EP2174729A1 - Ignition device with pump drive with variable speed - Google Patents

Abstract

A steel mill has a de-scaling assembly with de-scaling zones (4 - 6) with jets (7) spraying a liquid de-scaling agent (8) at high pressure onto an extruded metal bar (3). The jets are supplied through high-pressure pipes (9) from a low-pressure supply (12) and an electric (13) pump (11). The high-pressure pipe is also coupled to a high-pressure buffer reservoir (14). The electric motor (13) is linked via a rectifier (17) to a control unit (18) and mains power supply (16). The control unit and rectifier provide variable speed control for the electric motor.

Description

• wobei die Entzunderungseinrichtung mindestens einen Entzunderungsbereich aufweist,
• wobei in dem mindestens einen Entzunderungsbereich eine Anzahl von Düsen angeordnet ist, mittels derer ein flüssiges Entzunderungsmittel unter Hochdruck auf einen zu entzundernden Metallstrang aufspritzbar ist,
• wobei die Düsen an ein Hochdruckleitungssystem angeschlossen sind, über welches den Düsen das flüssige Entzunderungsmittel zuführbar ist,
• wobei an das Hochdruckleitungssystem eine mittels eines Elektromotors angetriebene Pumpe angeschlossen ist, mittels derer das flüssige Entzunderungsmittel aus einem Niederdruck-Versorgungsnetz unter Hochdruck in das Hochdruckleitungssystem förderbar ist,
• wobei an das Hochdruckleitungssystem eine Hochdruck-Speichereinrichtung angeschlossen ist, von der das unter Hochdruck stehende flüssige Entzunderungsmittel pufferbar ist.

The present invention relates to a descaling device,

• wherein the descaling device has at least one descaling area,
• wherein in the at least one descaling region a number of nozzles is arranged, by means of which a liquid descaling agent can be sprayed on under high pressure onto a metal strand to be descaled,
• the nozzles being connected to a high-pressure line system via which the liquid descaling agent can be supplied to the nozzles,
• wherein a pump driven by an electric motor is connected to the high-pressure line system, by means of which the liquid descaling agent can be conveyed from a low-pressure supply network under high pressure into the high-pressure line system,
• wherein a high-pressure storage device is connected to the high-pressure line system, from which the high-pressure liquid Entzunderungsmittel is bufferable.

Such a descaling device is well known in the art.

In the prior art, the pump is operated by means of the electric motor continuously and at constant speed. This is associated with a constant flow rate of the Entzunderungsmittels per unit time.

If the nozzles in the at least one descaling area are switched through, that is to say spray the liquid descaling agent onto the metal strand to be descaled, this is not a problem. On the other hand, if the nozzles are switched off, the delivered quantity of descaling agent must otherwise be "consumed". When the high-pressure storage device still has absorption capacity, the subsidized Entzunderungsmittel is taken over into the high-pressure storage device. From there, it will be fed back into the high-pressure piping system at a later date. In contrast, when the high-pressure storage device is filled, a return valve is opened in the prior art. The descaling agent is returned to the low-pressure supply network via the return valve.

The object of the present invention is to develop a descaling device of the type mentioned in such a way that it is more economical to operate.

The object is achieved by a descaling device having the features of claim 1. Advantageous embodiments of the descaling device are the subject of the dependent claims 2 to 4.

According to the invention, a descaling device of the aforementioned type is developed in such a way that the electric motor is connected to an electrical supply network via a converter, that the converter is connected in terms of control technology to a control device and that the control device is designed such that it controls the converter in such a way that the Electric motor is operated at variable speed.

The inventive design significantly reduces the operating costs of the descaling device. There is therefore an economical operation of the descaling device according to the invention, although the initial cost of the descaling device according to the invention is greater than the purchase cost of a descaling device of the prior art.

In a preferred embodiment of the present invention, the converter is designed as a DC link converter. at In this embodiment, the electric motor can be operated with greater dynamics.

Furthermore, it is preferred that the control device is designed such that it controls the inverter such that the variable speed always remains above a minimum speed, which in turn is greater than zero. By this configuration, the wear - especially in the bearings of the electric motor and the pump - can be minimized.

• einem Sollfüllgrad der Hochdruck-Speichereinrichtung,
• einem Istfüllgrad der Hochdruck-Speichereinrichtung,
• einem Betriebszustand des mindestens einen Entzunderungsbereichs,
• einer noch zu vergehenden Zeitspanne bis zum Beginn eines Entzunderungsvorgangs,
• einer Gesamtbelastung des elektrischen Versorgungsnetzes und
• einer Gesamtbelastung des Niederdruck-Versorgungsnetzes.

Preferably, the control device is designed such that it controls the converter as a function of at least one of the following variables:

• a desired filling level of the high-pressure storage device,
• a Istfüllgrad the high-pressure storage device,
• an operating state of the at least one descaling area,
• an elapsed time until the beginning of a descaling process,
• a total load of the electrical supply network and
• a total load of the low-pressure supply network.

