Patent Application
20190255605
The present invention relates to an immersion-type burner heater and a molten-metal holding furnace that are used for casting aluminum, aluminum alloy, or the like as well as for melting ingots, for example.
Conventionally, in order to heat and hold molten metal to be casted such as, for example, aluminum, aluminum alloy, or the like in a molten-metal holding furnace, a heater for heating the molten metal that is configured to be inserted through the furnace wall has been used.
Although a molten-metal holding furnace that employs a metal heating element as a heat source for the heater described above for heating the molten metal has been in practical use, a gas burner has been suggested to be used instead of the metal heating element as a heat source.
For example, Patent document 1 discloses a combustion tubular heater for heating molten metal as a burner heater including an inner cylinder that is arranged inside an outer cylinder serving as a heater protection tube, wherein combustion gas is supplied through the space between the inner cylinder and the outer cylinder, and then the exhaust gas is collected from the inner cylinder.
Such a burner heater increases the temperature of the outer cylinder side by passing the combustion gas between the inner cylinder and the outer cylinder so as to efficiently heat the molten metal. Also, the exhaust gas is collected from the tip-end opening of the inner cylinder through the inside thereof into an exhaust gas pipe on the base end side of the inner cylinder.
Generally, in a molten-metal holding furnace that is configured so that a heater is inserted through the furnace wall and then immersed in the furnace, the molten metal in the furnace can be leaked out of the furnace through the gap between a heater protection tube and the furnace wall. For preventing this leakage, the temperature inside the heater protection tube at the part embedded in the furnace wall has to be 600° C. or lower (the melting point of aluminum is 660° C.), for example, that is the temperature at which, if the molten metal enters the gap between the furnace wall and the heater protection tube, the molten metal can be solidified so as to be prevented from leaking out.
However, when a gas burner is used, the exhaust gas having a high temperature can heat the furnace wall, thus causing the molten metal to leak out. Hence, in the configuration of the burner heater and the molten-metal holding furnace disclosed in Patent document 1, the exhaust gas is collected from the inner cylinder and combustion air is passed through its outside, so that the exhaust gas having a high temperature does not pass through immediately inside the furnace wall.
[Patent Document 1] Japanese Unexamined Patent Application Publication H11-347720
Problems to be Solved by the Invention
The following problems still remain in the conventional technology described above.
In the burner heater disclosed in Patent Document 1, the temperature of the furnace wall side is prevented from becoming high by collecting the exhaust gas from the inner cylinder. However, in order to sufficiently lower the temperature of the furnace wall side so as to completely prevent the molten metal from leaking out, the temperature of the exhaust gas has to be further lowered. It also has a problem that since the heat of a flame cannot be efficiently transferred to the heater protection tube, the temperature of the burner heater cannot be efficiently increased and accordingly the combustion gas is inconveniently collected into the inner cylinder and exhausted therefrom before all the gas has been burnt out.
The present invention has been made in view of the aforementioned problems, and an object of the present invention is to provide an immersion-type burner heater and a molten-metal holding furnace that can provide a high heat transfer coefficient and can allow the exhaust gas temperature to be lowered.
The present invention adopts the following configuration in order to solve the aforementioned problems. Specifically, an immersion-type burner heater according to a first aspect of the present invention comprises: a heater protection tube that is installed so as to penetrate a furnace wall or an upper lid of a molten-metal holding furnace with the tip end thereof being closed; an inner cylindrical member that is arranged inside the heater protection tube so as to define a flow passage for combustion (hereafter referred to as “combustion flow passage”) between the heater protection tube and itself with the tip end side thereof being open and the inside thereof serving as an exhaust gas flow passage; and a gas burner part for supplying fuel gas and air to the combustion flow passage, wherein a helically extending projecting part is provided on at least one of the outer peripheral surface of the inner cylindrical member and the inner peripheral surface of the heater protection tube at a position that is closer to its tip end side than to the part penetrating the furnace wall or the upper lid.
