JP2024064570A - Metal melting holding furnace - Google Patents

Abstract

To provide a metal melting holding furnace which can suitably cool a radiation type heater for heating a crucible and can avoid the breakage or the like of the radiation type heater caused by heat.SOLUTION: A metal melting holding furnace comprises: a crucible 1 storing a metal to be melted; a crucible storage enclosure 2 surrounding the crucible; radiation type heaters 3 positioned between an outer circumference of the crucible and an inner circumference of the crucible storage enclosure and heating the crucible; tubular members 4 each surrounding an outer circumference of the radiation type heater with a prescribed interval provided between itself and the outer circumference of the radiation type heater. The tubular member is configured so as to allow radiation heat emitted from the radiation type heater to pass therethrough and further has cooling means for cooling the radiation type heater.SELECTED DRAWING: Figure 2

Description

The present invention relates to a metal melting and holding furnace.

It is widely known that metal melting furnaces, which heat and melt metals, use gas burners as their heat source, but using gas burners as a heat source poses an environmental problem in that they generate carbon dioxide, a greenhouse gas. In recent years, there has been a strong call to reduce carbon dioxide emissions generated by industrial production as a measure against global warming, and in light of this situation, it is desirable to avoid the use of gas burners, which generate carbon dioxide, as much as possible.

In response to the aforementioned environmental issues, Patent Document 1 discloses a technology that utilizes an electric heater as a heat source for a metal melting and holding furnace. That is, Patent Document 1 discloses an invention relating to an aluminum melting and holding furnace that is composed of an outer tank 3 made of an insulating fireproof material, an inner tank 5 made of an insulating fireproof material arranged with a space 7 between the outer tank 3, and a high-power electric heater 8 arranged in the space 7, and that melts aluminum ingots brought into the inner tank 5 by heating with the high-power electric heater 8.

JP 2014-70890 A

However, the invention shown in Patent Document 1 has the following problems. That is, the invention provides an electric heater in the space between the outer tank and the inner tank, which may shorten the life of the electric heater or, in some cases, damage the electric heater. More specifically, when the temperature of the inner tank rises due to the heat radiated from the electric heater, the heat emitted from the inner tank is transmitted not only to the inside of the inner tank but also to the space located outside, gradually raising the temperature of the space in which the electric heater exists. And when the temperature of the space rises and becomes high, it inevitably puts a load on the electric heater, which results in a short life of the electric heater or damage. In particular, the terminal part of the electric heater is relatively vulnerable to heat, so it is even more likely to be damaged. On the other hand, in order to avoid a rise in the temperature of the space in which the electric heater exists, it is necessary to suppress the output of the electric heater, but if the output is too low, problems occur such as not being able to melt the metal or taking a long time to melt the metal. To solve this problem, it is essential to use some means to cool the electric heater while maintaining its output when it is in use.

Therefore, in order to solve the above problems, the present invention aims to provide a metal melting and holding furnace that can reduce the load on the radiant heater by appropriately cooling the radiant heater while it is in use, thereby preventing damage to the radiant heater.

In order to solve the above problems, the present invention provides a metal melting and holding furnace that includes a crucible that contains the metal to be melted or the molten metal, a crucible housing that surrounds the crucible, a radiant heater that is located between the outer surface of the crucible and the inner surface of the crucible housing and heats the crucible by radiant heat, and a tubular member that surrounds the outer periphery of the radiant heater at a predetermined distance from the outer periphery of the radiant heater, the tubular member being configured to be permeable to the radiant heat emitted from the radiant heater and having a cooling function for cooling the radiant heater.

The cooling function of the present invention may also be such that gas or liquid can be circulated through the gap between the tubular member and the radiant heater.

Furthermore, the cooling function in the present invention may be achieved by exposing both ends of the tubular member to the outside of the crucible housing, and discharging gas or liquid taken in from one end of the tubular member from the other end of the tubular member.

According to the present invention, the radiant heater can be kept cooled while it is in operation, which reduces the load on the radiant heater and thus prevents damage to the radiant heater.

