DE1690572A1 - Microwave oven for strips or strips - Google Patents

Description

Dipl.-Ing. W.Beyer
6 Frankfurt / Main Freiherr-vom-Stein-Str. 18th

Hirst (Microwave Heating) Ltd. Crawley, Sussex / England

Patent application

Priority of British Patent Application No. 10 592/67

from the ?. March 1967

Microwave oven for goods in the form of strips or strips

The invention relates to a band-shaped or strip-shaped microwave oven Good, consisting of a number of serpentine interconnected and aligned longitudinal slots Waveguide and a vibration generator connected to one end of the waveguide coil for feeding of microwave energy. In such a microwave oven, the material passed through the slots in the transverse direction one after the other for each waveguide and is heated therein.

A microwave oven of this type is known in which the adjacent walls separated by common partitions Waveguides are not connected to each other at their ends by connecting bends, but by windows in the partition walls are. As a result, one waveguide practically follows the other without any spacing between them, and there is no cooling of the Goods to be heated up when they are transported from one waveguide to the next through the longitudinal slots.

At this:; well-known microwave oven is at the other end A dummy charge is connected to the waveguide coil. With a sufficient total path length for the microwaves within of the waveguide snake, i.e. a sufficient sum of the

109823/0372

H 3153 / 5.3.68

Lengths of all waveguides from one end of the snake to the other, most of the microwave energy supplied by the vibration generator will be absorbed by the material to be heated, and the dummy charge will only serve to absorb a remaining amount of energy of perhaps 5 % or 10 % of the total amount emitted. Since the field strength of the microwave radiation drops according to an exponential curve along the waveguide coil (regardless of the effects of the heating on the absorption properties of the goods), those waveguides that are closer to the dummy charge will lead to microwave energy of comparatively low intensity and relatively little to warming contribute to the good

The object of the invention is to eliminate this disadvantage and to create a microwave oven of the type mentioned above, in which the individual waveguides contribute more evenly to the heating of the goods than in the known furnace. Inventing This object is achieved according to the fact that the at the other end of the waveguide snake another vibration generator is connected, which feeds microwave energy into the waveguide coil in the opposite direction.

In order to prevent with certainty that the vibration generators reciprocate with the remaining amounts of energy absorbed overload, is in an advantageous embodiment of the invention a device for monitoring the mutual Applying energy to the two vibration generators by comparing the vibration energy emitted with the impacting vibration energy on springs vibration generator by switching off the Power supply to both vibration generators provided, when the relationship between hitting to 'delivered Vibration energy of one of the two generators a predetermined Value exceeds.

An embodiment of the microwave oven according to the invention is explained in more detail below with reference to the drawing. Show it :

109823/0 3 72
H 3155 / 5.5.68

1 shows a serpentine waveguide arrangement equipped with two vibration generators and a monitoring device,

FIG. 2 shows a detail from FIG. 1 with a sensing element the monitoring device on a larger scale and cut,

3 shows the control circuit of the monitoring device and

4 shows another embodiment of the control circuit. A.

The microwave oven according to Fig * 1 consists of the serpentine Arrangement 11 of a larger number of interconnected, alternately at one and the other end through windows, Longitudinally slotted waveguide 12 for heating a band-shaped or strip-shaped item 13 through the slots in the direction of arrow 14 (or in the opposite direction) passed through will. In this respect, the waveguide coil corresponds to the known design.

At the opposite ends of the waveguide coil 11j, two magnetrons 15 and 16 are connected by means of hollow connecting conductors 17 and 18 ', respectively. As can be seen, the energy supplied to one Λ end of the waveguide snake 11 through the corresponding magnetron is conducted along the snake-shaped interior of the waveguide and at the end hits the other magnetron with a remainder that is not absorbed or absorbed by the good 13 before reaching the other magnetron has been weakened. ·,

Assuming that instead of the magnetron 16 and the connecting conductor 18, a dummy load is provided, which is known in FIG Way, the remainder of the amount emitted by the magnetron 15 Absorbs energy during the serpentine path. · ■ within the waveguide snake 11 not in the form of a band or strip Having been well absorbed, it stands to reason that, for sufficient heating of the object, the length of the

H 3153 / 5.5.68 109823/0372

Waveguide coil 11 formed microwave path, taking into account the absorption properties of the good 1 $, must be large enough if it is to be ensured that the main part of the energy is actually absorbed by the good 13 and not by the dummy load. Since the absorption capacity of the material 13 essentially decreases according to an exponential function with the distance (along the serpentine lying) from the magnetron 15, it is understandable that those waveguides 12 which are located in the vicinity of the end of the waveguide snake 11 connected to the magnetron 15 , a relatively large proportion and, in contrast, those waveguides 12, which are located in the vicinity of the other end of the waveguide coil, only a comparatively small proportion to the heating of the band or. Contribute strip-shaped material 13 when this is passed through the waveguide snake 11. If, however, the absorption capacity of the good 13 is large (for example greater than 90 % or even 95%), then the remaining 10 % or 5 % will be low enough to pass from the second, according to the invention, to the waveguide snake instead of a load 11 connected magnetron 16, which in turn emits energy at the same level as the magnetron 15, can be safely absorbed. Such an arrangement then increases the microwave field strength in the waveguide 12 closest to the magnetron 16 such that it corresponds to the field strength in the waveguide 12 closest to the magnetron 15, and the heating effect along the waveguide coil 11 is considerably evened out.

