JP7428312B2 - Mounting structure of immersion heater for heating molten metal - Google Patents

Description

The present invention relates to a mounting structure for an immersion heater for heating molten metal, which heats the molten metal by immersing it in the molten metal used for melting or temperature maintenance.

Conventionally, as shown in FIG. 6, it has been known to heat the molten metal M in the melting chamber 101 of a melting and holding furnace 100 with an immersion heater 102. Since air AR exists between the two, there is a problem in that the oxide OX of the molten metal M adheres to the surface of the immersion heater 102 exposed from the upper lid 103.

If the oxide OX adheres to the surface of the immersion heater 102, the immersion heater 102 may not be able to radiate heat locally sufficiently, which may cause disconnection or electrical leakage.
Further, the work of removing oxide OX from the immersion heater 102 is dangerous because it involves hot work, and there is also a high risk of damaging the immersion heater 102 and the like during the work.

On the other hand, as shown in FIG. 7, the upper opening of the melting chamber 101 is closed with a melting chamber lid 105 to which an immersion heater 102 is attached, and a space is created between the melting chamber lid 105 and the molten metal M. It is known that the molten metal M and the air AR do not come into contact with each other in the melting chamber 101 by preventing the formation of air AR (for example, Patent Document 1).
According to this, oxidation can be prevented during heating of the molten metal M.

Patent No. 6638158

However, in the case shown in FIG. 7, the immersion heater 102 is bonded and firmly fixed to the melting chamber lid 105, so if a failure occurs in the immersion heater 102, only the immersion heater 102 is removed from the melting chamber lid 105. It cannot be removed and replaced.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a mounting structure for an immersion heater for heating molten metal that can be easily replaced while preventing the adhesion of oxides.

In order to achieve the above object, the mounting structure of the immersion heater for heating molten metal of the present invention is such that the immersion heater for heating molten metal is immersed in the molten metal (M) used for melting or temperature maintenance in the melting and holding furnace (10). M) A mounting structure for an immersion heater (20) for heating molten metal,
The immersion heater (20) is made of a refractory material, and the immersion heater (20) is inserted inside the melting and holding furnace (10), and extends in the upper and lower inner and outer directions of the melting and holding furnace (10). A heater support member (30) in which a through hole (35) is formed with a tapered portion (37) having a circular cross section that becomes smaller, and a lower end side of the through hole (35) in the furnace is immersed in the molten metal (M). and,
A hollow cylindrical part (41) is formed inside which is inserted into the tapered part (37) of the heater support member (30) and through which the immersion heater (20) passes, and whose outer shape follows the tapered part (37). a tapered sleeve (40);
When the sleeve (40) is inserted into the tapered part (37), it is in close contact with the tapered part (37) and the immersion heater (20), and the sleeve (40) is in close contact with the tapered part (37). In addition to being removable and not glued to the
In the through hole (35, 55) formed in the heater support member (30, 50), a hollow cylinder is connected to the tapered part (37, 57) on the outside of the furnace of the tapered part (37, 57). A shaped cylindrical portion (36, 56) is provided;
The cylindrical portion (36, 56) is characterized in that a removable collar (60) that presses the sleeve (40) from the outside of the furnace toward the inside of the furnace is inserted .

Further, the present invention is characterized in that the collar (60) is not bonded to the immersion heater (20) either.

The present invention also provides the installation of an immersion heater (20) for heating molten metal, which heats the molten metal (M) by immersing it in the molten metal (M) used for melting or temperature maintenance in the melting and holding furnace (10). The structure is
The immersion heater (20) is made of a refractory material, and the immersion heater (20) is inserted inside the melting and holding furnace (10), and extends in the upper and lower inner and outer directions of the melting and holding furnace (10). A heater support member (30) in which a through hole (35) is formed with a tapered portion (37) having a circular cross section that becomes smaller, and a lower end side of the through hole (35) in the furnace is immersed in the molten metal (M). and,
A hollow cylindrical part (41) is formed inside which is inserted into the tapered part (37) of the heater support member (30) and through which the immersion heater (20) passes, and whose outer shape follows the tapered part (37). a tapered sleeve (40);
When the sleeve (40) is inserted into the tapered part (37), it is in close contact with the tapered part (37) and the immersion heater (20), and the sleeve (40) is in close contact with the tapered part (37). In addition to being removable and not glued to the
The sleeve (40) is also not bonded to the immersion heater (20).