FIG. 2 is a perspective view of a metal melting and holding furnace installed on a stand. FIG. 2 is a vertical cross-sectional front view of a metal melting and holding furnace installed on a stand. FIG. 3 is a cross-sectional plan view of a metal melting and holding furnace. FIG. FIG. Plan view of a metal melting and holding furnace. Bottom view of a metal melting and holding furnace. Side view of a metal melting and holding furnace. FIG. 4 is a side view of a radiation heater according to another embodiment.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings. Fig. 1 is a perspective view of a metal melting and holding furnace installed on a stand, Fig. 2 is a vertical sectional front view of the metal melting and holding furnace installed on a stand, Fig. 3 is a cross-sectional plan view of the metal melting and holding furnace, Fig. 4 is a cross-sectional plan view of a tubular member and a radiant heater, and Fig. 5 is a side view of the radiant heater. The metal melting and holding furnace according to this embodiment shown in these drawings is roughly composed of a crucible 1 that contains the metal to be melted, a crucible housing 2 that surrounds the crucible 1, a radiant heater 3 that is located between the outer surface of the crucible 1 and the inner surface of the crucible housing 2 and heats the crucible 1 by radiant heat, a tubular member 4 that surrounds the outer periphery of the radiant heater 3 at a predetermined interval from the outer periphery of the radiant heater 3, and a reflector 5 provided outside the tubular member 4. In this embodiment, the metal melting and holding furnace is placed on a stand 6.

The crucible 1 is made by compressing and sintering graphite or the like, and is formed into a bottomed cylindrical shape with a predetermined height in the vertical direction. That is, the crucible 1 is formed with a peripheral wall that rises upward from the periphery of the bottom, which is circular in plan view, and the top is open. The metal to be melted can be contained in the space inside the bottom and the peripheral wall. The crucible 1 is placed on the top surface of the crucible installation stand 16, which will be described later, via a heat insulating sheet (not shown).

The crucible housing 2 is configured to surround the crucible 1 and house the crucible 1 therein. The crucible housing 2 surrounds the crucible 1 to maintain airtightness that blocks the inflow of outside air into the space between the crucible 1 and the housing 2. Here, the configuration of the crucible housing 2 will be specifically described. The crucible housing 2 is configured of a main body 10 having an inner diameter larger than that of the crucible 1 and formed in a cylindrical shape with openings at the top and bottom, an upper lid 11 that covers and closes the upper opening of the main body 10, and a lower lid 12 that covers and closes the lower opening of the main body 10. More specifically, the main body 10 has an outer portion formed in a cylindrical shape from a metal plate such as iron, and an insulating material is laminated on the inner portion. On the other hand, both the upper lid 11 and the lower lid 12 are square with the length and width of the sides greater than the diameter of the main body 10, and are formed in the shape of a plate having a predetermined thickness. In addition, both the upper lid 11 and the lower lid 12 are formed with a metal plate such as iron around them, and are formed with a heat insulating material housed inside. Furthermore, a circular opening 13 with a diameter greater than the outer diameter of the crucible 1 is drilled in the center of the upper lid 11. An opening/closing lid 14 is provided above the opening 13 to close the opening 13. The opening/closing lid 14 is formed in the shape of a disk with a diameter greater than the diameter of the opening 13, and although not shown, one end of the opening/closing lid 14 is hinged to the upper lid 12, so that the opening 13 can be opened by moving one end of the opening/closing lid 14 upward. Incidentally, the opening/closing lid 14 is also formed with a metal plate such as iron around them, and is formed with a heat insulating material housed inside them. Meanwhile, a circular base insertion hole 15 having a diameter substantially equal to that of the crucible installation base 16 is provided in the center of the lower lid 12, and is a hole for inserting a crucible installation base 16 described later. In addition, in each of the upper lid 11 and the lower lid 12, a plurality of circular tubular member insertion holes 17, 17... having a diameter substantially equal to that of the outer diameter of the tubular member 4 are provided at equal intervals at a position slightly outwardly away from the opening hole 13 in the upper lid 11 and at a position slightly outwardly away from the base insertion hole 15 in the lower lid 12, so as to surround the opening hole 13 and the base insertion hole 15. In addition, in each of the upper lid 11 and the lower lid 12, a plurality of arc-shaped reflector insertion slits 18, 18... are provided outwardly (toward the crucible housing 2) from the tubular member insertion holes 17, 17.... The reflector insertion slits 18, 18, ... are connected at their centers to parts of the tubular member insertion holes 17, 17, .... In this embodiment, twelve tubular member insertion holes 17 and twelve reflector insertion slits 18 are drilled in each of the upper cover 11 and the lower cover 12. Furthermore, rod insertion holes for inserting support rods 19 are drilled in the four corners of each of the upper cover 11 and the lower cover 12.