The manufacturers of magnetrons normally give the maximum allowable ratio between that against the magnetron of 'Energy reflected from a charge and the energy emitted by the magnetron Energy on. In the arrangement according to FIG. 1, of course, the band or strip-shaped material 13 must be that of each The amount of energy emitted by the magnetron weakens sufficiently ■ the entire on each magnetron from the waveguide snake 11 easter power impinging out in a sufficiently low level

H 3153 /5.3.68 109823/0372

Relative to the energy emitted by the magnetron. Jenn does not meet this requirement (for example when the item 13 is completely pulled out of the waveguide coil), the magnetrons are quickly destroyed.

In order to prevent such destruction, monitoring means are assigned to each magnetron, which determine the relationship between the incident energy to the radiated energy in Monitor insight into the permissible limits. As shown in Fig., These monitoring means consist of four sensing elements 19 »20, 21 and 22, one of which, namely the antennae 19 is shown enlarged in Fig. 2 in its details.

The sensing element 19 according to FIG. 2 is a so-called resistance ski Eifen-Eichtung coupler (Eesistive loop directional coupler), its principle of operation in the article "The reflectome ter" by H.E. Alien and C.D. Corling, published on p. 25 the Proceedings of the Institute of Electrical Engineers, 194-9.96, Part III. The connecting conductors 17 and have a non-square rectangular cross-section, and the feeler elements are located in the wider wall parts of the same, one of which is labeled Ί7 'in FIG. 2.

To attach the sensing element 19, the wall part 17 'contains an opening into which a terminal screw 24-provided Holder 23 is inserted. The sensing element has an inserted into the holder 23 and from the screw 24 in Position held electrically conductive body 25 with two Bores 26 and 27, of which the bore 26 has a resistance body 28 receives, one end of which is electrically grounded by a connecting conductor 29 on the body 25 and from the other end of which is a wire loop 30 into the interior of the hollow connecting conductor 17 extends and dorfc in its Is kinked longitudinally. After another kink wire loop 30 extends coaxially into the second Bore 27 and there opens centrally into a bore 27

109823/0372
H 3153 / 5.3.68

inserted two-pole connector.

The 'sensing member of Fig. 2 is both electrical and magnetic with the propagating through the connection conductor 17 as an EL -.- wave Microwave energy is coupled, the effect of the magnetic coupling being the effect of the electric coupling for the microwaves propagating in the direction of arrow 32 superimposed and mutually canceling for the propagation in the opposite direction. By appropriate selection of the Circuit constants, in particular the extent to which the wire loop 30 extends into the interior of the connecting conductor 17 extends, it can be ensured that the electrical and magnetic couplings are of the same size, so that the resulting output signal of the microwave oscillation at the connector 31, which is proportional to the field strength of the is in the direction of 32 propagating microwaves Microwaves propagating in the opposite direction drops to zero. The dimensions of the portion of wire loop 30 that goes into the Inside the connecting conductor 17 extends are much smaller than the monitored wavelength of the microwaves. Resistance 28 is preferably a carbon composite resistor, since such resistors have a radio frequency resistance that is close to constant and independent of the direct current Wi the value in a range of approximately 100 ohms to 1 megohm.

The presence of the bore 26 and the arrangement of the resistance element 28 completely in the same, cause an almost complete shielding of the resistance element of the lines of force of the microwaves with which the wire loop 30 is coupled within the connecting conductor 17, and this shielding of the resistance element 28 enables the sensing element 19 to monitor much greater field strengths, than it could withstand if the resistance element were not shielded.

H 3153 / 5.3.68

109823/0372

The sensing element 20 is identical to the I sensing element 19, but its electrically conductive body 25 is inserted rotated by 180 °. In this way, an output signal of the microwave oscillation occurs at the sensing element 19, which is proportional to the microwave lines of force emitted by the magnetron 15, and the sensing element 20 supplies a microwave output signal which is proportional to the microwave radiation impinging on the magnetron 15. Lines of force is. In a similar way, the sensing elements 21 and 22 emit output signals proportional to the aur ^a magnetron 16 impinging on or by the lines of force generated. -

As shown in Fig. 3, the output signals of the sensing elements 19 and 20 are via corresponding radio frequency detectors 33 or 34- fed to a comparison and amplifier circuit 35, whose output signal is proportional to the ratio between the rectified input signals on the part of the Sensing elements 19 and 20 and a relay 36 is supplied, a contact if the energy ratio exceeds the permissible value specified by the magnetron manufacturer 36 'actuated in a control circuit that interrupts the electrical power supply to the two magnetrons and the circuit for this purpose, it holds open until it is reset from the outside. The rectified output signals of the sensing elements 19 and can also, as shown, microampermeters 37 and 38 supplied then, the emitted or incident energy Show. The sensing elements 21 and 22 are similarly connected to the circuit and are used to supply energy to the magnetron 16. In this way, both magnetrons, if only one of them, have an impermissible ratio from incident to radiated energy is switched off until the cause of this has been determined.