The present invention also provides the installation of an immersion heater (20) for heating molten metal, which heats the molten metal (M) by immersing it in the molten metal (M) used for melting or temperature maintenance in the melting and holding furnace (10). The structure is
The immersion heater (20) is made of a refractory material, and the immersion heater (20) is inserted inside the melting and holding furnace (10), and extends in the upper and lower inner and outer directions of the melting and holding furnace (10). A heater support member (30) in which a through hole (35) is formed with a tapered portion (37) having a circular cross section that becomes smaller, and a lower end side of the through hole (35) in the furnace is immersed in the molten metal (M). and,
A hollow cylindrical part (41) is formed inside which is inserted into the tapered part (37) of the heater support member (30) and through which the immersion heater (20) passes, and whose outer shape follows the tapered part (37). a tapered sleeve (40);
When the sleeve (40) is inserted into the tapered part (37), it is in close contact with the tapered part (37) and the immersion heater (20), and the sleeve (40) is in close contact with the tapered part (37). In addition to being removable and not glued to the
The sleeve (40) is a compression molded product made of ceramic fiber.

The present invention also provides the installation of an immersion heater (20) for heating molten metal, which heats the molten metal (M) by immersing it in the molten metal (M) used for melting or temperature maintenance in the melting and holding furnace (10). The structure is
The immersion heater (20) is made of a refractory material, and the immersion heater (20) is inserted inside the melting and holding furnace (10). A heater support member (50) is formed with a through hole (55) provided with a tapered portion (57) with a circular cross section that becomes smaller, and the inside of the furnace of the through hole (55) is immersed in the molten metal (M). ,
A hollow cylindrical part (41) that is inserted into the tapered part (57) of the heater support member (50) from the outside of the furnace and through which the immersion heater (20) passes is formed inside, and whose outer shape is the same as that of the tapered part (57). comprising a tapered sleeve (40) along the
When the sleeve (40) is inserted into the tapered portion (57), it is in close contact with the tapered portion (57) and the immersion heater (20), and the sleeve (40) is inserted into the tapered portion (57). It is characterized by being removable and not adhesive.

The present invention also provides the installation of an immersion heater (20) for heating molten metal, which heats the molten metal (M) by immersing it in the molten metal (M) used for melting or temperature maintenance in the melting and holding furnace (10). The structure is
The immersion heater (20) is made of a refractory material, and the immersion heater (20) is inserted inside the melting and holding furnace (10), extending obliquely from above to below and in and out of the furnace. A heater support is formed in which a through hole (35) is provided with a tapered portion (37) having a circular cross section whose diameter gradually decreases, and the inside of the furnace of the through hole (35) is immersed in the molten metal (M). A member (30);
A hollow cylindrical part (41) is formed inside which is inserted into the tapered part (37) of the heater support member (30) from the outside of the furnace and through which the immersion heater (20) passes. comprising a tapered sleeve (40) along the
When the sleeve (40) is inserted into the tapered part (37), it is in close contact with the tapered part (37) and the immersion heater (20), and the sleeve (40) is in close contact with the tapered part (37). It is characterized by being removable and not adhesive.

Here, the symbols in parentheses above indicate corresponding elements or matters listed in the drawings and the detailed description below.

According to the present invention, since the furnace side of the heater support member that supports the immersion heater for heating molten metal is immersed in the molten metal, there is no air layer between the immersion heater and the molten metal.
This prevents oxides from adhering to the immersion heater exposed from the heater support member.
Further, the immersion heater is attached to the heater support member through a tapered sleeve, and the sleeve is inserted from above into the tapered part of the through hole formed in the heater support member. Since it is in close contact with the part and the immersion heater, molten metal is prevented from entering through the through hole. If the sleeve is made of a compression molded product made of ceramic fiber, for example, the adhesion can be further improved.
Furthermore, since the sleeve is detachable from the tapered portion and is not bonded, the immersion heater can be easily removed from the heater support member and replaced when the immersion heater breaks down, for example.