In this immersion-type burner heater, since the helically extending projecting part is provided on at least one of the outer peripheral surface of the inner cylindrical member and the inner peripheral surface of the heater protection tube at a position that is closer to its tip end side than to the part penetrating the furnace wall or the upper lid, combustion gas helically advances in the combustion flow passage between the inner cylindrical member and the heater protection tube by being guided by the projecting part. Due to this configuration, the flow rate of the combustion gas can be increased compared with the case without the helically extending projecting part, and therefore the heat transfer coefficient to the heater protection tube by the convection flow can be increased. In addition, the helical advancement of the combustion gas causes a turbulent flow to occur, thereby making it easier to mix the combustion gas with air. As a result, the combustion efficiency can be improved and the amount of the combustion gas that is exhausted from the inner cylindrical member without having been burnt out can be reduced. Furthermore, the increase of the heat transfer coefficient to the heater protection tube can cause the heat exchange to be more actively performed between the molten metal and the heater, thereby making it possible to lower the temperature of the exhaust gas.
An immersion-type burner heater according to a second aspect of the present invention is characterized by the immersion-type burner heater according to the first aspect, wherein the projecting part is provided between the portions of the helical groove that is formed on the inner peripheral surface of the heater protection tube.
Specifically, in this immersion-type burner heater, since the projecting part is provided between the portions of the helical groove that is formed on the inner peripheral surface of the heater protection tube, the projecting part can be readily formed by groove machining or the like on the inner peripheral surface of the heater protection tube and the flow rate or the like of the combustion gas can also be readily set depending on the groove width or the like. In addition, the projecting part can increase the surface area of the heater protection tube, thereby further improving the heat exchanging property between the protection tube and the heater.
An immersion-type burner heater according to a third aspect of the present invention is characterized by the immersion-type burner heater according to the first aspect, wherein the projecting part is a helical fin that is provided on the outer peripheral surface of the inner cylindrical member.
Specifically, in this immersion-type burner heater, since the projecting part is a helical fin that is provided on the outer peripheral surface of the inner cylindrical member, the flow rate or the like of the combustion gas can be readily set depending on the shape of the helical fin or the like.
An immersion-type burner heater according to a fourth aspect of the present invention is characterized by the immersion-type burner heater according to any one of the first to third aspects comprising an air flow passage for supplying air into the combustion flow passage at the part penetrating the furnace wall or the upper lid, wherein a heat exchange fin that is fixed on the inner cylindrical member or an air supply line is provided in the air flow passage.
Specifically, in this immersion-type burner heater, since the heat exchange fin is provided in the air flow passage, the heat exchange is performed between the air that is supplied into the air flow passage and the heat exchange fin that is fixed on the inner cylindrical member or the air supply line, and therefore the supplied air can be efficiently warmed.
An immersion-type burner heater according to a fifth aspect of the present invention is characterized by the immersion-type burner heater according to any one of the first to fourth aspects, wherein a heat insulating member made of a heat insulating material having a lower heat conductivity than that of the heater protection tube is provided on the outer peripheral part of the base end side of the inner cylindrical member.
In the technology disclosed in Patent document 1, since the base end of the inner cylindrical member is overheated and then the exhaust gas is warmed by the base end of the inner cylindrical member, the temperature of the exhaust gas is inconveniently increased. Specifically, the temperature of the base end of the heater becomes very high because this part is in direct contact with the flame of the burner. Therefore, when the inner cylindrical member becomes excessively hot, the temperature of the exhaust gas passing therethrough can also become high.
However, in the present invention, since the heat insulating member made of a heat insulating material having a lower heat conductivity than that of the heater protection tube is provided on the outer peripheral part of the base end side of the inner cylindrical member, the inner cylindrical member can be prevented from being overheated and also heat can be efficiently transferred to the heater protection tube.
