DE4442801A1 - Inductive heating system for metal tubes - Google Patents

Abstract

The heating system has the metal tubes (1) transported along a conveyor (2), with the inductive heating effective along a limited area extending in a line along the tube mantle surface during the passage of each tube past an inductor (3) extending parallel to the tube axis.Pref. the tubes are moved past the inductor at a rate of 3 m/s, with the relative spacing between the inductor and the tube axis being variable. Pref. the inductor is provided by a hollow waveguide.

Description

The invention relates to a method and a Arrangement for performing the method for Heating preferably by means of sheet metal packaging Induction device for thermal influence of materials applied to frames that the Formation of a coating on the longitudinal frame seam to serve. Depending on the type of materials applied are these to be melted, dried, hardened, to network, to vulcanize or in a similar way and way to influence thermally.

Process and arrangement for inductive heating for Sheet metal frames are, inter alia, from EP 0 202 869 and from U.S. Patents 468 0871, 469 4586 and 505 0315 known. With these solutions they are Induction devices in the form of a coil like this trained that the sheet metal frame either stationary for heating inside the Induction coil is located or by means of a Transport device through the inside of the coil is led through. The sheet metal frame is in all of them warmed.

The disadvantage of these solutions is that in these devices only heated the entire frame can be. Furthermore, there are complicated Frame transport devices necessary are still inside the induction coil, which places high demands on the Material selection result, e.g. B. the use of non-conductive materials.  

Further disadvantages are spatial problems with very small frames and unfavorable coupling conditions between inductor coil and frame.

The object of the present invention is to achieve this based on avoiding the disadvantages mentioned above and to create a method and an arrangement which allows only individual areas of the To heat sheet metal frame inductively.

According to the invention this is achieved in that the Partial heat input in a limited area along a generatrix, e.g. B. along the Frame weld seam, while moving the Frame on the inductor. The transport of the frames takes place at a speed of up to 3 m / s, the frames moving past an inductor and the heating process online in the Manufacturing process of the frames can take place. There are only narrow, axial segments of the frame warmed along a surface line.

The heating up causes them to become angry Materials for coating the frame weld seam either melted, dried, hardened, cross-linked or vulcanized.

The temperature of the segments to be heated is infinitely variable by varying the inductor current I and / or the frequency f adjustable.

The temperature gradient of the heating phase is also continuously by means of the variation of Induction current I and / or frequency f adjustable.  

This makes it possible to constructively the arrangement simplify and immediately after a frame welding machine and the Arrange seam coating device. At this Arrangement can be the existing one Frame transport device, e.g. B. the magnetic tape, to be used.

The arrangement according to the invention consists of a Induction device used as a longitudinal inductor trained and at an adjustable distance approximately parallel to the frame transport device is arranged. The forward and return conductors of the Inductor are approximately in the radial direction in a row or at the same distance from the Frame surface arranged. The longitudinal inductor can consist of two individual inductors, the first Inductor for heating the sheet metal frames and the second inductor to maintain one approximately constant final temperature is used.

The longitudinal inductor is preferably round or rectangular waveguide is formed and Cooling fluid flows through cooling. For The inductor is preferably supplied sinusoidal current with a frequency between 16 up to 50 kHz for use. The longitudinal inductor can with a capacitor coupled to an oscillating circuit be and together with an electronic Circuit form a resonant circuit inverter.

An embodiment is described below with reference to Drawings are explained in more detail.

Show it

Fig. 1 is a schematic heater in side view,

Fig. 2 is a partially be heated A frame having a heating zone,

Fig. 3 shows a heating device in cross-section,

Fig. 4 shows a heating device in cross-section,

Fig. 5 a simplified representation of the magnetic field gradients,

Fig. 6 shows a variant of the heating device with partial inductors.

The invention will be described below with reference to FIGS. 1 to 6. It is assumed that the frames are preferably circular-cylindrical, but the statements made also apply to cross-sectional shapes that deviate therefrom.

Fig. 1 shows a schematic representation of a heating device according to the invention. The frames 1 to be partially heated are moved by means of a transport mechanism 2 at the speed v below the inductor 3 . In the case shown, it is a conveyor belt 2 . However, other means such as driven rollers, chains with a driving finger and other arrangements are also possible. Due to the inductor arranged completely outside the frame, very simple mechanical constructions of the heating device result.

Fig. 2 shows a partially heated frame 1 with the axial heating zone 5 of width b. Significant heat input occurs only in the hatched area. The energy saving compared to conventional induction systems becomes clear.

FIGS. 3 and 4 show two different Induktorausführungen.

In Fig. 3 there are supply and return conductors 3 in the radial direction one after the other. This arrangement is advantageous for very narrow heating zones and represents the standard version. Below the inductor 3 there is the maximum of the tangential component of the magnetic field strength on the frame surface. If the surface curvature of the frame 1 is neglected and if an idealized, linear inductor is assumed, the simplified, quantitative relationship is obtained as the basis for the rough dimensioning of the inductor

H₀ (x) = (1 / 2π) {-h / (x² + h²) + (h + a) / [x² + (h + a) ²]}.

This formula is used in conjunction with the general Maxwell's equations for quasi stationary electromagnetic fields as the basis for further Dimensioning of the induction device.

