KR20230164884A - High Frequency Inducitve Alloy Melting Furnace Device - Google Patents

Abstract

The present invention relates to a high-frequency alloy melting furnace based on induction heating.
The present invention relates to a high-frequency melting furnace, comprising: a body 100 having a melting chamber 200 for melting materials; A high-frequency oscillator 400 provided in the body 100 to supply high-frequency current, provided on the outer peripheral surface of the wall of the dissolution chamber 200, connected to the high-frequency oscillator 400 through a terminal, and the high-frequency oscillator ( an induction coil 300 that guides the high frequency supplied from 400) to dissolve the material in the dissolution chamber 200; A plurality of infrared sensors 500 installed in the dissolution chamber 200 to sense the melting point of the material and output a sensing signal value; An induction heating-based high-frequency alloy melting furnace including a control unit 600 that controls the high-frequency oscillator 400 through the sensing signal value of the infrared sensor 500 is presented.
The present invention has the advantage of obtaining an optimized alloy by installing a number of infrared sensors in the melting chamber of the melting furnace and operating a high-frequency oscillator through the melting point.

Description

High frequency alloy melting furnace based on induction heating {High Frequency Inducitve Alloy Melting Furnace Device}

The present invention relates to a high-frequency melting furnace, and more specifically, to a high-frequency melting furnace based on high-performance induction heating that can stably melt metals such as platinum by generating high frequencies of 100-400 kHz to the materials in the melting chamber of the melting furnace. It's about.

In general, looking at the manufacturing process for manufacturing precious metal accessories, it includes the process of manufacturing precious metal with a desired shape through a casting process, the process of processing the manufactured precious metal into the desired shape or form, and the process of soldering the connection between the processed precious metals. It is manufactured by sequentially performing solder welding processes.

On the other hand, when melting the raw materials of precious metals as described above, a melting furnace is used. The melting furnace uses coke, coal gas, natural gas, heavy oil, coal, etc. as fuel depending on the heating method, and an electrothermal method, There is an arc heating method that uses arc heat, and a high-frequency heating method that heats using resistance heating by flowing a high-frequency induced current.

The high-frequency induction heating method has excellent heating efficiency and an excellent working environment, so it does not cause environmental pollution, so it has been most in demand recently.

The high-frequency oscillator of the induction heating method described above is a method of heating a conductive object by placing it in a changing magnetic field. The object to be heated must be conductive, and in high-frequency induction heating, a high-frequency current supplied from a high-frequency power source moves the induction coil. As it flows along, the surface of the object to be heated is quickly heated by heat loss due to eddy current and hysteresis due to electromagnetic induction in the object to be heated, wound around the induction coil and located at the center.

However, platinum (Pt) and gold (Au), which are widely used as precious metal materials, require separate processing technology due to their high melting point and soft nature. Pt 950, a platinum alloy material, and gold, which are characteristics of pure gold, are Due to its softness, the product is prone to damage, and when thin lines are processed to express detailed shapes, deformation and breakage occur easily, resulting in design problems that make precise machining difficult, resulting in increased weight and cost. It has technical problems.

In addition, pure platinum with a purity of 99.9% or higher has problems such as difficulty in processing due to its high melting point and scratches easily due to its brittle nature (Hv 37-108). Pure gold also has a brittle nature (Hv 20-58), making it difficult to use in elaborate jewelry. There are limits to production.

In addition, the most widely used material for platinum products is Pt 950, but platinum alloy products using Pt 950 alloy currently on the market do not meet the strength required in the platinum jewelry market due to their low strength, making them vulnerable to external shocks. It has disadvantages and is an obstacle to the development of high-quality products with various designs.

Moreover, the casting process, which is currently a core process in jewelry manufacturing, requires a post-treatment process of about 120 minutes in a hydrofluoric acid environment for Pt950 products and about 10 minutes in sulfuric acid (or hydrochloric acid) for Au995 products to remove films and impurities, so workers There is a problem with long-term exposure to harmful substances to the human body.

Meanwhile, in the case of platinum (Pt) 950 and 99.5% pure gold metal materials, sufficient durability can be maintained even at low weight, so there is a need to develop high-strength materials that can reduce production costs and new material technologies that can maximize design freedom.

The background or prior art described above is information possessed by the present inventor or acquired in the process of deriving the present invention, and is only intended to help understand the technical significance of the present invention, and is information to which this invention belongs before filing the application for the present invention. It should be noted that this does not mean that it is a widely known technology in the field.

