JPH07102591B2 - Synthetic resin screw forming method and device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for molding a synthetic resin screw and a molding apparatus for carrying out the method.

[0002]

2. Description of the Related Art Synthetic resin screws are significantly lighter in weight than metal screws and can be mass-produced, and the material cost is low, so that the manufacturing cost is low and the pitch is different. Since it is easy to manufacture products with different thread cross-sectional shapes, they are used by being incorporated into various types of feeding devices and are being used more and more.

For example, in a sorting device (sorter) installed in a copier, a large number of trays provided in the vertical direction are sequentially moved to predetermined positions to be dispersed and arranged, or they are gathered at the bottom, and further copying is performed. It is necessary to have a mechanism for making the interval of the portion where the ejected paper is sent out wider than other portions, and a synthetic resin screw is used for this mechanism. It is also used in various devices such as a camera zoom mechanism and a printer head moving mechanism.

[0004]

When molding such a synthetic resin screw by the cavities formed on the divided surfaces of the upper and lower molds, a screw longer than one pitch is extracted from the mold. Will be difficult. Specifically, when this screw is placed horizontally and viewed from the side, focusing on one side of the side (flight) of the screw thread, the upper half of the center line is 90 ° (1/4 pitch of the screw thread). It is the exposed state where you can see, that is, the "non-undercut state" in which the molded product can be pulled out from the mold in the direction of the eyes. On the other hand, it can be seen that the 90 ° range located below the center line following the upper half is not exposed, that is, the "undercut state" in which the molded product cannot be extracted from the mold.

The side surface of the upper half of the center line opposite to the side surface of the non-undercut thread is in an undercut state. When is a non-undercut state, the facing side is undercut. In this way, when focusing on the side surface of the screw thread, a so-called "undercut" portion in which the molded product cannot be extracted from the mold in the same portion of the screw thread occurs every 90 °, and When the surface is in a non-undercut state, the opposite side is in an undercut state.

Since the shape of the screw thread is formed by the twisted surface in this way, the material to be molded is flexible like polyethylene resin, and when the screw is thin, it may be forcibly separated from the mold. However, in the case of resin used for structural materials such as nylon, the undercut part gets caught in the mold cavity, so mold using a simple structure with few moving parts. Is practically difficult.

Another problem is that the cross-sectional shape of the screw thread is a square screw or a trapezoidal screw. However, when the square screw is formed, the side surface of the screw thread rises at a right angle to the bottom of the valley. Most of the threads are undercut,
It is difficult to remove the molded screw from the mold.
As a countermeasure, a trapezoidal screw having a considerably inclined side surface was used in order to make a draft. When a square screw with side faces formed at right angles to the valley bottom is used in the feed mechanism, it has the function of accurately feeding the feed member that meshes with this screw, but the molded product is easier to mold than the mold. If the side surface is inclined as described above so that it can be pulled out, there is a problem that the transfer distance of the feed member becomes inaccurate accordingly.

Therefore, when manufacturing a square screw made of synthetic resin, a screw having a trapezoidal cross section having a large draft was formed, and this had to be machined into a square screw. As described above, the square screw made of synthetic resin machined after the molding process has a good feed accuracy, but the manufacturing cost is unavoidable.

In the prior art, after molding the screw,
Due to the technical problem that it is difficult to remove this from the mold, when molding a synthetic resin screw,
"Screw unit" by positioning the screw shaft in the direction orthogonal to the mating surface of the mold in the state of being cut into 1 pitch lengths
It has been molded. Further, a convex portion and a concave portion which are fitted with a spigot are provided in the central portion of the screw unit body, and further, a projection portion for a stopper and a concave portion into which the projection portion is fitted are provided in the central portion in order to prevent displacement. ing.

The "mating surface" of the mold is a surface where a plurality of molds meet, and is a parting surface when the molds that have been molded are separated from each other. Means the part that appears. Hereinafter, in this specification, "division plane"
Called. When assembling the screw unit molded in this way to form a screw of a predetermined length, a metal rod is penetrated through the hole provided in the center of the screw unit, and the mating surface of the unit is further formed. The formed convex portion and concave portion are fitted to each other and assembled to give strength.

However, in the synthetic resin screw constituted by connecting the screw units in this manner, since the screw units are divided by one pitch of the screw thread, a step is likely to be formed on the joint surface to be connected. There's a problem. If the screw has a step as described above, the feeding is not smooth, noise is likely to occur, and accurate and stable feeding cannot be performed. Since a conventional synthetic resin screw is formed by connecting a large number of screw units in series, dimensional errors are accumulated, and a considerable size error occurs in the entire length of the screw. Further, since the screw units divided by one pitch are fitted and connected in the axial direction to assemble, the mechanical strength is low, and at most, it can be used as a feeder for a support plate of a sorter of a copying machine.