In addition, since the tip end of the inner cylindrical member is not in direct contact with the flame of the burner, the temperature thereof becomes lower than that of the base end thereof. Therefore, the inner cylindrical member can be prevented from being overheated by dissipating heat from the inner cylindrical member without attaching the heat insulating material.
A molten-metal holding furnace according to a sixth aspect of the present invention is characterized by the immersion-type burner heater according to any one of the first to fourth aspects, wherein a heat insulating member made of a heat insulating material having a lower heat conductivity than that of the heater protection tube is provided on the inner cylindrical member over a range from its base end side to a vicinity of its tip end.
Specifically, in this molten-metal holding furnace, since the heat insulating member made of a heat insulating material having a lower heat conductivity than that of the heater protection tube is provided on the inner cylindrical member over a range from its base end side to a vicinity of its tip end, the thermal energy generated from the combustion gas can be repelled by the heat insulating member that is provided over a broad range of the outer peripheral part of the inner cylindrical member and heads toward the heater protection tube. As a result, the heat transfer coefficient to the heater protection tube can be increased in proportion to the attached range of the heat insulating member.
A molten-metal holding furnace according to a seventh aspect of the present invention comprises a holding tank for holding molten metal and the immersion-type burner heater according to any one of the first to sixth aspects that is installed so as to penetrate the furnace wall or the upper lid of the holding tank.
Specifically, since this molten-metal holding furnace comprises the immersion-type burner heater according to any one of the first to sixth aspects, the immersion-type burner heater of the present invention having the increased heat transfer coefficient and energy efficiency allows for holding molten metal with less energy compared with that of the prior art.
According to the present invention, the following effects may be provided.
Specifically, in the immersion-type burner heater of the present invention, since the helically extending projecting part is provided on at least one of the outer peripheral surface of the inner cylindrical member and the inner peripheral surface of the heater protection tube at a position that is closer to its tip end side than to the part penetrating the furnace wall or the upper lid, the heat transfer coefficient can be increased and the temperature of the exhaust gas can also be lowered. Accordingly, the combustion efficiency can be improved and the amount of unburnt combustion gas that is exhausted from the inner cylindrical member can be reduced.
Therefore, the immersion-type burner heater and the molten-metal holding furnace of the present invention can allow the temperature of the furnace wall to be lowered compared with that of the prior art, thereby surely preventing the molten metal from leaking out.
Hereinafter, an immersion-type burner heater and a molten-metal holding furnace according to a first embodiment of the present invention will be described with reference to
As shown in
In addition, as shown in
On the inner peripheral surface of the heater protection tube 2 at a position that is closer to its tip end side than to the part penetrating the furnace wall 11a (the part embedded into the furnace wall 11a) is provided a helically extending projecting part 2a.
The helical projecting part 2a is formed between the portions of the helical groove that is formed on the inner peripheral surface of the heater protection tube 2. This helical projecting part 2a is formed up to the tip end of the heater protection tube 2 coaxially therewith.
The heater protection tube 2 is made of, for example, fine ceramics, silicon carbide based refractory, or the like. To this heater protection tube 2 is attached a mounting cylindrical member 5 on the base end side thereof that is fixed to the furnace wall 11a through the mounting cylindrical member 5. Note that the mounting cylindrical member 5 may be integrated into the heater protection tube.
The inner cylindrical member 3 is made of heat-resistant metal, ceramics, or the like.
The gas burner part 4 includes a gas supply line 7 for combustion gas that has a jet nozzle 6 at the tip end thereof and an air supply line 8 for supplying air to a combustion flow passage S.
The base end of the gas supply line 7 is connected to a combustion gas pipe (not shown) for supplying combustion gas.
The jet nozzle 6 is arranged so as to project more medially with respect to the furnace wall 11a (i.e., towards the tip end side of the heater) into the combustion flow passage S that is a part immersed in the molten metal M in order to leave the flame far away from the furnace wall 11a as much as possible.
