JPH0455568B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to an injection molding machine having a needle valve for opening and closing a nozzle at the tip of a heating cylinder.

(Prior art) Generally, in an injection molding machine, after measuring and accumulating plasticized resin by storing it at the tip of a heating cylinder, the screw is advanced to inject the molten resin into the mold. However, before injection, some pressure is applied to the molten resin in the heating cylinder, so if no measures are taken, molten resin will drip from the tip of the nozzle, which is called drueing. will occur.

Therefore, in some injection molding machines, a needle valve is inserted into the nozzle and the nozzle is blocked by the needle valve before injection to prevent drueing.

FIG. 5 shows a conventional injection molding machine of this type, in which 1 is a heating cylinder into which a screw 2 is inserted so as to be able to rotate and reciprocate; 3 is a cylinder head fixed to the tip of the heating cylinder 1; A flange 3a is formed at the base end of the cylinder head 3, and the rear end surface of the flange 3a is in contact with the tip of the heating cylinder 1. Numeral 4 is a bolt for fixing the cylinder head 3 to the heating cylinder 1, which passes through the flange 3a of the cylinder head 3 and is screwed into the tip of the heating cylinder 1. Reference numeral 5 denotes a head body fitted into the through hole 3b of the cylinder head 3. Steps 5a and 5b are formed on the outer surface of the head body 5, and the step 5b on the rear side is connected to the cylinder head 3.
It is in contact with a step formed in the through hole 3b.
As shown in FIG. 6, this head body 5 is formed with a plurality of resin passages 6, 6, . An opening 8 is formed. This opening 8 is the resin passage 6, 6
It extends in a direction perpendicular to... and opens into a through hole 9 formed in the peripheral wall of the cylinder head 3.

Reference numeral 10 denotes a nozzle, the base end of which is screwed into the through hole 3b of the cylinder head 3, and the rear end surface of the nozzle 10 is in contact with the step 5a on the front side of the head body 5.

A needle valve 11 opens and closes the tip opening of the nozzle 10. The base end of the needle valve 11 slidably passes through a sliding hole 12 formed in the center of the head body 5. It protrudes into the opening 8.

As described above, one end of the lever 7 is inserted into this opening 8, and the peripheral edge of the end surface of the proximal end of the needle valve 11 is in contact with it.

One end of this lever 7 is inserted into an opening 8 through a through hole 9 formed in the peripheral wall of the cylinder head 3, and is slidably supported by a pin 13 attached to the cylinder head 3. . The other end of the lever 7 projects outward from the cylinder head 3 and is connected to a drive mechanism 14 that swings the lever 7.

The drive mechanism 14 includes a cylinder 15 and a cylinder 1.
The operating rod 1 connected to the piston rod 15a of 5
6, and an operating rod 16 is connected to the other end of the lever 7 via a pin 17.

18 is a fixed plate, and 19 is a locate ring attached to the opening of the fixed plate.

(Problems to be Solved by the Invention) In the above configuration, the nozzle 10 is closed in advance by the needle valve 11 when measuring and accumulating the resin.
That is, before the metering accumulation starts, the cylinder 15
The piston rod 15a moves to the right in the drawing, and the operating rod 16 also moves to the right, so the lever 7 rotates counterclockwise. As a result, the needle valve 11 is in contact with one end of the lever 7.
moves forward and closes the nozzle 10.

When the metering accumulation is completed with the nozzle 10 closed, the piston rod 15a moves in the opposite direction to the above, and the operating rod 16 also moves to the left, so the lever 7 rotates clockwise and returns to its original position. Return to position. At this time, the nozzle 10 is still in the forward position, so the nozzle 10 is not in contact with the lever 7.

In this state, the screw 2 advances and injection is performed, and when the molten resin begins to fill a mold (not shown), a reaction force of injection pressure (maximum around 2000 kg/cm ² ) acts on the tip of the needle valve 11. Therefore, the needle valve 11 moves back and comes into contact with one end of the lever 7. In this way, the needle valve 11 is supported by the lever 7 during filling of the mold with resin.

By the way, since the rear end surface of the needle valve 11 is only partially in contact with one end of the lever 7,
The surface pressure during injection will be quite high. This surface pressure Pc
(Kg/cm ² ) is given by the following equation.

Pc=S ₂ /S ₁ ×P Here, S ₁ is the contact area between the needle valve 11 and the lever 7, S ₂ is the cross-sectional area of the needle valve 11, and P is the injection pressure (Kg/
^cm2 ).

