KR20040000735A - heater for injection molding - Google Patents

Abstract

PURPOSE: A heater for an injection molding machine and method for molding the heater is provided to improve productivity and working efficiency by simplifying manufacturing processes. CONSTITUTION: A heater(h) for an injection molding machine is composed of a heat pipe(10) adhering closely to a heating surface of the injection molding machine, an inner insulated ceramic layer(20) formed at the outer surface of the heat pipe, a hot wire(30) wound on the outer circumference of the heat pipe, and an outer insulated ceramic layer(40). The outer insulated ceramic layer is formed at the outer surface of the hot wire.

Description

Heater for injection molding machine and heater molding method {heater for injection molding}

The present invention relates to a heater applied to a component of an injection molding machine, and more particularly, to a heater for an injection molding machine that can maximize the thermal conductivity while enabling the miniaturization of the injection molding machine.

In general, an injection molding machine is a mechanical device for molding a product by injecting a molten synthetic resin into a mold having a predetermined shape, and includes a manifold and a valve assembly for smoothly injecting molten synthetic resin.

That is, the injection molding machine is melted by putting a synthetic resin raw material into a cylinder provided on one side, the molten synthetic resin is injected into the mold at a high pressure through a nozzle in a liquid state, the synthetic resin injected into the mold is solidified , The mold consisting of the bottom is separated from each other to take out the molded product.

In this case, the injection molding machine is classified into a manifold type and a valve assembly type according to its structure. Here, the manifold type includes a manifold in which a heater is embedded in order to receive a synthetic resin and to maintain the liquid state, and at least one nozzle connected to the manifold to inject a liquid synthetic resin into a mold.

In addition, the valve assembly type generally does not require a manifold, and a resin flow path receiving synthetic resin is formed therein, and the resin flow path is connected to the discharge port of the nozzle. In addition, a heater for heating is provided around the resin flow passage and the nozzle, and the nozzle has a configuration in which the discharge port is opened and closed by a driving source.

1 is a cross-sectional view illustrating a valve assembly for a general injection molding machine, and as shown therein, the valve assembly includes a driving unit 100 and a valve body 200.

The drive unit 100 is a configuration in which a plurality of nipples 110 are protruded to enter the compressed air from the outside, the inside is made of an airtight structure for preventing the leakage of compressed air. The drive unit 100 is provided with a valve pin 120 that is raised and lowered by the compressed air supplied from the outside, the valve pin 120 is extended to the lower side in the resin flow path formed in the valve body 200 And positioned on 210.

The valve body 200 is a portion that substantially forms a nozzle for injecting resin into a mold. The valve body 200 is provided in a general cylinder shape, and the upper end of the valve body 200 is coupled to the drive unit 100 while maintaining airtightness. The valve body 200 has a resin flow path 210 for receiving a resin from a cylinder (not shown) to guide the mold to the inside of the valve body 200, and a valve pin 120 connected to the resin flow path 210 at a distal end thereof. A gate 220 is formed at the lower end of the gate 220.

The valve assembly for a conventional injection molding machine configured as described above opens and closes the gate 220 formed at the end of the valve body 200 while the valve pin 120 is moved up and down by compressed air, and the gate 220 at this time. The resin flowing along the resin flow path 210 by opening and closing is injected into the mold (not shown) or blocked.

On the other hand, the valve assembly is provided with a heater (h) around the valve body 200, the heater (h) at this time exothermic action to prevent the solidification of the resin passing through the resin flow path 210 to the liquid state It is configured to be able to flow to.

2 is a perspective view schematically illustrating a molding process of a heater applied to an injection molding machine according to the prior art. As shown in the drawing, the heater h according to the prior art includes a heat pipe 300, a heating wire 400, and magnesium ( 500).

The heat pipe 300 is made of copper, stainless steel, ceramics, tungsten, and the like, which have excellent thermal conductivity, and the inside thereof is provided in a hollow form. The heat wire 400 is provided in the heat pipe 300.

