KR102665357B1 - Magnet core pin with sensor applied to detect defective inserts in injection molds - Google Patents

Abstract

The present invention relates to a magnet core pin applied with a sensor for detecting insert defects in an injection mold, which is implemented to reduce the insert defect rate by stably fixing the insert to the object during the injection process, and is installed in the injection mold at the position where the insert is to be seated. Core pins installed; A magnet installed at the front end of the core pin to fasten the insert; A cap pin that covers the magnet and is fastened to the core pin, and on which the insert is seated; and a temperature sensor installed along the inside of the core pin and the cap pin and sensing the temperature of the cap pin.

Description

Magnet core pin with sensor applied to detect defective inserts in injection molds}

The present invention relates to a sensor-applied magnet core pin for detecting insert defects in an injection mold. More specifically, a sensor-applied magnet for detecting insert defects in an injection mold implemented to detect defects in the presence or absence of an insert in an injection mold. It's about core pins.

For example, frames that support battery cells for secondary batteries include one or more nuts or bushes made of different materials, more specifically, metal materials. Frames of this type are injection molded from plastic material with one or more nuts or bushes inserted.

A frame in which such metal nuts or bushes are integrated together is manufactured by double insert injection molding. like this

Double injection molding includes a set of mold blocks including a mold base and a plurality of slide mold blocks located therein. Additionally, a set of mold blocks defines a molding space, and core pins are used to retain the inserted nut or bush within that molding space.

The insert injection process is used in a repetitive process of manually inserting the insert into the insert core pin within the mold, ejecting the product, and then inserting the insert again.

When inserting an insert part, it is held only by the magnet inserted into the mold core pin itself, so a large amount of separation occurs due to insertion errors by the operator and vibrations from various injection machines. This is linked to an increase in the defect rate, so injection molding is used to reduce this. We visually inspect products by hand.

The magnetic force of the inserted magnet decreases in strength over a certain period of time, which is believed to be the cause of insert separation defects. Since the injection machine injects according to the operator's signal regardless of the presence or absence of an insert, defects can be reduced. This is something that cannot be done.

Meanwhile, the above-mentioned background technology is technical information that the inventor possessed for deriving the present invention or acquired in the process of deriving the present invention, and cannot necessarily be said to be known technology disclosed to the general public before filing the application for the present invention. .

Korean Patent No. 10-0659368 (announced on December 19, 2006)

One aspect of the present invention is that it was previously impossible to check whether there was an abnormality in the magnetic force of the magnet. However, by attaching a temperature sensor to each core pin, the temperature difference monitored through the temperature sensor was used when insert separation failure occurred due to inconsistent magnetic force in the magnet. We provide a sensor-applied magnet core pin to detect insert defects in injection molds, which can be expected to achieve great results in quality improvement by checking the presence or absence of inserts using .

The technical problem of the present invention is not limited to the technical problem mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below.

A magnet core pin applied with a sensor for detecting defective inserts of an injection mold according to an embodiment of the present invention includes a core pin installed in the injection mold at a position where the insert is to be seated; A magnet installed at the front end of the core pin to fasten the insert; A cap pin that covers the magnet and is fastened to the core pin, and on which the insert is seated; and a temperature sensor installed along the inside of the core pin and the cap pin and sensing the temperature of the cap pin.

In one embodiment, the magnet may have a circular donut shape.

In one embodiment, the core pin includes a pin body inserted into the injection mold; and a sensor seating portion formed to penetrate the pin body in the longitudinal direction so that the temperature sensor can be seated.

In one embodiment, the cap pin is inserted and fastened through a front end opening of the sensor seating portion formed at the front end of the pin body after the rear end penetrates the magnet, and the insert is seated at the front end exposed to the front of the magnet. a fastening pillar; a fastening wing installed along the circumference of the fastening pillar so as to be seated on the front end of the magnet; and a sensor seating groove extending along the inside of the fastening pillar from the rear end of the fastening pillar inserted into the sensor seating part so that the sensing part of the temperature sensor can be seated and sense the temperature of the fastening pillar. there is.

In one embodiment, the magnet core pin applied with a sensor for detecting defective inserts of an injection mold according to an embodiment of the present invention reads whether the insert is seated on the cap pin using temperature information sensed by the temperature sensor. It may further include a non-defective product reading unit.

In one embodiment, the core pin may further include a body cooling unit installed along the pin body to prevent overheating of the pin body.

In one embodiment, the body cooling unit includes a ring seating groove extending in a circular ring shape along the rear end of the pin body exposed to the outside of the injection mold; a plurality of air inlet portions extending from the ring seating groove along the inside of the pin body; a plurality of air discharge units that communicate from each end of the plurality of air inlet units to the rear end of the pin body along the inside of the pin body to discharge air introduced through the air inlet unit to the outside of the pin body; and an air inflow guide that is seated along the ring seating groove and introduces air for cooling the fin body into the air inlet.

