EP1130266B1 - Device for supplying molten metal to casting installations - Google Patents

Description

The invention relates to a melting removal device for Melting furnaces for feeding casters with a melt conveying pump from a lower melt inlet and an upper melt outlet forming pump tube and one inside the pump tube extending pump shaft carrying a pump rotor. Such a The preamble of claim 1 corresponding device is made each of the documents mentioned in the next paragraph refer to.

Prerequisite for proper feeding of casting machines or similar facilities is the possibility of a functionally reliable and metered Melt conveyance from the storage space of melting and holding furnaces, wherein hitherto, as described in EP 0 609 197 B, DE 195 41 093 A or DE 44 20 655 A discloses, as feed pumps usually screw pumps are used, however, in terms of their delivery of the pressure conditions in the melt inlet area of their pump tubes and thus of the are dependent on the respective head, which is strong during the operation fluctuating melt level heights in the melt storage space of the melting furnaces to a significant impairment of the dosing of the pump flow rates leads.

US Pat. No. 4,398,589 A already discloses a pump device for liquid Metal known that works on the electromagnetic principle and at the flow rate can be regulated by means of a return. Indeed here the pumping device must be located outside the melting furnace, which leads to considerable thermal engineering difficulties.

The invention is therefore based on the object, a melt removal device to create the kind of way that is characterized by their largely independent of changes in melt levels distinguished.

The invention solves this problem in that the melt pump a charging device is arranged to keep the delivery height constant, which charging device a receiving the pump tube with the melt inlet Loading container and a loading container up to a loading height comprising a melting melt fillable charge pump, wherein the capacity of the charge pump exceeds that of the feed pump. These Charging device with its charging container and the charge pump ensures during the Removal operation by the melt filling of the cargo container to the Melt overflow for constant pressure conditions in the melt inlet area the melt feed pump, so that even with external melt level fluctuations For the melt pump a constant, the pressure conditions determining melt level height, the loading height, and is effective therefore also independent of the respective melt level heights in the storage space the furnaces to a constant head for the melt conveyor pump and thus the desired exact metering of the flow rates comes. The overflow itself will be in the range of the maximum melt level lie to the pressure conditions to the actual conditions to adapt and to avoid the maintenance of unnecessary loading heights. The charge pump is also to vote on the pump, so on the one hand sufficient melt excess is conveyed into the loading container to a melt removal via the melt pump a drop in the Melting mirror within the cargo container under the melt overflow exclude, on the other hand, but also with the lowest possible melt overflow to be able to ensure a constant delivery height. You can do that as a melt pump and as a charge pump all suitable feed pumps use and there are also a variety of design options for the charging device itself.

For example, the loading container from a melt inlet surrounding chamber with a lower suction opening and a towering, consist of the melt overflow forming riser and the charge pump having a seated in the Ansaugöffnungsbereich loading rotor. It comes to a compact assembly of melt conveyor pump and charging device, wherein the riser with respect to the flow cross section under consideration the risk of blockage caused by blockages u. Like. As small as possible will be measured.

To easily prevent that at pump standstill Melting mirror height within the loading container up to the respective melt level height in the storage space drops, which without additional control effort for prefilling the loading container before the actual melt removal initial fluctuations in delivery height would be the case Intake a Rückströmventil with a suction in the opposite direction assigned to the intake closing valve body, so that when standing Charge pump the return valve closes the intake and a flow out prevents the melt from the loading container, which also at the beginning of extraction essentially unchanged pressure conditions or loading heights are ensured.

As a valve body of the Rückströmventils suitable valve plates od. Like. Be used in corresponding valve housings, it is advantageous but also possible that the hubverstellbar arranged above the intake opening Charging rotor itself forms the valve body, so that at a drive rotation Lifting loader engine releases the intake and the non-powered Loading rotor closes the intake opening again when the weight drops.

A convenient construction results when the loading container coaxial with the pump tube is arranged, which is the formation of loading chamber and riser allowed as stepped pipe section.

