings 15c and 15d are the same as those of the second valve core housing hole 17b of the valve core guide 17, but are in contact with the inner wall of the second valve core housing hole 17b of the valve core guide 17 to guide and slide. However, it is necessary not to inhibit the movement of the valve core 15.
The depths of the grooves 15a and 15b provided on the outer periphery of the valve core 15 are equal to the inner diameters of the slide rings 15c and 15d.
The material of the slide rings 15c and 15d is resin or metal, but it is required that the material is slightly softer than the material of the valve core 15 and the valve core guide 17.
In the present embodiment, the two slide rings are arranged on the outer periphery of the valve core 15, but there is no particular limitation, and one or more can be selected as appropriate within the scope of the present invention.

As an example of the nozzle according to the present invention, a nozzle mechanism including the nozzle body 14 having the first valve core housing hole 19 and the valve core guide 17 having the second valve core housing hole 17b as described above will be described. However, it is possible to deal with highly viscous materials by using other nozzle mechanisms. That is, the nozzle body 14 and the valve core guide 17 of the present embodiment are integrally formed, and a single valve core housing hole communicating with the nozzle hole provided at the nozzle tip is formed to the nozzle rear end. The shape of the structure can be arbitrarily changed within the scope of the present invention.
"Nozzle variants"

FIG. 4 shows a modification of the nozzle according to the present invention. Instead of the nozzle 12 described with reference to FIGS. 1 to 3, a nozzle 112 having the following configuration may be used.
FIG. 5 is an exploded view of the nozzle 112, and FIG. 4 is an assembly view thereof.
The nozzle 112 includes a nozzle main body 114, a collar portion 116 fitted on the rear end side of the nozzle main body 114, and a valve core 115 disposed in the nozzle main body 114 so as to be able to advance and retract.

The nozzle body 114 includes a first valve core accommodation hole 119, an injection hole 118, a material inlet 120, and a collar portion arrangement hole 114a.
The total length of the nozzle body 114 is the same as the total length of the nozzle 12 described in FIG. 1 (the total length of the nozzle body 14 and the valve core guide 17). The arrangement of the single valve core accommodation hole 119, the injection hole 118, and the material inlet 120 is the shape of the tip of the nozzle body 12 described in FIG. 1, the first valve core accommodation hole 19, the injection hole 18, and the material flow. Since it is the same as arrangement | positioning of the entrance 20, it omits.

In this embodiment, as shown in FIG. 5, a collar portion disposing hole 114 a that communicates coaxially with the first valve core housing hole 119 is provided in the rear end portion of the nozzle body 114.
The collar portion disposing hole 114a is formed in a long cylindrical shape having a diameter larger than that of the first valve core housing hole 119, with the first valve core housing hole 119 provided substantially at the center of the inner bottom surface.

The collar portion 116 includes a collar 116a, a packing 116b, and an O-ring 116d.
As shown in FIG. 4, the collar 116a is fitted into the collar portion arrangement hole 114a, and when fitted, the rear end surface of the collar 116a and the rear end surface 114b of the nozzle body 114 can be accommodated on the same plane. It is formed in a cylindrical shape. As shown in FIG. 5, the collar 116 a includes a second valve core housing hole 116 h that is recessed with the same diameter from the rear end surface inward, and a third valve core housing hole that is provided open at the front end surface. 116g, a packing fitting groove 116m provided in communication between the second valve core housing hole 116h and the third valve core housing hole 116g, and a front end face of the collar 116a, the third valve core housing hole And an O-ring receiving groove 116e provided around the opening of 116g.
The third valve core housing hole 116g has a smaller diameter than the second valve core housing hole 116h, and has the same inner diameter as the first valve core housing hole 119 of the nozzle body 114. The packing fitting groove 116m has a larger diameter than the second valve core housing hole 116h, and the second valve core housing hole 116h, the packing fitting groove 116m, and the third valve core housing hole 116g It communicates coaxially with the first valve core housing hole 119 of the nozzle body 114.

