JP2004148408A - Vessel - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vessel in which trouble caused by molten aluminum is eliminated. <P>SOLUTION: The vessel which can hold the molten aluminum and can supply the molten aluminum to the outer part by adjusting the pressure difference between the inner part and the outer part, is provided with a vessel body having a first opening part at the outer part, a flowing passage which can make the molten aluminum held in the above vessel flow to the inner part and the outer part, a cover disposed so as to cover the first opening part in the vessel body and having a second opening part of smaller diameter than that of the first opening part and an openable/closable hatch arranged at the upper surface side of the above cover at the second opening part of the cover and provided with a gas passage for pressurizing in the vessel from the outer part. <P>COPYRIGHT: (C)2004,JPO

Description

  The present invention relates to a container.

  In a factory where aluminum is formed using a large number of die-casting machines, aluminum materials are often supplied not only from within the factory but also from outside the factory. In this case, a ladle containing molten aluminum is transported from the material supply side factory to the molding side factory, and the molten material is supplied to each die casting machine. .

Conventionally, the ladle has a structure like a teapot where the supply pipe is attached to the side wall of the container body where the molten metal is stored. By tilting the ladle, the holding furnace on the molding side can be tilted from the pipe. The molten metal is supplied to the steel.
Japanese Utility Model Publication No. 3-31063

  However, in such a ladle, for example, the inclination of the ladle is performed using a forklift, and such work is not necessarily safe. Moreover, since it is necessary to provide a turning mechanism in the forklift in order to incline the ladle, the configuration is special, and a worker skilled in the operation of the forklift is required for such operation. was there.

  Therefore, the present inventors have proposed a molten metal supply system using a pressure difference. In this system, a pipe for extracting molten metal to the outside is provided in a sealed container, and a pipe for supplying pressurized gas to the container is further connected, and the inside of the container is pressurized so that the metal is extracted. Molten metal is led out from the piping to, for example, a holding furnace on the molding side.

  However, the container having the above configuration has a problem that the pressurized gas supply pipe is easily clogged. In particular, in the above-mentioned system, for example, the container is often mounted on a truck and is shaken because it is transported from a factory to another factory via a public road. Scatters in the container, and these adhere to the pressurized gas supply pipe. And, for example, pipe clogging occurs due to repeated such adhesion.

  The present invention is intended to solve such problems.

In the present invention, molten aluminum can be accommodated, and a container capable of supplying molten aluminum to the outside by adjusting a pressure difference between inside and outside,
A container body having a first opening at the top;
A flow path capable of circulating the molten aluminum contained in the container inside and outside;
A lid that is arranged to cover the first opening of the container body and has a second opening having a smaller diameter than the first opening;
And a hatch provided on the upper surface side of the lid so as to be openable and closable in the second opening of the lid and provided with a gas passage for pressurizing the inside of the container from the outside. To do.

In the present invention, in an airtight container that contains molten aluminum and can supply the molten aluminum to the outside by a pressure difference,
A container body having a first opening at the top and capable of accommodating the molten aluminum;
A flow path that allows the molten aluminum to flow through the inside and outside of the container;
A lid that is arranged to cover the first opening of the container body and has a second opening having a smaller diameter than the first opening;
And a hatch that is provided on the upper surface of the lid so as to be openable and closable, and has a pressurized gas introduction part that pressurizes the container.

In the present invention, in an airtight container that contains molten aluminum and can supply the molten aluminum to the outside by a pressure difference,
A container body having a first opening at the top and capable of accommodating the molten aluminum;
A flow path that allows the molten aluminum to flow through the inside and outside of the container;
A lid that is arranged to cover the first opening of the container body and has a second opening having a smaller diameter than the first opening;
And a hatch provided on the upper surface of the lid so as to be openable and closable and having a pressurized gas inlet for pressurizing the container.

In the present invention, in an airtight container that contains molten aluminum and can supply the molten aluminum to the outside by a pressure difference,
A container body having a first opening at the top and capable of accommodating the molten aluminum;
A flow path that allows the molten aluminum to flow through the inside and outside of the container;
A lid that is arranged to cover the first opening of the container body and has a second opening having a smaller diameter than the first opening;
And a hatch provided on the upper surface of the lid so as to be openable and closable and having a pressurized gas hole for pressurizing the container.