On the other hand, a precise screw is required for the zoom mechanism of the camera lens and the moving mechanism of the head of the printer, but only the one manufactured by machining each screw can be used for such an application. It is in. The present invention provides a single synthetic resin screw forming method with high accuracy and a device optimal for the same, which solves the drawbacks of the conventional synthetic resin screw forming method and its device.

[0013]

In order to achieve the above object, a method for molding a synthetic resin screw according to the present invention is such that a 1-pitch screw thread is divided into at least 4 parts around a screw shaft, and a mold is divided. Surfaces are formed on the threads and the bottom of the valley, and the 1-pitch threads are formed by at least 6 mold members to form a cavity. Molten resin is injected into the cavity to form a synthetic resin screw, With the mold member that is in the undercut state fixed to this screw, pull out the mold member that is in the non-undercut state, and then move the mold member that is in the undercut state to the non-undercut state. It is characterized by being extracted.

Further, when the screw is removed from the mold after molding, the slide core supported by the mold member is moved first, and then the mold member is opened. A synthetic resin screw molding apparatus according to the present invention includes a mold member (main mold member: an upper mold and a lower mold) that is divided into two parts from a dividing surface, and the mold member supported by the mold member. It is composed of at least 6 mold members of 4 slide cores (auxiliary mold members) that are extracted in a direction orthogonal to the dividing surface of the mold member. And, the cavity of the screw is formed on the mating surface where these mold members are assembled, and the dividing surface of these mold members is at least divided into four equal parts with one pitch of the screw thread centered on the screw axis. The mold is placed. Then, dividing surfaces of the mold are formed on the thread and the bottom of the valley, respectively, and the 1 pitch thread has a cavity formed by at least eight mold parts (parts on which the screw shape is engraved). It is a feature.

The mold is roughly divided into an upper mold and a lower mold (main mold members) divided into front and rear or right and left, and two sets of slide cores each constituting a part of the cavities of these mold members. It is a combination of (auxiliary mold members). The mold member in this case is composed of a minimum of 6 mold members including an upper mold, a lower mold, and four sets of slide cores. However, normally, when the mold member of the present invention is composed of an upper mold and a lower mold, the forming process of the cavity becomes remarkably complicated. Therefore, in order to avoid this, the upper mold and the lower mold are each divided into two parts. However, these molds are operated as one unit in the molding machine.

Specifically, the circumference of the molded screw is divided into four parts at intervals of 90 ° about the axis, and the cavity formed in each mold member and the slide core has a thread portion Y and a valley portion T. A parting line is formed on the and, and a cavity is formed on the surface in contact with the resin so that an undercut does not occur. The basic technical idea of the present invention is that the periphery of a screw to be molded is divided into four parts at equal angles around the screw axis, and a mold is arranged on each divided surface. Another feature is that a part of the upper die or the lower die and a slide core attached to the upper die or the lower die are arranged as a pair between the threads. However, in some cases, it is also possible to divide it further if necessary.

A total of 6 slide cores consisting of 2 die members for 1 pitch screw (ie upper die and lower die) and 2 sets provided on the upper die and lower die respectively, totaling 4 sets. The cavity formed in any one of the mold members and the slide core is brought into contact by contacting the mold members (when the upper mold and the lower mold are divided into two parts for the convenience of processing, a total of eight). Undercutting does not occur.

[0018]

[Operation] Therefore, a screw-shaped cavity is formed in a state where the upper die and the lower die and the slide cores respectively provided on the upper die and the lower die are assembled, and the molten synthetic resin is injected into the cavity. By holding the upper mold and the lower mold in the closed state of the mold and moving the slide cores respectively provided in the upper mold and the lower mold, the slide core portion is removed from the synthetic resin screw. In this state, the synthetic resin screws are supported by these molds by the upper mold and the lower mold.

As described above, since the synthetic resin screws are held by the upper mold and the lower mold, the screw is released from the mold member by making a relative opening between the upper mold and the lower mold. That is, the molded screw can be taken out. For convenience of explanation, the two mold members are described as the upper mold and the lower mold, but it is clear that the mold members may be arranged on the left and right.