The packing 116b is fitted into the packing fitting groove 116m of the second valve core housing hole 116h. For example, when the packing 116b is fitted and fixed in the packing fitting groove 116m, the packing 116b has a cylindrical shape with the same diameter from the front end portion toward the rear end portion. The valve core slide contact hole 116j is provided.
The valve-sliding contact hole 116j is formed to have a smaller diameter than the third valve-core housing hole 116g of the collar 116a and communicates coaxially with the first valve-core housing hole 119 of the nozzle body 114a.

  The O-ring 116d is fitted in an O-ring receiving groove 116e formed in the collar 116a, and is not particularly limited and has a well-known shape, but at least the front end surface of the collar 116a is in the collar portion disposing hole 114a. When inserted, as shown in FIG. 4, the gap between the injection hole 119 side and the collar 116a is separated in the circumferential direction to prevent the material of the injection hole 119 from leaking to the outer peripheral side. is doing.

  Further, in the present embodiment, as shown in FIG. 5, the collar 116a has a screw hole 116f at its rear end face, and a drawing bolt 116k can be screwed into the screw hole. The pull-out bolt 116k is for pulling out the collar 116a fitted with the rear end face of the collar portion arrangement hole 114a of the nozzle body 114 being fitted from the collar portion arrangement hole 114a. Accordingly, the pull-out bolt 116k is removed when the nozzle 112 is assembled and used, as shown in FIG.

The valve core 115 is formed to be longer than at least the length of the nozzle body 114, and when the front end portion 115e of the valve core 115 contacts the injection hole 118 of the nozzle body 114, the valve core 115 is more than the rear end surface 114b of the nozzle 114. It is an elongated cylindrical shape formed to the extent that the rear end portion 115f of the valve core protrudes rearward, and the front end portion 115e is conical and sharp.
As shown in FIG. 4, the outer diameter of the valve core 115 is smaller than the first valve core accommodation hole 119 of the nozzle body 114 and the third valve core accommodation hole 116g of the collar 116a, and the collar portion. 116 is the same diameter as the diameter of the valve core sliding contact hole 116j of the packing 116b or slightly larger than the diameter of the valve core sliding contact hole 116j.

Further, as shown in FIG. 5, grooves 115 a and 115 b are provided in the valve core 115 in the circumferential direction at a predetermined position on the outer periphery of the valve core 115. Slide rings 115c and 115d are fitted into the protrusions in the grooves 115a and 115b, respectively.
As shown in FIG. 4, the outer diameter of the slide rings 115c and 115d is the same as that of the second valve core housing hole 116h, but slides in contact with the inner wall of the second valve core housing hole 116h. It is necessary not to inhibit the movement of the lead 15.
The depth of the grooves 115a and 115b provided on the outer periphery of the valve core 115 is equal to the inner diameter of the slide rings 115c and 115d.
The material of the slide rings 115c and 115d is resin or metal, but it is required that the material is slightly softer than the material of the valve core 115 and the valve core guide 117.
In this modification, the two slide rings 115c and 115d are arranged on the outer periphery of the valve core 115, but there is no particular limitation, and one or more can be selected as appropriate within the scope of the present invention. .

  The nozzle described above is used in an injection molding machine as described below. Moreover, although the following injection molding machines can selectively use both the nozzle 12 shown in FIG. 1 and the nozzle 112 shown in FIG.

  As shown in FIG. 9, the injection molding machine A includes a gantry 1, an injection device 3 for injecting and filling a plurality of molds 6 scattered in the horizontal longitudinal direction of the gantry 1, and the plurality of injection devices 3. The moving unit 5 moves along the direction in which the individual molds are arranged, and the rails 4 a and 4 b that support the injection device 3 moved by the moving unit 5. According to this embodiment, the injection device 3 is connected to a material supply means as shown in FIG. Hereinafter, the frame 1, which is a rough component of the injection molding machine A of the present embodiment, the injection device 3, the moving means 5, and the rails 4a and 4b will be described in detail.

