JPH0712631B2 - Injection mold and its injection molding method - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an injection molding die and an injection molding method therefor, and more particularly to an injection molding die for preventing backflow of resin from a cavity by performing gate sealing and a molding method therefor.

[0002]

2. Description of the Related Art Conventionally, in an injection molding die, a cavity for forming a cavity is formed in a fixed die and a movable die, and a groove portion for forming a runner is fixed as a resin supply passage to the cavity. There is one in which a sprue which communicates with the groove portion and supplies molten resin from the outside to the runner is formed on the mold side. In this injection mold, there was a problem that the resin injected and filled in the cavity backflowed under the influence of the pressure change on the runner side, causing distortion. It has been proposed to add a sealing function to solve the above problems.

Examples of this type of injection molding die and injection molding method include, for example, JP-A-48-7949, JP-A-57-34933, JP-A-57-70626, and JP-A-57-. No. 72831, JP-A-58-94
No. 436, No. 58-94440, No. 59-24620, No. 60-132719, No. 60-47227, No. 60-2.
08214, JP-A-61-252123,
In addition, those described in Japanese Utility Model Laid-Open No. 63-77721 are known, and the outline of each is described below.

(1) Described in JP-A- 48-7949
For the thing, the cavity block provided in the mold body
Cooling of molten resin material by moving by tons
During the period, we will cut the resin of the gate part and seal the gate.
With this, take out the molded product and cut it after molding
It is designed to save you time. (2) JP-A-57-349
The one described in Japanese Patent No. 33 has a plurality of cavities simultaneously.
Runner that communicates with each cavity in the injection device
-Have hydraulically driven flow path adjustment block
It controls the opening and closing of the runner channel diameter.
It is designed to control pressure.

(3) Described in JP-A-57-70626
Drive the pin with a pin drive cylinder,
Block the sprue part with
It prevents backflow. (4) JP-A-57-7283
The one described in Japanese Patent No. 1 has a shaft by a hydraulic cylinder.
That drives the shaft to close the sprue part with the shaft
Therefore, the resin flows backward in the pressure cooling process of the pressure compression molding method.
It is designed to prevent

(5) Described in Japanese Patent Laid-Open No. 58-94436
In the fixed mold and the movable mold, a fixed sleeve and a movable sleeve that surround the cavity and form a gate between the concave and convex portions adjacent to the cavity are provided, and the movable sleeve is closed in the mold closed state. By sealing the gate by pressing it against the fixed sleeve, it is possible to prevent the resin from flowing back from the gate in the compression step of the pressure compression molding method.

(6) Described in Japanese Patent Laid-Open No. 58-94440
The one with the same movable sleeve as (5) is pushed up
The resin of the gate part is cut by the close fitting of the
It eliminates the need to remove the gate part after projecting.
It (7) Those described in JP-A-59-24620
After the resin has flowed into the cavity, press the piston
The gate driven by the cavity from the injection cylinder side
To close the gate by protruding it into the runner leading to
is there.

(8) Described in JP-A-60-132719
The ones listed are for the fixed mold and the movable mold respectively.
With a movable piece-shaped cavity forming mold
To move these cavity forming molds relative to the main unit.
To prevent resin backflow in the pressure cooling process.
It has become. (9) Japanese Patent Laid-Open No. 60-208214
The one described has the fixed insert piece and the movable insert piece in the same sleeve.
By moving in parallel inside,
Move the sandwiched cavity away from the gate.
The resin inside the cavity when the gate is sealed.
It was made possible.

(10) Described in Japanese Patent Laid-Open No. 61-47227
The ones listed above depend on the pressure of the resin injected into the cavity.
The movable core is retracted, and the retracting movement of this core is redirected.
By means of transmitting to the backflow prevention body,
Pressure compression molding method
To prevent resin backflow in the pressurizing process
There is.

(11) Japanese Patent Laid-Open No. 61-252123
The ones listed are provided with an insert piece that is moved by a pressure cylinder.
The gate is shut off by moving the moving piece (moving in the axial direction).
It is something .

[0011]

However, in such a conventional injection molding die, a gate sealing mechanism is used.
Gate sealing of the drive source and its driving force such as the hydraulic system to drive
Since a link mechanism etc. for transmitting to the mechanism is required,
It was difficult to reduce the size of the injection molding die while providing it with a gate sealing function.