As shown in
This air supply line 8 has a triple cylindrical structure, that is, it includes an outer cylindrical part 13 having an air hole 13a to which an air pipe 12 is connected on the base end side thereof; a middle cylindrical part 14 that is arranged inside the outer cylindrical part 13 and provided so as to define a first flow passage 9a between the outer cylindrical part 13 and itself; and an inner cylindrical part 15 that is arranged inside the middle cylindrical part 14 and provided so as to define a second flow passage 9b between the middle cylindrical part 14 and itself and also define a third flow passage 9c between the inner cylindrical member 3 and itself. Specifically, the air flow passage 9 is composed of three layers of the first flow passage 9a, the second flow passage 9b, and the third flow passage 9c.
The tip end of the middle cylindrical part 14 is arranged at a position closer to the base end side thereof compared with the tip ends of the outer cylindrical part 13 and the inner cylindrical part 15, and the base end of the inner cylindrical part 15 is arranged at a position closer to the tip end side thereof compared with the base end of the middle cylindrical part 14.
In addition, the tip end of the air supply line 8 is closed except the tip-end opening of the inner cylindrical part 15 (the tip-end opening of the third flow passage 9c) and the base end thereof is closed by a flange member 16.
Therefore, the first flow passage 9a is in communication with the tip end side of the second flow passage 9b on the tip end side thereof. In addition, the second flow passage 9b is in communication with the third flow passage 9c on the flange member 16 side, and the tip end of the third flow passage 9c is open and is in communication with the combustion flow passage S. Specifically, the air that is supplied through an air hole 13a to the air supply line 8 firstly flows through the first flow passage 9a towards its tip end side, turns around at its tip end side, and then flows through the second flow passage 9b towards the flange member 16 side. Furthermore, the air flowing through the second flow passage 9b turns around at the flange member 16 side, flows through the third flow passage 9c towards its tip end side so as to be supplied through the tip-end opening into the combustion flow passage S.
On the other hand, the gas supply line 7 is penetrating the flange member 16 and is installed so as to be inserted into the second flow passage 9b with the jet nozzle 6 projecting into the combustion flow passage S. From the jet nozzle 6, combustion gas is supplied into the combustion flow passage S, where this combustion gas is mixed with the air that is supplied into the combustion flow passage S so as to be burnt.
Note that the first flow passage 9a can be formed into a flow passage having a thin layer by configuring the space between the outer cylindrical part 13 and the middle cylindrical part 14 to be narrow, thereby increasing the flow rate of air. As a result, the heat exchange can be performed efficiently.
In the third flow passage 9c of the air flow passage 9, a heat exchange fin 17 that is fixed to the inner cylindrical member 3 is provided. This heat exchange fin 17 is helically attached to the outer peripheral surface of the inner cylindrical member 3. Specifically, the air flowing through the third flow passage 9c is helically flown by the heat exchange fin 17 and is then supplied into the combustion flow passage S after being warmed by the heat exchange with the inner cylindrical member 3. Note that the heat exchange fin 17 may be fixed to the air supply line 8.
In addition, although the temperature at the time when the combustion gas is burnt is about 1100° C., the energy required for increasing the temperature to the above described combustion temperature can be reduced because the supplied air is warmed as described above.
In
As described above, in the immersion-type burner heater 1 of the present embodiment, since the helically extending projecting part 2a is provided on the inner peripheral surface of the heater protection tube 2 at a position that is closer to its tip end side than to the part penetrating the furnace wall 11a, the combustion gas helically advances in the combustion flow passage S between the inner cylindrical member 3 and the heater protection tube 2 by being guided by the projecting part 2a. Due to this configuration, the flow rate of the combustion gas is increased compared with the case without the helical projecting part 2a, and therefore the heat transfer coefficient to the heater protection tube 2 by the convection flow is increased.