[0020]

[Examples] Next, a method and an apparatus for molding a synthetic resin screw according to the present invention will be described with reference to the drawings. Fig. 1 shows a case where a synthetic resin screw 1 is molded on the horizontal axis. For convenience of drawing, an upper mold is arranged on the left side and a lower mold is arranged on the right side with the screw 1 as the center, and supported by each mold. It shows a state in which the slide core is retracted from the screw thread.

The mold has a horizontal line H ₁ -H ₂ passing through the center of the synthetic resin screw 1 and a mold member divided into a plurality of cross-sections by vertical lines V ₁ -V ₂ facing each other. The predetermined cavity 1a is formed in the assembled portion. Incidentally, in an actual molding apparatus, the molds are arranged on the left and right sides or vertically. The upper die of the mold includes a first upper die member 2, a pair of first slide cores 2a forming a part of the first upper die member 2, the first upper die member 2 and a pair. Second upper mold member 4 and a pair of second slide cores 4 forming a part of the second upper mold member 4.
It is composed of a. The lower mold paired with the upper mold is composed of a first lower mold member 3, a second lower mold member 5 and slide cores 3a, 5a.

The slide cores 2a, 4a, 3a, 5
For convenience of manufacture, a is individually manufactured and fixed to the support block 6 to be integrated, but it is also possible to manufacture the slide core and the support block as one body. Further, the upper mold and the lower mold are each divided into two and assembled, but these may be integrated as long as they can be manufactured.

These eight mold members 2, 2a,
A cavity 1a for molding the screw 1 is formed on the mating surfaces of 4,4a, 3,3a, 5,5a. First
A pair of first slide cores 2a is assembled to the upper mold member 2 so as to be movable in the direction of the center of the cavity 1a, and these first slide cores 2a are supported by a support block 6 to be integrated. There is. Further, the second slide core 4a provided on the opposite side of the first slide core 2a is also supported by the support block 6 and is integrally in the opposite direction to the first slide core 2a, and approaches the center of the cavity 1a. Or to separate from each other.

As will be described later, for example, in FIG. 1, the upper mold members 2 and 4 and the slide cores 2a and 4a engaged with the upper mold members 2 and 4 move integrally in the direction H _{3 with} respect to the plane of the drawing, and these slide cores are further moved. 2a, 4a is adapted to be moved to V ₃ or V ₄ direction, which is a direction perpendicular with H ₃ direction. The upper mold members 2 and 4 and the slide core 2 are usually
a and 4a are integrally fixed to the molding apparatus side. Further, the reason why the upper mold is divided into the upper mold members 2 and 4 and the lower mold is divided into the lower mold members 3 and 5, respectively, is that the mold of the present invention is complicated and the cavities are easily formed, as will be described later. Since it cannot be formed, it is for facilitating the formation of the cavity. If the cavity can be easily formed, the upper mold members 2 and 4 and the lower mold members 3 and 5 are formed. It is also possible to integrate each.

On the other hand, the lower die is composed of a first lower die member 3, a second lower die member 5, a third slide core 3a and a fourth slide core 5a. Then, for example, the upper molds 2 and 4 are fixed on a fixed support base of a molding apparatus, the lower molds 3 and 5 are supported on a movable support base, and the lower molds 3 and 5 are supported with respect to the upper molds 2 and 4. It can be moved. The molds for molding the synthetic resin screw 1 adopted for carrying out the present invention are the first upper mold member 2 and the second upper mold member 4, and these upper mold members 2 and 4, respectively. The supported first slide core 2a and second slide core 4a form one set to form an upper mold (or a left mold and a right mold). The symbol N is a nozzle for injecting the molten synthetic resin and is arranged in the center of the upper mold.

Further, the first lower mold member 3, the second lower mold member 5 and the third lower mold members 3 and 5 engaged with these lower mold members 3 and 5, respectively.
The slide core 3a and the fourth slide core 5a form a set to form a lower mold (or a right mold and a left mold), and are attached to the movable support base. Next, the movement of the mold member when molding the synthetic resin screw 1 will be briefly described. In FIG. 1, upper mold members 2 and 4 and slide cores 2a that engage with the upper mold members 2 and 4,
4a, the lower mold members 3 and 5, and the slide cores 3a and 5a engaging with the lower mold members 3 and 5 are gathered in the central portion to form a cross-shaped dividing surface, and the cavity 1a of the screw 1 is formed in the central portion. For example, the molten resin is injected from the nozzle N into the cavity from the center of the upper mold. When the resin is solidified, the slide cores 2a and 3a are pulled out in the V ₃ direction, and the other slide cores 4a and 5a are pulled out in the V ₄ direction. In this state, the synthetic resin screw 1 is supported between the upper mold and the lower mold.