The hot wire 400 is a conventional tungsten wire is used, the current flows through the tungsten wire is heated by the heat generated by the resistance.

As described above, magnesium 500, which serves as an insulating material, is filled in the heat pipe 300 into which the heating wire 400 is inserted while preventing the heating wire 400 from being exposed to air.

Subsequently, the heat pipe 300 provided with the heating wire 400 and the magnesium 500 as described above is forged so that its cross-sectional shape becomes a quadrangular shape so as to be able to contact a large area with the target surface to be heated. . At this time, the forging process increases the heat transfer area of the heat pipe 300 for the heating object and at the same time compresses the powder magnesium 500 filled in the heat pipe 300 to improve the degree of vacuum.

On the other hand, the heat pipe 300 subjected to the forging process is a uniform surface due to the nature of the forging process is to uniformly process the surface through polishing.

The heater h formed by the above process is an example of a heating object, and is positioned by the cover c provided at the outer circumference of the valve body 200 as shown in FIG. 1. It is fixed.

The heater (h) is formed as described above, the heating wire 400 is generated by the resistance of the current, the heat at this time to the heat pipe 300 through the magnesium (500) surrounding the heating wire 400 It is inverted and consequently heats the object in contact with the heat pipe 300.

However, the heater h for the conventional injection molding machine configured as described above has disadvantages in that its molding process is complicated and low productivity and difficulty in miniaturization.

That is, the conventional injection molding machine heater (h) involves the step of inserting the heating wire 400 in the heat pipe 300 having a hollow shape and then filling the magnesium 500 as an insulating material, and forging again in such a state And after the surface polishing process is completed, because the number of work processes are complicated and many, not only the workability is poor, but also the productivity is lowered.

In addition, since the heat pipe 300 must have a space for accommodating the heating wire 400 and the magnesium 500 therein, there is a limit to reducing the diameter, and due to this limitation, a small injection product subject to volume constraints There is a problem that cannot be applied to an injection molding machine for molding.

In particular, the conventional heat pipe 300 has a disadvantage that the heat efficiency is low because the heat generated from the hot wire 400 is not directly transmitted to the heat pipe but is conducted to the heat pipe 300 through the magnesium (500).

The present invention was created in order to solve the above problems, an object of the present invention is to form a heater by a simple process to improve productivity and at the same time a heater and an injection molding machine heater that can quickly generate heat to the heating target It is to provide a molding method of.

1 is a cross-sectional view showing a valve assembly for a general injection molding machine,

Figure 2 is a perspective view showing the molding process of the heater applied to the injection molding machine according to the prior art,

3 to 6 are views sequentially showing a molding process of a heater applied to an injection molding machine according to the present invention;

7 is a perspective view showing another embodiment of the heater according to the present invention;

8 is a cross-sectional view showing an embodiment in which the heater according to the present invention is applied to a heating target surface;

9 is a flow chart showing a molding process of a heater according to the present invention.

<Explanation of symbols for the main parts of the drawings>

h: heater

10,10 ': heat pipe

11: Spiral groove

20,20 ': Insulation ceramic inner layer

30,30 ': heating wire

40,40 ': Insulated ceramic outer layer

50: installation groove

In the heater for an injection molding machine according to the present invention for realizing the above object, in the heater provided on the target surface for heating in the injection molding machine,

A heat pipe having a tubular shape as a thermally conductive material having a length material in which one surface is in close contact with the surface to be heated, an insulating ceramic inner layer solidified by being heated to a high temperature after being injected in a molten state to an outer surface of the heat pipe, and the insulation Heated wire spirally wound on the outer circumferential surface of the heat pipe having the ceramic inner layer formed therein and generated by electric resistance, and insulated ceramic outer layer which is solidified by heat treatment at high temperature after being sprayed in the molten state on the outer surface of the heat wire to block the heat wire from air. It is characterized by the configuration.

As a preferable feature of the present invention, the heat pipe has a spiral groove formed on an outer surface thereof, in which the insulating ceramic inner layer, the hot wire and the insulating ceramic outer layer are sequentially formed.