In addition, the helical advancement of the combustion gas causes a turbulent flow to occur, thereby making it easier to mix the combustion gas with air. As a result, the combustion efficiency can be improved and the amount of the combustion gas that is exhausted from the inner cylindrical member 3 without having been burnt out can be reduced. Furthermore, the increase of the heat transfer coefficient to the heater protection tube 2 can cause the heat exchange to be more actively performed between the molten metal M and the heater 1, thereby lowering the temperature of the exhaust gas. In addition, the projecting part 2a can increase the surface area of the heater protection tube 2, thereby further improving the heat exchanging property.
In addition, since the projecting part 2a is provided between the portions of the helical groove that is formed on the inner peripheral surface of the heater protection tube 2, the projecting part 2a can be readily formed by groove machining or the like on the inner peripheral surface of the heater protection tube 2, and the flow rate or the like of the combustion gas can also be readily set depending on the groove width or the like.
In addition, since the heat exchange fin 17 is provided in the air flow passage 9, the heat exchange is performed between the air that is supplied into the air flow passage 9 and the heat exchange fin 17 that is fixed to the inner cylindrical member 3 or the air supply line 8.
Next, immersion-type burner heaters and molten-metal holding furnaces according to second to fourth embodiments of the present invention will be described below with reference to
The second embodiment is different from the first embodiment in the following points. In the first embodiment, the projecting part 2a is provided between the portions of the helical groove that is formed on the inner peripheral surface of the heater protection tube 2, whereas in an immersion-type burner heater 21 and a molten-metal holding furnace according to the second embodiment, as shown in
Specifically, in the second embodiment, the helical fin, which constitutes the helical projecting part 23a on the outer peripheral surface of the inner cylindrical member 23, defines the helical combustion flow passage S in the gap between the heater protection tube 22 and the inner cylindrical member 23.
The projecting part 23a of the helical fin is removably attached to the outer peripheral surface of the inner cylindrical member 23.
Note that, in the heater protection tube 22 according to the second embodiment, the projecting part is not formed by the helical groove on the inner peripheral surface thereof. In addition, the heater protection tube 22 is formed integrally with the mounting cylindrical member so as to have a mounting cylindrical part 25 at the base end thereof. Note that this mounting cylindrical part 25 may be fabricated as a separate mounting cylindrical member from the heater protection tube and then attached thereto as in the first embodiment.
As described above, in the immersion-type burner heater 21 and the molten-metal holding furnace according to the second embodiment, since the projecting part 23a is a helical fin that is provided on the outer peripheral surface of the inner cylindrical member 23, the flow rate or the like of the combustion gas can be readily set depending on the shape of the helical fin or the like.
Next, the difference of a third embodiment from the first embodiment will be described below. In the inner cylindrical member 3 according to the first embodiment, the outer peripheral part is exposed in the heater protection tube 2, whereas in an immersion-type burner heater 31 and a molten-metal holding furnace according to the third embodiment, as shown in
The heat insulating member 33 is formed so as to have a cylindrical shape and is then attached so as to cover the outer peripheral part of the base end of the inner cylindrical member 3. For the heat insulating material of this heat insulating member 33, a heat insulating material of alumina-based ceramics or the like having a lower heat conductivity than that of the heater protection tube 2 may be employed, for example.
As described above, in the immersion-type burner heater 31 and the molten-metal holding furnace according to the third embodiment, since the heat insulating member 33 made of a heat insulating material having a lower heat conductivity than that of the heater protection tube 2 is provided on the outer peripheral part of the base end side of the inner cylindrical member 3, the inner cylindrical member 3 can be prevented from being overheated and heat can be efficiently transferred to the heater protection tube 2.
In addition, since the tip end of the inner cylindrical member 3 is not in direct contact with the flame of the burner, the temperature thereof becomes lower than that of the base end thereof. Therefore, the inner cylindrical member 3 can be prevented from being overheated by dissipating heat from the inner cylindrical member 3 without using the heat insulating member 33.