  In the present invention, since the hatch is provided on the upper surface side or the upper surface portion of the lid, the distance between the rear surface of the hatch and the liquid surface is longer by the thickness of the lid than the distance between the rear surface of the lid and the liquid surface. Therefore, the possibility that metal adheres to the rear surface of the hatch is reduced. Therefore, in this invention, clogging of piping, a hole, etc. used for internal pressure adjustment can be prevented.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a diagram showing an overall configuration of a metal supply system according to an embodiment of the present invention.

  As shown in the figure, the first factory 10 and the second factory 20 are provided, for example, in places separated by a public road 30.

  In the first factory 10, a plurality of die-cast machines 11 as use points are arranged. Each die-casting machine 11 uses a molten aluminum as a raw material and molds a product having a desired shape by injection molding. Examples of such products include parts related to automobile engines. Of course, the molten metal is not limited to an aluminum alloy but may be an alloy mainly composed of other metals such as magnesium and titanium. In the vicinity of each die-casting machine 11, a holding furnace (hand holding furnace) 12 for temporarily storing molten aluminum before a shot is arranged. In this holding furnace 12, molten aluminum for a plurality of shots is stored, and molten aluminum is injected from the holding furnace 12 into the die-cast machine 11 via a ladle 13 or a pipe for each shot. It has become. Each holding furnace 12 has a liquid level detection sensor (not shown) for detecting the level of molten aluminum stored in the container and a temperature sensor (not shown) for detecting the temperature of the molten aluminum. Has been placed. The detection results by these sensors are transmitted to the control panel of each die cast machine 11 or the central control unit 16 of the first factory 10.

  In the receiving part of the first factory 10, a receiving table 17 for receiving a container 100 described later is arranged. The container 100 received by the receiving table 17 of the receiving unit is delivered to a predetermined die cast machine 11 by a delivery vehicle 18 so that molten aluminum is supplied from the container 100 to the holding furnace 12. The container 100 that has been supplied is returned to the receiving table 17 of the receiving unit by the delivery vehicle 18 again.

  The first factory 10 is provided with a first furnace 19 for melting aluminum and supplying it to the container 100, and the container 100 supplied with the molten aluminum by the first furnace 19 is also a delivery vehicle 18. Is delivered to a predetermined die-casting machine 11.

  The first factory 10 is provided with a display unit 15 that displays when it is necessary to add molten aluminum in each die-casting machine 11. More specifically, for example, a unique number is assigned to each die-casting machine 11, and the number is displayed on the display unit 15. This corresponds to the number of the die-casting machine 11 that requires addition of molten aluminum. The number on the display unit 15 to be lit is turned on. Based on the display on the display unit 15, the operator uses the delivery vehicle 18 to carry the container 100 to the die cast machine 11 corresponding to the number and supplies molten aluminum. The display on the display unit 15 is performed by the central control unit 16 controlling based on the detection result by the liquid level detection sensor.

  The second factory 20 is provided with a second furnace 21 for melting aluminum and supplying it to the container 100. For example, a plurality of types of containers 100 having different capacities, pipe lengths, heights, widths, and the like are prepared. For example, there are a plurality of types having different capacities depending on the capacity of the holding furnace 12 in the die cast machine 11 in the first factory 10. However, of course, the container 100 may be unified and standardized.

  The container 100 supplied with the molten aluminum by the second furnace 21 is placed on a transport truck 32 by a forklift (not shown). The truck 32 carries the containers 100 through the public road 30 to the vicinity of the receiving table 17 of the receiving section in the first factory 10, and these containers 100 are received by the receiving table 17 by a forklift (not shown). . Further, the empty container 100 in the receiving section is returned to the second factory 20 by the truck 32.