In addition, in the injection molding method, the game is
The molding process is complicated because the sealing mechanism is operated by external force, and it is not easy to take out and handle the molded product. Furthermore, when using the pressure compression molding method,
In that case, the pressure compression process is an essential process, and
As the molding die and the entire equipment become large-scale,
It was inevitable that the degree of complexity was too great.

On the other hand, it is highly accurate while eliminating such pressurization.
Injection molding with extremely high pressure
It would be good if the high voltage was driven externally.
Could not be sealed with the various gates mentioned above
Therefore, it is not possible to obtain excellent transferability without a pressure cooling step.
There wasn't. Therefore, the present invention can withstand high pressure and
A completely new type that does not require a drive source or transmission mechanism for sealing
Gate sealing function by realizing the gate sealing mechanism
Provide a small injection mold with
With an efficient molding method that does not require a process for sealing
Therefore, the pressure and compression process can be omitted, and high molding accuracy is achieved.
It is an object of the present invention to provide a new injection molding method that can obtain

[0014]

To achieve the above object, the invention according to claim 1 provides a cavity and a cavity.
Provided in a resin supply passage that communicates with a part of the resin supply passage
And a sealing mechanism section having a movable member
A metal mold, said movable member, the pressure and the cavity in the resin supply passage of the cavity-side is driven by the pressure difference between the pressure in the opposite side of the resin supply passage in the resin feed direction to said cavity tee It is a movable member that is capable of reducing the size of the gate sealing mechanism section.

The invention according to claim 2 isWith a cavity,
A resin supply passage communicating with the cavity, and a resin supply passage
A sealing mechanism section having a movable member provided in a part of the path,
An injection molding die comprising: the movable member,
Resin is filled in the cavity through the resin supply passage.
When moving, it moves in the resin supply direction due to the pressure of the resin
To form a predetermined flow path and complete the filling.
Sometimes, moving in the direction opposite to the resin supply direction
Characterized by closing a predetermined flow pathIs something
It makes it easier to downsize the gate sealing mechanism.
It

Further, the injection molding according to the invention of claim 3
The mold is formed in a part of the resin supply passage to the cavity.
A valve body storage part, a valve body stored in the valve body storage part, and
A gate formed on the opposite side of the valve body storage from the cavity
And a sealing mechanism section consisting of
When resin is filled in the cavity,
The valve body is seated on the gate by the pressure of the resin
The feature is that the gate is sealed, and
This is to obtain the sealing performance.

According to a fourth aspect of the present invention, the gate is the
With a stepped valve seat that protrudes inward from the inner wall of the resin supply passage
Seated on the inner peripheral edge of the gate.
The gate sealing property is
It is to improve the performance. Further, claim 5
Of the injection molding method according to the invention of
Gate on a part of the passage and on the cavity side of the gate
Prepare a split mold in which the valve body storage part to be positioned is formed, and
Prior to the mold clamping, the groove forming the resin supply passage is
A process for storing the valve disc in a portion corresponding to the valve disc storage part
Then, the mold is clamped and the cavity and the resin are supplied.
A step of defining a supply passage, a step of injecting and filling a molten resin into the cavity through the resin supply passage, and a step of seating the valve element on the gate by the pressure of the resin in the cavity and sealing the gate And a step of solidifying the resin in the gate-sealed state, and a step of opening the mold to take out the solidified resin in the cavity and the valve body storage portion. A molding method suitable for a molding die, capable of obtaining high molding accuracy while omitting a special step for gate sealing, and capable of omitting a pressure compression step.

[0018]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the drawings. 1 to 3 are views showing a first embodiment of an injection molding die according to the present invention. First, the configuration will be described. 1 to 3, reference numeral 1 is an injection mold, and the injection mold 1 has a fixed mold 2 and a movable mold 3. Fixed mold 2
The movable mold 3 is a pair of split molds, which are brought into contact with and separated from each other in the vertical direction in the figure. Fixed mold 2
The groove portions 2a, 2b, 2c, the concave portion 2d and the mold clamping surface 2
e is formed, and the movable mold 3 is formed with grooves 3a, 3b, 3c facing each of the fixed molds 2, a recess 3d, and a mold clamping surface 3e. When the mold clamping surface 2e and the mold clamping surface 3e are brought into contact with each other, the groove portions 2a and 3a form the first runner 5, and the groove portions 2b and 3b form the second runner 6 ( tree.
The valve body accommodating portion ) formed in a part of the oil supply passage is provided with the groove portion 2
c and 3c define the second gate 7 and recesses 2d and 3d.
Respectively configure the cavities 8 in which the molded products are molded. Also, the fixed mold 2 is formed with a sprue 9 is a flow inlet of the molten resin, the sprue 9 communicates with the cavity 8 through the first runner 5, the second runner 6 and the second gate 7 , These sprue 9 to the second
Cavity by each passage 5, 6, 7, 9 to the door 7.
A resin supply passage to 8 is formed.