Basically, it does not matter which operating principle Conveying and / or loading pump work, although a coaxial arrangement pump and charger motor benefits. So can the pump shaft down out of the pump tube and with its protruding End serve as a drive shaft for the supercharger, bringing a common drive given for both pumps.

Of course, but also the loader on its own, by the hollow pump shaft guided drive shaft sit, creating a larger Adaptability of the charge pump performance to the particular conditions achieved becomes.

Another expedient embodiment of the charging device is that the loading container two sub-containers, one the pump tube receiving, closed on the floor charging unit and a charge pump receiving, the lower intake opening having filling part, comprising wherein the filling part and loading part via an overflow edge in fluid communication with each other stand and the filling part forms the melt overflow. Here The charger ensures the constant loading height and prevents this charger at the same time due to its closed bottom, a drop in this loading height at pump standstill, so that substantially always a constant head is guaranteed. The filling part with the charging pump secures the filling or Schmelzenbeaufschlagung the charging part with a corresponding excess melt, so that in turn of outer melt level fluctuations independent, constant pressure conditions for the melt feed pump result.

An appropriate unit arises in turn, if charging and Filling are arranged coaxially to the pump tube and the filling the loading part surrounds, with the charge pump one below the charging section, on one out Having the loading part led out drive shaft seated loading rotor. Here the filling part goes inwards into the loading section and forms with its upper part Outer edge to the outside of the melt overflow. As drive shaft for the charge pump the lower end of the pump shaft can be used, but it can also a guided through the hollow pump shaft own drive shaft be provided for the supercharger.

Are for another constructive solution charging and filling arranged side by side and has the charge pump of the filling a to Pump shaft parallel drive shaft with a lower charger rotor can, as Charge pump one of the melt pump completely independent Pumping device may be provided which optimizes the loading operation, For example, by prefilling the Befüllteils before the start of sampling u. Like., Allows.

In order to use largely the same components, takes the filling a pump similar to the melt delivery pump as a charge pump, whose Melt outlet preferably opens into the loading part, which is essentially same pumping devices for a perfect charging operation for the Removal device leads.

To a directly a furnace belonging to a sampling device To reach the loading container can be installed in a melting furnace wherein the charging part is separated from the storage space of the melting furnace, via the filling part to the storage space connected sampling chamber forms. Thus, the charging device can be integrated in a melting furnace and here secures the used in the loading part melt pump the desired constant delivery heights.

In this case, a melt level measuring device can be provided in the loading part and the charge pump drive depending on the melt level of the Charging parts can be controlled, so that one exactly to the removal conditions can install adaptable charging device.

Fig. 1 bis 7

sieben Ausführungsbeispiele einer erfindungsgemäßen Schmelzenentnahmevorrichtung jeweils an Hand eines Axialschnittes.

In the drawing, the subject invention is for example illustrated in more detail, and that show the

Fig. 1 to 7

seven embodiments of a melting removal device according to the invention in each case on the basis of an axial section.

A melt removal device for feeding casters od. Like. Has one in the melt bath S one not shown Melting furnace immersed melt conveyor pump 1, which consists of a Pump tube 2 with a lower melt inlet 3 and an upper melt outlet 4 and one within the pump tube 2 extending over a not shown drive motor drivable pump shaft 5 with a Screw conveyor above the melt inlet 3 as a pump rotor 6, so that upon rotation of the pump shaft 5 melt through the melt inlet Sucked 3 and promoted on the pump tube 2 to the melt outlet 4 becomes.

To one of the melt level fluctuations of the melt bath S between a maximum melt level O and a minimum melt level U largely independent melting promotion and thus a Ensuring properly metered melt removal is the melt feed pump a charging device 7 for keeping constant the delivery height upstream, which charging device a pump tube 2 with the melt inlet 3 receiving loading container 8 and a loading container up to a charge level determining melt overflow 9 melt-fillable Charging pump 10 includes, so that by the charging device 7 for the melt feed pump 1 a through the height difference between melt outlet 4 and melt overflow 9 resulting constant head h is ensured wherein the overflow 9 in the range of the maximum melt level O des Schmelzenbades S is located.