Immersion heaters can be installed vertically so as to extend vertically relative to the melting and holding furnace, horizontally so as to extend horizontally relative to the melting and holding furnace, or installed upwardly relative to the melting and holding furnace. It can be applied even when it is installed so as to extend diagonally downward from the base.
When the immersion heater is installed vertically, the heater support member is installed, for example, on the ceiling wall of the melting and holding furnace, and the lower end side of the through hole in the furnace projects so as to be immersed in the molten metal. When the immersion heater is installed horizontally, the heater support member is installed, for example, on a side wall of the melting and holding furnace, so that the inside of the through hole is immersed in the molten metal. In this case, the inner side of the heater support member may protrude into the molten metal from the inner side surface of the side wall, or may be flush with the inner side surface of the side wall. Further, when the immersion heater is installed at an angle, the heater support member is installed, for example, on an inclined wall surface of the melting and holding furnace, so that the inside of the through hole in the furnace is immersed in the molten metal.

In addition, in the through hole formed in the heater support member, a hollow cylindrical part is provided on the outside of the taper part in a continuous manner with the taper part, and the sleeve is inserted into the cylindrical part from the outside of the furnace to the inside of the furnace. Since a collar is inserted to press the sleeve toward the tapered portion, the sleeve can be stably attached to the tapered portion even if it is not bonded with adhesive or the like.
Furthermore, since the collar is removable, the immersion heater and the sleeve can be easily removed from the heater support member and replaced when the immersion heater breaks down, for example.

Further, according to the present invention, since the sleeve is not bonded to the immersion heater in addition to the tapered portion, the immersion heater can be replaced after being removed from the sleeve.
Further, according to the present invention, since the collar is not bonded to the immersion heater in addition to the cylindrical portion, it can be replaced with the immersion heater removed from the collar.
According to these, only the immersion heater part can be replaced, and the sleeve and collar can also be reused.

1 is a sectional view showing a mounting structure of an immersion heater for heating molten metal according to an embodiment of the present invention. FIG. 2 is an enlarged sectional view of the heater support member shown in FIG. 1. FIG. FIG. 2 is an enlarged exploded perspective view of the immersion heater, sleeve, and collar shown in FIG. 1. FIG. It is a sectional view showing the attachment structure of another immersion heater for heating molten metal concerning an embodiment of the present invention. It is a sectional view showing the attachment structure of yet another immersion heater for heating molten metal concerning an embodiment of the present invention. FIG. 2 is a cross-sectional view showing a mounting structure of a conventional immersion heater for heating molten metal. FIG. 7 is a cross-sectional view showing a mounting structure of another immersion heater for heating molten metal according to a conventional example.

A mounting structure for an immersion heater for heating molten metal according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3.

As shown in FIG. 1, the mounting structure of the immersion heater for heating molten metal according to the present embodiment is immersed in molten metal M used for melting or temperature maintenance in a melting and holding furnace 10 for non-ferrous metals such as aluminum. The present invention relates to a mounting structure for an electric immersion heater 20 that heats a heater.

FIG. 1 shows a case where an immersion heater 20 is attached to a molten metal M in a heating chamber 15 of a melting and holding furnace 10.
The melting and holding furnace 10 includes a side wall 11, a bottom wall 12, and a ceiling wall 13, and a heater support member 30 for supporting the immersion heater 20 is provided on the ceiling wall 13. The ceiling wall 13 only needs to cover the upper part of the melting and holding furnace 10, and the whole or part thereof may be a lid (for example, a lid for cleaning). The immersion heater 20 is generally used, and includes a heating element (not shown) in a protective tube 21 in the form of a long tube with a closed bottom, and a conductor (not shown) that allows current to flow from the wiring terminal to the heating element. (omitted) is built-in. Further, although an example in which one immersion heater 20 is attached is shown here, a plurality of immersion heaters 20, such as three immersion heaters 20, may be attached at intervals, for example.