In this embodiment, the radiant heater 3 is an infrared heater. As shown in Figs. 4 and 5, the infrared heater 3 is formed inside a glass tube 25 filled with an inert gas, with a long, thin carbon heating element 26 and lead wire connection parts (terminals) 28, 28 located at both ends of the carbon heating element 26 and connecting lead wires 27. Electricity can be applied to the carbon heating element 26 of the infrared heater 3 through the lead wires 27 led out to the outside of the glass tube 25. In this embodiment, the carbon heating element 26 of the infrared heater 3 has a plurality of slits 29, 29... cut from one side edge to just before the other side edge along the longitudinal direction at equal intervals, and these slits 29, 29... are arranged so that the cut start ends of adjacent slits 29, 29 are opposite to each other. In other words, when a certain slit 29 is cut from one side edge, the slit 29 located next to it is cut from the other side edge, and these are alternately continuous. In addition, a fitting 20 is attached to the upper end of the infrared heater 3 to abut and hook the upper end of the tubular member 4.

The tubular member 4 is formed in a tubular shape that surrounds the outer periphery of the infrared heater 3, and both ends, i.e., the upper and lower ends, are open. When the tubular member 4 surrounds the infrared heater 3, a circular gap S is provided between them. That is, the inner circumferential surface of the tubular member 4 is positioned at a predetermined distance from the outer circumferential surface of the infrared heater 3, and this gap S is configured to allow air to pass through (cooling means). The tubular member 4 is also formed from a material that is permeable to the infrared rays emitted by the infrared heater 3, which in this embodiment is glass.

The reflector 5 is a member located outside the tubular member 4, specifically, on the side of the tubular member 4 that does not face the crucible 1, and reflects the infrared rays emitted from the infrared heater 3 toward the crucible 1, and is formed from a metal plate curved in an arc. The entire inner surface of the reflector 5 is coated with a reflective paint.

The stand 6 is formed by positioning the upper frame 30 and the lower frame 31, which are formed from four narrow rectangular metal plates in a frame shape, at a predetermined interval above and below, and fixing support plates 32, 32, ... to each of the four corners of the upper frame 30 and the lower frame 31. A square top plate 33 is fixed to the upper end of the upper frame 30. The vertical and horizontal dimensions of the upper frame 30 and the lower frame 31 of the stand 6 are formed to be the same size as the upper cover 11 and the lower cover 12 of the crucible housing 2. In addition, a plurality of circular air intake holes 34, 34, ... with a diameter approximately the same as the inside diameter of the tubular member 4 are drilled at equal intervals at positions spaced a predetermined distance from the center of the top plate 33. These air intake holes 34, 34,... are positioned vertically in a straight line with the tubular member insertion holes 17, 17,... provided in the upper lid 11 and the lower lid 12 of the crucible housing 2. Furthermore, a rod insertion hole for inserting the support rod 19 is drilled in each of the four corners of the top plate 33. Casters 35, 35,... are attached to each of the four corners of the lower end of the stand 6, making it possible to move the metal melting and holding furnace provided on the stand 6.