Next, with the upper die members 3 and 5 fixed, the lower die members 2 and ₄ are moved in the H ₄ direction to take out the screw 1 formed inside the die from the opened die. Can be done. Although not shown, it goes without saying that a projecting pin or the like is used to take out the screw 1. FIG. 2 shows the upper mold members 2 and 4 and slide cores 2a and 4a, and the lower mold members 3 and 5 and slide cores 3a and 5a.
8 mold members of a are gathered in the central part and the cavity 1a
It shows a state in which is formed. The slide cores are fixed to the support blocks 6 and move as a unit.

The screw thread forming the screw 1 is formed by cavities S ₁ , S ₂ , S ₃ and S _{4 which} are divided into four around a cylindrical cavity B in the center of the mold member. It has become. In FIG. 3, the vertical axis V ₁ at one pitch p of the screw 1 is the center, that is, O °, minus 90 °, minus 180 ° on the right side, plus 90 °, plus 180 ° on the left side.
And 90 °, respectively, to show the arrangement of the mold members in that portion, and the vertical lines indicate the vertical axes V ₁ and V ₂ and the horizontal axes H ₁ and H ₂ of FIG. ₁ , respectively.

In the figure, each arrow shows the moving direction of each mold member forming the cavity 1a with reference to the position of V ₁ , that is, the position of O °.
The downward arrow indicates the mold member that moves to the front side, the upward arrow indicates the mold member that moves to the back side with respect to the paper surface, and the left and right arrows indicate the mold member that moves to the left or right. ing.

The following can be understood from FIG. A) Eight mold members are arranged to form one pitch thread. B) The slide cores 2a, 4a or 3a, 5a are 2 for the upper mold members 2, 4 or the lower mold members 3, 5, respectively.
-2a, 4-4a, 3-3a, 5-5a are arranged as a pair.

C) Adjacent die members move in directions different from each other by 90 °. D) The upper mold members 2 and 4 and the lower mold members 3 and 5 have different phases. For example, when the upper mold member 2 molds one side of a screw thread in the range of 90 °, the other upper mold member 4 molds the other side of the screw thread in the next range of 90 °.

Therefore, when the upper mold members 2 and 4 and the lower mold members 3 and 5 are integrally formed, they are arranged at different phases by 1/4 of the thread. 4 is shown in FIG.
The upper mold member 2 and the lower mold member 3 and the first slide core 2a and the third slide core 3a that are engaged with these are shown in the vertical axis V ₁ of FIG. The layout of the mold members is shown).

It can be understood from FIG. 4 that the slide cores 3a and 2a can be pulled out to the front side (shown by the downward arrow) because the undercut is not formed on the front side, but the upper mold member 2 and the The mold member 3 is in a state in which an undercut portion is generated on the side surface of the screw thread Y and the screw 1 is held. When the slide cores 2a and 3a come out of the die member, side cavity of the upper die member 2 and the lower die member 3 (see FIG. 7).
8)), the upper mold member 2 can be moved to the right and the lower mold member 3 can be moved to the left around the vertical axis V ₁ as indicated by the arrow.

Further, FIG. 5 shows the arrangement state of the die members on the horizontal axis H ₂ , and FIG. 6 shows the arrangement state of the die members on the horizontal axis H ₁ . In FIG. 5, the upper mold members 2 and 4 are movable to the front side where no undercut occurs, the slide core 4a is moved to the right side, and the slide core 2a is moved to the left side, as indicated by arrows.

In FIG. 3, the line [e] indicates the valley bottom portion T of the screw 1.
And the lines [f] and [g] respectively show the dividing surface formed on the top of the thread portion Y, and thus, the root portion T of the screw and the thread portion Y are thus formed. The dividing surface is formed on the top of the. Then, along the side surface of the same thread portion Y, a die member composed of an upper die or a lower die and slide cores are alternately arranged. In addition, 2 in the same place
A mold member and a slide core are arranged as a pair between the side surfaces of the one thread portion Y.