In one embodiment, the air inflow guide unit includes: an inflow guide ring formed in a circular ring shape corresponding to the shape of the ring seating groove; and a ring drive gear that is installed and connected to the outer peripheral surface of the inflow guide ring by a gear combination and is rotationally driven to rotate the inflow guide ring.

In one embodiment, the inflow guiding ring includes: a first ring having a circular ring shape with a diameter corresponding to the outer diameter of the ring seating groove; a second ring formed in a circular ring shape with a diameter corresponding to the inner diameter of the ring seating groove; A plurality of rings are installed to be inclined between the first ring and the second ring and spaced at regular intervals to support the space between the first ring and the second ring and at the same time, as the first ring and the second ring rotate. inclined wing panels that rotate together and induce an upward airflow to flow into the air inlet between the first ring and the second ring; and a gear mountain formed along the outer peripheral surface of the first ring so as to engage with the ring driving gear by gear coupling.

In one embodiment, the air inlet and the air outlet may be formed to extend spirally along the inside of the pin body while surrounding the sensor seating portion.

In one embodiment, the air inlet part may be formed to extend along the inside of the pin body closer to the sensor seating part than the air outlet part.

According to one aspect of the present invention described above, it was previously impossible to check whether there was an abnormality in the magnetic force of the magnet. However, a temperature sensor was attached to each core pin, so that when an insert separation defect occurs due to an inconsistent magnetic force in the magnet, the temperature sensor By checking the presence or absence of inserts using the monitored temperature difference, great results can be expected in quality improvement.

The effects of the present invention are not limited to the effects mentioned above, and various effects may be included within the scope apparent to those skilled in the art from the contents described below.

1 and 2 are diagrams showing the schematic configuration of a magnet core pin using a sensor for detecting insert defects in an injection mold according to an embodiment of the present invention.
Figure 3 is a diagram showing the structure of a conventional core pin.
Figure 4 is a diagram showing another embodiment of the core pin of Figure 1.
Figures 5 and 6 are diagrams showing the body cooling unit of Figure 4.
Figure 7 is a diagram showing the inlet guide ring of Figure 6.

The detailed description of the present invention described below refers to the accompanying drawings, which show by way of example specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different from one another but are not necessarily mutually exclusive. For example, specific shapes, structures and characteristics described herein may be implemented in one embodiment without departing from the spirit and scope of the invention. Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description that follows is not intended to be taken in a limiting sense, and the scope of the invention is limited only by the appended claims, together with all equivalents to what those claims assert, if properly described. Similar reference numbers in the drawings refer to identical or similar functions across various aspects.

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

1 and 2 are diagrams showing the schematic configuration of a magnet core pin using a sensor for detecting insert defects in an injection mold according to an embodiment of the present invention.

Referring to Figures 1 and 2, the magnet core pin 10 to which a sensor is applied for detecting defective inserts of an injection mold according to an embodiment of the present invention includes a core pin 100, a magnet 200, and a cap pin 300. and a temperature sensor 400.

The core pin 100 is installed in the injection mold at the position where the insert (P) will be seated, and components such as the core pin 100, magnet 200, cap pin 300, and temperature sensor 400 are installed.

In one embodiment, the core pin 100 may include a pin body 110 and a sensor seating portion 120.

The pin body 110 is inserted and installed into the injection mold.

The sensor seating portion 120 is formed to penetrate the pin body 110 in the longitudinal direction so that the temperature sensor 400 can be seated.

The magnet 200 is installed at the front end of the core pin 100 by the cap pin 300 to fasten the insert (P).

In one embodiment, the magnet 200 may have a circular donut shape.

The cap pin 300 is installed to cover the magnet 200 and is fastened to the core pin 100, and the insert (P) is seated.

In one embodiment, the cap pin 300 may include a fastening pillar 310, a fastening wing 320, and a sensor seating groove 330.

The fastening pillar 310 is inserted and fastened through the front end opening of the sensor seating portion 120 formed at the front end of the pin body 110 after the rear end penetrates the magnet 200, and is exposed to the front of the magnet 200. The insert (P) is seated at the front end.

The fastening wing 320 is installed along the circumference of the fastening pillar 310 so that it can be seated on the front end of the magnet 200.

The sensor seating groove 330 is at the rear end of the fastening pillar 310, which is inserted into the sensor seating part 120 so that the sensing part 410 of the temperature sensor 400 can be seated and sense the temperature of the fastening pillar 310. It is formed to extend along the inside of the fastening pillar 310.