The gantry 1 is constructed in a frame structure by a structural material, and is vertically arranged between four columns 1c, 1d, 1e, and 1f having the same length and the lower ends of the columns 1c, 1d, 1e, and 1f. Formed by horizontally extending beams 1g, 1h, 1j, and 1k, and the upper ends of the four pillars 1c, 1d, 1e, and 1f, and beams (not shown) connecting these ends. The top plate 1a provided on the surface to be formed forms a rectangular shape that is long in the left-right direction in the front view of FIG.
The top plate 1a is composed of a horizontal surface, and the horizontal surface is used as a mold arrangement surface, and a plurality of the mold disposition surfaces communicate with injection holes of the disposed molds. Each of the through holes is bored with the same diameter on the same straight line in the longitudinal direction (left and right direction in FIG. 6) at the approximate center of the top plate in the short direction (depth direction in FIG. 6).
Further, in this embodiment, the installation plates 5d and 5e that are spanned between the right columns 1c and 1d adjacent to each other at a narrow interval (adjacent in the depth direction in FIG. 6) and between the left columns 1e and 1f are provided. I have.
In place of the top plate 1a, a plurality of beams (not shown) that connect the upper ends of the columns 1d and 1e and 1f and 1c are spanned in the depth direction of FIG. It may be a beam.

  The injection device 3 is a device that injects a material into the mold 6 and includes a lifting mechanism E of a nozzle mechanism and a nozzle mechanism F as shown in FIG.

  The lifting mechanism E of the nozzle mechanism includes a base 8, a lifting cylinder 10, a rod 10 a extending from the lifting cylinder 10, and a lifting base 9.

  The base 8 is a horizontally-arranged plate-like body, and the elevating cylinder 10 is fixed perpendicularly to the upper surface of the base 8 through the base 8.

The elevating cylinder 10 is a fluid pressure cylinder that includes, for example, a rod 10a that can be raised and lowered, and moves the rod 10a up and down.
The upper end of the rod 10 a is fixed so as to be orthogonal to the lower surface of the lifting platform 9 and moves up and down the lifting platform 9.
In this embodiment, the lifting cylinder 10 uses a hydraulic cylinder as an example. However, other lifting means may be used as long as the lifting platform 9 can be lifted, for example, a rack instead of the rod 10a. The mechanism may be a rack and pinion by a motor having a pinion mechanism instead of the elevating cylinder 10.
Further, the lifting cylinder 10 is provided with a pressure sensor (not shown) and measures the pressure applied when the rod 10a is lifted.

  A pair of legs 9 a, 9 a are extended downward on the lower surface of the lifting platform 9, and the pair of legs 9 a, 9 a pass through a pair of guide holes 8 a, 8 a provided in the base 8. The guide holes 8a and 8a restrict the movement of the legs 9a and 9a in the horizontal direction, and as a result, the horizontal rotation of the lifting platform 9 is suppressed.

  The nozzle mechanism F is disposed on the upper surface of the lifting platform 9 and includes a nozzle table 11, a nozzle 12, and an injection control device 13.

  The nozzle base 11 is a plate-like body that is smaller than the lifting platform 9 in which a through-hole 11b that vertically penetrates the upper surface 11c and the lower surface 11d is provided at a substantially central position. In order to constitute 11e, it is horizontally supported above the lifting platform 9 by a pair of legs 11a, 11a of the same length arranged at a predetermined interval.

  Since the nozzle 12 and the nozzle 112 have been described in detail above, description thereof will be omitted.

As shown in FIGS. 7 and 8, the injection control device 13 is installed at the center of the upper surface of the lifting platform 9 in the space 11e.
The injection control device 13 is provided with a fluid pressure cylinder, for example, a hydraulic cylinder 13 a perpendicular to the upper surface of the lifting platform 9, and the hydraulic cylinder 13 a raises and lowers the rod 13 b from the upper surface of the injection control device 13. . A tip 13c of the rod 13b extends outward from the rear end surface of the nozzle 12 (the rear end surface 17g of the valve core guide 17) when the rod 13b is raised, and is a through hole provided in the nozzle base 11. It contacts the rear end portion 15f of the valve core 15 extending downward of the nozzle base 11 through 11b.

  The moving means 5 is a means for moving the injection device 3 along the arrangement of the molds 6, 6... Arranged in the left-right direction in front view on the top plate 1a of the gantry 1. In the present embodiment, As an example, a single ball screw mechanism 5 shown in FIG. 6 is used.