Normally, the contact area S ₁ between the needle valve 11 and the lever 7 is
It is less than 1/3 of the cross-sectional area _S2 of the needle valve. Therefore, the surface pressure Pc becomes more than three times the injection pressure P.

As described above, in the above conventional example, excessive surface pressure acts on a part of the rear end surface of the needle valve 11, so fatigue of the needle valve is accelerated early, and when the needle valve 11 moves forward, the needle valve 11
Since the tip of nozzle 1 does not completely contact the inner wall at the tip opening of nozzle 10, it is not possible to completely prevent resin drooling.

Further, in the conventional example described above, the nozzle 10 is fixed to the cylinder head 3 by screwing, so the degree of tightening of the nozzle 10 becomes an issue.

That is, the thread diameter of the nozzle 10 is generally quite large, and therefore, a considerable amount of torque is required to sufficiently tighten the nozzle 10. For example, if the nominal diameter of the threaded part of the nozzle 10 is 40 mm,
A torque of 16300Kgcm or more is required. By the way, when tightening using a tool based on input, it is said that the torque limit is 10,000 kgcm when the nominal diameter is 36 mm or less.

In this way, it is extremely difficult to tighten the nozzle 10 sufficiently to apply pretension.
Therefore, the tightening must be incomplete, but if injection is performed in such a state, the head body 5 will expand in the radial direction and contract in the axial direction due to the reaction force of the injection pressure, so that the back of the nozzle 10 A gap is created between the end face and the step 5a on the front side of the head body 5, and between the step 5b on the rear side of the head body 5 and the step of the cylinder head 3. , B, the resin leaks, and the leaked resin passes through the outer peripheral surface of the head body 5 and the inner peripheral surface of the cylinder head 3 and enters the through hole 9 of the cylinder head 3.
leaks to the outside.

The present invention has been made to overcome the above-mentioned problems, and an object of the present invention is to provide an injection molding machine that can reduce the surface pressure of the nozzle against the lever and can prevent resin leakage.

(Means for Solving the Problems) The present invention provides a flange portion on the outer surface of the nozzle, and fastens the flange portion and a cylinder head attached to the tip of the heating cylinder with a screw member,
Furthermore, the base end of the needle valve inserted into the nozzle is slidably inserted into the sliding hole of the head body inserted into the cylinder head, so that the rear end surface of the needle valve can freely come into contact with the bottom of the sliding hole. and one end of a swingable lever is engaged with the circumferential surface of the needle valve, and the other end of the lever is connected to a drive mechanism that swings the lever.
That is what it is.

(Function) The needle valve moves forward and backward by swinging a lever engaged around the needle valve. During injection, the needle valve is moved backward by the swinging of the lever, and the rear end surface of the needle valve comes into contact with the bottom of the sliding hole in the head body. Therefore, the needle valve, on which the reaction force of the injection pressure acts, is supported by the entire rear end surface of the needle valve coming into contact with the bottom of the sliding hole. Therefore, excessive surface pressure is not applied to the needle valve, thereby preventing premature fatigue of the needle valve.

In addition, since the means for fixing the nozzle to the cylinder head is a screw member, it can be sufficiently tightened, and as a result, it is possible to give sufficient pretension to the screw member, and this pretension allows the nozzle to be sufficiently pressed against the head body. Pressure is obtained, and the head body expands in the radial direction due to the reaction force of the injection pressure. Even if there is a gap between the nozzle and the step inside the head, this gap is absorbed because the nozzle presses against the head body. Therefore, resin leakage caused by the above-mentioned gap is prevented.

(Example) Examples of the present invention will be described below with reference to the drawings. In FIGS. 1 and 2, the same reference numerals as in FIGS. 5 and 6 indicate the same or corresponding parts. A cylinder head 3 is fixed to the tip of the heating cylinder 1 via bolts 4, a head body 5 is fitted into the cylinder head 3, and a nozzle 1 in which a needle valve 11 is inserted is inserted into the cylinder head 3.
0 is attached, one end of the lever 7 is inserted into the opening 8 formed in the head body 5 through the through hole 9 of the cylinder head 3, and the drive mechanism 14 is connected to the other end of the lever 7. These points are similar to FIGS. 5 and 7, but the present invention differs from FIGS. 5 and 7 in the following points. That is, means for fixing the nozzle 10 to the cylinder head 3, means for supporting the needle valve 11 during injection, and means for linking the needle valve 11 and the lever 7.

