KR101363482B1 - Cooling structure of rotor core - Google Patents

Abstract

The present invention relates to the cooling structure of a rotor core, and especially, includes a rotor core with cooling grooves formed inside the rotor core in a longitudinal direction and having a rod shape; a cooling water pipe which has a smaller diameter than that of the cooling groove and is installed in the cooling groove; a housing with an inlet through which the cooling water passes to the cooling water pipe and an outlet discharging the cooling water discharged through the cooling grooves; and a cooling main body which includes a rotor-supporting part rotatably supporting the rotor core on the housing. The cooling water passed through the inlet moves to the front end of the rotor core, is discharged, and is collected into the housing along the cooling water pipe so the cooling water conducts heat-exchange by direct contact, thereby maximizing cooling efficiency. Besides, the rotor-supporting part which is combined with the rotor core and rotatably supports the rotor core and a sealed part are prepared so that the leakage of the cooling water can be prevented even when the rotor core rotates.

Description

Cooling Structure of Rotating Core {COOLING STRUCTURE OF ROTOR CORE}

The present invention relates to a rotating core used in injection molds, and in particular, in cooling the injection molding rotating core used when molding a container lid with a thread formed therein, it is possible to maximize the cooling efficiency due to direct cooling. Of course, the present invention relates to a cooling structure of a rotating core capable of preventing leakage of cooling water due to rotation to improve cooling and process reliability.

Container lids in which the lids of various containers such as beverage lids and cosmetic container lids are closed and opened by rotating from the container body are generally manufactured using an injection molding method.

In the above case, since the container lid has to form a male thread inside the lid, a core having a shape corresponding thereto should be used. In particular, when the container lid is taken out, a screw thread is formed therein so that the core is rotated. It is essential to take out.

Conventionally, with respect to the non-rotating core that does not need to form a thread inside the injection molding, as disclosed in Korean Patent Application No. 2000-2679, a cooling structure for forming a cooling water passage inside the core to circulate the cooling water to perform cooling. Have been proposed.

However, the non-rotating core is in a state where the core is fixed, so that the problem of leakage of coolant is not serious unless the core is separated into several cores. The core has to be rotated during the injection of the injection molding, there is a problem that the risk of cooling water leakage.

To this end, an attempt has been made to prevent the leakage of cooling water by inserting a cooling water pipe inside the rotating core, but in this case, since the cooling water directly contacts the rotating core, indirect heat exchange is performed through the cooling water pipe without heat exchange. There was a problem that the cooling efficiency is lowered.

Accordingly, an object of the present invention is to maximize the cooling efficiency according to the direct heat exchange between the coolant and the rotary core, and at the same time improve the structure between the rotary core and the non-rotating cooling device to prevent the leakage of the cooling water cooling structure of the rotary core To provide.

The object is, according to an embodiment of the present invention, in the rotating core of the injection mold, having a rod shape, the cooling core is formed therein along the longitudinal direction; A housing having a diameter smaller than that of the cooling groove and having a cooling water pipe installed along the inside of the cooling groove, an inlet through which the cooling water flows into the cooling water pipe, and an outlet through which the cooling water discharged along the cooling groove is discharged to the outside; And a cooling main body including a rotation support part for rotatably supporting the rotating core in the housing, wherein the cooling water flowing into the inlet is moved to the front end of the rotating core through the cooling water pipe and flows out. It is achieved by the cooling structure of the rotating core which is returned to the housing along the groove and discharged to the outlet.

Here, the rotation support portion, a groove corresponding to the cooling groove is formed therein, the core connection tube is rotated by one end coupled to the rotating core, and a plurality of balls rotatably supporting the core connection tube to the housing It may include a bearing.

It may further include a sealing member provided between the other end of the core connection pipe and the outlet port to prevent the cooling water from flowing out.

The sealing member is formed of an elastic material, one end has a sealing groove for receiving the engaging portion formed on the other end of the core connecting pipe, the other end is fixed to the outlet is inserted, between the other end of the sealing member and the housing A pressurizing member may be further provided to pressurize the sealing member toward the core connecting tube to prevent the leakage of the cooling water.

On the other hand, when the plurality of rotary cores are provided side by side, the cooling body is provided for each of the rotating cores, respectively, the outlet of one of the cooling body is connected to the inlet of the other cooling body adjacent to the cooling water It may be provided to sequentially pass through each of the rotating core and the cooling body.

According to the cooling structure of the rotating core according to the present invention having the above structure, since the cooling water introduced along the cooling water pipe is discharged from the tip of the rotating core and recovered along the cooling groove, the cooling water performs heat exchange by direct contact with the rotating core. Therefore, the cooling efficiency can be maximized.

