EP4279614A1 - Waste heat use in cooling slags from iron and steel production - Google Patents

Abstract

The present invention relates to a device for using the waste heat from slag 10, the device having a first application area, the first application area having a first contact surface, the first contact area being designed for the direct surface application of the liquid slag 10, with under and in thermal contact with the first contact surface of the first task area, a first heat storage device 30 is arranged, wherein under or in the first heat storage device 30 and in thermal contact with the first heat storage device 30 a first heat exchange device through which a heat exchange fluid can flow is arranged, the first heat exchange device being fluidically connected to a first heat exchange fluid storage device is connected.

Description

The invention relates to a method and a device for utilizing the waste heat, for example for generating electrical energy, which is generated when slag is cooled.

Slag is created in metallurgical processes, for example in the production of pig iron in a blast furnace or in steel production in an electric arc furnace or in an LD converter, but also in other processes, particularly metal processing, for example in foundries. In principle, the slag is a by-product of the process, which can be used, for example, as an additive or aggregate in other processes or products. The slag is usually created at the high temperatures of the process, for example in a blast furnace or steelworks. Due to the high process temperature, usually over 1,450 °C, in the processes that produce the slag, the thermal energy of the slag is often very high, usually in the range of 1.5 to 2 GJ per ton of slag. Nevertheless, nowadays the slag is mainly dumped in open slag beds, where it is then cooled slowly using air and/or water cooling and without any use of heat or energy recovery. For further use, the cooled slag is usually broken, iron removed and usually sieved and/or classified.

There are approaches to heating air using the high temperature of the slag when it cools down and then using the air as a drying agent in further processes. However, the need and possible applications for hot air for drying purposes are limited and the space required for the drying system is very high.

Since the thermal energy is generated at a very high level, for example steelworks slag is usually molten and poured into the slag bed at temperatures of usually more than 1,300 °C, it would be possible to convert it into one high-quality form of energy, for example and in particular electricity generation, is desirable.

The problem with this process, however, is that the slag is only produced discontinuously. Therefore, this cannot be directly linked to a continuous process.

The object of the invention is to use the waste heat in the production of slag.

This task is solved by a device with the features specified in claim 1. Advantageous further developments result from the subclaims, the following description and the drawings.

The device according to the invention is used to use the waste heat from slag. The source of the slag can be very different. It can be, for example, blast furnace slag, cupola furnace slag, steelworks slag, in particular converter slag, electric furnace slag, stainless steel slag or secondary metallurgical slag or metal works slag. The device has a first task area. The molten slag is fed into the first feed area, which can be arranged, for example, in a slag bed, at a temperature of, for example, more than 1,250 ° C. The first application area has a first contact surface, the first contact surface being designed for direct surface application of the liquid slag. The first contact surface is suitable for the liquid and flowable slag to be applied directly and to be in direct thermal contact. A first heat storage device is arranged below and in thermal contact with the first contact surface of the first task area. The heat storage device, for example a metal structure containing a refractory material therein, has two functions. Firstly, the maximum temperature peak is reduced when new hot slag is applied. As a result, the underlying heat exchange fluid is not overheated at certain points and/or over time. The second effect is that the release of thermal energy is also stretched, even if only slightly, so that an initial temporal equalization effect is achieved. Under or in the first Heat storage device and a first heat exchange device through which a heat exchange fluid can flow is arranged in thermal contact with the first heat storage device. An example of a first heat exchange device in the first heat storage device would be pipes or lines arranged in, for example, fireproof masonry, through which a heat exchange fluid can flow. A further example would be a first heat exchange device present in the first heat storage device in the form of a bed, for example made of broken or pelletized slag, arranged pipes or lines through which a heat exchange fluid can flow. An example of a first heat exchange device below the first heat storage device would be, for example, a copper block with channels embedded therein for the flow of a heat exchange fluid. The first heat exchange device is fluidly connected to a first heat exchange fluid storage device. The initially cold heat exchange fluid flows into the heat exchange device, is heated there and from there heated into the heat exchange fluid storage device. The flow rate is preferably adapted to the initial temperature of the heat exchange fluid. Thus, immediately after the application of slag, a large amount of heat exchange fluid would be delivered quickly; with cooling, the delivery rate of the heat exchange fluid would be reduced, but the temperature would preferably remain constant. In a preferred embodiment, the first heat exchange fluid storage device is connected to a first power generation device. The connection can be direct or indirect. A direct connection can be advantageous, for example, if the heat exchange fluid is water, which is thus heated to steam, for example at 500 °. This steam can then be fed directly to a corresponding turbine of the first power generating device. If the heat exchange fluid is a molten salt, an indirect connection may make sense, i.e. in particular the molten salt generates steam in another heat exchanger, which is then applied to a turbine. The first heat exchange fluid storage device achieves uniformity and the discontinuous process of slag cooling can be efficiently combined with continuous electricity generation. Furthermore, especially for the use of “low-value” heat, for example a thermoelectric converter (thermoelectric generator, thermocouple, Peltier element) can be used to generate electricity be used. The efficiency of up to 17% is well below the efficiency that can be achieved with the Carnot process, but can be designed to be particularly robust and low-maintenance, especially as a component without moving parts.