Between the first runner 5 and the second runner 6,
That is, a step-like first gate 10 protruding inward from the inner walls of the runners 5 and 6 is formed on the side opposite to the cavity 8 with respect to the second runner 6.
10 is an inner valve seat facing the spherical valve body 4 (movable member)
It has a peripheral edge 10a . Inner peripheral edge 10 of this first gate 10
Although a is a sharp edge, the edge may be chamfered. In this case, it is preferable that the chamfering width, that is, the chamfering width of the two surfaces (the fixed mold 2 side and the movable mold 3 side) forming the inner peripheral edge 10a is 1 mm or less.

Reference numeral 11 is a stop pin
11 is supported by the fixed mold 2 so as to project into the groove 2b. The spherical valve element 4 is housed in the second runner 6 between the stop pin 11 and the first gate 10, and the spherical valve element 4 stops when the molten resin flows into the cavity 8. When the resin hits 11 and is locked, and the resin is about to flow out of cavity 8, the first gate
It is pressed against the stepped inner peripheral edge 10a of the step 10 and is seated in a liquid-tight manner.

That is, the injection molding die 1 of this embodiment is
Cavity 8 and the resin supply communicating with the cavity 8
The passages (5, 6, 7, 9) and some of these passages
And a spherical valve body 4 provided therewith.
4 is a cavity in the resin supply direction to the cavity 8.
The pressure inside the runner 6 on the 8th side and the side opposite to the cavity 8
To be driven by the pressure difference from the pressure inside the runner 5
And the cavity through the resin supply passage
When resin is filled in 8, the pressure of the resin causes
Moving in the resin supply direction to form a predetermined flow path 12, while,
When the filling is completed, the direction opposite to the resin supply direction
To close the predetermined flow path 12. Can be moved
Noble spherical valve body 4 and the second runner 6 that houses it
The first gate 10 on which the spherical valve body 4 can be seated and pressure contacted, and the spherical valve
A stop pin that regulates the movement of the body 4 toward the cavity 8
11 and constitutes a sealing mechanism unit 15, and the sealing mechanism unit 15 is
Cavite through the first runner 5 and the second runner 6.
When the resin is filled into the cavity 8, it is filled into the cavity 8.
The spherical valve body 4 is moved to the first gate 10 by the high pressure of the resin that is generated.
It has a valve-type gate sealing mechanism that is seated on.

Next, together with its operation, an embodiment of the injection molding method according to the present invention which is carried out by using the above-mentioned structure will be described. First, an injection molding consisting of a fixed mold 2 and a movable mold 3.
Prepare the mold 1, and before clamping the molds 2 and 3 (mold
(Before tightening), runner forming grooves 2a, 2b
In the part 2b corresponding to the second runner 6 (valve body storage part)
The spherical valve body 4 is stored. Then, molds 2 and 3 are clamped
The first runner 5, the second runner 6, the gate 7 and
The cavity 8 is defined.

In this state, a molten resin is injected from an injection molding nozzle (not shown), and this resin is passed from the sprue 9 to the first runner 5, the first gate 10, the second runner 6, and the second gate 7. It is made to flow in one by one, and the molten resin is filled in the cavity 8 via these. At this time, as shown in FIG. 2, the stop pin is driven by the pressure F of the inflowing molten resin.
The spherical valve element 4 pressed against 11 does not obstruct the molten resin flowing from the first runner 5 having a large pressure to the second runner 6 having a small pressure.