Next, the assembly of the metal melting and holding furnace consisting of the above-mentioned components will be described. First, the support rods 19, 19, ... are inserted into the rod insertion holes drilled in the four corners of the top plate 33 of the stand 6. The outer periphery of the support rod 19 is threaded. Then, nuts are fastened to the support rod 19 from both the bottom and top of the top plate 33 so that the support rod 19 stands up above the top plate 33. Next, a nut is attached to the support rod 19 at a position a predetermined distance above the top plate 33. Then, the upper ends of the support rods 19, 19, ... are inserted through the rod insertion holes of the bottom cover 12 of the crucible housing 2, and the bottom cover 12 is placed on the bottom cover 19 fixed to the support rod 19, and the top surface of the bottom cover 12 is fastened with a nut to fix the bottom cover 12. Next, the crucible installation stand 16 is inserted into the stand insertion hole 15 drilled in the center of the bottom cover 12, and the crucible installation stand 16 is placed on the bottom cover 12 while being fitted into the stand insertion hole 15. At this time, the upper end of the crucible installation stand 16 is in a state of protruding above the bottom cover 12. Then, the main body 10 of the crucible housing 2 is placed on the upper surface of the bottom cover 12. Next, the support rod 19 is attached to a position at a predetermined distance above the bottom cover 12. Then, the rod insertion holes of the top cover 11 of the crucible housing 2 are inserted from the upper ends of the support rods 19, 19, ..., and the top cover 11 is placed on the nuts fixed to the support rods 19, and the top surface of the top cover 12 is tightened with the nuts to fix the top cover 11. At this time, no gap is created between the top surface of the main body 10 and the bottom surface of the top cover 11. Next, the reflectors 5, 5, ... are inserted through the reflector insertion slits 18, 18, ... of the top cover 11. As a result, the reflectors 5, 5, ... are positioned inside the main body 10. Next, the tubular members 4, 4, ... are inserted through the tubular member insertion holes 17, 17, ... of the top cover 11, and the lower ends of the tubular members 4, 4, ... are inserted through the tubular member insertion holes 17, 17 of the bottom cover 12. Note that the diameter of the air intake hole 34 of the top plate 33 of the stand 6 is set smaller than the outer diameter of the tubular members 4, so that the lower ends of the tubular members 4, 4, ... do not fall out of the air intake holes 34, 34, .... In other words, the lower ends of the tubular members 4, 4, ... are placed on the upper surface of the top plate 33 of the stand 6. However, since the diameter of the air inlet hole 34 is approximately the same as the inside diameter of the tubular member 4, outside air can flow into the tubular members 4 from the air inlet holes 34. In this state, the upper ends of the tubular members 4 protrude above the upper cover 11. Next, the infrared heater 3 is inserted inside the tubular members 4. The infrared heater 3 is set to have a longer longitudinal dimension than the tubular member 4, and has a fitting 20 at its upper end, so that the infrared heaters 3 are hooked to the tubular members 4 by the fitting 20. Finally, the crucible 1 is inserted through the opening 13 of the upper cover 11 of the crucible housing 2, and the crucible 1 is placed on the crucible installation stand 16. This completes the assembly of the metal melting and holding furnace.

Next, a method of melting metal and generating so-called molten metal using the metal melting and holding furnace according to the present embodiment configured as described above will be described. First, the openable cover 14 provided on the top cover 11 of the crucible housing 2 is opened, and the opening of the crucible 1 is made to face the opening hole 13 of the top cover 11. Then, the metal to be melted, ingots of aluminum alloy in this case, are poured through the opening hole 13 and contained in the crucible 1. At this time, the amount of ingots to be poured into the crucible 1 is determined taking into account the capacity of the crucible 1. Next, the openable cover 14 of the crucible housing 2 is closed, and the inside of the crucible housing 2 is sealed, and then the infrared heater 3 is operated. As a result, the infrared rays emitted from the infrared heater 3 are irradiated to the outer periphery of the crucible 1 to heat the crucible 1. Then, when the crucible 1 heats up, the heat of the crucible 1 is then transferred to the aluminum alloy in contact with the inner periphery of the crucible 1, melting the aluminum alloy. That is, the heat of the crucible 1 is first transferred to the aluminum alloy in contact with the inner surface of the crucible 1, and melting begins from the contact area. Then, as the aluminum melts and liquefies, the contact area between the aluminum and the crucible 1 expands, so the aluminum continues to melt, and eventually the aluminum is completely liquefied, producing what is known as molten metal.