It is also possible to use the heat obtained in two stages, i.e. in particular to use the highest temperature to generate electricity in a first step and then feed the residual heat into a district heating system.

In a further embodiment of the invention, a protective layer, in particular made of broken slag, is arranged on the first contact surface of the feed area of the device. This protects the device underneath. In addition, the broken slag serves as additional heat storage, which reduces the temperature peak when the liquid slag is fed. At the same time, the use of cold, broken slag means that there is no contamination of the mineral slag product (e.g. aggregate after processing) with the broken slag from the protective layer. The crushed slag used is preferably the slag that has cooled and solidified in a previous run and is therefore chemically largely identical to the new liquid slag. Furthermore, the aggregate size of the crushed slag can be optimized, particularly with regard to the energy required for crushing.

In a further embodiment of the invention, the first contact surface of the feed area is a steel trough. In particular, the first contact surface of the application area is detachably connected to the first heat storage device. In particular, the steel pan is removed after the slag has cooled in order to remove the slag. Another steel pan can then preferably be introduced so that the next slag can already be cooled down.

In a further alternative embodiment of the invention, the first contact surface of the feed area is a rotating steel strip. The steel belt, preferably in the form of an endless conveyor belt, can either only be rotated when the slag has cooled or can be rotated continuously.

In a further embodiment of the invention, the first heat storage device consists of a fireproof material. In particular, the refractory material has an oxide, in particular silicon dioxide, aluminum oxide, magnesium oxide, calcium oxide, zirconium oxide and chromium oxide, silicon carbide, molybdenum and/or tungsten and/or platinum group metals as a metal, alloy, oxide or carbide.

In a further embodiment of the invention, the refractory material has at least one material which is selected from the group comprising fireclay, silica, magnesite, silicon carbide, bauxite, alundum, molybdenum oxide.

In a further embodiment of the invention, the heat exchange fluid is selected from the group comprising air, helium, water, thermal oil, molten salt. Temperatures of 900 °C can easily be achieved with air or helium. This enables high efficiency when converting heat into electricity, but leaves a lot of heat unused.

In a further embodiment of the invention, the device has a second task area. A second heat storage device is arranged below and in thermal contact with the second task area. A second heat exchange device through which a heat exchange fluid can flow is arranged beneath or in the second heat storage device and in thermal contact with the second heat storage device. The second heat exchange device is fluidly connected to the first heat exchange fluid storage device. Thanks to the parallel connection, the second feed area can be filled with new hot slag while the slag is still cooling in the first feed area.

In a further embodiment of the invention, a third heat exchange device through which a further heat exchange fluid can flow is arranged under the first heat exchange device. The third heat exchange device is fluidly connected to a third heat exchange fluid storage device. The third heat exchange fluid storage device can be connected directly or indirectly to the first Power generation device or connected to a second power generation device.

In a further embodiment of the invention, the first heat exchange fluid storage device is connected to a first power generation device. The connection can be direct or indirect. A direct connection can be advantageous, for example, if the heat exchange fluid is water, which is thus heated to steam, for example at 500 °. This steam can then be fed directly to a corresponding turbine of the first power generating device. If the heat exchange fluid is a molten salt, an indirect connection may make sense, i.e. in particular the molten salt generates steam in another heat exchanger, which is then applied to a turbine. The first heat exchange fluid storage device achieves uniformity and the discontinuous process of slag cooling can be efficiently combined with continuous electricity generation.

In a further embodiment of the invention, the first power generation device is fluidly connected to the first heat exchange device via a second heat exchange fluid storage device for storing the cold heat exchange fluid. This enables efficient circulation of the heat exchange fluid. The heat exchange fluid originating from the continuous process of the power generation device is again provided in the second heat exchange fluid storage device for the discontinuous process of slag cooling.
Of course, other task areas connected in parallel are also possible.

In a further embodiment of the invention, the first heat exchange fluid storage device is connected to a heat utilization device, in particular a district heating network.

• Fig. 1 erstes Beispiel
• Fig. 2 zweites Beispiel

The device according to the invention is explained in more detail below using an exemplary embodiment shown in the drawings.