  The second factory 20 is provided with a display unit 22 that displays when it is necessary to add molten aluminum to each die-casting machine 11 in the first factory 10. The configuration of the display unit 22 is substantially the same as that of the display unit 15 arranged in the first factory 10. The display on the display unit 22 is performed by, for example, being controlled by the central control unit 16 in the first factory 10 via the communication line 33. In addition, in the display part 22 in the 2nd factory 20, it was determined that molten aluminum is supplied from the 1st furnace 19 in the 1st factory 10 among the die-cast machines 11 which need supply of molten aluminum. The die cast machine 11 is displayed separately from the other die cast machines 11. For example, the number corresponding to the die cast machine 11 determined in such a manner blinks. As a result, it is possible to prevent the molten aluminum from being erroneously supplied from the second factory 20 side to the die cast machine 11 determined to be supplied with the molten aluminum from the first furnace 19. In addition to the above, the display unit 22 displays data transmitted from the central control unit 16.

  Next, the operation of the metal supply system configured as described above will be described.

  The central control unit 16 monitors the amount of molten aluminum in each holding furnace 12 via a liquid level detection sensor provided in each holding furnace 12. Here, when the necessity of supplying molten aluminum occurs in a certain holding furnace 12, the central control unit 16 detects the “unique number” of the holding furnace 12 and the temperature sensor provided in the holding furnace 12. The “temperature data” of the holding furnace 12, “morphological data” regarding the form of the holding furnace 12 (to be described later), the final “time data” when the molten aluminum disappears from the holding furnace 12, “traffic of the public road 30 Data, “quantity data” and “temperature data” of the molten aluminum required in the holding furnace 12 are transmitted to the second factory 20 side via the communication line 33. In the second factory 20, these data are displayed on the display unit 22. Based on these displayed data, the operator empirically reaches the holding furnace 12 immediately before the molten aluminum runs out of the holding furnace 12, and the second temperature is set so that the molten aluminum at that time reaches a desired temperature. The shipping time of the container 100 from the factory 20 and the temperature at the time of shipping the molten aluminum are determined. Alternatively, these data are taken into, for example, a personal computer (not shown), and the container 100 reaches the holding furnace 12 immediately before the molten aluminum runs out from the holding furnace 12 using predetermined software, and the molten aluminum at that time has a desired temperature. The shipping time of the container 100 from the second factory 20 and the temperature at the time of shipping of molten aluminum may be estimated and the time and temperature may be displayed. Alternatively, the temperature of the second furnace 21 may be automatically controlled based on the estimated temperature. The amount of molten aluminum to be accommodated in the container 100 may also be determined based on the “quantity data”.

  When the truck 32 on which the container 100 is loaded departs at the shipping time and arrives at the first factory 10 through the public road 30, the container 100 is received from the truck 32 to the receiving table 17 of the receiving unit.

  Thereafter, the received container 100 is delivered to a predetermined die-casting machine 11 together with the receiving table 17 by the delivery vehicle 18, and molten aluminum is supplied from the container 100 to the holding furnace 12.

  As shown in FIG. 2, in this example, by sending high-pressure air from the receiver tank 101 into the sealed container 100, the molten aluminum accommodated in the container 100 is discharged from the pipe 56 into the holding furnace 12. It comes to be supplied. In FIG. 2, 103 is a pressurizing valve, and 104 is a leak valve.

  Here, the holding furnace 12 has various heights, and can be adjusted by an elevating mechanism provided in the delivery vehicle 18 so that the tip of the pipe 56 becomes an optimum position on the holding furnace 12. However, depending on the height of the holding furnace 12, there are cases in which it is not possible to cope with only the lifting mechanism. Therefore, in the present system, as “form data” regarding the form of the holding furnace 12, data relating to the height of the holding furnace 12, the distance to the holding furnace 12, and the like are sent to the second factory 20 side in advance, and the second factory 20 On the side, based on this data, an optimal form, for example, an optimal height container 100 is selected and delivered. Note that an optimally sized container 100 may be selected and delivered according to the amount to be supplied.

  Next, a container (pressurized molten metal supply container) 100 suitable for the system configured as described above will be described with reference to FIGS. 3 and 4. 3 is a cross-sectional view of the container 100, and FIG. 4 is a plan view thereof.

  The container 100 has a large lid 52 disposed in an upper opening 51 of a bottomed and cylindrical main body 50. Flange 53 and 54 are provided in the outer periphery of the main body 50 and the large lid 51, respectively, and the main body 50 and the large lid 51 are fixed by fastening between these flanges with the volt | bolt 55. The main body 50 and the large lid 51 are, for example, made of metal on the outer side and made of a refractory material and a heat insulating material on the inner side.