FIG 1

schematisch eine Anlage der metallerzeugenden Industrie,

FIG 2

einen Elektromotor und dessen Anschaltung an ein elektrisches Versorgungsnetz,

FIG 3

beispielhaft einen Drehzahlverlauf als Funktion der Zeit und

FIG 4

schematisch die Wirkungsweise einer Steuereinrichtung.

Further advantages and details emerge from the following description of an embodiment in conjunction with the drawings. In a schematic representation:

FIG. 1

schematically a plant of the metal-producing industry,

FIG. 2

an electric motor and its connection to an electrical supply network,

FIG. 3

For example, a speed curve as a function of time and

FIG. 4

schematically the operation of a control device.

According to FIG. 1 For example, a plant of the metal-producing industry has various plant components. Are purely exemplary in FIG. 1 a continuous casting 1 and a rolling mill 2 shown. In the continuous casting a metal strand 3 is generated. The metal strand 3 is rolled in the rolling mill 2.

The metal strand 3 is formed in many cases as a steel strand. However, this is not mandatory. Alternatively, the metal strand 3 could be formed, for example, as an aluminum strand, as a copper strand, as a brass strand, etc. Furthermore, the metal strand 3 is often formed as a metal strip. However, this is not absolutely necessary. Alternatively, the metal strand 3 may have, for example, a rod shape or a tubular shape.

In particular, in the case that the metal strand 3 is made of steel and is band-shaped, the metal strand 3 is thus designed as a steel strip, the plant of the metal-producing industry is often designed as a heavy plate mill.

After the metal strand 3 has been produced, before the rolling of the metal strand 3 and / or after the rolling of the metal strand 3, descaling is required in many cases. For this purpose, a descaling device E is present.

The descaling device E has Entzunderungsbereiche 4 to 6. The Entzunderungsbereich 4 is the continuous casting 1 downstream. The Entzunderungsbereich 5 is upstream of the rolling mill 2. The Entzunderungsbereich 6 is downstream of the rolling mill 2.

As shown by FIG. 1 all three descaling areas 4 to 6 are present. However, this is not mandatory. In other embodiments of the descaling device E, it is possible that only two or in extreme cases even only one of the descaling regions 4 to 6 is present.

Each descaling section 4 to 6 has a number of nozzles 7 arranged in the respective descaling section 4 to 6. By means of the nozzles 7, during operation of the respective descaling region 4 to 6, a liquid descaling agent 8 is sprayed onto the metal strand 3 under high pressure in order to desalt the metal strand 3. The liquid descaling agent 8 - usually water with or without additives - is supplied to the nozzles 7 via a high-pressure line system 9, to which the nozzles 7 are connected.

The Entzunderungsbereiche 4 to 6 are independently operable. As shown by FIG. 1 This is achieved in that each Entzunderungsbereich 4 to 6 each have a main valve 10 is assigned, by means of which the supply of the Entzunderungsmittels 8 to the respective Entzunderungsbereich 4 to 6 is switched on and off. The main valves 10 are independently switchable.

The last-explained embodiment (a single main valve 10 per Entzunderungsbereich 4 to 6) is chosen only simpler representability so. As a rule, each descaling region 4 to 6 has a multiplicity of groups of nozzles 7, which can each be switched via a separate valve independently of all the other nozzles of the same and of the other descaling regions 4 to 6. However, this is in the context of the present invention of minor importance, so apart from a representation of the individual valves per group of nozzles 7.

The high-pressure line system 9 is fed via a pump 11, which is connected to the high-pressure line system 9. By means of the pump 11, the liquid descaler 8 is conveyed from a low-pressure supply network 12 under high pressure into the high-pressure line system 9. The pump 11 is connected for this purpose with an electric motor 13 which drives the pump 11.

To the high-pressure line system 9, a high-pressure storage device 14 is further connected. From the high-pressure storage device 14, the high-pressure liquid Entzunderungsmittel 8 is bufferable.

The descaling device E is operated essentially as follows:

The operation of the descaling sections 4 to 6 is intermittent. For each descaling region 4 to 6, therefore, there is a phase during which the liquid descaling agent 8 is sprayed onto the metal strand 3. Likewise, there is a phase during which the liquid descaling agent 8 is not sprayed onto the metal strand 3.

A maximum delivery rate of the pump 11 is designed such that the maximum delivery rate is less than the maximum demand for Entzunderungsmittel 8. However, the maximum capacity of the pump 11 and the capacity of the high-pressure storage device 14 are coordinated so that the need for liquid Entzunderungsmittel 8, which is not covered by the maximum capacity of the pump 11, can be removed from the high-pressure storage device 14. During the Entzunderungsphasen so the pump 11 is driven by the electric motor 13, wherein the shortage of liquid descaling 8 is removed from the high-pressure storage device 14. During the phases in which no descaling occurs, the high-pressure storage device 14 is replenished.