That is, eight mold parts are provided in the section formed by the vertical axis V ₁ , the horizontal axis H ₂ , the vertical axis V ₂ , the horizontal axis H ₁ , the vertical axis V ₂ and the dividing surfaces e, f, g. It is arranged. That is, 1 pitch p
Eight die members (a total of six die members when the upper die and the lower die are integrated) are arranged for forming the screw threads. As shown in FIG. 3, the _first axis is on the right side of the vertical axis V 1.
The upper mold member 2 and the first slide core 2a are arranged, and the first lower mold member 3 and the third slide core 3a are arranged on the left side, and the slide cores 2a and 3a are in front as shown by arrows. When it comes out to the side (V ₃ direction in FIG. 1), the upper mold member 2 moves to the right side (H ₃ direction in FIG. 1) and the lower mold member 3 moves to the left side (H ₄ direction in FIG. 1) to move sideways. In the range of 180 ° between the axes H _{1 and} H ₂ , a part of the screw 1 formed by removing the mold member and the slide core is separated from the mold.

FIG. 7 is a side view of the mold member shown in FIG. 2, showing the relationship between the cavity 1a of the screw 1, the mold member and the slide core. The valley portion T of the screw 1 is used as a base. The thread portion Y is formed in a spiral shape. The white parts on the left and right show the first upper mold member 2, the second upper mold member 4, the first lower mold member 3 and the second lower mold member 5, respectively. First slide core 2a, second slide core 4a, and third slide core 3
a and the fourth slide core 5a.

As shown in FIG. 7, the upper mold members 2 and 4, the lower mold members 3 and 5, and the slide core 2 are shown in FIG.
a and 4a, and the slide cores 3a and 5a have different phases, and the symbols in parentheses indicate mold members not shown. As can be understood from FIG. 7, the upper mold members 2 and 4, the lower mold members 3 and 5, and the first slide core 2a.
And a second slide core 4a and a third slide core 3a
And eight mold members consisting of the fourth slide core 5a,
The center line C of the screw 1 is used as a boundary to divide the upper and lower parts into two, and a parting line L is formed on the top surface of the thread portion Y and the valley bottom portion T.
(The symbols e, f, g in FIG. 3) are provided.
In other words, the cavity 1a is formed by assembling six or eight die members in order to form the screw thread 1 having one pitch.

The mold according to the present invention has the screw 1 formed inside the mold member as described with reference to FIGS.
The feature is that the parting line L (e, f, g) is provided on the top surface of the thread portion Y of the cavity 1a and the valley bottom portion T. The slide cores 2a and 3 of FIG.
a (the same applies to the slide cores 4a and 5a), the side surfaces (flights) of the threads are in a non-undercut state when viewed from the direction of extracting these cores, and the slide cores 2a and 3a are in the same direction (the front side of the paper surface). ), And also the slide core 4a
5a and 5a indicate that extraction is possible in the direction of the back surface of the paper.

These slide cores 2a, 3a,
After removing 4a and 5a, as shown in FIG. 8, cavities h, i, j, and
Since k, m, and n are formed, the upper mold members 2 and 4 and the lower mold members 3 and 5 can be used in the vertical direction with no undercut with respect to the paper surface by utilizing this cavity. You can move. That is, the upper mold members 2, 4 and the slide cores 2a, 4a associated with the upper mold members 2, 4
The lower die members 3 and 5 and the slide cores 3a and 5a attached to the lower die members 3 and 5 have undercut portions and non-undercut portions.
It is clear that this state is the same regardless of which part is taken by rotating the screw 1.

In other words, the remaining mold member, which is in a state of gripping the screw 1 by utilizing the cavity obtained by removing the slide core in the non-undercut state, is different from the extracting direction by 90 ° (Fig. It is possible to take out the molded screw 1 from the mold by moving it to (3). FIG. 8 shows a state in which the screw 1 is sandwiched between the upper mold members 2 and 4 and the lower mold members 3 and 5, and the slide cores 2a, 4a and 3a, 5a attached to the respective mold members are removed. Shows.

As a result of moving each slide core in the removing direction after molding, the portion R for molding the screw thread portion Y of the cavities h, i, j on the upper mold members 2 and 4 side is non-under when viewed from above the paper surface. It is located in the cut state and has a valley bottom T
The portion S for molding is a divided surface of the upper mold members 2 and 4. Further, the hollow parts k, m, n of the lower mold members 3, 5 form a non-undercut part and an undercut part at positions shifted by 90 ° from the above. That is, the slide cores 2a, 3a, 4a and 5 provided on the upper and lower mold members, respectively.
a can be extracted in a plane perpendicular to the paper surface shown in FIG. 8, and if these slide cores are extracted and cavities h, i, j, k, m, and n are formed. It means that the mold members 2, 4 and 3, 5 can be moved in the direction orthogonal to the slide core, that is, in the vertical direction on the paper surface.