  A pipe mounting portion 58 provided with a flow path 57 communicating from the inside of the main body 50 to the pipe 56 is provided at one location on the outer periphery of the main body 50, and the pipe 56 is connected to the flow path 57 of the pipe mounting section 58. Is fixed. The pipe 56 has a Γ shape, and the one end 59 of the pipe 56 is directed downward. More specifically, the one end port 59 of the pipe 56 is inclined by about 10 ° with respect to the perpendicular. By providing such an inclination, for example, when molten metal led out from the one end port 59 flows down to the server side, it is less likely that molten water droplets are scattered from the molten metal surface.

  An opening 60 is provided substantially at the center of the large lid 52, and a hatch 62 to which a handle 61 is attached is disposed in the opening 60. The hatch 62 is provided at a position slightly higher than the upper surface of the large lid 52. The hatch 62 is attached to the large lid 52 via a hinge 63 at one location on the outer periphery. Thereby, the hatch 62 can be opened and closed with respect to the opening 60 of the large lid 52. Further, bolts 64 with handles for fixing the hatch 62 to the large lid 52 are attached at two locations on the outer periphery of the hatch 62 so as to face the position where the hinge 63 is attached. The hatch 62 is fixed to the large lid 52 by closing the opening 60 of the large lid 52 with the hatch 62 and rotating the bolt 64 with a handle. Further, the bolts 64 with the handle can be reversely rotated to release the fastening, and the hatch 62 can be opened from the opening 60 of the large lid 52. And the maintenance of the inside of the container 100 and the insertion of the gas burner at the time of preheating are performed through the opening part 60 with the hatch 62 opened.

  Further, at the center of the hatch 62 or at a position slightly deviated from the center, an internal pressure adjusting through hole 65 for reducing the pressure and pressurizing the container 100 is provided. A piping 66 for pressure increase / decrease is connected to the through hole 65. The pipe 66 extends upward from the through hole 65, bends at a predetermined height, and extends in the horizontal direction therefrom. A thread is formed on the surface of the insertion portion of the pipe 66 into the through hole 65, and a thread is also formed in the through hole 65, whereby the pipe 66 is fixed to the through hole 65 by screwing. It has come to be.

  One of the pipes 66 can be connected to a pressurizing or decompressing pipe 67, and the pressurizing pipe is connected to a tank or pressurizing pump accumulated in the pressurized gas. A decompression pump is connected to the piping for use. Then, it is possible to introduce molten aluminum into the container 100 through the pipe 56 and the flow path 57 by using the pressure difference by reducing pressure, and the flow path 57 and the pipe 56 by using the pressure difference by applying pressure. The molten aluminum can be led out to the outside of the container 100. In addition, oxidation of molten aluminum at the time of pressurization can be more effectively prevented by using an inert gas such as nitrogen gas as the pressurization gas.

  In the present embodiment, the through-hole 65 for pressure increase / decrease is provided in the hatch 62 arranged at the substantially central portion of the large lid 52, while the pipe 66 extends in the horizontal direction. The operation of connecting the pressure or pressure reducing pipe 67 to the pipe 66 can be performed safely and easily. Further, since the piping 66 extends in this manner, the piping 66 can be rotated with a small force with respect to the through hole 65, so that the fixing and removal of the piping 66 screwed to the through hole 65 can be very difficult. For example, without using a tool.

  A pressure release through hole 68 is provided at a position slightly offset from the center of the hatch 62 and opposed to the pressure increasing / decreasing through hole 65. The pressure release through hole 68 includes a relief valve. (Not shown) is attached. Thereby, for example, when the inside of the container 100 becomes a predetermined pressure or more, the inside of the container 100 is opened to the atmospheric pressure from the viewpoint of safety.

  In the large lid 52, two through holes 70 for a liquid level sensor into which two electrodes 69 as a liquid level sensor are respectively inserted are arranged at a predetermined interval. Electrodes 69 are inserted into the through holes 70, respectively. These electrodes 69 are arranged so as to face each other in the container 100, and their respective tips extend to substantially the same position as the maximum liquid level of the molten metal in the container 100, for example. And it is possible to detect the maximum liquid level of the molten metal in the container 100 by monitoring the conduction state between the electrodes 69, and thereby more reliably prevent the excessive supply of the molten metal to the container 100. It has become.