In addition, by providing a rotation support and a sealing member coupled to the rotating core to support the rotation, it is possible to prevent the leakage of cooling water even when the rotating core rotates.

1 is a cross-sectional view of a rotating core cooling structure according to the present invention;
2 is a cross-sectional perspective view of the cooling main body shown in FIG. 1.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

First, referring to FIG. 1, a cooling structure of a rotating core according to an embodiment of the present invention includes a rotating core 10 having a rod shape and a cooling groove 15 formed therein along a length direction; It includes a cooling body (100) for introducing the cooling water to the front end portion along the cooling groove (15) inside the rotary core (10) and recovered along the cooling groove (15).

As a result, the cooling water introduced into the inlet 140 moves to the front end of the rotary core 10 through the cooling water pipe 130 and flows out into the cooling groove 15, followed by the cooling main body 100 along the cooling groove 15. Recovered to the housing 110 of the discharge port 150 is discharged.

Rotating core 10 is provided in a rod shape, as shown in Figure 1, the front end is inserted into a cavity formed in the mold (1). A male thread may be formed at the tip of the rotary core 10 to form an internal female thread of the container lid.

As shown in FIG. 1, a cooling groove 15 is formed along the longitudinal direction of the rotary core 10. The cooling groove 15 may be provided in various shapes such as a circular cross section or a polygonal cross section.

The cooling body 100 is provided to supply cooling water to the rotating core 10.

Cooling body 100 may be coupled to various positions of the rotary core 10, for example, it may be coupled to the rear end of the rotary core 10, as shown in FIG.

As shown in FIG. 2, the cooling body 100 includes a housing 110, a rotation support part 120, a cooling water pipe 130, an inlet 140, and an outlet 150.

The cooling water pipe 130 has a smaller diameter than the cooling groove 15 and is installed along the inside of the cooling groove 15. The diameters of the cooling water pipe 130 and the cooling groove 15 may be variously adjusted according to the cooling capacity.

The cooling water pipe 130 may be provided in contact with any one side of the cooling groove 15, but as shown in FIG. 2, the cooling water pipe 130 is preferably positioned at the center thereof so as not to contact the inner wall of the cooling groove 15.

This, when the cooling water pipe 130 is fixed to one side of the inner wall of the cooling groove 15, when the cooling water is discharged from the front end of the cooling water pipe 130 is recovered along the cooling groove 15, the cooling water pipe 130 is This is because direct contact between the cooling water and the inner wall of the cooling groove 15 may be prevented. To this end, if necessary, a plurality of support members (not shown) may be further provided such that the coolant pipe 130 is positioned at the center of the cooling groove 15.

On the other hand, since the rotating core 10 is continuously rotated, even if the coolant does not fill the entire cooling groove 15, the rotating core 10 may be sequentially contacted with the entire inner wall of the cooling groove 15, thereby improving cooling efficiency by direct cooling. .

The rotation support part 120 includes a core connector pipe 121 and a ball bearing 125.

The core connection pipe 121 is provided with a groove corresponding to the cooling groove 15 therein, and one end thereof is coupled to the rear end of the rotating core 10 to be rotatable.

The coupling of the core connector tube 121 and the rotary core 10 may be used in various ways, for example, as shown in Figure 2, to form a male thread on one end of the core connector tube 121, A female thread can be formed at the rear end of the rotary core 10. In addition, of course, it is also possible to use a fitting or a separate coupling member. Here, it is essential that the cooling water does not flow out of the coupling position of the core connecting tube 121 and the rotary core 10 using any of the above methods.

On the other hand, the rotating core 10 is rotated when the container cap is taken out, but since the cooling body 100 itself does not rotate, the ball bearing 125 so that the core connecting tube 121 can be rotated in the housing 110. ) Is prepared.

Here, the ball bearing 125 is only an embodiment of the rotation configuration, the present invention is not limited to this, of course, the rotation configuration of a variety of known structures can be used without limitation.

The sealing member 160 is provided between the other end of the core connecting pipe 121 and the outlet 150 to prevent the cooling water from flowing out.

Rotating core 10, which is the object of the present invention, unlike the core that is stationary, the core is rotated, so there is a risk of leakage of cooling water, it is very important to prevent it.

To this end, the sealing member 160 according to an embodiment of the present invention, as shown in Figure 2, is provided with an elastic material, one end of the engaging portion 127 formed on the other end of the core connecting tube 121 is Has a sealed groove sealing groove 161 is accommodated, the other end may be fixed to the outlet 150 is inserted.