According to the embodiment of FIG. 1, the loading container 8th from a melt inlet 3 surrounding chamber 11 with a lower Intake port 12 and a towering, the melt overflow 9 forming Riser 13th Chamber 11 and riser 13 are coaxial with the pump tube 2 and the charge pump 10 has a pump rotor 6 also coaxial Loading rotor 14, which is below the pump tube 2 in the region of the suction port 12 on the pump shaft led out of the pump tube 5 sits. If the melt pump is put into operation, takes place simultaneously with the pump rotor 6 and the drive of the charge pump 10, the over their Loading rotor 14 promotes melt from the melt bath S in the chamber 11 and in its performance is dimensioned so that, despite the melt through the feed pump 1 amount of melt conveyed away a melt excess through the Riser 13 promoted to the overflow 9 and to overflow and backflow is brought into the melt bath. This results in the range of Melting inlet 3 of the melt conveyor pump 1 always a by the height the melt overflow 9 specific loading height, for a constant head h and the delivery rate of the melt delivery pump 1 independently makes of the respective Schmelzennieveau of the melt bath.

At pump standstill, a drop in the melt level in the riser 13 to prevent and thereby in the beginning of a melt removal To avoid fluctuations in the delivery height, according to the embodiments 2 and 3 of the suction port 12, a return valve 15th associated with the suction opening 12 in the opposite direction to the suction closing valve body 16, which arranged a part of the stroke adjustable Loader motor 14 (FIG. 2) or its own valve plate 17 (FIG. 3), at an interruption of the charge pump operation, a return flow of the Melt from the riser 13 is prevented.

According to the embodiment of FIG. 4, the loading container 8 the charging device 7 two sub-containers, a pump tube 2 receiving, closed loading part 18 and a loading pump 10 receiving the bottom, the lower intake opening 12 having filling part 19, wherein the Filling part and the loading part via an overflow edge 20 with each other in flow communication stand and the filling part 19 forms the melt overflow 9. Here is from the melt bath S via the charge pump 10 melt in the Filling 19 pumped until they on the one hand on the overflow edge 20 the charging part 18 filled and on the other hand over the melt overflow 9 in the melt bath flowing back. As a result, in turn, via the melt overflow 9, the constant Delivery head h for the melt removal ensured and also prevented the loading part 18 a drop in the loading height below that through the overflow edge 20 predetermined amount even during a pump standstill.

The embodiment of FIG. 5 also shows a loading container 8 with a loading part 18 and a filling part 19, wherein loading and Befüllteil are arranged side by side and over an overflow edge 20 with each other in fluid communication. The loading part is melt-filled via the filling part and the filling part 19 determines with its melt overflow 9 the constant Head h for melt extraction. In contrast to the embodiment According to Fig. 4, according to which the charge pump 10 is a below the Loading parts at the extended end 21 of the pump shaft 5 seated loading rotor 14th has, in the embodiment of FIG. 5 is a melt to the feed pump 1 parallel charge pump 10 with its own drive shaft 22 and suitable Loading rotor 14 used in the filling 19, so that by an independent Charge pump control of the loading operation adapted exactly to the removal operation can be.

In Fig. 6 is an embodiment of FIG. 5 similar embodiment with juxtaposed loading and Befüllteilen 18, 19 vorgsehen, where the possibility is indicated, as a charge pump 10 with a Feed pump 1 same pump 23 to use, the melt outlet 4 in the Charging part 18 opens.