In the prior art, the electric motor 13 and with it the pump 11 are operated at a constant speed. When the high-pressure storage device 14 is filled and a period of time δt remains until the beginning of the next Entzunderungsvorgangs, therefore, in the prior art, a return valve 15 must be opened, so that funded by the pump 11 Entzunderungsmittel 8 from the high-pressure line system 9 and the high pressure Memory device 14 can be deducted.

Since the prior art electric motor 13 is operated continuously and at a constant speed, it is sufficient in the prior art for the electric motor 13 to be connected directly to an electrical supply network 16 (usually a three-phase system). In the embodiment according to the invention, however, the electric motor 13 is connected via an inverter 17 to the electrical supply network 16.

The inverter 17 may be formed in individual cases as a direct converter. However, it is preferred that the inverter 17 according to the in FIG. 2 shown embodiment is designed as a DC link converter. In this embodiment, the inverter 17 and with it the electric motor 13 with higher dynamics are operable.

The inverter 17 is connected to a control device 18 control technology. The control device 18 is designed such that it controls the converter 17 such that the electric motor 13 is operated at a variable speed n. FIG. 3 purely by way of example shows a curve of the rotational speed n of the electric motor 13 as a function of the time t. Obviously, the speed n varies over the time t. Regardless of the actual value of the rotational speed n, however, the rotational speed n is always above a minimum rotational speed nmin, which in turn is greater than zero. Furthermore, the speed n always remains below a maximum speed nmax. In particular, due to the fact that the rotational speed n always remains above the minimum rotational speed nmin, the electric motor 13 and the pump 11 thus rotate continuously, the wear can be minimized.

The control device 18 is usually designed as a software programmable control device. It can determine a drive state S of the converter 17, which in turn determines the speed n of the electric motor 13, in various ways.

In the simplest embodiment, the control device 18 determines the drive state S based on a Istfüllgrades F of the high-pressure storage device 14 in conjunction with a fixed Sollfüllgrad F * of the high-pressure storage device 14. For example, the controller 18 can realize a two- or multi-point controller. It is better, however, if the control device 18 takes into account the Istfüllgrad F and other variables in determining the driving state.

For example, the control device 18 can use the other variables to determine the desired fill level F * as a function of the time t and to regulate the actual fill level F to the respective desired fill level F *.

Furthermore, for example, the control device 18 can determine the desired fill level F * as a function of an operating state B of at least one of the descaling regions 4 to 6. In particular, in the case that the period of time δt is known until the beginning of the next descaling process, the size of the time interval Δt can also be taken into account in determining the desired fill level F *. From a cost point of view, it may also be useful to take into account a total load I of the electrical supply network 16 and / or a total load W of the low-pressure supply network 12 when determining the drive state S and / or the desired fill level F *.

The present invention has many advantages. In particular, the descaling device E according to the invention can be operated more cost-effectively than a comparable descaling device of the prior art. Furthermore, there is less wear. The current load of the electrical supply network 16 is smaller than in the prior art. The energy yield is improved. Furthermore, there is a longer service life of electric motor 13 and pump 11. Finally, the return valve 15 can be made smaller than is possible in the prior art.

The above description is only for explanation of the present invention. The scope of the present invention, however, is intended to be determined solely by the appended claims.

Claims (4)

descaling, wherein the descaling device has at least one descaling area (4 to 6), wherein in the at least one descaling region (4 to 6) a number of nozzles (7) is arranged, by means of which a liquid descaling agent (8) can be sprayed under high pressure onto a metal strand (3) to be descaled, - wherein the nozzles (7) are connected to a high-pressure line system (9) via which the nozzles (7), the liquid Entzunderungsmittel (8) can be fed, - wherein to the high pressure line system (9) by means of an electric motor (13) driven pump (11) is connected, by means of which the liquid Entzunderungsmittel (8) from a low pressure supply network (12) under high pressure in the high pressure line system (9) is conveyed wherein a high-pressure storage device (14) is connected to the high-pressure line system (9), from which the high-pressure liquid descaler (8) can be buffered, characterized,
in that the electric motor (13) is connected to an electrical supply network (16) via an inverter (17), that the converter (17) is connected in terms of control technology to a control device (18) and that the control device (18) is designed such that it the inverter (17) controls such that the electric motor (13) is operated at variable speed (n). Descaling device according to claim 1,
characterized in that the converter (17) is designed as a DC link converter. Descaling device according to claim 1 or 2,
characterized in that the control device (18) is designed such that it controls the inverter (17) such that the variable speed (n) always above a Minimum speed (nmin) remains, which in turn is greater than zero. Descaling device according to claim 1, 2 or 3,
characterized in that the control device (18) is designed such that it controls the converter (17) as a function of at least one of the following variables: a desired filling level (F *) of the high-pressure storage device (14), a Istfüllgrad (F) of the high-pressure storage device (14), an operating state (B) of the at least one descaling area (4 to 6), an elapsed time (δt) until the beginning of a descaling process, - A total load (I) of the electrical supply network (16) and - A total load (W) of the low pressure supply network (12).

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