FIG. 9 shows that after molding the synthetic resin screw 1, the slide cores 2a, 3a, 4a and 5a are removed, and then the upper mold members 2 and 4 and the lower mold members 3 and 5 are vertically moved (in FIG. 1). Shows a state in which the screw 1 is taken out by moving the screw 1 by a predetermined distance in the H ₃ and H ₄ directions. FIG. 10 shows a mold device attached to a molding machine, and an upper mold and a lower mold are arranged on the left and right in accordance with FIG.

The upper mold members 2 and 4 are fixed on the support plate 10, and the lower mold members 3 and 5 are fixed on the support plate 11. Although not shown in detail, the slide cores 2a and 4a are movably engaged with the upper mold members 2 and 4, respectively. Further, slide cores 3a and 5a are also engaged with the lower mold members 3 and 5, respectively. A cylinder device 12 is provided on the side of the support plate 10 (the cylinder device 12 is not necessary because the support plate 10 is fixed to the side of the molding device in a normal molding device), and a cylinder is provided on the side of the support plate 11. A device 13 is provided. Further, cylinder devices 14 are provided respectively in the upper and lower sides in the drawing for driving the slide cores 2a, 4a on the upper mold members 2, 4 side, and a cylinder for driving the slide cores 3a, 5a on the lower mold members 3, 5 side. The devices 15 are provided one above the other.

The upper mold members 2 and 4 are fixed to the molding machine side,
A nozzle N for injecting the molten resin is connected to the center of this. In this embodiment, as shown in FIG. 3, the mold has a complicated structure. Therefore, the upper mold members 2 and 4 and the lower members 3 and 5 are divided for convenience of manufacturing the mold. Is forming. However, if it is possible to manufacture, it is possible to form the upper mold member and the lower mold member by one mold member as described above.

When the upper mold members 2 and 4 and the slide cores 2a and 4a provided on the upper mold members 2 and 4 are supported on the support plate 10 and fixed to the molding machine side, the lower mold member 3 fixed to the support plate 11 is used. , 5 and slide cores 3a, 5a are driven back and forth by the cylinder device 13 to open and close the lower mold with respect to the upper mold. When the upper mold members 2 and 4 are fixed to the molding apparatus as described above, the cylinder device 12 is omitted.

If a cam mechanism is used instead of the cylinder device to move each mold member and the slide core engaged with the mold member, the device can be significantly downsized.
However, since this device is a complicated device, its illustration and description are omitted. When molding the synthetic resin screw 1,
The lower mold members 3 and 5 are placed at predetermined positions, and the cylinder device 15
Is operated to move the slide cores 3a and 5a to form the lower mold cavity.

With the above operation or with a time lag, the cylinder device 14 is operated to move the slide cores 2a, 4a to predetermined positions of the upper mold members 2, 4 to form the upper mold cavity. Next, the cylinder device 13 is operated to align the lower mold with the upper mold to form the cavity 1a of the screw 1 in the center of the mold. The closing operation of the mold is appropriately selected depending on the process.

When the cavity 1a of the screw 1 is formed in the mold as described above, the molten synthetic resin is injected from the injection molding machine through the nozzle N and held for a predetermined time to form the screw 1. To do. Next, the screw 1 thus formed
The order of removing the mold will be described. If injection molding of molten resin is performed in a state where the mold members of FIG. 1 are assembled as shown in FIG. 10, first, the cylinder devices 14 and 15 are operated to move the upper mold members 2 and 4 to the slide core 2a. 4a, and the slide cores 3a and 5a are moved from the lower mold members 3 and 5, respectively. This state is shown in FIG. 7 to FIG.
Through this step, the portion where the slide core was inserted becomes cavities h, i, j, k, m, and n.

Next, as shown in FIG. 9, slide cores 2a, 4a, 3 are utilized by utilizing the cavities h, i, j, k, m, n.
The screw 1 can be taken out by moving the upper mold members 2 and 4 in the H ₃ direction and the lower mold members 3 and 5 in the H ₄ direction orthogonal to the moving directions of a and 5a.
In addition, usually, the lower mold members 3 and 5 are retracted with respect to the upper mold members 2 and 4 to open between the upper mold and the lower mold.

As described above, the slide cores 2a, 4a, 3
When moving a and 5a, since the screw 1 is in a state of being attached to or gripping the upper mold members 2 and 4 and the lower mold members 3 and 5, these slide cores 2a, 4a, 3a and 5a can be easily moved. Can be made. As shown in FIG. 8, cavities h, i, j, k, m, and n are formed in the portion after the slide cores 2a, 4a, 3a, and 5a have been moved in this manner, and the cavities shown in FIG. Thus, the upper die member 2, 4 and the lower die members 3, 5 can be moved to take out the screw 1 from the die.