In another preferred aspect of the present invention, the heat pipe is provided with an installation groove of a shape corresponding to a heating object and is provided with an interference fitting structure in the installation groove.

The heater molding method for an injection molding machine according to the present invention comprises the steps of forming a spiral groove on an outer surface of a heat pipe provided with a thermally conductive material of a length member, by spraying ceramic particles in a molten state on the spiral groove and heat-treating them at a high temperature. Forming a ceramic solid layer having a thickness, winding a heating wire that generates heat by an electrical resistance along the spiral groove of the heat pipe on which the ceramic layer is formed, and melting the spiral wire of the heating pipe to which the heating wire is wound And spraying the ceramic particles in a state and heat-treating them at a high temperature to form a ceramic solid layer embedded therein.

Hereinafter, a preferred embodiment of a heater for an injection molding machine according to the present invention will be described in detail with reference to the accompanying drawings.

3 to 6 are views sequentially showing the molding process of the heater applied to the injection molding machine according to the present invention. Hereinafter, a description will be given with reference to FIG. 1 and like reference numerals refer to like parts.

As shown therein, the heater h of the present invention is provided between the heat pipe 10, the insulating ceramic inner layer 20, the insulating ceramic outer layer 40, and the insulating ceramic inner and outer layers 20, 40. It consists of a hot wire 30.

The heat pipe 10 has a substantially rectangular cross section and is provided in a hollow hollow tube shape. The heat pipe 10 is usually made of a material having excellent thermal conductivity, that is, copper, stainless steel, ceramics, tungsten, or the like, and has a structure in which a groove having a predetermined depth is spirally formed on the outer surface thereof.

The insulating ceramic inner layer 20 forms a coating film with a predetermined thickness, that is, about 0.1 to 2 mm, for the purpose of insulating the spiral groove 11 of the heat pipe 10 described above.

That is, the insulating ceramic inner layer 20 is sprayed on the target surface, that is, in the present invention, the spiral grooves 11 of the heat pipe 10 by using a molten spray device to apply a predetermined thickness to the ceramic ceramic layer in the molten state, It is shape | molded by heat-processing at a high temperature of about 1200-1800 degreeC, and solidifying. Since the insulating ceramic inner layer 20 is formed for the purpose of insulation, it is preferable to have an insulation resistance of about several tens of mΩ or more.

Meanwhile, the heating wire 30 is wound around the spiral groove 11 of the heat pipe 10 in which the insulating ceramic inner layer 20 is formed to have a uniform thickness as described above.

The heating wire 30 is a kind of conducting wire which is wired to allow current to flow at both ends, and is heated by heat generated by electrical resistance. Although not shown, the heating wire 30 is controlled by a temperature controller provided in an injection molding machine. Heat is generated to maintain this constant temperature.

The hot wire 30 is a thin wire of tungsten is generally used, but a conductive wire of various materials may be used as long as it has a characteristic of generating heat by electric resistance. For example, a wire using an active metal such as zirconium, titanium, or thorium may be used.

On the other hand, the heating wire 30 has a diameter that is fully inserted into the spiral groove 11 of the heat pipe 10, as shown in the drawing, the insulating ceramic formed in a uniform thickness on the outer surface of the heating wire 30 It is a structure covered by the outer layer 40.

The insulated ceramic outer layer 40 is similar to the insulated ceramic inner layer 20 described above, using the molten spray apparatus to heat the ceramic particles in a molten state, that is, the spiral of the heat pipe 10 on which the heating wire 30 is wound. The groove 11 is applied so as to be embedded, and it is molded by heat treatment at a high temperature of approximately 1200 to 1800 ° C. to solidify it. Since the insulating ceramic outer layer 40 is formed for the purpose of insulation, the insulating ceramic outer layer 40 is formed to have an insulation resistance of about several tens of mΩ or more and is provided as a thickness of approximately 0.1 to 2 mm.