  On the bottom rear surface of the main body 50, for example, two leg portions (channels) 71 having a predetermined cross-sectional shape into which a fork (not shown) of a forklift is inserted are arranged in parallel, for example. Further, the entire bottom of the main body 50 is inclined so that the flow path 57 side is lowered. Thereby, when the molten aluminum is led out to the outside through the flow path 57 and the pipe 56 by pressurization, so-called remaining hot water is reduced. Further, for example, when the molten aluminum is led out to the outside through the flow path 57 and the pipe 56 by tilting the container 100 during maintenance, the angle at which the container 100 is tilted can be made smaller, and safety and workability are excellent. .

  As described above, in the container 100 according to the present embodiment, the through-hole 65 for adjusting the internal pressure is provided in the hatch 62 and the piping 66 for adjusting the internal pressure is connected to the through-hole 65, so that the molten metal is put into the container 100. It is possible to confirm the adhesion of the metal to the internal pressure adjusting through-hole 65 every time it is supplied. Therefore, clogging of the piping 66 and the through hole 65 used for adjusting the internal pressure can be prevented in advance.

  Further, in the container 100 according to this embodiment, the through-hole 65 for adjusting the internal pressure is provided in the hatch 62, and the hatch 62 is located at a position where the change in the liquid level of the molten aluminum and the degree of droplet scattering are relatively small. Since it is provided at substantially the center of the upper surface portion of the corresponding container 100, the molten aluminum is less likely to adhere to the piping 66 and the through hole 65 for use in adjusting the internal pressure. Therefore, it is possible to prevent clogging of the piping 66 and the through hole 65 used for adjusting the internal pressure.

  Furthermore, in the container 100 according to the present embodiment, since the hatch 62 is provided on the upper surface portion of the large lid 52, the distance between the back surface of the hatch 62 and the liquid surface is the distance between the back surface of the large lid 52 and the liquid surface. Compared with the thickness of the large lid 52, it becomes longer. Therefore, the possibility that aluminum adheres to the back surface of the hatch 62 provided with the through hole 65 is reduced, and the piping 66 and the through hole 65 used for adjusting the internal pressure can be prevented from being clogged.

  Next, a supply system from the second furnace 21 to the container 100 in the second factory 20 will be described with reference to FIG.

  As shown in FIG. 5, molten aluminum is stored in the second furnace 21. The second furnace 21 is provided with a supply unit 21a, and a suction tube 201 is inserted into the supply unit 21a. The suction tube 201 is arranged such that one end (the other tip 201b of the suction tube 201) protrudes and protrudes from the molten aluminum liquid surface of the supply unit 21a. That is, one tip 201a of the suction tube 201 extends to the vicinity of the bottom of the second furnace 21, and the other tip 201b of the suction tube 201 is led out from the supply unit 21a. The suction tube 201 is basically held at an inclination by the holding mechanism 202. The inclination angle is, for example, about 10 ° with respect to the perpendicular, and matches the inclination of the tip of the pipe 56 in the container 100. The distal end portion 201b of the suction tube 201 is connected to the distal end portion of the pipe 56 in the container 100, and the distal end portion 201b of the suction pipe 201 and the distal end of the pipe 56 in the container 100 are thus matched. Connection with the part becomes easy.

  Then, the pipe 67 connected to the pump 313 for pressure reduction is connected to the pipe 66. Next, the pump 313 is operated to depressurize the inside of the container 100. Thereby, the molten aluminum stored in the second furnace 21 is introduced into the container 100 through the suction pipe 201 and the pipe 56.

  In the present embodiment, in particular, the molten aluminum stored in the second furnace 21 is introduced into the container 100 through the suction pipe 201 and the pipe 56. There is no contact with air. Therefore, no oxide is produced, and the molten aluminum supplied using the present system has a very good quality. Moreover, the operation | work for removing an oxide from the inside of the container 100 becomes unnecessary, and workability | operativity also improves.

