DE202022105339U1 - Device for heating rod-shaped metallic workpieces - Google Patents

Abstract

Device for heating rod-shaped metallic workpieces (1), in particular bolts made of aluminum or copper and their alloys, with an induction furnace (2) for inductive heating, the induction coils (3) of the induction furnace (2) being cooled by means of a cooling device (5), and with a preheating device (9) for preheating the workpieces (1), characterized in that the cooling device (5) uses a liquid temperature control medium guided in a cooling circuit and that the workpieces (1) pass through before entering the induction furnace (2). the heated temperature control medium is heated in the preheating device (9).

Description

The present invention relates to a device and a method for heating rod-shaped metallic workpieces, in particular bolts made of aluminum or copper and their alloys, with an induction furnace for inductive heating, the induction coils of the induction furnace being cooled by means of a cooling device, and with a preheating device for preheating the workpieces.

Such devices are also referred to as “inductive stud heating systems (IBE)”. These are used to heat metallic press bolts and have proven themselves for decades for numerous reasons. A generic device is, for example, from WO 2010/031503 A1 known. The very high heat output enables high throughput with a small space requirement. With the help of such a high heat output, a targeted temperature profile can be set in the bolt, which offers advantages in the subsequent processing. The fact that inductive heating is based on electricity makes the system even more interesting these days, as CO ₂ -free energy can be used when using electricity produced from renewable sources.

Compared to press bolts made of ferritic materials, the heating of non-ferritic materials such as aluminum and copper, as well as their alloys, results in poorer efficiencies. This is due to the different magnetic coupling of the induction field. However, due to the advantages mentioned at the beginning, its use is quite common for aluminum and copper, for example.

With magnetic coupling and thus with inductive heat transfer, there are losses in efficiency, especially with non-ferritic feed materials. This requires cooling of the induction coils of the induction furnace, which is usually carried out using water cooling. With this cooling, the heat radiation from the preheated bolts is also dissipated onto the induction coil(s). To a lesser extent, waste heat is also generated in the electrical control, which is also dissipated via the cooling water. The overall efficiency is in the order of approx. 60%, so that approx. 40% of the electrical energy supplied has to be dissipated predominantly via the cooling water.

To save primary energy, gas-fired preheating furnaces are often installed upstream of inductive billet heating systems. Here, preheating to a basic temperature level takes place. Above this level, the very rapid residual heating required by the process is carried out using the inductive bolt heating system. In current developments, it should be noted that gas-heated preheating leads to CO ₂ emissions, which can only be avoided by using regeneratively produced hydrogen as fuel gas.

Proceeding from this, the present invention is based on the object of designing and developing the device mentioned at the beginning and previously described in more detail in such a way that a gas-heated preheating oven for preheating the rod-shaped workpieces can be dispensed with. In particular, inductive bolt heating should increase energy efficiency in order to minimize or completely avoid energy losses.

This object is achieved in a device with the features of the preamble of claim 1 in that the cooling device uses a liquid temperature control medium guided in a cooling circuit and that the workpieces are heated by the heated temperature control medium in the preheating device before entering the induction furnace. In this way, the unused residual heat from the induction furnace can be fully used to preheat the workpieces. It is possible to directly heat the workpieces (bolts) with the temperature control medium of the cooling device.

A further teaching of the invention provides that the cooling circuit has a heat exchanger. A treatment medium carried in a second circuit can be heated indirectly via the heat exchanger with the temperature control medium of the cooling device of the induction furnace and used for the direct heating of the bolts supplied to the preheating device.

Another preferred embodiment of the invention provides that an intermediate heating device is provided between the preheating device and the induction furnace. This is always useful if a sufficient temperature level of the workpieces/bolts cannot be achieved through preheating.

The preheating device can preferably have a basin for preheating the bolts using the temperature control medium. Devices for mixing the temperature control medium and/or for increasing the heat transfer can be arranged in the basin. Such mixing devices can include nozzles or circulation units.