Meanwhile, in the present invention, in forming the insulating ceramic inner layer 20 and the insulating ceramic outer layer 40, a method of coating and heat treating the insulating ceramic inner layer 20 to have a predetermined thickness in a molten state is shown, but the present invention is not limited thereto. Insulating material such as fiber powder may be used and various methods such as deposition or electrodeposition may be applied if it has the feature of completely insulating the heating wire 30 wound around the outer surface of the pipe 10.

The heater h according to the present invention configured as described above is provided on the outer surface of the heating target surface of the injection molding machine to heat the heating target surface by generating heat.

At this time, since the heat generated from the heating wire 30 is conducted to the heat pipe 10 through a relatively thin insulating layer, the heat conduction response speed is achieved while the thermal efficiency is good, thus enabling precise temperature management. Become.

9 is a flowchart showing a method of forming the heater h described above.

As shown therein, the heater h of the present invention is formed by the following process, forming a spiral groove 11 on the outer surface of the heat pipe 10 provided with the thermally conductive material of the first length member. Include.

Subsequently, spraying ceramic particles in a molten state into the spiral grooves 11 formed in the heat pipe 10 and heat-treating them at a high temperature to form a ceramic solid layer having a thickness, that is, an insulating ceramic inner layer 20. .

Following the step, the step of winding the heating wire 30 that generates heat by the electrical resistance along the spiral groove 11 of the heat pipe 10 in which the insulating ceramic inner layer 20 is formed.

Subsequent to the above step, the ceramic solid layer, that is, the insulating ceramic outer layer 40, is embedded in the spiral groove 11 of the heat pipe 10 in which the heating wire 30 is wound, injecting the ceramic particles in a molten state and heat-treating them in a high temperature. Forming a step.

7 is a perspective view showing another embodiment of the heater according to the present invention. As shown therein, the heater h according to the present invention has the same heat pipe 10 and insulating ceramic inner layer 20 as in the above-described embodiment. And a heating wire 30 provided between the insulating ceramic outer layer 40 and the inner and outer layers 20 and 40 of the insulating ceramic.

The heat pipe 10 has a substantially circular cross section and is provided in the form of a solid tube filled therein. The heat pipe 10 is usually made of a material having excellent thermal conductivity, that is, copper, stainless steel, ceramics, tungsten, and the like, and the outer surface of the insulating ceramic outer layer 40 as shown in the drawing has a uniform film thickness. It is a configuration to form.

The insulating ceramic inner layer 20 forms a coating film with a predetermined thickness for the purpose of insulation on the outer surface of the heat pipe 10 as described above. It is formed by spraying the spiral groove 11 of the heat pipe 10 and applying it to a predetermined thickness, and heat-treating it at a high temperature of approximately 1200 to 1800 ° C. to solidify it. Since the insulating ceramic inner layer 20 is formed for the purpose of insulation, it is preferable to have an insulation resistance of about several tens of mΩ or more.

As such, the heating wire 30 is wound around the outer surface of the heat pipe 10 in which the insulating ceramic inner layer 20 is formed to have a constant thickness.

The heating wire 30 is a kind of conducting wire which is wired to allow current to flow at both ends, and is heated by heat generated by electrical resistance. Although not shown, the heating wire 30 is controlled by a temperature controller provided in an injection molding machine. Heat is generated to maintain this constant temperature.

The hot wire 30 is a thin wire of tungsten is generally used, but a conductive wire of various materials may be used as long as it has a characteristic of generating heat by electric resistance. For example, a wire using an active metal such as zirconium, titanium, or thorium may be used.

On the other hand, the heating wire 30 is a configuration that is completely covered by the insulating ceramic outer layer 40 is formed in a uniform thickness on its outer surface as shown in the figure.

The insulating ceramic outer layer 40 is similar to the insulating ceramic inner layer 20 described above, and the surface to be heated, that is, the outer surface of the heat pipe 10 to which the heating wire 30 is wound, using a molten spray apparatus for melting ceramic particles in a molten state. Is applied as a constant thickness. At this time, the insulating ceramic outer layer 40 is preferably completely coated while the outer surface is completely filled with the heating wire 30. The insulating ceramic outer layer 40 thus applied is molded by heat-treating and solidifying at a high temperature of approximately 1200 to 1800 ° C.