KR Patent Registration No. 10-1934005 Registration date 2018.12.24 KR Patent Registration No. 10-1141692 Registration Date 2012.04.24 KR Patent Registration No. 10-1756545 Registration Date 2017.07.04 KR Patent Publication No. 10-2008-0003196 Publication date 2008.01.07

Accordingly, the present inventor has developed a melting furnace with a new structure that can safely melt metal materials such as platinum, with the idea of comprehensively considering all of the above-mentioned matters and simultaneously solving the technical limitations and problems of existing technologies. As a result of continuous research with great effort, the present invention was created.

Therefore, the technical problem and purpose to be solved by the present invention is to provide a 100-400kHz high frequency melting furnace.

In other words, it forms a vacuum melting chamber with greatly improved high-temperature heating and temperature control performance, has many infrared sensors capable of measuring ultra-high temperatures, and provides a FET-type induction heating-based melting furnace with a capacity of 100-400 KHz. I'm doing it.

Here, the technical problems and objectives to be solved by the present invention are not limited to the technical problems and objectives mentioned above, and other technical problems and objectives not mentioned will be clearly understood by those skilled in the art from the description below.

A specific means according to the implementation of the present invention for effectively achieving a specific technical purpose while embodying a new idea for solving the technical problem of the present invention as described above is a high-frequency melting furnace having a dissolution chamber for dissolving the material. A body, a high-frequency oscillator provided on the body and supplying a high-frequency current, provided on the outer peripheral surface of the wall of the dissolution chamber, connected to the high-frequency oscillator through a terminal, and guiding the high frequency supplied from the high-frequency oscillator to the material of the dissolution chamber. Induction comprising an induction coil that melts, a plurality of infrared sensors installed in the dissolution chamber to sense the melting point of the material and output a sensing signal value, and a control unit that controls a high-frequency oscillator through the sensing signal value of the infrared sensor. A heating-based high-frequency alloy melting furnace is presented.

It would be desirable to apply a capacity of 100-400 kHz to the high-frequency oscillator.

The dissolution chamber may be made of a ceramic material.

As a result, the present invention can significantly improve temperature control performance even under high temperature heating through an infrared sensor installed in a vacuum melting chamber, and has a new effect of dissolving alloys such as platinum through induction heating with a capacity of 100-400 KHz. .

According to the technology of the present invention, which is based on a unique solution to solve the above technical problems, a number of infrared sensors are installed in the melting chamber of the melting furnace and a high-frequency oscillator with a capacity of 100-400 kHz is operated through the melting point to produce an optimized alloy. There is an advantage that can be obtained.

Here, the effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

Figure 1 is a configuration diagram showing the installation state of an induction heating-based high-frequency alloy melting furnace according to an embodiment of the present invention.
Figure 2 is a front view showing the induction heating-based high-frequency alloy melting furnace of Figure 1.
Figure 3 is a plan view showing the induction heating-based high-frequency alloy melting furnace of Figure 1.
Figure 4 is a perspective view of the induction heating-based high-frequency alloy melting furnace of Figure 1.

Hereinafter, embodiments according to the present invention will be described in more detail with reference to the accompanying drawings. Before describing the present invention, the terms described below are defined in consideration of the functions in the present invention, which are technical aspects of the present invention. It is specified that it should be interpreted as a concept that corresponds to the idea and a meaning commonly used or commonly recognized in the relevant technical field. Additionally, if it is determined that a detailed description of a known function or configuration related to the present invention may obscure the gist of the present invention, the detailed description will be omitted.

The drawings attached herein illustrate the composition and operation of the technology, and some parts are exaggerated or simplified for convenience and clarity of understanding, and each component does not exactly match the actual size and shape.

In addition, in this specification, the term and/or refers to a combination of a plurality of related described items or includes any item among a plurality of related described items, and when a part includes a certain element, this refers to a specially opposed description. This does not mean excluding other components unless there is a , but means that other components can be included in addition.

In other words, terms such as 'include', 'equipped', 'have', etc. mean the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in this specification. However, it should be understood that this does not exclude the presence or addition of one or more other features, numbers, step operation components, parts, or combinations thereof.

In addition, terms such as top, bottom, upper surface, lower surface, or upper, lower, upper, lower, front and back, left and right are used for convenience to distinguish the relative positions of each component. For example, the upper part of the drawing may be referred to as upper and the lower part as lower, the longitudinal direction may be referred to as the front-to-back direction, and the width direction may be referred to as the left-right direction.