Further, with the upper mold members 2 and 4 in that position, the lower mold members 3 and 5 are retracted to open the mold, and then the screw 1 supported on the upper mold members 2 and 4 side. Can be taken out by sticking out with a sticking pin (not shown). The structure of the mold and the method of opening the mold have been described above. The structure of the mold for molding the screw and the features of the manufacturing method thereof are as follows.

1) The first feature of the method for molding a synthetic resin screw according to the present invention is to mold a synthetic resin screw by using a mold having split surfaces at the top and valley of the screw thread. . 2) The second feature is that slide cores are provided side by side in the upper mold and the lower mold, respectively, and the cavity is formed in the assembly portion of the mold member and the slide core. Form a part of the cavity, and the mold member and the slide core are movable in different directions. When the slide core moves in the non-undercut direction and a space is formed, The space is used to move the mold member in the non-undercut direction, and the screw formed by utilizing this feature can be easily extracted from the mold.

To form the non-undercut portion,
When the die member is viewed from the axial direction passing through the center of the screw 1,
It is divided on a cross plane that is divided into horizontal axes H _{1 to} H ₂ and vertical axes V _{1 to} V ₂ about this axis. When the upper die member and the lower die member are integrally formed, the division surface is formed between the upper die and the lower die, and the slide core is formed with the division surface in a direction orthogonal to the division surface. It

Further, the parting line L of the die member
(E, f, g) are formed at the top of the mountain portion Y and the valley bottom portion T. As described above, the upper mold members 2 and 4 that form the upper mold, the lower mold members 3 and 5 that form the lower mold, and the slide cores 2a and 4a engaged with these mold members, respectively.
3a and 5a are arranged at different positions by 90 ° as shown in FIG. 3, and the mold members on the side surfaces of the same thread portion Y can be moved in the directions displaced by 90 °.

By making the mold member movable in different directions within the range of 90 °, it is possible to prevent the undercut portion from being formed on the side surface of the thread portion. Further, when attention is paid between two screw thread portions at the same location, the upper mold member or the lower mold member and the slide core are arranged in a pair, and the moving directions of these members are different by 90 °. ing.

As described above, the upper mold members 2 and 4, the lower mold members 3 and 5, and the slide cores 2a, 4a and 3a which can move in directions opposite to each other in parallel to the dividing surfaces of these mold members.
, 5a in combination, it is possible to prevent the undercut portion from occurring at any place of the screw 1. According to the present invention, a long screw having a thread shape similar to that of a square screw or a screw that can be accurately fed,
Moreover, it is possible to continuously and integrally form.
This means that a long screw is not formed by combining the screw units as in the conventional case.

Since the long screw integrally formed in this way has a large strength and a step portion does not occur in the thread ridge or valley, a precise screw can be manufactured. Further, according to the present invention, a cavity portion consisting of a minimum of eight portions (a minimum of six dies) is continuously formed to form a one-pitch screw. By changing the shape of each cavity portion, the portion is formed. A new type of synthetic resin screw that could not be manufactured at all with conventional molding methods, such as screws with different pitches, screws with different thread cross sections, or those that do not have threads formed on specific parts. It can be easily molded. It should be noted that the cavity portion composed of at least eight portions does not necessarily mean that eight die members are required, and the upper die member and the lower die member, and the four die members provided on these die members, respectively. It goes without saying that it is also possible to constitute by a pair of slide cores. The present invention is not limited to the above-mentioned embodiment, but can be applied to a technique for manufacturing a screw made of synthetic resin within the scope of the technical idea of the present invention.

[Brief description of drawings]

FIG. 1 is a perspective view showing a state in which an upper mold and a lower mold are arranged on the left and right for convenience of drawing, and a synthetic resin screw is arranged in an intermediate portion thereof.

FIG. 2 is an explanatory diagram showing a relationship between an upper mold and a lower mold, a slide core (mold member) combined with these molds, and a synthetic resin screw.

FIG. 3 is a development view showing an arrangement state of an upper die, a lower die, and a slide core arranged within one pitch of a screw.

FIG. 4 is a diagram showing an arrangement of mold members at a position of V ₁ in FIG.

FIG. 5 is a view showing the arrangement of mold members at the position H ₂ in FIG.

FIG. 6 is a view showing the arrangement of mold members at the position H ₁ in FIG.

