Electric heating – Microwave heating – Field modification
Reexamination Certificate
1999-09-20
2001-04-03
Leung, Philip H. (Department: 3742)
Electric heating
Microwave heating
Field modification
C219S749000, C219S695000, C219S693000, C219S762000, C264S405000, C264S432000, C264S489000, C425S17480R
Reexamination Certificate
active
06211503
ABSTRACT:
FIELD OF THE INVENTION
The present invention concerns a device for heating parts made of one or more microwave absorbing plastics containing microwave absorbing additives, having a microwave generator that generates microwaves of a certain wavelength, having an antenna to which the microwaves are aimed, having at least one free end, and having a device for shielding surrounding the antenna. In addition, this invention concerns a method of heating parts made of a microwave absorbing plastic.
BACKGROUND OF THE INVENTION
Microwaves are understood to be electromagnetic radiation in a frequency range of approximately 300 MHz to 300 GHz generated with the help of microwave generators. Microwaves are sent from a microwave generator through a hollow conductor or coaxial cable to their site of use where they are output via an antenna, for example, which projects by at least one quarter of the wavelength into a shielded chamber. In this chamber, the microwaves interact with the parts to be heated.
For heating parts by means of microwaves, in principle two different devices are differentiated:
With one device, the microwaves are radiated into a chamber whose dimensions are much larger than the wavelength. The microwaves are reflected on the walls of the chamber and are superimposed to form a complex field distribution (multimode). However, microwaves cannot be concentrated spatially in such a chamber, so defined heating of certain sections of a part is not possible. The chamber has the function of determining the field distribution and protecting the operator of the device from microwaves.
With the other device, the microwaves are radiated into a chamber whose dimensions correspond approximately to the wavelength, so that a defined field distribution (monomode) develops within the chamber. However, with such a chamber, defined spatial heating of parts can be achieved only to a limited extent, because this field distribution is not homogeneous in space. Thus, the chamber here has the function of defining the field distribution and again protecting the operator from microwaves.
With these devices from the related art, the parts can thus be heated only as a whole or in nonhomogeneous sections, although that is neither desirable nor necessary for most applications. Furthermore, implementation of an opening necessary for introduction of the parts into the shielded chamber is complicated with these devices, because such openings in that location are feasible only by means of doors or microwave absorbers.
SUMMARY OF THE INVENTION
Against this background, the object of the present invention is to design a device for heating parts of microwave absorbing plastics in such a way as to allow spatially limited but nevertheless homogeneous heating of the parts. Furthermore, an opening for the parts to be introduced is to be created in a simple manner with this device. In addition, a method of heating parts made of a microwave absorbing plastic is to be provided.
With the device according to this invention, this object is achieved by a device for heating parts made of microwave absorbing plastics.
Since the device for shielding is designed in a tube shape, with the device having an inside diameter smaller than half the wavelength and projecting beyond the free end of the antenna, the antenna can emit practically no microwaves into the free space. With these dimensions, there is exponential damping of the microwaves. Therefore, almost all the electromagnetic energy is concentrated in the narrow zone between the free end of the antenna and the device for shielding, so a very strong electromagnetic field prevails in this zone. As a result, a spatially limited or precisely defined heating of the parts takes place within the zone, but there is no heating of the parts outside the zone.
Since the device for shielding has an opening in the end face, this forms an opening through which the parts to be heated can be inserted into the zone between the free end of the antenna and the device. This opening need not be closed while the parts are being heated, because in this way practically no microwaves can be radiated into the free space. This offers the possibility of inserting only a section of the part into the zone between the device and the antenna and thus heating only that section, while the remainder of the part, which may project out of the opening, is not being heated.
To prevent microwaves from propagating in the free space, the device for shielding should project beyond the free end of the antenna by at least one quarter of the wavelength of the microwaves generated by the microwave generator. With this feature, emission of microwaves into the space is reliably suppressed. However, if the device projects beyond the free end of the antenna by only a small extent, emission of the microwaves is no longer suppressed so reliably. However, effective heating of the parts is possible in both cases.
It is expedient for the zone between the free end of the antenna and the device for shielding to be designed with dimensions that depend on the dimensions of the parts to be heated. Essentially, the electromagnetic field will be more pronounced, the narrower the zone or the smaller the distance between the free end of the antenna and the device for shielding. With such a strong electromagnetic field, a high energy density and thus optimum utilization of the energy input are achieved. However it is important for the parts to be inserted into the zone without contact in order to avoid soiling of the device in particular when the parts are heated to temperatures above the melting point. In addition, the longer the zone, the larger may be the spatially limited or precisely defined section of the part which is heated.
The zone between the free end of the antenna and the tubular device for shielding is advantageously designed to be especially narrow in one area in order to be able to heat the parts introduced into the zone in a spatially limited or precisely defined manner precisely in this area. This permits good handling of parts for the first time in welding, shaping or crosslinking since the parts remain cool outside the precisely defined area. Furthermore, the microwave energy applied can also be utilized with an extremely high efficiency.
It is especially advantageous that the parts introduced into the zone can be heated within the narrow area in accordance with the respective requirements, so that suitable heating of the parts can be implemented, depending on whether welding, shaping or crosslinking is to be performed.
If a dielectric is provided between the antenna and the device for shielding, it may serve for optimum positioning of the parts to be heated because the dielectric determines the extent to which the parts can be introduced into the device. Furthermore, such a dielectric represents a cold contact surface for the parts to be heated, which can prevent an excessive welding bead on the inside in welding tubular parts, for example.
In a preferred first embodiment of this invention, the free end of the antenna is conical in shape. The electromagnetic field that develops in the zone between the free end of the antenna and the device for shielding is designed to be the strongest here in the narrowest area of the zone, so this zone is especially suitable for welding parts. To do so, two parts that are to be welded together may be introduced at one end into the zone between the free end of the antenna and the device for shielding, heated there and then welded together. In a refinement of this embodiment, the device for welding tubular parts may have an antenna with two free ends to heat the end faces of the two tubes to be welded together simultaneously to a temperature above the melting point. The two free ends of the antenna should point in opposite directions.
According to a second embodiment of this invention, the free end of the antenna is designed in a mandrel shape. The mandrel-shaped end of the antenna serves to widen tubular parts which are pushed onto the free end of the antenna and are heated to a tem
Dommer Armin
Emmerich Rudolf
Jauss Michael
Mugge Horst
Fraunhofer Gesellschaft zur Forderung der angeandten Forschung e
Leung Philip H.
Pitney Hardin Kipp & Szuch LLP
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