  In the present embodiment, in particular, since the introduction of molten aluminum into the container 100 and the derivation of molten aluminum from the container 100 can be performed substantially using only two pipes 56 and 312, the system configuration is very simple. Can be. Moreover, since the opportunity for molten aluminum to come into contact with the outside air is drastically reduced, the generation of oxides can be almost eliminated.

  FIG. 6 shows a manufacturing flow when the above system is applied to an automobile factory.

  First, as shown in FIG. 5, molten aluminum stored in the second furnace 21 is introduced (received hot water) into the container 100 through the suction pipe 201 and the pipe 56 (step 501).

  Next, as shown in FIG. 1, the container 100 is transported from the second factory 20 to the first factory 10 by the truck 32 via the public road 30 (step 502).

  Next, in the first factory (use point) 10, the container 100 is delivered to the die cast machine 11 for manufacturing the automobile engine by the delivery vehicle 18, and molten aluminum is supplied from the container 100 to the holding furnace 12 (step 503). ).

  Next, in this die cast machine 11, the automobile engine is molded using the molten aluminum stored in the holding furnace 12 (step 504).

  Then, the automobile is assembled using the automobile engine and other parts molded in this way, and the automobile is completed (step 505).

  In this embodiment, since the automobile engine is made of aluminum containing almost no oxide as described above, it is possible to produce an automobile having an engine with good performance and durability.

  Still another embodiment of the present invention will be described.

  FIG. 7 is a cross-sectional view of a container according to the second embodiment of the present invention. In the figure, an inclined state is shown.

  A container 2100 shown in the figure includes a container main body 2110 and a pipe 2130 disposed outside the container main body 2110 from a position 2112 shifted from the center 2111 of the container main body 2110.

  The container main body 2110 has an opening 2113 in the upper part thereof, and a lid 2114 is attached so as to close the opening 2113.

  The container body 2110 is arranged so as to form a second space 117 between a first frame 2116 made of steel such as SS400 (JIS) and the like, which constitute the first space 2115, and the first frame 2116. And a second frame 2118 made of steel such as SS400 (JIS). These frame materials are preferably composed of a material having a small linear expansion coefficient, and it is preferable to adopt a material having a small difference in linear expansion coefficient from a heat insulating material such as a caster applied to the inner layer. Furthermore, it is preferable to coordinate the physical properties of the first frame and the second frame, and here, materials having the same physical properties are selected and adopted.

  A pair of mouth-shaped locking members 2119 and 2119 into which a fork of a forklift is inserted are attached to the bottom of the container body 2110.

  The lid 2114 is provided with an opening 2121 for pouring a molten metal 2120 such as aluminum into the container main body 2110 near the center thereof. A child lid 2122 is pivotally attached to the opening 2121 and is not shown. The child lid 2122 is fixed to the opening 2121 by the fixing tool.

  In addition, the lid 2114 is provided with an inlet 2123 for introducing a gas for pressurization from a pressurization pump (not shown) into the first space 2115 in the container main body 2110. By using an inert gas such as nitrogen gas as the gas, oxidation of the molten metal 2120 can be prevented.

  Furthermore, a pipe 2130 disposed outside the container main body 2110 is attached to the lid 2114 from a position 2112 that is offset from the center 2111 of the container main body 2110. The lower end 2131 of the pipe 2130 is located to the vicinity of the bottom in the container main body 2110. A mechanism that can freely open and close the lower end 2131 may be provided. Thereby, it becomes possible to prevent hot water from flowing out when the container falls. The pipe 2130 has, for example, an inclined portion 2132 that is inclined about 5 ° to 10 ° upward and a discharge portion 2133 that opens downward, outside the container main body 2110.

  Here, the distance between the center 2111 of the container body 2110 and the shift position 2112 is, for example, about 30 cm in the case of a container having an inner diameter of 80 cm. The same effect can be obtained whether the displacement is larger or smaller.

  In such a container 2100, first, in a horizontal state, a pressurized gas is introduced from the introduction port 2123, and the molten metal 2120 in the container body 2110 is pressure-fed from the pipe 2130 to the outside. Then, as shown in FIG. 7, it is made to incline to the piping 2130 side with a forklift, and the remaining molten metal 2120 is pumped out of the piping 2130 outside.