As shown in FIG. 6, the ball screw mechanism 5 includes a single ball screw shaft 5a that is stretched across the left and right installation plates 5d and 5e of the gantry 1 in the horizontal longitudinal direction, and the ball screw shaft 5a in the axial direction. And one slide block 5b that moves to the position.
The ball screw shaft 5a of the ball screw mechanism 5 is fixed to the left and right installation plates 5d and 5e of the gantry 1 via bearings, and at least one end thereof is provided with a servo motor 5c that drives the ball screw shaft 5a. Yes.

The slide block 5b is a nut body of the ball screw mechanism 5. When the ball screw shaft 5a is rotated by the servo motor 5c, the slide block 5b is horizontally moved on the ball screw shaft 5a (see arrow H in the figure). It is provided to reciprocate.
The slide block 5 b is fixed to the bottom surface of the base 8 of the lifting mechanism E, avoiding the location of the lifting cylinder of the lifting mechanism E of the nozzle mechanism constituting the injection device 3.

  The moving means 5 may be other moving means as long as the slide block 5b can move in the horizontal direction. For example, the moving means 5 may be a rack mechanism instead of the ball screw shaft 5a, and a pinion instead of the slide block 5b. A motor having a mechanism may constitute a rack and pinion, or may be a linear motor.

  The moving means 5 may be arranged at any position as long as the slide block 5b can move in the horizontal direction as long as it does not hinder the operation of the injection device. For example, the ball screw shaft The slide block 5b provided on the base 8 may be movable on the ball screw shaft 5a.

As shown in FIG. 6, the rails 4 a and 4 b extend over the left and right installation plates 5 d and 5 e of the gantry 1 so as to be positioned at predetermined intervals on the front and rear sides in the depth direction around the ball screw mechanism 5. It is stretched parallel to the horizontal longitudinal direction.
In this embodiment, as shown in FIG. 6, both bottom surfaces in the depth direction of the base 8 of the injection device 3 fixed on the slide block 5b of the ball screw mechanism 5 slide on the rails 4a and 4b. It is supported movably.

The means for supporting the base 8 with the rails 4a and 4b may be such that the bottom surfaces in the depth direction are merely in contact with each other between the rails 4a and 4b as in this embodiment. Any form is acceptable as long as it does not interfere.
For example, although not particularly illustrated, the base 8 is provided with a length in the depth direction shorter than the distance between the rails 4a and 4b, and arms are extended from both ends of the base 8 in the depth direction. The base 8 may be slidably supported by the engagement between the rails 4a and 4b. Further, a hook (not shown) is extended upward from both ends of the base 8 in the depth direction, and the base 8 is slidably supported by the engagement between the hook and the rails 4a and 4b. It is also possible.
Further, for example, a continuous groove (not shown) may be provided on the upper surface of the rails 4a and 4b, and the injection device 3 may be slidably supported according to the groove, or instead of the rail, A linear guide device such as a slide guide, a slide table, a slide unit, a slide way, or a ball spline may be used.

  Here, the operation of the injection molding machine of this embodiment will be described. In the following description, only the step of injecting the material to the single mold 6 will be described, but the injection device is placed horizontally with respect to the plurality of molds 6, 6. It goes without saying that it is possible to inject and fill the material by sequentially moving in the direction.

  First, as shown in FIG. 6 or FIG. 10, dies 6, 6,... Are set on the top plate 1a.

The material is injected from the material supply means shown in FIG. 10 through the hose P into the first valve core housing portion 19 through the material injection hole 20 of the nozzle body, and the first valve core housing hole 19 and the valve core 15 are in contact with each other. The gap is injected and filled (FIG. 1 shows the injected and filled state of the material).
During the filling and filling operation of the material into the nozzle 12, the tip portion 15e of the valve core 15 is pressed against the injection hole 18 by the rod 13b of the raised injection control device 13, so that the pressed portion Thus, the material injection path is closed and the material injection is stopped (see FIGS. 1 and 4). The injection and filling process of the material into the nozzle 12 may be during the horizontal movement of the injection device 3, and the injection device 3 is lifted to bring the nozzle tip 18 a into contact with the mold 6. It may be performed later, and the design can be changed within the scope of the present invention.