The temperature sensor 400 is installed along the inside of the core pin 100 and the cap pin 300 and senses the temperature of the cap pin 300.

The magnet core pin 10 using a sensor for detecting defective inserts of an injection mold according to an embodiment of the present invention having the above-described configuration may further include a good product reading unit 500.

The non-defective product reading unit 500 uses temperature information sensed by the temperature sensor 400 to read whether the insert P is seated on the cap pin 300.

As shown in FIG. 3, the conventional core pin 2 also consists of a core pin 21, a magnet 22, and a cap pin 23.

However, in the case of the magnet 22, the strength of the magnetic force decreases over a certain period of time, which is believed to be the cause of the insert separation defect.

Accordingly, the magnet core pin 10 applied with a sensor for detecting insert defects in an injection mold according to an embodiment of the present invention having the configuration described above,

1 홀을 가공하였고 마그넷 코어핀에선 온도 센서 몸통이 들어 갈 수 있도록

4.3와

5의 홀을 가공하였다. A temperature sensor was used to check the presence or absence of the insert, and a temperature sensor was used in the center of the cap pin that the sensor could detect.

1 hole was machined and the magnet core pin was made so that the temperature sensor body can fit into it.

4.3 and

Hole 5 was machined.

Due to this, it has a structure that allows a temperature sensor to be inserted into the magnet core pin, and the rear part is treated with silicone to enable replacement.

In other words, the good product reading unit 500 measures 1) when there is no insert, the closing temperature of the core pin is measured to be 200 degrees or higher because the injection temperature of the resin is 250 degrees or higher, and 2) when there is an insert, the temperature is 100 degrees lower than that. Since it is measured in degrees, the presence or absence of an insert can be confirmed using the data in this result.

Accordingly, the sensor-applied magnet core pin 10 for detecting insert defects in an injection mold according to an embodiment of the present invention having the above-described configuration has a temperature sensor attached to each core pin so that the magnetic force on the magnet is not constant. In the event of an insert deviation defect, great results can be expected in quality improvement by checking the presence or absence of the insert using the temperature difference monitored through the temperature sensor.

Figure 4 is a diagram showing another embodiment of the core pin of Figure 1.

Referring to FIG. 4, a core pin 100a according to another embodiment includes a pin body 110, a sensor seating portion 120, and a body cooling portion 600.

Here, since the pin body 110 and the sensor seating portion 120 are the same as the components in FIG. 1, their description will be omitted to avoid duplication of explanation.

The body cooling unit 600 is installed along the pin body 110 to prevent overheating of the pin body 110.

In one embodiment, the body cooling unit 600 may include a ring seating groove 610, a plurality of air inlets 620, a plurality of air discharge parts 630, and an air inlet guide part 640.

The ring seating groove 610 extends in a circular ring shape along the rear end of the pin body 110 exposed to the outside of the injection mold so that the air inflow guide portion 640 can be installed.

A plurality of air inlets 620 are formed extending from the ring seating groove 610 along the inside of the pin body 110 so that the air supplied for cooling the pin body 110 can move.

The plurality of air discharge parts 630 are formed in communication from each end of the plurality of air inlet parts 620 to the rear end of the fin body 110 along the inside of the fin body 110 and are formed to communicate through the air inlet part 620. The introduced air is discharged to the outside of the fin body 110.

The air inlet guide part 640 is seated along the ring seating groove 610 and introduces air for cooling the fin body 110 into the air inlet part 620.

In one embodiment, the air inlet guide part 640 may include an inlet guide ring 641 and a ring drive gear 642.

The inflow guide ring 641 is formed in a circular ring shape corresponding to the shape of the ring seating groove 610.

The ring drive gear 642 is installed and connected to the outer peripheral surface of the inflow guide ring 641 by a gear combination and is driven to rotate to rotate the inflow guide ring 641.

The core pin (100a) according to another embodiment having the above-described configuration continuously supplies cool external air to the pin body (110), and at the same time, the air heated during the cooling process quickly flows to the outside of the pin body (110). By discharging it to , it is possible to prevent the temperature sensor 400 from being damaged by heat generated during the injection process.

Figure 7 is a diagram showing the inlet guide ring of Figure 6.

Referring to FIG. 7, the inflow guiding ring 641 includes a first ring 6411, a second ring 6412, an inclined wing panel 6413, and a gear mountain 6414.

The first ring 6411 has a circular ring shape with a diameter corresponding to the outer diameter of the ring seating groove 610.

The second ring 6412 has a circular ring shape with a diameter corresponding to the inner diameter of the ring seating groove 610.

A plurality of inclined wing panels 6413 are installed to be inclined between the first ring 6411 and the second ring 6412 and spaced at regular intervals to form a space between the first ring 6411 and the second ring 6412. It supports and simultaneously rotates as the first ring 6411 and the second ring 6412 rotate and rises to flow into the air inlet 620 between the first ring 6411 and the second ring 6412. Induce air currents.