When the pressure of the molten resin filled in the cavity 8 reaches the set pressure, the injection of the injection nozzle is stopped. When the pressure in the first runner 5 starts to drop due to the stop of the injection, as shown in FIG. 3, the molten resin tends to flow backward from the second runner 6 having a large pressure to the first runner 5 having a smaller pressure than this. At this time, the spherical valve body 4 is pressed against the first gate 10 by the reverse flow pressure F'and is pressed against and seated on the first gate 10. In this state, the semi-solidified layer is formed on the edge surface of the inner peripheral edge 10a, which is the valve seat, by the solidification of the resin.
This semi-solidified layer is a very thin film of resin that has solidified by contacting the wall surface of the mold, and is called a skin layer. Usually, a very large force is required to crush the semi-solidified layer formed on a flat surface, but in the present embodiment, the semi-solidified layer is formed on the edge surface of the stepped inner peripheral edge 10a which is a sharp edge. Therefore, the semi-solidified layer can be easily crushed with a small force. Therefore, the spherical valve body 4 is
The liquid can be easily seated on the gate 10 in a liquid-tight manner, and the resin flowing back from the gap of the semi-solidified layer can be completely sealed in a short time, that is, the flow passage 12 can be closed to secure the first gate 10 securely. Seal. In this way, the resin in the cavity 8 immediately after the injection is stopped
Utilizing the differential pressure between the pressure and the resin pressure of the first runner 5.
The pressure contact of the spherical valve body 4 to the first gate 10 causes wear translocating can be gate sealing.

Then, the cavity is sealed in this gate-sealed state.
While maintaining the resin in 8 at a predetermined pressure, it is cooled and solidified.
After that, the fixed mold 2 and the movable mold 3 are opened to form a molded product.
Take out (not shown). At this time, the spherical valve body 4
Is solidly seated in the liquid, and
It is cut off before and after the gate 10 of 1.
Product part in cavity 8 and second runner 6 and gate
The resin solidified in 7 integrally forms grooves 2b, 2c and
And the concave portion 2d. Therefore, this molding
The product is a molded product body corresponding to the shape of the cavity 8, and
Corresponding to 2 runners 6 and molded integrally with the body of the product
A part of the valve body 4 has a valve body exposed portion exposed at the end.
Will be

Thus, in this embodiment, injection molding
In the second runner 6 of the mold 1, in response to the front and rear resin pressure,
A spherical valve element 4 that opens and closes the flow path 12 is provided so that external force is required.
Since the sealing mechanism section 15 that does not require is configured,
Gate cutting mechanism by means of etc. and complicated machine for crushing
A compact and simple sealing mechanism can be realized without the need for a structure.
A small injection mold 1 that has a gate sealing function.
Can be provided. Also, as mentioned above, the fixed mold
2 and the spherical valve body 4 prior to the mold clamping of the movable mold 3.
It is stored in 2 runners 6, and injection resin pressure is applied to this spherical valve body 4.
When the cavity 8 is injected and filled, the gate is sealed.
For gate sealing (and disconnection)
The number of man-hours is reduced, and even with high injection resin pressure,
Indeed, it becomes possible to seal the first gate 10. Furthermore
In addition, injection molding with high forming degree without pressure compression process
Shapes can be made.

4 to 7 show an injection molding die according to the present invention.
It is a figure which shows a 2nd Example. First, FIG. 4 shows a state immediately after mold clamping of the fixed mold 21 and the movable mold 22 in the present embodiment. The spherical valve body 23 (movable member) is the valve body of the fixed mold 21 before the mold clamping. It is stored in the storage section 24a. Fixed mold 21 and movable mold 23 are clamped, cavity 25, runner
26 (resin supply passage), valve housing chamber 24 and first gate
Once 30 has been defined, then the sprue, as shown in FIG.
The molten resin P is supplied from the 28 (resin supply passage) to the valve body storage chamber 24. At this time, the spherical valve body 23 separates from the first gate 30 , which is the valve seat, by the supply pressure of the molten resin P, and contacts the stopper 29. Since the stopper 29 is arranged so as to allow the molten resin P to pass therethrough, the molten resin P in the valve body accommodating chamber 24 is supplied into the cavity 25 via the second gate 27 . When the molten resin P is filled in the cavity 25,
The supply of the molten resin P from the sprue 28 is stopped, and the molten resin P tries to flow back to the sprue 28 side. At this time,
As shown in FIG. 6, the spherical valve body 4 has a tapered first gate.
Seat watertightly on the boat 30 and close the runner 26 halfway.
After the runner 26 is closed, the resin P in the cavity 25 is solidified. Next, the mold opening is performed as shown in FIG. At this time, the resin molded product P ₁ (molded product body) molded in the cavity 25 can be taken out. Next, when the push-out pin 31 is projected into the valve body housing portion 24a,
The second resin portion solidified without a break integrally with the resin molded article P ₁ at the gate within 27 of P ₂ (valve body exposed portion) is lifted with the resin molded article P _1. At this time, the resin portion P ₂ and the subsequent
It is separated from the resin in the resin supply passage by a spherical valve element 23.
Therefore, as shown in FIG. 7, the resin portion P _{2 on} the right side in the drawing
A part of the spherical valve body 23 is exposed at the end. According to
Molded product in which resin molded product P ₁ and resin portion P ₂ are integrated
Is completed.