As indicated in Fig. 7, the charging device 7 can also be directly in a melting furnace 24 may be installed, wherein the loading container 8 of the charging device 7 is integrated into the storage space 25 of the melting furnace 24 and with its charging part 18 a separated from the storage space 25, on the Befüllteil 19 connected to the storage space 25 extraction chamber forms. Here too there is an overflow edge 20 between the charging part 18 and filling part 19, which is the Target level determined in the sampling chamber, and the filling part 19 forms with its upper edge a melt overflow 9 for the melt return in the Storage space 25 in case of overfilling. The charge pump 10 discharges melt the storage space 25 in the filling part 19, from where this melt on the Overflow edge 20 enters the loading section 18 and for the melt removal by the feed pump 1 at a substantially constant level of the melt is held, which in turn ensures a constant head h. Is in the Removal chamber, a melt level measuring device 26 may be used the charge pump 10 with regard to its drive as a function of the melt level the sampling chamber are controlled, so that a fine-tuning of the Loading operation is possible to the removal operation.

Claims (13)

1. Melt discharge device for melting furnaces for feeding casting machines having a melt conveying pump (1) comprising a pump tube (2) forming a lower melt inlet (3) and an upper melt outlet (4) and a pump shaft (5) carrying a pump rotor (6) running within the pump tube (2), characterised in that a loading device (7) is arranged before the melt conveying pump (1) for the purpose of maintaining constant the conveying height (h) which loading device comprises a loading container (8) taking up the pump tube (2) with the melt inlet (3) and a loading pump (10) which can fill the loading container (8) with melt up to the melt overflow (9) determining the load height wherein the conveying performance of the loading pump (10) exceeds that of the conveying pump (1).
2. Melt discharge device according to claim 1, characterised in that the loading container (8) consists of a chamber (11) surrounding the melt inlet (3) having a lower suction opening (12) and an upwardly projecting rising tube (3) forming the melt overflow (9) and the loading pump (10) has a loading rotor lying in the suction opening area (12).
3. Melt discharge device according to claim 2, characterised in that a return valve (15) with a valve body (16, 17) closing the suction opening (12) in the opposite direction to the suction direction is assigned to the suction opening (12).
4. Melt discharge device according to claim 3, characterised in that the loading tube (14) itself which is arranged in a displaceable way above the suction opening (12) forms the valve body (16).
5. Melt discharge device according to one of the claims 2 to 4, characterised in that the loading container (8) is arranged coaxially to the pump tube (2).
6. Melt discharge device according to one of the claims 2 to 5, characterised in that the pump shaft (5) is guided downwards out of the pump tube (2) and serves with its projecting end as a drive shaft for the loading rotor (14).
7. Melt discharge device according to one of the claims 2 to 5, characterised in that the loading rotor lies on its own drive shaft guided through the hollow pump shaft.
8. Melt discharge device according to claim 1, characterised in that the loading container (8) comprises two partial containers, a loading part (18) closed at the bottom and receiving the pump tube (2) and a filling part (19) having the lower suction opening (12) and receiving the loading pump (10) wherein the filling part and the loading part are in flow connection with each other through an overflow edge (20) and the filling part (19) forms the melt overflow (9).
9. Melt discharge device according to claim 8, characterised in that the loading part (18) and filling part (19) are arranged coaxially to the pump tube (2) and the filling part (19) surrounds the loading part (18) wherein the loading pump (10) has a loading rotor (24) lying below the loading component (18) on a drive shaft guided out of the loading part.
10. Melt discharge device according to claim 8, characterised in that the loading part (18) and filling part (19) are arranged beside each other and the loading pump (10) of the filling part (19) has a drive shaft (22) parallel to the pump shaft (5) having a lower loading rotor (14).
11. Melt discharge device according to claim 10, characterised in that the filling part (19) receives a pump (23) similar to the melt conveying pump (1) as a loading pump (10) whose melt outlet (4) preferably runs into the loading part (18).
12. Melt discharge device according to claim 8, characterised in that the loading container (8) is built into a melting furnace (24) wherein the loading part (18) forms a discharge chamber separated from the storage area (25) of the melting furnace (24) and connected to the storage area (25) by means of the filling component (19).
13. Melt discharge device according to claim 12, characterised in that a melt level measuring device (26) is provided in the loading part (18) and the loading pump drive can be controlled depending upon the melt level of the loading part (19).

Images