These will be explained in order below. nozzle 10
The base end of the nozzle 10 is fitted into the through hole 3b of the cylinder head 3, and the rear end surface of the nozzle 10 is in contact with the step 5a on the front side of the head body 5. A cylindrical flange 21 is fitted on the outside of the nozzle 10, and the rear end surface of the flange 21 is in contact with the front end surface of the cylinder head 3. Further, a step portion 22 is formed on the inner surface of the flange 21, and this step portion 22 is connected to the nozzle 1.
It engages with a stepped portion 20 formed on the outer surface of 0. Furthermore, a plurality of screw holes 23, 23, .
Screw holes 24, 24... in locations corresponding to 3, 23...
is formed. Bolts 25, 25... are inserted into the screw holes 23, 23... of the flange 21, and their tips are connected to the screw holes 23, 23... of the cylinder head 3.
It has reached 4,24...

That is, the nozzle 10 is fixed to the cylinder head 3 via the flange 21 with bolts 25, 25, . . . . Therefore, the bolts 25, 25... are tightened to the extent that the bolts 25, 25... are pretensioned.
When tightened, the flange 21 is firmly pressed against the head body 5, and the head body 5 is firmly pressed against the stepped portion inside the cylinder head 3.

Next, the relationship between the needle valve 11 and the lever 7 will be described. As mentioned earlier, the proximal end of the needle valve 11 slidably passes through the sliding hole 12 of the head body 5 and projects into the opening 8 formed in the head body 5. The portion projecting into the opening 8 has a large diameter as shown in FIG. 3, and opposing portions of its circumferential surface are cut flat to form a flat portion 11a. That is, the portion of the needle valve 11 that protrudes into the opening 8 consists of a flat portion 11a and large diameter portions 11b and 11c located on both sides of the flat portion 11a.

FIG. 4 shows the lever 7, in which one end of the lever 7 located within the opening 8 is formed into a forked shape;
The flat part 11a of the needle valve 11 is located at the interval 7a between the forked parts.
is positioned, and when the lever 7 swings, it comes into contact with either of the large diameter portions 11b, 11c on both sides of the flat portion 11a. That is, when the lever 7 swings counterclockwise in the drawing, the left side surface of the forked part of the lever 7 comes into contact with the large diameter part 11b on the left side and moves the needle valve 11 forward, and conversely, the lever 7 swings clockwise. When it swings, the right side of the forked portion comes into contact with the large diameter portion 11c on the right side, causing the needle valve 11 to retreat.

As mentioned above, the lever 7 moves forward and backward by swinging the lever 7. When the lever 7 swings clockwise, the needle valve 11 moves back and the slide hole 12
It abuts on the bottom 12a of. The bottom 12a of the sliding hole 12 substantially coincides with the right side surface 8a of the opening 8 formed in the head body 5.

By the way, the bottom 12a of the sliding hole 12 is formed by a plug 26. That is, a through hole 27 is formed between the right side surface 8a of the opening 8 and the rear end surface of the head main body 5, and a plug 26 is fitted into this through hole.

In this way, the through hole 27 is formed in the head body 5,
The plug 26 is fitted into the through hole 27 of the needle valve 1.
This is done in consideration of ease of assembly between the head body 5 and the head body 5. That is, when assembling the needle valve 11 to the head body 5, the needle valve 11 is inserted from its distal end into the through hole 27 and the sliding hole 12, and after the proximal end of the needle valve 11 is positioned in the opening 8, The plug 26 is fitted into the through hole 27.

By the way, the diameter of the through hole 27 is larger than the diameter of the large diameter parts 11b, 11c so that the large diameter parts 11b, 11c of the needle valve 11 can be inserted therethrough.

Next, the operation of the injection molding machine having the above configuration will be described. When the raw resin is ready to be stored at the tip of the heating cylinder 1, the cylinder 15 is activated and the piston rod 15a moves rightward in the drawing. At the same time, the operating rod 16 also moves to the right, so that the lever 7 swings counterclockwise, and one end thereof abuts the left large diameter portion 11b of the needle valve 11, thereby moving the needle valve 11 forward. The needle valve 11 thus moves forward and closes the tip opening of the nozzle 10.

When the tip opening of the nozzle 10 is closed by the needle valve 11 as described above, the raw resin is supplied to the base end of the heating tube 1, and the supplied resin is transferred to the tip of the heating tube 1 by the screw 2. will be transferred to. The resin plasticized in this way is stored at the tip of the heating cylinder 1, but as described above, the nozzle 10
Since the tip of the needle is closed by the needle valve 11,
Plasticized resin does not drip from the tip of the nozzle 10.