Thus, also in this embodiment, injection molding is performed.
The valve body storage chamber 24 is formed in a part of the mold runner 26.
A spherical valve element 23 that can be seated on the first gate 30 is stored in the chamber 24.
As a result, a compact and simple sealing mechanism section is constructed. According to
The gate cutting mechanism and trees that require external force as in the past.
Without providing a complicated mechanism for crushing fat,
Realizes a small injection mold with gate sealing function
You can

Further , as described above, the balls are
The valve body 23 is stored in the valve body storage chamber 24 which is a part of the runner 26.
Then, the spherical valve element 23 and the resin pressure are applied to the cavity 25.
After the gate is sealed when the injection filling is completed,
Both perform the injection molding method of taking out the spherical valve body 23.
Therefore, the number of steps for gate sealing is reduced, and
It is easy to take out and handle the shape. In particular,
When projecting the extrusion pin 31 to the valve body accommodating portion 24a as described above, projecting the molding body solidified while integrally connected to the resin molded product P ₁ is a resin portion P ₂ (valve exposed portion) As a result, the resin molded product P ₁ is not damaged,
The work of taking out a molded product becomes extremely easy.

A gate sealing function is added and the size is reduced.
In this respect, the effects of both the first and second embodiments are as described above.
Although obtained, the first embodiment is preferable in terms of sealing performance.
Yes. That is, the comparison of the sealing performances in both Examples by the change of the resin pressure in the mold is as shown in FIG.
In the figure, injection of the molten resin is started at time t ₀ and stopped at time t ₁ . In the case of the second embodiment, it takes a time from t ₁ to t ₃ until the spherical valve body 23 crushes the semi-solidified layer and seats on the first gate 30 to seal the outflow of the resin. the pressure in the mold is reduced, in the case of the first embodiment, since the spherical valve body 4 immediately after the injection stop t ₂ is seated on the inner peripheral edge 10a of the first gate 10 stepped, semi-cured layer moment And the reverse flow of the resin is almost completely prevented. That is, in the first embodiment, by forming the first gate 10 as a stepped valve seat, it is possible to extremely reduce the pressure drop in the mold during gate sealing, and to ensure deformation during cooling. Therefore, it is possible to obtain a molded article with higher accuracy.

It goes without saying that the technical scope of the present invention is not limited to the embodiments. For example, although the above-described embodiment is a mold and a molding method that do not require a pressure compression step, it can be applied to a mold and a molding method that perform a pressure compression step. Even in this case, it is possible to eliminate the mechanism for transmitting the force from the outside to the sealing mechanism, reduce the size of the mold and reduce the cost, and improve the gate sealing performance. This is because there is no difference in achieving the effect of being able to do it.

[0032]

According to the invention described in claim 1, the movable member
On the cavity side in the direction of resin supply to the cavity
Of the resin inside the resin supply passage and the resin on the side opposite to the cavity
Because be driven by differential pressure between the pressure in the supply communication path may be a simple sealing mechanism in conventional small that does not require an external force so.

According to the second aspect of the present invention, a tree for the cavity is provided.
For the oil-filled character, the movable member is a resin supply method by the pressure of the resin.
To form a predetermined flow path, and
By moving the movable member in the direction opposite to the resin supply direction,
Since the flow path is closed, it is possible to
The gate can be opened and closed only by itself, making it possible to reduce the size of the injection mold.
Can be made easier.

According to the invention of claim 3, the resin supply passage
A valve body storage part in a part of the passage and a cavity for the valve body storage part
And a gate located on the opposite side of the
The valve body is stored in the body storage unit to form the sealing mechanism unit.
So a small and simple encapsulation machine that does not require external force
It can be used as a structural part and has high injection resin pressure.
However, the resin pressure is used to exert a reliable gate sealing function.
We provide an injection mold with high molding accuracy and excellent transferability.
You can

According to the invention of claim 4, the gate is stepped.
Formed in a difference shape so that the valve body is seated on the inner peripheral edge
Therefore, the pressure in the mold during gate sealing may drop significantly.
Can be reduced to prevent deformation during cooling.
It is possible to obtain a highly accurate molded product. Claim 5
According to the invention, the valve body is attached to the valve body prior to the mold clamping of the split mold.
It is stored in the storage part and this valve body is injected and filled into the cavity.
When the resin pressure at the time of completion is set, the gate will be pressure-bonded and seated.
To prevent the gate from leaking even if the resin pressure is high.
Can be stopped, and the man-hour for gate sealing is small,
Efficient molding work can be performed and
It is also very easy to take out shaped articles. Furthermore, pressurization
You can also eliminate the compression step, so do it
More efficient molding work can be performed.