  Then, if the servo motor 5c is operated by operating the control device C and the ball screw shaft 5a is rotated, the injection device 3 provided on the slide block 5b provided to the ball screw shaft 5a so as to be reciprocally movable. Moves in the axial direction (horizontal direction indicated by reference numeral H in FIGS. 6 to 8) while being slidably supported by the rails 4a and 4b.

Then, when the injection device 3 moves directly below the desired mold 6, the operation of the ball screw shaft 5a is stopped.
At this time, the means for detecting whether or not the injection apparatus 3 has moved directly below the desired mold 6 may be a generally known means. For example, a photoelectric tube sensor that moves together with the injection apparatus 3, a light A reflector may be provided to determine the presence of the mold 6 based on the presence or absence of light returning to the phototube sensor. Alternatively, the position information of the mold 6 may be stored in the control device C in advance. The ball screw shaft 5c may be operated until the device 3 moves from the base position to the position of the mold 6.
Alternatively, movement switches S, S... Are provided on the front surface of the top plate 1a on which the molds 6, 6... Are arranged, and the operator presses the switch S corresponding to the desired mold 6. Therefore, the injection device 3 may be moved directly below the mold 6.

Next, the rod 10a of the elevating cylinder 10 of the injection device 3 is extended to raise the nozzle mechanism F (see the upward arrow V shown in FIGS. 6 and 7).
And when the front-end | tip of the nozzle 12 contacts the injection hole of the metal mold | die 6 through the through-hole of the top plate 1a, the raise of the nozzle mechanism F stops (state of FIG. 8).
In this embodiment, whether or not the tip of the nozzle 12 is in contact with the injection hole of the mold 6 is determined by a pressure sensor provided in the lifting cylinder 10 of the nozzle mechanism F of the injection device 3. However, the means for detecting whether or not the tip of the nozzle 12 is in contact with the injection hole of the mold 6 is a generally known means and is not limited. For example, a proximity switch may be provided at the tip portion 18a of the nozzle 12 so that the tip of the nozzle 12 touches the injection hole of the mold 6 to determine whether or not the proximity switch is turned on. Information on the distance from the base point position of the nozzle mechanism F to the injection hole of the mold 6 is stored in the control device C, and the elevating cylinder 10 is operated until the nozzle mechanism F rises from the base point position to the position of the injection hole. It may be made to do.

Next, when the rod 13b of the injection control device 13 is lowered, the contact between the tip portion 13c of the rod 13b and the rear end portion 15f of the valve core 15 is released. When the material is filled in the injection path and the pressure in the injection path increases, the material pushes down the valve core 15 (see the downward arrow G shown in FIG. 2).
As a result, the tip 15e of the valve core 15 pressed against the injection hole 18 is released, the material injection path is opened, and the material is injected from the injection hole 18 of the nozzle 12 (arrow I shown in FIG. 2). reference). The injected material is filled into the internal space D of the mold 6 through the injection hole of the mold 6 (FIG. 2 shows an injection state).

When the rod of the injection control device 13 is lifted after the material in the inner space of the mold 6 is filled, the tip 13c of the rod 13b comes into contact with the rear end 15f of the valve core 15, and the rod 13b The valve core 15 is pushed up by further raising (see the upward arrow G shown in FIG. 8). The leading end of the valve core 15 is pressed against the rear end of the injection hole 18 to block the material path, so that the nozzle 12 stops the material injection and the material leaks from the injection hole 18. To prevent that.
The determination of whether or not the material has been filled in the internal space may be performed by a generally known means. For example, the material measured in advance to the capacity to be injected may be injected.
Then, after the injection of the material is completed, the entire nozzle mechanism F is lowered by lowering the rod 10a to prepare for the next movement / injection away from the back surface of the top plate 1a.

The system configuration using the injection molding machine according to the present invention will be described below.
FIG. 10 is an example of a system configuration diagram using an injection molding machine, in which two types of low viscosity materials are mixed and injected. For example, LIM (Liquid Injection Molding) in which the main agent and the curing agent are mixed, and the case where two colors of materials are used for injection correspond to this.