When the measurement accumulation is completed, the nozzle 10 moves forward with respect to the mold (not shown), and a nozzle touch is performed.
Next, the piston rod 15a of the cylinder 15 moves to the left, and the operating rod also moves to the left, so that the lever 7 swings clockwise in the opposite direction to the above, and one end of the lever 7 moves to the right of the needle valve 11. Large diameter part 1
1c. After the contact, the lever 7 further swings to move the needle valve 11 backward. When the rear end surface of the needle valve 11 comes into contact with the bottom 12a of the sliding hole 12, the tip of the nozzle 10 becomes open and injection is performed.

Injection is performed by advancing the screw 2, and the plasticized resin is filled into a mold (not shown). During this injection, a reaction force of the injection pressure acts on the needle valve 11, and the needle valve 11 is pressed against the bottom 12a of the sliding hole 12. However, in the present invention, since the entire rear end surface of the needle valve 11 is in contact with the bottom 12a of the sliding hole 12, the surface pressure does not become excessive as in the conventional case. Since the rear end surface of the needle valve 11 that comes into contact with the bottom 12a of the hole 12 is formed by the large diameter portion 11c, the surface pressure is considerably smaller than the injection pressure.

The reaction force of the injection pressure as described above also acts on the head body 5, and the head body 5 expands in the radial direction and contracts in the axial direction. The nozzle 10 is firmly pressed against the head body 5 by the pretension acting on the head body 5, and the head body 5 is firmly pressed against the step inside the cylinder head 3, so that there is no space between the nozzle 10 and the head body 5 and There is no gap between the head body 5 and the cylinder head 3.

Therefore, it is better to use a large number of small diameter bolts 25 for fixing the nozzle 10 in order to increase the pretension.

(Effects of the Invention) As explained above, in the present invention, the nozzle is fixed by the screw member through the flange portion, so the nozzle is firmly pressed against the head body by the print tension acting on the screw member, and the nozzle is firmly pressed against the head body. Since the main body is firmly pressed against the cylinder head, there is no gap between the nozzle and the head main body and between the head main body and the cylinder head during injection.

Further, since the entire rear end surface of the needle valve is in contact with the bottom of the sliding hole, the surface pressure on the needle valve does not become excessive during injection, and therefore early fatigue of the needle valve is prevented.

[Brief explanation of the drawing]

Fig. 1 is a sectional view of an injection molding machine according to the present invention, Fig. 2 is an enlarged view showing the main parts of the invention, Fig. 3 is a perspective view of the needle valve, and Fig. 4 is a perspective view showing one end of the lever. Figure 5 is a sectional view of a conventional injection molding machine, Figure 6 is a sectional view taken along the - line in Figure 7, and Figure 7 is a sectional view of a conventional injection molding machine.
It is an enlarged view showing a part of the figure. 1... Heating tube, 2... Screw, 3... Cylinder head, 5... Head body, 6... Resin passage,
7... Lever, 8... Opening, 10... Nozzle,
DESCRIPTION OF SYMBOLS 11... needle valve, 12... sliding hole, 12a... bottom, 14... drive mechanism, 21... flange (flange part), 25... bolt (screw member).

Claims (1)

[Claims] 1. A cylinder head is attached to the tip of a heating cylinder into which a screw is inserted so as to be able to rotate and reciprocate, and a head body in which a resin passage is formed is inserted into the cylinder head, and the head body is attached to the rear of the head body. The nozzle protrudes from the cylinder head by bringing the end face into contact with a stepped portion inside the cylinder head, further fitting the base end of the nozzle into the cylinder head, and bringing the rear end face into contact with the front end face of the head body. A flange portion is provided on the outer surface of the cylinder head, the flange portion and the cylinder head are fastened together with a screw member to bring the rear end surface of the nozzle into pressure contact with the front end surface of the head body, and the cylinder head is further inserted into the nozzle. The proximal end of a needle valve that opens and closes the nozzle is slidably inserted into the sliding hole of the head main body, and the rear end surface of the needle valve is allowed to come into contact with the bottom of the sliding hole so that it can swing freely. one end of the lever is inserted into an opening formed in the head main body, the one end of the lever is engaged with the peripheral surface of the needle valve, and the other end of the lever is caused to swing. An injection molding machine characterized in that a drive mechanism for reciprocating the needle valve is connected thereto. 2. An injection molding machine according to claim 1, wherein the rear end surface of the needle valve that comes into contact with the bottom of the sliding hole is formed by a large diameter portion.