Next, the difference of a fourth embodiment from the third embodiment will be described below. In the third embodiment, the heat insulating member 33 is provided on the outer peripheral part of the base end side of the inner cylindrical member 3, whereas in an immersion-type burner heater 41 and a molten-metal holding furnace according to the fourth embodiment, as shown in
In addition, the fourth embodiment is different from the third embodiment in that a projecting part 43a is a helical fin as in the second embodiment and the projecting part 43a is provided on the outer peripheral surface of the heat insulating member 43.
As described above, in the immersion-type burner heater 41 and the molten-metal holding furnace according to the fourth embodiment, since the heat insulating member 43 made of a heat insulating material having a lower heat conductivity than that of the heater protection tube 22 is provided on the inner cylindrical member 3 over a range from its base end side to a vicinity of its tip end, the thermal energy generated from the combustion gas can be repelled by the heat insulating member 43 that is provided over a broad range of the outer peripheral part of the inner cylindrical member 3 and heads toward the heater protection tube 22. As a result, the heat transfer coefficient to the heater protection tube 22 can be increased in proportion to the installed range of the heat insulating member 43.
Note that the heat insulating member 43 may be installed on the inner cylindrical member 3 over a range from any position that is slightly spaced apart from its base end up to a vicinity of its tip end as long as it is installed on the base end side of the inner cylindrical member 3. Specifically, since the outer peripheral part in the vicinity of the base end of the inner cylindrical member 3 serves as a combustion space BS for combustion gas, the heat insulating member 43 may be provided on the inner cylindrical member 3 over a range from the middle of its base end side toward its tip end so as to avoid this combustion space BS. Providing the combustion space BS sufficiently can allow the combustion efficiency of the flame to be improved and the amount of an unburned gas to be reduced.
In addition, among the rolls of the helical fin of the projecting part 43a that is in direct contact with the flame of the combustion gas near the combustion space BS, at least three rolls of the helical fin from the combustion space BS side may be made of a different material.
The technical scope of the present invention is not limited to the aforementioned embodiments, but the present invention may be modified in various ways without departing from the scope or spirit of the present invention.
For example, in the first embodiment described above, although the helical projecting part is formed on the inner peripheral surface of the heater protection tube, it may be formed on the outer peripheral surface of the inner cylindrical member. In addition, the helical projecting part may be formed on both of the inner peripheral surface of the heater protection tube and the outer peripheral surface of the inner cylindrical member. In this case, the helical projecting parts are preferably configured to extend at the same interval in the same direction on both surfaces.
In addition, in the second embodiment described above, although the projecting part of the helical fin is attached to the outer peripheral surface of the inner cylindrical member, it may be attached to the inner peripheral surface of the heater protection tube. In addition, the projecting part having a shape other than the helical shape may be formed on the inner peripheral surface of the heater protection tube so as to increase the surface area of the heater protection tube.
Furthermore, in each embodiment described above, although the heater protection tube is installed so as to penetrate the furnace wall of the holding tank of the molten-metal holding furnace, that is, so as to be immersed into the molten metal from the lateral side, there may be an upper lid provided for closing the upper opening of the holding tank of the molten-metal holding furnace and then the heater protection tube may be installed so as to penetrate this upper lid. In this case, the immersion-type burner heater is installed so as to penetrate the upper lid of the holding tank with the heater protection tube being inserted through the upper lid so as to be longitudinally extended and immersed into the molten metal.
1, 21, 31, 41: immersion-type burner heater, 2, 22: heater protection tube, 2a, 23a, 43a: projecting part, 3, 23: inner cylindrical member, 4: gas burner part, 9: air flow passage, 10: molten-metal holding furnace, 11: holding tank, 11a: furnace wall, 17: heat exchange fin, 33, 43: heat insulating member, M: molten metal, S: combustion flow passage
| Number | Date | Country | Kind |
|---|---|---|---|
| 2016-211632 | Oct 2016 | JP | national |
| 2017-172597 | Sep 2017 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2017/038176 | 10/23/2017 | WO | 00 |