Fig. 4 shows an inductor version in which the forward and return conductors of the inductor 3 have the same distance from the frame surface. This inductor version can be used for wider heating zones. This results in two local maxima of the tangential component of the magnetic field strength H and thus also two current density maxima on the frame surface. Under the same assumptions as for the first inductor variant, a simplified, quantitative relationship between the geometric dimensions, the current intensity I and the surface field strength for a rough dimensioning of the inductor can also be derived here.

H _o (x) = (Ih / 2π) {[(xa / 2 )² + h²] ^-1 - [(x + a / 2 )² + h²] ^-1 }.

By varying the inductor parameters a and h there are good adjustment options to the  overall technological process

Fig. 5 illustrates the course of the magnetic field lines and the eddy currents caused thereby is simplified. The x designated in the formulas as a variable size is represented with. The coupling of the inductor to the frame can be influenced by varying the dimensions a and h. Small values of h and large values of a increase the coupling factor and vice versa. The coupling factor establishes the relationship between inductor current and surface field strength. This makes it possible to cover a wide range of applications with a uniform basic mechanical concept by varying parameters a, h.

Using the first Maxwell equation for quasi-stationary electromagnetic fields

red =

can vary from the magnetic field strength to the Eddy current density can be closed. poses here the vector of the magnetic field strength within the entire sheet thickness d and is over to calculate suitable boundary conditions. is the Current density vector.

By adding electrical conductivity of the sheet can be made in the concrete Temperature conditions on the power input getting closed.

Since the permeability µ in the sheet is a function of Field strength is H, there are nonlinear Connections. The exact mathematical evaluation the overall context, however, can be over iterative calculation by a specialist  comprehend.

An advantageous embodiment of the invention consists in dividing the inductor 3 into two different partial inductors. Fig. 6 shows a variant, which is characterized in that the inductors 3.1 , 3.2 are connected to each other in such a way that the same current I flows through both. Zone I serves as a heating zone, characterized by a high coupling factor with high heat input. Zone II serves to maintain a desired temperature and has a lower coupling factor combined with a lower heat input. Another advantage of the arrangement in Fig. 6 is that both inductor parts are flowed through by the same current and thus both are powered by an energy source. In addition to different coupling factors and heat inputs, different values for a and h also result in different inductor inductivities for the two sections I and II Individual inductors.

This results in simple, manageable Load conditions for the feeding source.

Both the heating temperature and the Temperature gradient can occur during the heating phase about the size of inductor current I and / or frequency f can be set. By using more suitable electronic circuits is this possibility given. The inductor can use a capacitor too a resonant circuit can be added and forms  of an electronic circuit Resonant circuit inverter. Here are different solutions possible:

• - Parallel compensation of the inductor and arrangement as an inverter with a parallel resonant circuit
• - Series compensation of the inductor and arrangement as Inverter with a series resonant circuit
• - Mixed compensation of the inductor (parallel and row capacity) and equivalent Inverter operation.

By using modern switchable Semiconductor components such as IGBT's there are many possible solutions for the concrete realization of the feeding source. There the specific electronic circuit for the feeding source is not the subject of the invention, should not continue on this point To be received.

A sinusoidal is used to supply the inductor Inductor current with a frequency of 16 to 50 kHz used. The influence is in this frequency range the electricity displacement can no longer be neglected. If copper is used as the inductor material, penetration depths of 0.3. . . 0.5 mm. The Current density in the inner part of a solid inductor would be almost zero. The inductor can therefore advantageously realized as a waveguide and by through a coolant.

In the plants for the production of sheet metal frames, especially in the packaging industry are usually always cooling water circuits available. Thereby there are usually favorable conditions for the Connection of the inductor cooling within the Overall process.  

With modern inverter circuits achieve internal efficiencies greater than 90%. Self taking into account the losses of the inductor from about 50% of the input power results Active power consumption of only 25. . . 50% versus the known solutions.

Claims (9)

1. A method for heating metallic frames by means of an induction device for thermally influencing materials applied to frames, characterized in that the heat input takes place partially in a limited area along a mat line while the frame is moving past the inductor. 2. The method according to claim 1, characterized in that the frames with a speed of up to 3 m / s be moved past the inductor. 3. Arrangement for carrying out the method according to Claims 1 and 2, consisting of a Induction device and one Frame transport device, characterized in that the induction device as a longitudinal inductor is formed and in an adjustable Distance approximately parallel to Frame transport device is arranged. 4. Arrangement according to claim 3, characterized in that Forward and return conductor of the longitudinal inductor approximately arranged one behind the other in the radial direction are. 5. Arrangement according to claim 3, characterized in that Forward and return conductor of the longitudinal inductor approximately at the same distance from the frame surface are arranged.   6. Arrangement according to claim 3 to 5, characterized in that the longitudinal inductor consists of two inductors, the first inductor for heating and the second inductor to maintain one approximately constant final temperature along the Matellin the frame is formed. 7. Arrangement according to claim 3 to 6, characterized in that the longitudinal inductor is designed as a waveguide,
(The waveguide has a round or rectangular cross section and a cooling liquid flows through it). 8. Arrangement according to claim 3 to 7, characterized in that the inductor preferably with a sinusoidal Current flows through, the frequency of the Inductor current in the range from 16 to 50 kHz lies. 9. Arrangement according to claim 3 to 8, characterized in that the series inductor is coupled to a capacitor is and with an electronic circuit as Resonant circuit inverter is formed.