  In the container 2100 of this embodiment configured as described above, the pipe 2130 is displaced from the center of the container main body 2110. Therefore, when the pipe 2130 is tilted, the displacement with respect to the liquid level in the container main body 2110 increases. When the water is discharged and returned to the horizontal position, a space is formed between the lower end 2131 of the pipe 2130 and the surface of the molten metal 2120, and the pipe is prevented from being clogged.

  FIG. 8 is a cross-sectional view of a container according to the third embodiment of the present invention. In the following embodiments, the same components as those already illustrated are designated by the same reference numerals and description thereof is omitted.

  In the container 2200, at least one passage (pipe) 2210 that connects the first space 2115 and the second space 2117 is provided.

  A pressurizing mechanism 2220 and a leak valve 2230 are attached to the second space 2117.

  In the pressurizing mechanism 2220, pressurized air is introduced from the air tank 2223 into the second space 2117 via the pressurizing valve 2221 and the pressure reducing valve 2222. A pressure controller 2224 is attached to the pressurizing mechanism 2220.

  Note that a vacuum pump can be connected instead of the pressurizing mechanism 2220.

  In the container 2200 configured as described above, if the second space 2117 is evacuated, heat is maintained, and a decrease in heat insulation performance due to a change in heat insulation over time can be compensated. For example, the degree of vacuum may be increased according to changes with time.

  Further, in the container 2200 configured as described above, when the first space 2115 is pressurized from the side between the second cavities 2116 via the passage 2210, the pressurized gas is preheated before the inside of the container (the first space 2115). ). Therefore, the temperature drop of the molten metal can be kept small. In particular, in the final stage of pumping, intermittent discharge of the molten metal and gas is likely to occur, and in that case, the temperature of the molten metal is deprived of the pumped gas and the viscosity increases. Therefore, by preheating the pressurized gas, it is possible to suppress the temperature drop of the molten metal and effectively prevent clogging of the piping. In addition, the hot water supply can be stopped safely, and the time required for the hot water supply stop can be shortened.

  Furthermore, in the container 2200 configured in this way, the high-temperature gas is cooled to some extent by causing the leakage of the first space 2115 from the second space 2117 side through the passage 2210 by the leak valve 2230. The leak valve 2230 is leaking. Therefore, the thermal load applied to the leak valve 2230 can be reduced, and the reliability of the apparatus can be improved and the life can be extended.

  FIG. 9 is a sectional view of a container according to the fourth embodiment of the present invention.

  In the container 2300 shown in the figure, a pressurizing mechanism 2220 is connected to the first space 2115, and a decompression mechanism 2310 is connected to the second space 2117. In the decompression mechanism 2310, for example, a vacuum pump 2312 is connected to the second space 2117 via a vacuum valve 2311, and a vacuum gauge 2313 and a leak valve 2314 are interposed therebetween.

  In addition, a leak valve 2320 as a second valve is inserted in a passage 2210 connecting the first space 2115 and the second space 2117, and further, a leak valve as a first valve is inserted in the container body. 2321 is connected.

  In the container 2300 having such a configuration, it is possible to shorten the time required for the hot water supply stop operation or to improve the reliability of the stop operation. That is, the second space 2117 is depressurized, and when the hot water supply is stopped, first the leak valve 2321 as the first valve is opened to restore the pressure in the first space 2115, and then the leak valve as the second valve 2320 is opened and the first space 2115 is set to a negative pressure. Thereby, the hot water supply can be completely stopped, and the molten metal in the pipe can be pulled back to the container side.

  FIG. 10 is a sectional view of a container according to the fifth embodiment of the present invention.

  In the container 2400 shown in the figure, a pipe 2420 having an upward slope is connected to the vicinity of the bottom of the container body 2410. The other end of the pipe 2420 extends to a position at least higher than the container 2400.

  FIG. 11 is a sectional view of a container according to the sixth embodiment of the present invention.

  The container 2500 shown in the figure includes a partition wall 2520 that bisects the container body 2510 in the vicinity of the lower portion, and a flange portion 2540 connected to one space 2530 side partitioned by the partition wall 2520. A pressure mechanism 2220 is connected to the other space 2531. A lid 2541 is provided on the upper portion of the flange portion 2540.