Alternatively or additionally, a spray/shower chamber can also be provided as a preheating device for preheating the bolts, which brings about intensive contact of the treatment medium with the bolt surface.

In any case, according to a further preferred embodiment of the invention, it is advantageous if the preheating device has devices for cleaning and/or descaling the bolts. The bolts can be cleaned mechanically and, for example, driven brushes can be provided within the preheating device.

A further teaching of the invention provides that devices for drying or blowing off the temperature control medium from the bolts are provided between the preheating device and the induction furnace so that they can be fed to the induction furnace as dry as possible.

Water is preferably used as the temperature control medium and/or treatment medium; the water can be mixed with chemical additives.

It is also possible to use a thermal oil as a temperature control medium and/or treatment medium instead of water, whereby an increase in the temperature level can be achieved.

According to a further teaching of the invention, it is provided that the cooling circuit of the cooling device is separated into different circles and only one circle, or several individual circles, are used for preheating the bolts.

According to a preferred embodiment of the invention, a fuel-heated heating device can be connected upstream and/or downstream of the induction furnace. Such a fuel-heated heating device can be gas-heated, the heating being carried out in particular using hydrogen or natural gas. However, it is also possible that the fuel-heated heating device uses liquid fuel.

An electrical (resistance-heated) heating device can also be connected upstream and/or downstream of the induction furnace, whereby the heat can be transferred to the bolts by means of convection or also by means of radiation.

In a further alternative, an exhaust gas-heated heating device can also be connected upstream and/or downstream of the induction furnace.

In any case, it is advisable if the preheating of the bolts is controlled using a mathematical model. Such a mathematical model records the preheating temperature and optimally adapts the inductive heating in the inductive stud heating system to the desired target temperature based on modeling of the entire heating process. This is also referred to as a “digital twin”. Optimization for maximum performance or maximum energy savings is possible. Environmental influences (for example air temperature or cooling water temperature) or process influences (for example stopping the subsequent press line) can also be possible.

• 1 eine induktive Bolzenerwärmungsanlage nach dem Stand der Technik in schematischer Darstellung,
• 2 ein erstes Ausführungsbeispiel einer erfindungsgemäßen Vorrichtung unter Verwendung eines Wärmetauschers,
• 3 ein zweites Ausführungsbeispiel der erfindungsgemäßen Vorrichtung und
• 4 ein weiteres Ausführungsbeispiel der Erfindung.

The invention is explained in more detail below with reference to a drawing which merely shows preferred exemplary embodiments of the invention. In the drawing show, all schematically,

• 1 a schematic representation of an inductive bolt heating system according to the state of the art,
• 2 a first exemplary embodiment of a device according to the invention using a heat exchanger,
• 3 a second embodiment of the device according to the invention and
• 4 another embodiment of the invention.

1 shows schematically the structure of an inductive billet heating system (IBE) in which a metallic, non-ferritic pressed billet (for example made of aluminum or copper) is inductively heated in an induction furnace 2, which is only indicated. You can see the schematically shown induction coil of the induction furnace 2 and an electrical control 4 necessary for this. A cooling device 5, which is only indicated, uses a liquid temperature control medium that is guided in a cooling circuit, which absorbs the unused heat (about 40% of the electrical energy supplied) from the induction coil 3 removed from the induction furnace 2. To a lesser extent, waste heat also arises in the electrical control 4, which is also dissipated via the temperature medium and fed to a heat exchanger 7. It is not shown that the further circuit takes the heat supplied to the heat exchanger and can be used, for example, to heat buildings for heating domestic water. A pump 6 ensures that the temperature control medium is fed back to the induction furnace 2 or the electrical control 4 for cooling purposes after leaving the heat exchanger 7.