That is, one end of the sealing member 160 is fixed to the other end of the core connecting pipe 121 is configured to prevent the leakage of the cooling water. Since the sealing member 160 is fixed to the housing, the locking portion 127 of the core connecting tube 121 is rotated while being inserted into the sealing groove 161.

On the other hand, the other end of the sealing member 160 is fixed to the outlet port 150 to maintain the sealing force. The sealing member 160 may be further made of an elastic material such as rubber to further improve the sealing force by restoring force after the fitting is fixed.

The sealing member 160 may be used without limitation various kinds of well-known, such as a sealing member in addition to the above embodiment.

The pressurizing member 170 is provided between the other end of the sealing member 160 and the housing 110 to improve the core connecting tube 121 to pressurize and close the sealing member 160 to prevent leakage of the cooling water.

The pressing member 170 may be provided in various kinds. For example, as shown in FIG. 2, the pressing member 170 may be provided as a coil spring.

The inlet 140 allows the coolant to flow from the outside to the coolant pipe 130. Inlet 140 may be provided in various kinds, for example, as shown in Figure 2, may be provided as a tube extending integrally with the cooling water pipe (130).

Outlet 150 is provided so that the cooling water recovered to the cooling groove 15 is discharged to the outside of the cooling body (100).

1 and 2, the operation of the cooling structure of the rotating core according to an embodiment of the present invention will be described.

First, referring to FIG. 2, external cooling water is introduced into the cooling water pipe 130 through the inlet 140 of the cooling body 100 (see A). After the coolant flows along the coolant pipe 130 and passes through the core connecting pipe 121 to the tip of the rotary core 10 (see B), the coolant is discharged from the tip of the rotary core 10.

The rotary core 10 is in a non-rotation state during injection molding, and when the molding is completed and the ejected product is taken out, the rotation core 10 rotates in a direction opposite to the thread in which the rotation is formed. By flowing along the bottom side inner wall of the cooling groove 15, but the inner wall itself rotates in the rotating state, the entire inner wall is in contact with and flows from the front end of the rotary core 10 to the rear end to perform heat exchange by direct contact. (See C)

Finally, the cooling water recovered to the cooling main body 100 through the core connecting pipe 121 is discharged to the outside via the outlet 150.

Here, in order to smoothly flow the coolant, a circulation may be achieved by applying a predetermined pressure to the coolant using a pump or the like, and by adjusting the inclination of the rotating core 10 and the direction in which the outlet 150 is formed, It can also be self-circulating by its own weight.

On the other hand, as shown in Figure 1, the cooling structure of the rotary core according to the present invention, when a plurality of rotary cores 10 are used, it is also possible to arrange them in a row to form a single cooling water circulation structure. .

1: Mold
10: rotating core 15: cooling groove
100: cooling body 110: housing
120: rotation support 121: core connector
125: ball bearing 127: engaging portion
130: cooling water pipe 140: inlet
150: outlet 160: sealing member
161: sealed groove
170: pressing member

Claims (5)

In the rotating core of the injection mold,
A rotating core having a rod shape and having a cooling groove formed therein along the longitudinal direction;
A housing having a diameter smaller than that of the cooling groove and having a cooling water pipe installed along the inside of the cooling groove, an inlet through which the cooling water flows into the cooling water pipe, and an outlet through which the cooling water discharged along the cooling groove is discharged to the outside; Including; a cooling body including a rotation support for rotatably supporting the rotating core to the housing;
Cooling water flowing into the inlet is moved to the front end of the rotary core through the cooling water pipe is discharged after the cooling groove of the rotating core, characterized in that it is recovered to the housing along the cooling groove and discharged to the outlet. The method of claim 1,
The rotatable support includes a core connection tube having a groove corresponding to the cooling groove therein, one end of which is coupled to the rotating core and rotated, and a plurality of ball bearings rotatably supporting the core connection tube in the housing. Cooling structure of the rotating core comprising a. 3. The method of claim 2,
And a sealing member provided between the other end of the core connecting pipe and the outlet to prevent the cooling water from flowing out. The method of claim 3,
The sealing member is formed of an elastic material, one end has a sealing groove for receiving the engaging portion formed on the other end of the core connecting pipe, the other end is fixed to the outlet opening,
Cooling structure of the rotary core between the other end of the sealing member and the housing is further provided with a pressing member for pressing the sealing member toward the core connecting tube to prevent the leakage of cooling water. 5. The method according to any one of claims 1 to 4,
When the plurality of rotating cores are provided and arranged side by side, the cooling main body is provided for each of the rotating cores, respectively, the outlet of one of the cooling main body is connected to the inlet of another neighboring cooling main body so that the cooling water is Cooling structure of the rotating core, characterized in that provided to sequentially pass through the rotating core and the cooling body.

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