• Fig. 1 first example
• Fig. 2 second example

In Fig. 1 a first example is shown. The first device of the first example has a steel trough 20 as the first contact surface. A layer of broken slag 12 is arranged in the steel tub 20. The liquid slag 10 is poured into the steel tub 20 from a slag bucket 14. The heat of the slag 10, which is applied, for example, at 1,300 ° C, is transferred through the steel pan 20 to the first heat storage device 30. This results in an equalization through the heating of the first heat storage device 30, so that the temperature peak of, for example, 1,300 ° C arrives at the first heat exchange device 40, but only 750 ° C, for example. At the same time, the higher temperature level is maintained longer. For further equalization, the heat exchange fluid is transferred from the first heat exchange device 40 into a first heat exchange fluid storage device 50. The heat exchange fluid is transferred from the first heat exchange fluid storage device 50 into a power generation device 60 and from the power generation device 60 into a second heat exchange fluid storage device 70, so that the cold heat exchange fluid can also be buffered. From the second heat exchange fluid storage device 70, the heat exchange fluid is then guided back into the heat exchange device 40 and thus in a circle. In the example shown, the heat exchange device 40 is designed as a tube bundle heat exchanger.

In order to achieve further uniformity, two, preferably four, particularly preferably even more devices according to the invention are constructed next to one another and parallel to one another. Since the steel tubs 20 are filled in batch operation and then cool slowly and the cooling process usually takes longer than the production of the amount of slag, the parallel connection and common use of the first heat exchange fluid storage device 50 can achieve an equalization of the temperature of the heat exchange fluid. This also equalizes the power supply to the power generating device 60. Fig. 2 shows a second example, which differs from that in Fig. 1 The first example shown differs in that the first contact surface is designed as a steel strip 22. This transports the slag 10 from the feed location via the first heat storage device 30 and thus releases the heat through the first heat storage device 30 to the heat exchange fluid in the first heat exchange device 40. The other components are the same.

While in the first example the steel tub 20 has to be removed and emptied cyclically, this is done on the steel strip 22 of the second example at the end of the steel strip 22. The second example is therefore particularly suitable for a quasi-continuous provision of slag 10.

Reference symbol:

10

slag

12

broken slag

14

Cinder bucket

20

Steel tub

22

Steel band

30

first heat storage device

40

first heat exchange device

50

first heat exchange fluid storage device

60

Electricity generating device

70

second heat exchange fluid storage device

Claims (13)

Device for using the waste heat from slag (10), the device having a first application area, the first application area having a first contact surface, the first contact area being designed for the direct surface application of the liquid slag (10), under and in the thermal A first heat storage device (30) is arranged in contact with the first contact surface of the first task area, wherein a first heat exchange device (40) through which a heat exchange fluid can flow is arranged under or in the first heat storage device (30) and in thermal contact with the first heat storage device (30). , wherein the first heat exchange device (40) is fluidly connected to a first heat exchange fluid storage device. Device according to claim 1, characterized in that the first contact surface of the application area is a steel trough (20). Device according to one of the preceding claims, characterized in that the first contact surface of the application area is detachably connected to the first heat storage device (30). Device according to claim 1, characterized in that the first contact surface of the application area is a rotating steel belt (22). Device according to one of the preceding claims, characterized in that the first heat storage device (30) consists of a fireproof material. Device according to claim 5, characterized in that the refractory material has an oxide, in particular silicon dioxide, aluminum oxide, magnesium oxide, calcium oxide, zirconium oxide and chromium oxide, silicon carbide, molybdenum and / or tungsten and / or platinum group metals as a metal, alloy, oxide or carbide. Device according to claim 5, characterized in that the refractory material has at least one material which is selected from the group comprising fireclay, silica, magnesite, silicon carbide, bauxite, alundum, molybdenum oxide. Device according to one of the preceding claims, characterized in that the heat exchange fluid is selected from the group comprising air, helium, water, thermal oil, molten salt. Device according to one of the preceding claims, characterized in that the device has a second application area, the second application area having a second contact surface, the second contact area being designed for direct surface application of the liquid slag (10), under and in thermal contact a second heat storage device (30) is arranged with the second contact surface of the second application area, wherein a second heat exchange device (70) through which a heat exchange fluid can flow is arranged under or in the second heat storage device (30) and in thermal contact with the second heat storage device (30), wherein the second heat exchange device (70) is fluidly connected to the first heat exchange fluid storage device. Device according to one of the preceding claims, characterized in that a third heat exchange device through which a further heat exchange fluid can flow is arranged under the first heat exchange device (40), the third heat exchange device being fluidly connected to a third heat exchange fluid storage device. Device according to one of the preceding claims, characterized in that the first heat exchange fluid storage device is connected to a first power generation device (60). Device according to claim 11, characterized in that the first power generating device is fluidically connected via a second Heat exchange fluid storage device for storing the cold heat exchange fluid is connected to the first heat exchange device (40). Device according to one of the preceding claims, characterized in that the first heat exchange fluid storage device is connected to a heat utilization device, in particular a district heating network.

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