  A system using an injection molding machine includes two kinds of solutions (a liquid and b liquid) 30a and 30b, drum pumps 31a and 31b for transferring the solutions, and measuring cylinders 32a and 32b for measuring a fixed quantity. The injection cylinders 41a and 41b for sending out the solution from the measuring cylinder, the static mixer 60 for mixing the two kinds of sent-out solutions, and the injection molding machine A.

The plungers 33 a and 33 b of the measuring cylinders 32 a and 32 b are connected to each other, and the pressure plate 34 is further connected to the plunger 42 of the injection cylinder 40.
A potentiometer 41 is connected to the plunger 42 of the injection cylinder 40.

Check valves (one-way valves) 51a and 51b are provided in paths 50a and 50b connecting the drum pumps 31a and 31b and the measuring cylinders 32a and 32b, and further, paths 52a and 52b connecting the injection cylinder and the static mixer are provided. Are provided with ball valves 53a, 53b with air actuators.
The static mixer 60 and the nozzle 12 of the injection molding machine A are connected by a hose P.

The a liquid 30a stored in the drum is pushed out by the drum pump 31a and supplied to the measuring cylinder 32a. At the same time, the liquid b stored in the drum is pushed out by the drum pump 31b and supplied to the measuring cylinder 32b.
The solutions 30a and 30b supplied to the measuring cylinders 32a and 32b push up the plungers 33a and 33b of the measuring cylinders 32a and 32b, respectively.
The pushed-up plungers 33a and 33b are detected by proximity switches 34a and 34b provided on the pressure plate 34, and whether the solutions 30a and 30b stored in the measuring cylinders 32a and 32b have reached a predetermined amount by a control device (not shown). It is determined whether or not.
When supplying the solution to the measuring cylinders 32a and 32b, the ball valves 53a and 53b with air actuator are closed in the paths 52a and 52b connecting the injection cylinder and the static mixer, and the stored solutions 30a and 30b are Outflow to the static mixer 60 is prevented.

When the solutions 30a and 30b stored in the measuring cylinders 32a and 32b reach a predetermined amount, the ball valves 53a and 53b with the air actuator are opened, and the plunger 42 of the injection cylinder 40 is pushed down so that the pressure plate 34 is moved. Accordingly, the plungers 33a and 33b of the measuring cylinders 32a and 32b are pushed down. The solutions 30a and 30b are sent from the measuring cylinders 32a and 32b to the static mixer 60 by pushing down the plungers 33a and 33b.
At this time, the solutions 30a and 30b flow backward toward the drum pumps 31a and 31b by the action of the check valves (one-way valves) 51a and 51b in the paths 50a and 50b connecting the drum pumps 31a and 31b and the measuring cylinders 32a and 32b. There is nothing.

The static mixer 60 mixes the solutions 30a and 30b, and the mixed solution is supplied to the nozzle 12 of the injection molding machine A through the hose P.
"Modification of injection molding machine"

FIG. 9 shows a modification of the injection molding machine A.
In the present embodiment, the support structure of the injection device 3, the arrangement of the moving means 5 and the rails 4a and 4b are different from the injection molding machine of FIG.

The basic configuration of the injection device 3 is the same as that of the injection device by the injection molding machine shown in FIG. 6, but in this embodiment, the side surface in the depth direction of the base 8 is fixed in an orthogonal shape when FIG. 9 is viewed from the front. A flat base support plate 8b is provided.
Further, rail engaging means 8c and 8d are provided on the back side of the base 8 so as to extend in the horizontal direction with a predetermined interval.

  The basic configuration of the moving means 5 and the rails 4a and 4b is the same as that of the first embodiment. In this embodiment, the left and right columns 1c and 1f on the rear side in the depth direction when FIG. In the horizontal position, left and right support plates 5d and 5e having the same vertically long plate shape projecting toward the front pillars 1d and 1e are provided, and the moving means 5 is bridged between the left and right support plates 5d and 5e. At the same time, the rails 4a and 4b are bridged on the upper and lower sides of the moving means 5 with a predetermined gap between them.