Additionally, terms such as first and second may be used to describe various components. That is, terms such as first, second, etc. may be used only for the purpose of distinguishing one component from another component. For example, the first component may be named the second component as long as it does not deviate from the scope of protection of the present invention, and the second component may also be named the first component.

The present invention relates to a high-frequency melting furnace based on induction heating.

The present invention includes a body 100 forming a melting furnace as shown in FIGS. 1 to 4, a melting chamber 200 provided inside the body 100, and a high frequency oscillator 400 that supplies high frequency current. , an induction coil 300 installed on the outer wall of the dissolution chamber 200 and connected to the high-frequency oscillator 400 through a terminal to generate high frequencies, and an induction coil 300 installed in the dissolution chamber 200 to sense the melting temperature of the material. It is comprised of a plurality of infrared sensors 500 and a control unit 600 that controls each component through sensing values.

The body 100 has the appearance of a melting furnace and a melting chamber 200 is installed on the inside.

The dissolution chamber 200 is made of a ceramic material that can withstand approximately 3000°C, the interior is maintained in a vacuum state, and an induction coil 300 is wound around the outer peripheral surface of the wall.

The induction coil 300 is provided in a form wound around the outer wall of the dissolution chamber 200 to rapidly heat the material in the dissolution chamber 200 through induction heating when power is applied from the high-frequency oscillator 400. do.

The induction heating refers to a method of heating a conductive object by placing it in a changing magnetic field, and the object to be heated must be conductive.

In high-frequency induction heating, when a high-frequency current supplied from the high-frequency oscillator 400 by power supply flows along the induction coil 300, it is wound by the induction coil 300 and produces an electromagnetic induction effect on the material of the object to be heated located at the center. The surface of the material to be heated is rapidly heated due to heat loss due to eddy current and hysteresis.

The high-frequency oscillator 400 may be an oscillator that supplies a known high-frequency current and generates a high frequency of 100-400 kHz so that alloys such as platinum can be dissolved.

Accordingly, the material to be heated in the dissolution chamber 200 is melted through electromagnetic induction by high-frequency current.

The infrared sensor 600 is capable of measuring extremely high temperatures, and is installed in plural numbers in the melting chamber 200 to sense the melting temperature of the material.

The process of melting the material through the induction heating-based high-frequency alloy melting furnace according to the present invention configured as described above is as follows.

As shown in FIG. 1, an alloy material such as platinum is placed in the dissolution chamber 200 within the body 100, and the high-frequency oscillator 400 is operated. Then, a high-frequency current with a capacity of approximately 100-400 kHz is generated through the induction coil 300 to heat the material. After the material begins to melt and reaches an appropriate temperature, the infrared sensor 600 senses and outputs the temperature value, and the control unit 600 controls the high-frequency oscillator 400 through the input sensing value and the previously stored temperature value to stabilize the temperature. Molten material can be obtained.

Meanwhile, the present invention is not limited to the above-described embodiments and the accompanying drawings, and may be modified and applied in various ways not exemplified without departing from the technical spirit of the present invention. It is clear to those skilled in the art that the present invention can be broadly applied by replacing components and changing it to other equivalent embodiments. Therefore, contents related to modifying and applying the technical features of the present invention should be construed as being included within the technical idea and scope of the present invention.

100: body
200: Dissolution chamber
300: Induction coil
400: high frequency oscillator
500: Infrared sensor
600: Control unit

Claims (3)

In a high-frequency melting furnace,
a body having a dissolution chamber for dissolving the material;
A high-frequency oscillator provided in the body to supply high-frequency current,
an induction coil provided on the outer peripheral surface of the wall of the dissolution chamber, connected to the high frequency oscillator through a terminal, and guiding the high frequency supplied from the high frequency oscillator to melt the material of the dissolution chamber;
A plurality of infrared sensors installed in the dissolution chamber to sense the melting point of the material and output a sensing signal value;
a control unit that controls a high-frequency oscillator through the sensing signal value of the infrared sensor;
Induction heating-based high-frequency alloy melting furnace including.
According to paragraph 1,
The high-frequency oscillator is,
A high-frequency alloy melting furnace based on induction heating, characterized by a capacity of 100-400 kHz.
According to paragraph 1,
The melting chamber is an induction heating-based high-frequency alloy melting furnace, characterized in that it is made of a ceramic material.

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