Although the heater support member 30 is not particularly limited, here, as shown in FIG. 31a, a metal plate 33 that covers the upper member 32 from above, and a pedestal 34 that protrudes above the metal plate 33. The legs 31b are constantly immersed in the molten metal M. In FIG. 1, the upper surface of the molten metal M is located above the height that divides the leg 31b of the lower member 31 into two halves, but the upper surface of the molten metal M is located below the lower end of the leg 31b of the lower member 31. It is made so that it does not become.
The lower member 31 is entirely made of a fireproof material, and the upper member 32 is made of a heat insulating material.

A through hole 35 is formed in the heater support member 30 and extends in the inner and outer directions of the upper and lower furnaces and penetrates vertically.
In the through hole 35, a hollow cylindrical portion 36 and a tapered portion 37 communicate with each other and extend vertically. The tapered portion 37 has a circular cross section whose diameter gradually decreases from the top to the bottom from the top to the bottom end of the leg 31b of the lower member 31. The diameter of the cylindrical portion 36 is the same as the maximum diameter (diameter at the upper end) of the tapered portion 37, and extends to part of the legs 31b of the upper member 32 and the lower member 31.

As shown in FIG. 3, the protective tube 21 of the immersion heater 20 is passed through the center of the through hole 35, and the sleeve 40 is inserted and fitted into the tapered part 37 of the through hole 35, and the sleeve 40 is inserted into the cylindrical shape of the through hole 35. A collar 60 is inserted and fitted into the portion 36.

The sleeve 40 is a truncated cone with a hollow cylindrical portion 41 formed in the center through which the protective tube 21 of the immersion heater 20 passes. The outer shape of the sleeve 40 is shaped along the tapered portion 37 of the through hole 35.
Further, the sleeve 40 is a compression molded product made of ceramic fiber, and when inserted into the tapered portion 37 of the through hole 35 from above, it is in close contact with the tapered portion 37 and the immersion heater 20 without any gaps. Molten metal M is prevented from entering.
Further, the sleeve 40 is not bonded to the tapered portion 37 or the immersion heater 20 with any adhesive or the like.
It should be noted that the sleeve 40 may be half-shaped to facilitate replacement work.

The collar 60 is made by connecting an upper disk 61 and a lower disk 62 having a smaller diameter with a column 63, and wrapping the column 63 from top to bottom with a heat insulating material 65 (note that the heat insulating material 65 ). The diameter of the column portion 63 is smaller than the diameters of the upper disk 61 and the lower disk 62, and a hollow cylindrical portion 64 through which the protection tube 21 of the immersion heater 20 passes is formed in the center.
The diameter of the lower disk 62 is slightly smaller than the diameter of the upper surface of the sleeve 40, and when the collar 60 is inserted into the cylindrical portion 36 of the through hole 35 from above, it has already been inserted into the tapered portion 37 of the through hole 35. The inserted sleeve 40 is pressed from the upper side (outside the furnace) to the lower side (inside the furnace).
When the collar 60 is fitted into the cylindrical portion 36, its upper disc 61 is supported from below by the holder 34.
The collar 60 is not bonded to the cylindrical portion 36 or the immersion heater 20 with any adhesive or the like.

When installing the immersion heater 20 in the melting and holding furnace 10, first, the protective tube 21 of the immersion heater 20 is passed through the sleeve 40 and the collar 60 so that the sleeve 40 is on the lower side than the collar 60. do.

Next, the protective tube 21 of the immersion heater 20, into which the sleeve 40 and collar 60 have been inserted, is directed downward from above to the through hole 35 of the heater support member 30 provided in the ceiling wall 13 of the melting and holding furnace 10. The sleeve 40 is lowered to the protective tube 21 of the immersion heater 20 at the desired position, inserted into the tapered part 37 of the through hole 35, and fitted without using adhesive. As a result, the immersion heater 20 is positioned in the vertical direction (height).