Then, the back side of the base support plate 8b is fixed to the front surface of the slide block 5b provided in the moving means, and the engaging means 8c and 8d provided on the back side of the base support plate 8b are connected to the rail 4a, 4b is engaged.
By adopting such a configuration, in this embodiment, the injection device 3 is provided so as to be movable in the horizontal direction via the moving means 5 and the rails 4a and 4b on the rear side in the depth direction of the gantry.

According to a modification of the present injection molding machine, as compared with the injection molding machine shown in FIG. 6, the moving means 5 arranged immediately below the gantry is provided with the injection device so as to be movable in the horizontal direction as follows. There are various effects. That is, when the material is injected into the molds 6, 6..., Even if the material leaks and drops, the rails 4a, 4b and the moving means 5 may be contaminated by scattering to the lower side of the injection device 3. As a result, maintenance is improved.
The other configurations and operational effects are the same as those of the injection molding machine shown in FIG.
"Variation of moving means of injection device"

Further, in the injection molding machine shown in FIG. 6 and FIG. 9, the moving device of the injection device 3 is composed of a biaxial moving device in the horizontal direction and the vertical direction. By using the shaft moving means, the injection device 3 can be controlled to move in the depth direction.
For example, as a specific configuration of the three-axis moving means, for example, a linear motor in the depth direction may be incorporated in the base 8, or the ball screw shaft 5a may be a flexible helical body.
According to such a configuration, for example, it is possible to cope with the molds 6, 6... Arranged in a zigzag pattern. For example, the mold fixing jigs are arranged in a zigzag pattern on the top plate 1 a. Further, even if the types of molds arranged on the mold fixing jig are different and the distances between the injection holes between the molds are different, the three axes of the injection device 3 It is possible to cope with this by controlling the amount of movement by the control device C.

Sectional drawing which shows the state which injection of the nozzle for injection molding machines by this invention stopped. Sectional drawing which shows the injection state of the nozzle of FIG. FIG. 3 is an exploded view of the nozzle of FIG. 2. Sectional drawing which shows the modification of a nozzle. FIG. 6 is an exploded view of the nozzle of FIG. 5. The perspective view which shows the injection molding machine using the nozzle by this invention. Sectional drawing by the BB 'line | wire of FIG. Sectional drawing which shows the state which the nozzle of FIG. 8 raised. The perspective view which shows the modification of the injection molding machine using the nozzle by this invention. The system block diagram containing the injection molding machine using the nozzle by this invention. Sectional drawing which shows the nozzle for the conventional injection molding machines.

Explanation of symbols

A Injection molding machine 12 Nozzle 14 Nozzle body 14b Rear end 15 Valve core 16g Third valve core accommodation hole 17b Second valve core accommodation hole 18 Injection hole 19 First valve core accommodation hole 20 Material inlet

Claims (6)

The valve core is accommodated in the valve core accommodation hole communicating with the material inflow port so as to be able to advance and retract,
A nozzle comprising a packing and a slide ring disposed so as to be slidable between the valve core housing hole and the valve core,
An injection nozzle for an injection molding machine, wherein the packing is arranged closer to a material inlet than a slide ring. The nozzle is composed of a nozzle body and a valve core guide in contact with the rear end of the nozzle body,
The valve core housing hole communicates with a first valve core housing hole provided in the nozzle body through the same central axis as the first valve core housing hole, and a second valve core housing provided in the valve core guide. Composed of holes and
The nozzle body is provided with a material inlet that penetrates the first valve core housing hole from the outside of the nozzle body, and an injection hole that penetrates the outer periphery of the first valve core housing hole and the tip of the nozzle body. The injection nozzle for an injection molding machine according to claim 1, wherein the injection nozzle is used. The slide ring is disposed so as to be slidable between the second valve core housing hole and the valve core.
An injection nozzle for an injection molding machine according to claim 2. The packing is housed in a collar that surrounds the outer periphery of the packing,
The injection nozzle for an injection molding machine according to claim 2, wherein the collar is disposed between a rear end of the nozzle body and a valve core guide. The injection nozzle for an injection molding machine according to claim 4, wherein the collar is accommodated in a rear end portion of the nozzle body. The injection nozzle for an injection molding machine according to claim 4, wherein the collar is accommodated in the tip end portion of the valve core guide.

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