The gear mountain 6414 is formed along the outer peripheral surface of the first ring 6411 so as to be engaged with the ring drive gear 642 by gear engagement.

In one embodiment, the air inlet 620 and the air outlet 630 may be formed to surround the sensor seating portion 120 and extend in a spiral shape along the inside of the pin body 110.

In one embodiment, the air inlet 620 may be formed to extend along the inside of the fin body 110 closer to the sensor seating part 120 than the air outlet 630.

The inlet guide ring 641 having the above-described configuration not only continuously introduces external air into the plurality of air inlets 620, but also discharges the air supplied through the plurality of air inlets 620. It can be induced to be discharged through part 630.

The above-described embodiments are for illustrative purposes, and those skilled in the art will recognize that the above-described embodiments can be easily modified into other specific forms without changing the technical idea or essential features of the above-described embodiments. You will understand. Therefore, the above-described embodiments should be understood in all respects as illustrative and not restrictive. For example, each component described as unitary may be implemented in a distributed manner, and similarly, components described as distributed may also be implemented in a combined form.

The scope sought to be protected through this specification is indicated by the patent claims described later rather than the detailed description above, and should be interpreted to include the meaning and scope of the claims and all changes or modified forms derived from the equivalent concept. .

10: Magnet core pin with sensor applied to detect defective inserts in injection molds
100: core pin
200: Magnet
300: cap pin
400: temperature sensor

Claims (3)

In the magnet core pin applied with a sensor to detect insert defects in an injection mold, which is implemented to reduce the insert defect rate by stably fixing the insert to the object during the injection process,
A core pin installed in the injection mold at a position where the insert will be seated;
A magnet installed at the front end of the core pin to fasten the insert;
A cap pin that covers the magnet and is fastened to the core pin, and on which the insert is seated; and
A magnet core pin using a sensor for detecting defective inserts of an injection mold, including a temperature sensor installed along the inside of the core pin and the cap pin and sensing the temperature of the cap pin.
According to paragraph 1,
The magnet is,
It is made up of a circular donut shape.
The core pin is,
a pin body inserted into the injection mold; and
It includes a sensor seating portion formed to penetrate the pin body in the longitudinal direction so that the temperature sensor can be seated,
The cap pin is,
a fastening pillar whose rear end penetrates the magnet and is then inserted and fastened through a front end opening of the sensor seating portion formed at the front end of the pin body, the insert being seated at the front end exposed to the front of the magnet;
a fastening wing installed along the circumference of the fastening pillar so that it can be seated on the front end of the magnet; and
It includes a sensor seating groove extending along the inside of the fastening pillar from the rear end of the fastening pillar inserted into the sensor seating part so that the sensing part of the temperature sensor can be seated and sense the temperature of the fastening pillar,
A magnet core pin using a sensor for detecting defective inserts of an injection mold, further comprising a good product reading unit that reads whether the insert is seated on the cap pin using temperature information sensed by the temperature sensor.
According to paragraph 2,
The core pin is,
It further includes a body cooling unit installed along the pin body to prevent overheating of the pin body,
The body cooling unit,
a ring seating groove extending in a circular ring shape along the rear end of the pin body exposed to the outside of the injection mold;
a plurality of air inlet portions extending from the ring seating groove along the inside of the pin body;
a plurality of air discharge units that communicate from each end of the plurality of air inlet units to the rear end of the pin body along the inside of the pin body to discharge air introduced through the air inlet unit to the outside of the pin body; and
It includes an air inflow guide that is seated along the ring seating groove and introduces air for cooling the fin body into the air inlet,
The air inflow guide part,
an inflow guiding ring formed in a circular ring shape corresponding to the shape of the ring seating groove; and
It includes a ring drive gear that is installed and connected to the outer peripheral surface of the inlet guide ring by a gear combination and is rotationally driven to rotate the inflow guide ring,
The inflow guiding ring is,
a first ring having a circular ring shape with a diameter corresponding to the outer diameter of the ring seating groove;
a second ring formed in a circular ring shape with a diameter corresponding to the inner diameter of the ring seating groove;
A plurality of rings are installed to be inclined between the first ring and the second ring and spaced at regular intervals to support the space between the first ring and the second ring and at the same time, as the first ring and the second ring rotate. inclined wing panels that rotate together and induce an upward airflow to flow into the air inlet between the first ring and the second ring; and
A magnet core pin applied with a sensor for detecting defective inserts of an injection mold, including a gear mountain formed along the outer peripheral surface of the first ring so as to engage with the ring driving gear and the gear combination.