Next, the collar 60 is lowered and inserted into the cylindrical portion 36 of the through hole 35, and the sleeve 40 is fitted by being pressed from above without using an adhesive. As a result, the sleeve 40 can be stably attached even if it is not connected to the tapered portion 37 of the through hole 35 with adhesive.

In addition, when replacing the immersion heater 20 when a failure occurs in the immersion heater 20, the collar 60 is pulled upward from the heater support member 30, and then the immersion heater 20 is pulled out together with the sleeve 40, and a new immersion heater 20 is replaced. As described above, the sleeve 40 and collar 60 are inserted and attached to the heater support member 30.

In addition, at the time of initial installation, the heater support member 30 on which the immersion heater 20 is supported via the sleeve 40 and the collar 60 may be provided on the ceiling wall 13.

According to the immersion heater mounting structure according to the present embodiment, since the inside of the heater support member 30 that supports the immersion heater 20 is completely immersed in the molten metal M, there is a gap between the immersion heater 20 and the molten metal M. There are no air spaces.
This prevents oxides from adhering to the immersion heater 20 exposed from the heater support member 30.
Further, the immersion heater 20 is attached to the heater support member 30 via a tapered sleeve 40, and the sleeve 40 is inserted from above into the tapered portion 37 of the through hole 35 formed in the heater support member 30, In this state, the sleeve 40 is in close contact with the tapered portion 37 and the immersion heater 20, so that the molten metal M is prevented from entering through the through hole 35.
Furthermore, since the sleeve 40 is detachable from the tapered portion 37 and is not bonded, the immersion heater 20 can be easily removed from the heater support member 30 and replaced when the immersion heater 20 breaks down, for example.

Further, in the through hole 35 formed in the heater support member 30, a hollow cylindrical portion 36 is provided on the outside of the furnace of the tapered portion 37 and is connected to the tapered portion 37. Since the collar 60 is inserted to press the sleeve 40 from the outside of the furnace toward the inside of the furnace, the sleeve 40 can be stably attached to the tapered portion 37 even if it is not bonded with an adhesive or the like.
Moreover, since the collar 60 is removable, for example, when the immersion heater 20 breaks down, the immersion heater 20 can be easily removed from the heater support member 30 together with the sleeve 40 and replaced.

Further, since the sleeve 40 is not bonded to the immersion heater 20 in addition to the tapered portion 37, the immersion heater 20 can be removed from the sleeve 40 for replacement.
Furthermore, since the collar 60 is not bonded to the immersion heater 20 in addition to the cylindrical portion 36, it can be replaced with the immersion heater 20 removed from the collar 60.
According to these, only the immersion heater 20 can be replaced, and the sleeve 40 and collar 60 can also be reused.

In the above embodiment, the immersion heater 20 is installed vertically so as to extend vertically with respect to the melting and holding furnace 10, but as shown in FIG. It can be installed horizontally so that it extends, or it can be installed so that it extends obliquely from above to below with respect to the melting and holding furnace 10, as shown in FIG.

That is, the heater support member 50 is made of a refractory material, into which the immersion heater 20 is inserted, and extends in the left and right directions of the melting and holding furnace 10 (in the case of FIG. 5, the heater support member 30 is A through hole 55 is formed on the inside of the furnace and has a tapered portion 57 with a circular cross section whose diameter gradually decreases from the outside of the furnace to the inside of the furnace. The inside of the furnace 55 is immersed in the molten metal M. The heater support member 50 is provided on the side wall 11 of the melting and holding furnace 10 (in the case of FIG. 5, the heater support member 30 is the inclined wall 14 of the melting and holding furnace 10). In the case of FIG. 5, the furnace inner side of the heater support member 30 is flush with the furnace inner side surface of the inclined wall 14). Note that, similarly to the heater support member 30, the legs 51b of the internal member 51 are It may be made to protrude into the molten metal M from the inner side surface of the side wall 11 in the furnace. The outer member 52 is covered with a metal plate 53, and a pedestal 54 is provided protruding from the metal plate 53.