[Brief description of drawings]

FIG. 1 is a sectional view of an essential part showing a first embodiment of an injection molding die according to the present invention.

[Fig. 2] When molten resin is injected into the cavity
It is an action explanatory view showing a gate as a valve body and its valve seat .

FIG. 3 is an operation explanatory view showing the valve body and the gate when the gate is sealed .

FIG. 4 shows a second embodiment of an injection molding die according to the present invention .
FIG.

FIG. 5 shows that molten resin is injected into the cavity .
In the action explanatory view showing the gate as the valve body and its valve seat
is there.

FIG. 6 is a function theory showing the valve body and the gate when the gate is sealed .
It is a clear view.

FIG. 7 is an explanatory diagram of the molded product taking-out step.

FIG. 8 shows the gate sealing performance of the first and second embodiments with gold.
It is a graph which compared by the resin pressure change in a type | mold.

[Explanation of symbols]

1 Injection mold 2,21 Fixed mold (divided mold) 2b Groove (Valve housing in the groove that forms the resin supply passage )
Part corresponding to the storage part) 3,22 Movable mold (divided mold) 4,23 Spherical valve body (movable member, valve body) 5 First runner (resin supply passage) 6 Second runner (one of resin supply passage) Provided in the department
Valve housing portion) 7, 27 a second gate (resin supply passage) 8, 25 cavity 10, 30 a first gate (stepped valve seat) 10a within a peripheral edge 12 a predetermined flow passage 15 the sealing mechanism 24 valve Body storage chamber (valve body storage part) 24a Valve body storage part (valve of groove forming resin supply passage )
Part position) 26 runner corresponding to the body housing portion (resin supply passage) P molten resin P ₁ resin molded article (molded article body) P ₂ resin portion (the valve exposed portion)

Claims (5)

[Claims] 1. A and cavity, communicating with the cavity
A resin supply passage and an optional resin provided in a part of the resin supply passage.
With a sealing mechanism section having a moving member,
There, the movable member, the resin supply to the cavity
And pressure in the resin supply passage on the cavity side in the
To the pressure difference between the resin supply passage on the side opposite to the cavity
Injection molding characterized by being a movable member driven more
Shaped mold. 2. A cavity and a communication with the cavity.
A resin supply passage and an optional resin provided in a part of the resin supply passage.
With a sealing mechanism section having a moving member,
If the movable member passes through the resin supply passage,
When resin is filled in the cavity,
Moves in the resin supply direction by pressure to form a predetermined flow path
Rutotomoni, when the fill is completed, the resin supply
Moving in the opposite direction to close the predetermined flow path
An injection molding die characterized in that. 3. Formed in a part of a resin supply passage to a cavity
Valve body storage section and valve body stored in the valve body storage section
And is formed on the side opposite to the cavity with respect to the valve body storage portion.
And gates, comprising a sealing mechanism consisting, the resin supply
When resin is filled in the cavity through the passage,
The pressure of the filled resin causes the valve body to move to the gate.
Injection mold to feature that the gate sealing seated. 4. The gate is provided from an inner wall of the resin supply passage.
The gate is formed as a stepped valve seat protruding inward.
The valve element is seated on the inner peripheral edge of the
The injection mold according to claim 1. 5. A gate is provided in a part of a resin supply passage to the cavity.
And valve body storage located on the cavity side of the gate
Prepare a split mold with parts formed on it and prior to clamping the mold.
The valve body housing in the groove forming the resin supply passage
A step of accommodating the valve body in a portion corresponding to the part, mold mold
Tighten to define the cavity and resin supply passage
Process, and through the resin supply passage into the cavity
The step of injecting and filling the molten resin with the resin in the cavity
The valve is seated on the gate by pressure and the gate is sealed.
And the process of solidifying the resin in the gate sealing state.
Then, the mold is opened to open the cavity and the valve body.
And a step of taking out the resin solidified in the storage section.
Characteristic injection molding method.