  In the container 2500 of this embodiment, when the inside of the container is pressurized by the pressurizing mechanism 2220, the hot water in the container is discharged to the outside through the flange 2540.

That is, if the piping is inside the body,
(1) Maintenance is hard
(2) Easy to clog
(3) There is a problem that piping is easily damaged during maintenance.

  On the other hand, in the container 2500 of this embodiment, one space 2530 separated by the partition wall 2520 is used instead of piping, and for example, overflows from the opening 2532 and hot water is supplied by the flange 2540. As a result, the maintenance becomes very simple, it is hard to clog, and even if clogged, it can be recovered by normal maintenance.

  FIG. 12 is a sectional view of a container according to the seventh embodiment of the present invention.

  A container 2600 shown in FIG. 11 is obtained by removing the lid 2541 disposed on the upper portion of the flange 2540 in the container shown in FIG.

It is the schematic which shows the structure of the metal supply system which concerns on one Embodiment of this invention. It is a figure which shows the relationship between the container and holding furnace which concern on one Embodiment of this invention. It is sectional drawing of the container which concerns on one Embodiment of this invention. FIG. 4 is a plan view of FIG. 3. It is a figure which shows the structure of the supply system from the 2nd furnace to a container in the 2nd factory which concerns on one Embodiment of this invention. It is a flowchart which shows the manufacturing method of the motor vehicle using the system of this invention. It is sectional drawing of the container which concerns on 2nd Embodiment. It is sectional drawing of the container which concerns on 3rd Embodiment. It is sectional drawing of the container which concerns on 4th Embodiment. It is sectional drawing of the container which concerns on 5th Embodiment. It is sectional drawing of the container which concerns on 6th Embodiment. It is sectional drawing of the container which concerns on 7th Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 50 Container main body 51, 60 Opening part 57 Flow path 62 Hatch 65 Through-hole 66 for internal pressure adjustment Pipe 60 for internal pressure adjustment Opening 100 Molten metal supply container

Claims (6)

A container capable of containing molten aluminum and capable of supplying molten aluminum to the outside by adjusting a pressure difference between the inside and outside,
A container body having a first opening at the top;
A flow path capable of circulating the molten aluminum contained in the container inside and outside;
A lid that is arranged to cover the first opening of the container body and has a second opening having a smaller diameter than the first opening;
And a hatch provided on the upper surface side of the lid so as to be openable and closable at the second opening of the lid and provided with a gas passage for pressurizing the inside of the container from the outside. In an airtight container that contains molten aluminum and can supply the molten aluminum to the outside by a pressure difference,
A container body having a first opening at the top and capable of accommodating the molten aluminum;
A flow path that allows the molten aluminum to flow through the inside and outside of the container;
A lid that is arranged to cover the first opening of the container body and has a second opening having a smaller diameter than the first opening;
And a hatch provided on the upper surface of the lid so as to be openable and closable and having a pressurized gas introduction part for pressurizing the container. In an airtight container that contains molten aluminum and can supply the molten aluminum to the outside by a pressure difference,
A container body having a first opening at the top and capable of accommodating the molten aluminum;
A flow path that allows the molten aluminum to flow through the inside and outside of the container;
A lid that is arranged to cover the first opening of the container body and has a second opening having a smaller diameter than the first opening;
And a hatch provided on the upper surface of the lid so as to be openable and closable and having a pressurized gas inlet for pressurizing the container. In an airtight container that contains molten aluminum and can supply the molten aluminum to the outside by a pressure difference,
A container body having a first opening at the top and capable of accommodating the molten aluminum;
A flow path that allows the molten aluminum to flow through the inside and outside of the container;
A lid that is arranged to cover the first opening of the container body and has a second opening having a smaller diameter than the first opening;
And a hatch provided on the upper surface of the lid so as to be openable and closable and having a pressurized gas hole for pressurizing the container. The container according to any one of claims 1 to 4,
The distance between the rear surface of the hatch and the liquid level of the molten aluminum accommodated in the container is larger than the distance between the rear surface of the lid and the liquid level of the molten aluminum accommodated in the container. . The container according to any one of claims 1 to 5,
The container, wherein the second opening is located near the center of the lid.

Images