The sleeve 40 is inserted into a tapered portion 57 of a through hole 55 formed in the heater support member 50 from outside the furnace. A hollow cylindrical portion 41 through which the immersion heater 20 passes is formed inside the sleeve 40 and has a tapered outer shape along a tapered portion 57 . When the sleeve 40 is inserted into the tapered portion 57, it is in close contact with the tapered portion 57 and the immersion heater 20, and is detachable from the tapered portion 57 and the immersion heater 20 and is not bonded.

Further, the collar 60 is inserted from the outside of the furnace into a hollow cylindrical portion 56 provided in a continuous manner on the outside of the furnace of the tapered portion 57 in the through hole 55 formed in the heater support member 50, and the sleeve 40 is The pressure is applied from the outside of the furnace to the inside of the furnace. When the collar 60 is inserted into the cylindrical portion 56, it is detachable from the cylindrical portion 56 and the immersion heater 20 and is not bonded.

Further, in this embodiment, the sleeve 40 is not bonded to the immersion heater 20 either, but the sleeve 40 is bonded to the immersion heater 20, and when replacing the immersion heater 20, the immersion heater 20 with the sleeve 40 integrated is attached to the heater support member 30. , 50 or may be inserted in the opposite direction.
Further, the collar 60 may also be bonded to the immersion heater 20.

Further, in this embodiment, the collar 60 is provided to press the sleeve 40, but when the sleeve 40 is inserted into the tapered portions 37, 57 of the through holes 35, 55 formed in the heater support members 30, 50, If the sleeve 40 can be kept in a stable state, the collar 60 can be omitted.

Further, in this embodiment, the heater support member 30 (FIGS. 1 and 5) is provided on the ceiling wall 13 or the inclined wall 14 of the melting and holding furnace 10, and the heater support member 50 (FIG. 4) is provided on the melting and holding furnace 10. Although the immersion heater 20 is provided on the side wall 11, the present invention is not limited thereto, and the immersion heater 20 may extend vertically (vertically) or diagonally (inclined) so that no air layer exists between the immersion heater 20 and the molten metal M. The heater support member 30 is provided at the immersion heater 20 and the heater support member 50 is provided so that the immersion heater 20 extends left and right (horizontally) and there is no air layer between the immersion heater 20 and the molten metal M.

10 Melting and holding furnace 11 Side wall 12 Bottom wall 13 Ceiling wall 14 Inclined wall 15 Heating chamber 20 Immersion heater 21 Protective tube 30 Heater support member 31 Lower member 31a Head 31b Leg 32 Upper member 33 Metal plate 34 pedestal 35 Through hole 36 Cylindrical part 37 Tapered part 40 Sleeve 41 Hollow cylindrical part 50 Heater support member 51 Internal material 51a Head 51b Leg part 52 External material 53 Metal plate 54 Receiver 55 Through hole 56 Cylindrical part 57 Tapered part 60 Collar 61 Upper disk 62 Lower disk 63 Column part 64 Hollow cylindrical part 65 Heat insulating material 100 Melting and holding furnace 101 Melting chamber 102 Immersion heater 103 Upper lid 105 Melting chamber lid AR Air OX Oxide M Molten metal

Claims (6)