In 2 A first exemplary embodiment of the device according to the invention is now shown schematically, with the further circuit behind the heat exchanger 7 has a line 8, which is fed to a preheating device 9. This can have a basin 10 for receiving the treatment medium carried in the second circuit, with the supplied bolts 1 coming into complete contact with the treatment medium in order to heat the bolts 1. Alternatively or additionally, it is also possible to provide a spray/shower chamber 11 or a sprinkler device (only shown schematically) in the area of the preheating device 9. A pump 12 ensures that the treatment medium cooled during preheating is fed back to the heat exchanger 7 to complete the second circuit.

3 shows only the schematic representation of a second embodiment of the invention, with no heat exchanger being present. The heat of the temperature control medium taken from the induction furnace 2 and also the electrical control 4 is fed directly to the preheating device 9 by means of a heat pump 6 'via a line 8, which has the same structure as in the device according to 2 . From the basin 10, the temperature control medium is then fed to the cooling device 5 in the cooled state by means of the pump 6, as already described above.

Finally it's in 4 a modification of the device according to 2 shown, in which an intermediate heating device, only indicated, can be provided between the preheating device 9 and the induction furnace 2. This can be heated with different forms of energy, as described in the subclaims.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2010/031503 A1 [0002]

Claims (18)

Device for heating rod-shaped metallic workpieces (1), in particular bolts made of aluminum or copper and their alloys, with an induction furnace (2) for inductive heating, the induction coils (3) of the induction furnace (2) being cooled by means of a cooling device (5), and with a preheating device (9) for preheating the workpieces (1), characterized in that the cooling device (5) uses a liquid temperature control medium guided in a cooling circuit and that the workpieces (1) pass through before entering the induction furnace (2). the heated temperature control medium is heated in the preheating device (9). Device according to Claim 1 , characterized in that the cooling circuit has a heat exchanger (7) and that a treatment medium guided in a second circuit is heated indirectly via the heat exchanger (7) with the temperature control medium of the cooling device (5) of the induction furnace (2) and for the direct heating of the the workpieces (1) supplied to the preheating device (9) are used. Device according to Claim 1 or 2 , characterized in that an intermediate heating device (13) is provided between the preheating device (9) and the induction furnace (2). Device according to one of the Claims 1 until 3 , characterized in that the preheating device (9) has a basin (10) for preheating the bolts (1) by the temperature control medium. Device according to Claim 4 , characterized in that devices for mixing the temperature control medium and/or for increasing the heat transfer are arranged in the basin (10). Device according to Claim 5 , characterized in that the devices for mixing have nozzles or units for circulation. Device according to one of the Claims 1 until 3 , characterized in that a spray/shower chamber (11) is provided for preheating the bolts. Device according to one of the Claims 1 until 7 , characterized in that the preheating device has devices for cleaning and/or descaling the bolts. Device according to Claim 8 , characterized in that the bolts are cleaned mechanically and that driven brushes are provided within the preheating device. Device according to one of the Claims 1 until 9 , characterized in that devices for drying or blowing off the temperature control medium from the bolts are provided between the preheating device and the induction furnace. Device according to one of the Claims 2 until 10 , characterized in that the temperature control medium and/or the treatment medium is water. Device according to Claim 11 , characterized in that the water is mixed with chemical additives. Device according to one of the Claims 1 until 10 , characterized in that the temperature control medium and/or the treatment medium is thermal oil. Device according to one of the Claims 1 until 13 , characterized in that the induction furnace is preceded and/or followed by a fuel-heated heating device. Device according to Claim 14 , characterized in that the fuel-heated heating device is gas-heated, in particular heated using hydrogen or natural gas. Device according to Claim 14 , characterized in that the fuel-heated heating device is liquid fuel-heated. Device according to one of the Claims 1 until 13 , characterized in that an electrical resistance-heated heating device is connected upstream and/or downstream of the induction furnace. Device according to one of the Claims 1 until 13 , characterized in that the induction furnace is preceded and/or followed by an exhaust gas-heated heating device.

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