FIG. 7 is an explanatory diagram showing a relationship between an upper die, a lower die, and a slide core attached thereto.

FIG. 8 is an explanatory view showing a state in which a slide core is pulled out from an upper die and a lower die, and a synthetic resin screw is arranged inside.

FIG. 9 is an explanatory diagram showing a state in which an upper die and a lower die are moved to take out a synthetic resin screw.

FIG. 10 is a view showing a driving means of a mold.

[Explanation of sign]

1 synthetic resin screw 1a cavity 2 upper mold member 2a slide core 3 lower mold member 3a slide core 4 upper mold member 4a slide core 5 lower mold member 5a slide core 6 support block

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Claims (15)

[Claims] 1. A method for molding a screw made of synthetic resin, which comprises molding using a mold having dividing surfaces at the top and the bottom of the thread portion. 2. A mold having a split surface at the top and the bottom of the thread portion has screw cavities formed by an upper mold member, a lower mold member, and a slide core engaged with these mold members. After the cavity is filled with molten resin and solidified, the slide core is moved, and then the upper mold member and the lower mold member are moved by utilizing the space in which the slide core has moved to perform molding. The method for molding a synthetic resin screw according to claim 1, wherein the screw is taken out. 3. The slide core is moved in a direction that does not undercut the side surface of the thread of the molded screw,
The synthetic resin screw molding method according to claim 2, wherein the upper mold member and the lower mold member are moved in a direction intersecting with the screw. 4. The slide core is moved in a direction that does not undercut the side surface of the thread of the molded screw,
The method for molding a synthetic resin screw according to claim 2, wherein the upper mold member and the lower mold member are moved in directions different from each other by 90 °. 5. A single long screw is integrally formed along the dividing surface between the upper mold member and the lower mold member.
A method for molding a synthetic resin screw as described. 6. The method for molding a synthetic resin screw according to claim 1, wherein one screw having a thread having a different pitch or a partially different cross-sectional shape is integrally formed. 7. An apparatus for molding a screw made of synthetic resin, comprising: an upper mold member and a lower mold member; and a slide core supported by the upper mold member and the lower mold member, respectively, and pulled out in a direction parallel to a dividing surface. 8. An upper mold member and a lower mold member, and a slide core that is supported by these mold members and moves in a direction parallel to a dividing surface, and the slide core is formed of a screw to be molded. The molding device for synthetic resin screws according to claim 7, wherein the shaft has a contact surface at the center of the shaft. 9. An upper mold member and a lower mold member, and slide cores supported by these mold members and moving in a direction parallel to the dividing surface, centering around the axis of the molded screw. It is divided into four parts, and a cavity of 1 pitch thread is formed by at least eight cavity parts, and the moving direction of the slide core and the moving direction of the upper mold member or the lower mold member supporting the slide core differ by 90 °. An apparatus for forming a synthetic resin screw according to claim 7. 10. The upper mold member and the lower mold member are each divided into two mold members, each mold member is provided with a slide core, and a slide core is provided in a direction intersecting the moving direction of the mold member. The synthetic resin screw molding apparatus according to claim 7, wherein the screw is moved. 11. Upper die members 2, 4 constituting an upper die, lower die members 3, 5 constituting a lower die which are fitted to the upper die members 2, 4, and supported by these die members 2, 4, 3, 5 respectively. The slide cores 2a, 4a, 3a, which are moved in a direction parallel to the dividing surfaces of the upper mold members 2 and 4 and the lower mold members 3 and 5,
The synthetic resin screw forming apparatus according to claim 7, which is made of 5a. 12. The upper mold is composed of upper mold members 2 and 4 and slide cores 2a and 4a, and the lower mold is composed of lower mold members 3 and 5 and slide cores 3a and 5a. The synthetic resin screw forming apparatus according to claim 11, wherein the screw is supported so as to approach and separate from each other. 13. A mold for molding a one-pitch screw includes upper mold members 2, 4, lower mold members 3, 5, a slide core 2a,
The synthetic resin screw molding apparatus according to claim 11, wherein the cavity is formed by at least eight cavity portions which are composed of 4a, 3a, and 5a, and in which these mold members are assembled. 14. Slide cores 2a, 4a, 3a, 5a
12. The synthetic resin screw forming apparatus according to claim 11, wherein each is formed in a plate shape, and these are fixed by a support block 6 to be integrated. 15. The mold member arranged between the adjacent screw threads comprises an upper mold member or a lower mold member, and a slide core supported by these mold members as a pair. Item 11. A synthetic resin screw forming apparatus according to Item 11.