Since the insulating ceramic outer layer 40 is formed for the purpose of insulation, it is preferable that the insulating ceramic outer layer 40 is formed to have an insulation resistance of about tens of mΩ or more.

The heater (h) according to the present invention configured as described above is provided on the outer surface of the heating target surface of the injection molding machine to heat the heating target surface to a predetermined temperature. At this time, since the heat generated from the heating wire 30 is conducted to the heat pipe 10 through a relatively thin insulating layer, the heat conduction response speed is achieved while the thermal efficiency is good, thus enabling precise temperature management. Become.

Referring to the application example of the heater (h) for injection molding machine according to the present invention configured as described above are as follows.

First, as shown in FIG. 1, the heater h of the present invention is covered by a cover c provided as an outer circumferential surface of the valve body 200 in a state in which a heating object is wound, that is, wound around the outer circumference of the valve body 200. It may be provided in a structure that is fixed to the position.

The heater (h) is provided as described above when the heating wire 30 generates heat by the electrical resistance, the heat pipe 10 is conducted by the conductive heat to the outer surface of the valve body 200 by passing through the resin flow path resin Is prevented from solidifying.

In addition, the heater (h) of the present invention, as shown in Figure 8 to form a mounting groove 50 in the heating object, the structure that can be fixed to the mounting groove (50) in the mounting structure in the heater h position It can be prepared as. At this time, the installation groove 50 is preferably provided in a shape corresponding to the heater h so that the heater h can be fitted.

It is apparent to those skilled in the art that the present invention is not limited to the described embodiments, and that various modifications and changes can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or variations will have to belong to the claims of the present invention.

The injection molding machine heater constructed and operated as described above is manufactured by a simple process of forming an insulating ceramic inner layer on the outer surface of the heat pipe, winding a heating wire around the insulating ceramic inner layer, and then forming an insulating ceramic outer layer for insulation. Since this is possible, workability and productivity are greatly improved.

In other words, workability and productivity are improved because a separate post-processing process, such as forging to form a conventional magnesium and compressing it, to form a vacuum, and a polishing process for evenly processing the surface, is not required.

In addition, since the heat pipe is provided with a heating wire on the outer surface, the diameter of the heat pipe can be drastically reduced in comparison with the past, thus providing an advantage that can be applied to an injection molding machine for molding a small injection molding without limitation.

Claims (4)

A heat pipe having a tubular shape as a thermally conductive material of a length member in which one surface is in close contact with the heating target surface of the injection molding machine; An insulating ceramic inner layer solidified by being sprayed on the outer surface of the heat pipe in a molten state and heat treated at high temperature; A heating wire spirally wound on an outer circumferential surface of the heat pipe on which the insulating ceramic inner layer is formed, and generating heat by electric resistance; An insulating ceramic outer layer which is sprayed on the outer surface of the hot wire in a molten state and heat treated at high temperature to solidify and blocks the hot wire from air; Injection molding machine heater, characterized in that consisting of. The method of claim 1, wherein the heat pipe, A spiral groove is formed on an outer surface, and an insulating ceramic inner layer, a hot wire, and an insulating ceramic outer layer are sequentially formed in the spiral groove. The heater according to claim 1, wherein the heat pipe is provided with an installation groove having a shape corresponding to a heating object and is provided with an interference fitting structure in the installation groove. Forming a spiral groove on an outer surface of the heat pipe provided with the thermally conductive material of the length member; Spraying ceramic particles in a molten state in the spiral groove and heat-treating them at high heat to form a ceramic solid layer having a thickness; Winding a heating wire that generates heat by an electrical resistance along the spiral groove of the heat pipe on which the ceramic layer is formed; Spraying ceramic particles in a molten state into a spiral groove of the heat pipe wound with the hot wire and heat-treating the same to form a ceramic solid layer filled with heat; Heater molding method for injection molding machine comprising a.