Incidentally, in the above-mentioned aluminum alloy melting process, the metal melting and holding furnace of this embodiment has the following effects. That is, in the aluminum alloy melting process, when the temperature of the crucible 1 rises due to the radiant heat from the infrared heater 3, the heat emitted from the crucible 1 is also transmitted to the space outside the crucible 1, and the temperature inside the crucible housing 2 gradually rises. If the temperature inside the crucible housing 2 rises, a load is applied to the electric heater 3 installed therein, and in some cases, the electric heater 3 may be damaged. In addition, when the glass tube constituting the electric heater exceeds its heat resistance temperature, it absorbs moisture and becomes cloudy, and this clouding may cause the infrared rays emitted from the electric heater to be reflected inside the glass tube, further increasing the possibility of the electric heater being damaged. In this regard, the metal melting and holding furnace according to this embodiment is designed to cool the infrared heater 3 almost at the same time as the infrared heater 3 emits radiant heat in order to avoid this. That is, when the infrared heater 3 is operated, the infrared heater 3 itself becomes hot, and the surrounding air is heated. Here, since the lower end of the infrared heater 3 is exposed to the lower end of the crucible housing 2, the outside air around the exposed lower end of the infrared heater 3 is also heated. Then, the heated outside air flows in through the air intake hole 34 of the top plate 33 of the stand 6 located at the lower end of the infrared heater 3 by natural convection, passes through the gap S formed between the infrared heater 3 and the tubular member 4, and is discharged from the upper end opening of the tubular member 4. Therefore, since air flows through the gap S while the infrared heater 3 is operated, the infrared heater 3 can be maintained in a state where it is continuously cooled by the air. In particular, since the crucible 1 is heated by radiant heat, it is extremely beneficial that only the infrared heater 3 can be cooled without lowering its temperature. Another advantage is that only the infrared heater 3 can be cooled at all times while the crucible 1 is being heated, so the output of the infrared heater 3 can be set high.

In the above explanation, the present invention has been described as a metal melting furnace, but it also has an aspect as a metal holding furnace. In other words, it can be used as a furnace to hold molten liquid metal in the crucible 1 and hold this molten state.

Figure 9 is a side view of another embodiment of an infrared heater. The infrared heater 50 shown in this embodiment is formed by arranging two carbon heating elements 51, 52 side by side and housing these carbon heating elements 51, 52 inside a glass tube 53. In this way, when two carbon heating elements are provided, the output of the infrared heater 50 can be increased, and the lead wires 54, 54 can be advantageously pulled out together at the top end of the infrared heater 50.

Incidentally, in the above embodiment, an example was shown in which natural convection was used to circulate outside air through the gap between the tubular member and the radiant heater (infrared heater), but other cooling means can also be used. For example, a means for circulating air through the gap between the tubular member and the radiant heater using a pressure pump or the like can be used. In addition, as other means, a means for circulating a medium such as cooling water or cooling gas through the gap between the tubular member and the infrared heater can also be used. Furthermore, in the above embodiment, an example was shown in which both ends of the tubular member were exposed to the outside of the crucible housing so that outside air could flow in and out from there, but this is not necessarily required. In other words, even if the end of the tubular member is positioned inside the crucible housing, the object of the present invention can be achieved by providing a separate means for transporting air or liquid to the end. In addition, in the above embodiment, a crucible made of compressed and sintered graphite or the like was used as an example of a crucible, but this is not limited to this, and the crucible may be made of other materials. Furthermore, in the above embodiment, the tubular member is formed from glass, but it can be formed from another material as long as it is capable of transmitting the radiant heat emitted from the radiant heater. In addition, in the above embodiment, an example of the crucible housing is shown to be composed of three separate members, the main body, the top lid, and the bottom lid, but this is not limited to this, and the object of the present invention can be achieved, for example, by molding the main body, the top lid, and the bottom lid as a single unit. In the above embodiment, aluminum is shown as an example of the metal to be melted in the metal melting and holding furnace, but the metal melting and holding furnace of the present invention can of course also be used to melt other metals.

1 Crucible 1
2 crucible housing 3 radiation heater 4 tubular member

Claims (3)

A crucible for containing the metal to be melted or the molten metal;
A crucible housing surrounding the crucible;
a radiant heater located between an outer surface of the crucible and an inner surface of the crucible housing, the radiant heater heating the crucible by radiant heat;
A metal melting and holding furnace including a tubular member surrounding the outer periphery of the radiant heater at a predetermined interval,
The tubular member is configured to be permeable to radiant heat emitted from the radiant heater, and is provided with a cooling function for cooling the radiant heater. The metal melting and holding furnace according to claim 1, characterized in that the cooling function is capable of circulating gas or liquid through the gap between the tubular member and the radiant heater. The metal melting and holding furnace according to claim 1, characterized in that the cooling function is achieved by exposing both ends of the tubular member to the outside of the crucible housing, and discharging gas or liquid taken in from one end of the tubular member from the other end of the tubular member.

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