If desired, the radio frequency detectors 33 and 34-in the sensing elements 19 and 20 or 21 and 22 are included *, which are inserted into a bore 27 in each case and electrically in series between the inner contact of the

H 5155 / 5.3-68 ^ _982370372

Connection part 31 and the end of the bore 27 extending wire loop 30 are.

As an alternative to the use of radio frequency detectors designed as diodes can be the radio frequency output of a filling member such as the sensing element 19 are also given to a lamp, the luminosity of which is proportional to the received output signal, and the lamp can then influence a photocell, its output power as well is a measure of the radio frequency output signal. In this case, the lamp can be inserted into the bore 27, wherein their terminals are connected to the body 25 or the wire loop 30 will.

If desired, the sensing members 19 and 22 can also be omitted and the signals proportional to the energy emitted by the two magnetrons can be obtained in other ways will. Such a possibility is illustrated in FIG. 4, which, similar to FIG. 3, shows the connection of the sensing element 20 via a rectifier 34- with a microampermeter 38 and the input side of a comparison and amplifier circuit 35 shows which is connected to a relay "36 controlling the contact 36 '. The other input signal for the Circuit 35 is derived from the anode circuit of magnetron 15, which contains a resistor 39 across which a voltage is proportional the anode current of the magnetron occurs. In fact, the anode current of the magnetron is nearly proportional to that radiated energy and can be used to a sufficient extent for the second. Input signal from. Voltage drop to derive at resistor 39. The microampermeter 38 shows normally the energy incident on the magnetron 15, however, when the sensing element 20 is rotated by 180 °, the energy emitted by the magnetron 15. To the energy given up to be able to read this way is between the Rectifier 34 and the comparison and amplifier circuit 35

H 3153 / March 5, 1968

109823/0372

a switch 40. It goes without saying that this switch must be opened before the sensing element 20 is used Reading of the radiated energy is rotated. It is also understood that the JBtihl member 22 in a similar manner can be omitted and the corresponding signal from the anode circuit of the magnetron 16 can be tapped.

Patent claims /
H 5155 / 5.3.68

10 98 2 3/0372

Claims (1)

Claims 1. Microwave oven for strip or strip-shaped material, consisting of 'a number of serpentine interconnected and aligned longitudinal slots provided waveguide and a vibration generator connected to one end of the waveguide snake for feeding in microwave energy, thereby characterized, ■ that at the other end (connecting conductor 18) of the waveguide coil (11) another vibration generator (16) is connected, the microwave energy in the opposite direction in the waveguide coil (11) feeds. 2. Microwave oven according to claim 1, characterized by a device (19,20,21,22, 33-40) for monitoring the reciprocal application of energy to the two vibration generators (15,16) by comparing the emitted with the incident vibration energy at each vibration generator and through Shutdown of the power supply to both vibration generators when the ratio between the incident to the output vibration energy of a ^{v of} the two generators exceeds a predetermined value. 3. Microwave oven according to claim 2, characterized in that that the monitoring device at each end (connecting conductor 17, 18) of the waveguide coil (11) direction-sensitive cooling member (19,22), which on ; the one in the waveguide coil (11) to the end in question (Connection conductor 17 or 18) responds conducted microwave energy. H 3153 / ^ .3.1968 109823/0372 4-. Microwave oven according to claim 2 or 3 »characterized characterized in that the monitoring device jiittel (39) for detecting the power consumption of each Vibration generator (15 »16) and thus for indirect measurement the amount of microwave energy emitted. 5. Microwave oven according to claim 2 or 3 »characterized in that the monitoring _{device at each end (connecting conductor 17 5} 18) of the waveguide snake (11) has a direction-sensitive sensing element (20, 21) which is directed to the waveguide snake A from the end in question supplied microwave energy responds. 6. Microwave oven according to one of claims 2, 3 or 5 »characterized in that each direction-sensitive sensing element (19) in Fig. 2) consists of an electrically conductive body (25) inserted into a wall (17 'of the end (17) of the waveguide coil) with a through hole (27), in the outer end of which a two-pole connection piece (31) is inserted, one conductor of which is conductively connected to the body (25) and of the other conductor of which a wire loop (30) extends through the hole (27 extends) into the interior of the end (17) of the waveguide line and back to a fully recorded by a second bore (26) of like body (25) and with its other end to the body connected Vi of the stand element (28). ^> 153 / 4.3.1968 109823/0372