A mounting structure for an immersion heater for heating molten metal that heats the molten metal by immersing it in the molten metal used for melting or temperature maintenance in a melting and holding furnace,
The immersion heater is inserted inside the melting and holding furnace, which is made of a refractory material, extends in the upper and lower inner and outer directions of the melting and holding furnace, and has a circular cross-sectional taper whose diameter gradually decreases from the top to the bottom at the bottom end of the furnace. a heater support member in which a through hole is formed, and a lower end side of the through hole in the furnace is immersed in the molten metal;
a tapered sleeve that is inserted into the tapered part of the heater support member from above, has a hollow cylindrical part formed therein through which the immersion heater passes, and has a tapered outer shape that follows the tapered part;
When the sleeve is inserted into the tapered part, it is in close contact with the tapered part and the immersion heater, and the sleeve is detachable from the tapered part and is not bonded .
In the through hole formed in the heater support member, a hollow cylindrical part is provided on the outside of the furnace of the tapered part and is connected to the tapered part,
A mounting structure for an immersion heater for heating molten metal , characterized in that a removable collar is inserted into the cylindrical portion to press the sleeve from the outside of the furnace toward the inside of the furnace . The mounting structure for an immersion heater for heating molten metal according to claim 1, wherein the collar is not bonded to the immersion heater either. A mounting structure for an immersion heater for heating molten metal that heats the molten metal by immersing it in the molten metal used for melting or temperature maintenance in a melting and holding furnace,
The immersion heater is inserted inside the melting and holding furnace, which is made of a refractory material, extends in the upper and lower inner and outer directions of the melting and holding furnace, and has a circular cross-sectional taper whose diameter gradually decreases from the top to the bottom at the bottom end of the furnace. a heater support member in which a through hole is formed, and a lower end side of the through hole in the furnace is immersed in the molten metal;
a tapered sleeve that is inserted into the tapered part of the heater support member from above, has a hollow cylindrical part formed therein through which the immersion heater passes, and has a tapered outer shape that follows the tapered part;
When the sleeve is inserted into the tapered part, it is in close contact with the tapered part and the immersion heater, and the sleeve is detachable from the tapered part and is not bonded.
A mounting structure for an immersion heater for heating molten metal, characterized in that the sleeve is not bonded to the immersion heater either. A mounting structure for an immersion heater for heating molten metal that heats the molten metal by immersing it in the molten metal used for melting or temperature maintenance in a melting and holding furnace,
The immersion heater is inserted inside the melting and holding furnace, which is made of a refractory material, extends in the upper and lower inner and outer directions of the melting and holding furnace, and has a circular cross-sectional taper whose diameter gradually decreases from the top to the bottom at the bottom end of the furnace. a heater support member in which a through hole is formed, and a lower end side of the through hole in the furnace is immersed in the molten metal;
a tapered sleeve that is inserted into the tapered part of the heater support member from above, has a hollow cylindrical part formed therein through which the immersion heater passes, and has a tapered outer shape that follows the tapered part;
When the sleeve is inserted into the tapered part, it is in close contact with the tapered part and the immersion heater, and the sleeve is detachable from the tapered part and is not bonded.
A mounting structure for an immersion heater for heating molten metal, wherein the sleeve is a compression molded product made of ceramic fiber . A mounting structure for an immersion heater for heating molten metal that heats the molten metal by immersing it in the molten metal used for melting or temperature maintenance in a melting and holding furnace,
The immersion heater is inserted inside the melting and holding furnace, which is made of a refractory material, and extends in the left and right directions with respect to the melting and holding furnace. a heater support member in which a through hole is formed, and an inner side of the through hole is immersed in the molten metal;
A sleeve is inserted into the tapered part of the heater support member from the outside of the furnace, has a hollow cylindrical part formed inside thereof through which the immersion heater passes, and has a tapered outer shape that follows the tapered part,
Molten metal heating, wherein the sleeve is in close contact with the tapered part and the immersion heater when inserted into the tapered part, and the sleeve is detachable from the tapered part and is not bonded. Mounting structure of immersion heater. A mounting structure for an immersion heater for heating molten metal that heats the molten metal by immersing it in the molten metal used for melting or temperature maintenance in a melting and holding furnace,
The immersion heater is made of a refractory material, and the immersion heater is inserted inside the melting and holding furnace. a heater support member in which a through hole is formed with a tapered portion having a circular cross section, and an inner side of the furnace side of the through hole is immersed in the molten metal;
A sleeve is inserted into the tapered part of the heater support member from the outside of the furnace, has a hollow cylindrical part formed inside thereof through which the immersion heater passes, and has a tapered outer shape that follows the tapered part,
Molten metal heating, wherein the sleeve is in close contact with the tapered part and the immersion heater when inserted into the tapered part, and the sleeve is detachable from the tapered part and is not bonded. Mounting structure of immersion heater.