DE4119846A1 - Microwave drying device for solid loose material - has HF and earth electrodes below and above transport base for loose material - Google Patents

Abstract

The microwave drying device has a low conductance transport base (2), e.g. of plastics material, with a dielectric constant of 10 or less, fed continuously through one or more drying chambers in the form of a conveyor band. A HF electrode (5) lies beneath the base (2), with an earth electrode (6) above the material (1) supported by the base (2) at an adjustable height, to obtain a uniform electromagnetic penetration of this material (1). A second earth electrode is formed as a screening disk and acts as an air capacitor determining the resonance frequency, with rollers etc supporting the base (2) and stabilising the airgap between the HF electrode (5) and the base (2). USE/ADVANTAGE - For continuous drying process. Shortened drying time with reduced mechanical and thermal loading.

Description

The invention relates to a device with which moist solids and Bulk goods faster, gentler and with higher efficiency than up to be dried here. Especially for continuous continuous drying ner, the device according to the invention has the above-mentioned. Advantages over Vibratory fluid bed dryers with hot air energy feed or vortex layer dryers. The measurable energy absorption takes place selectively especially through the water molecules. It decreases with what water content in the solid dressing, which at the same time increases the reproducibility Availability of water removal can be improved.

The known attempts to use high frequency for drying processes there were technical problems. The inflow floor on which the dry material was used as the measuring electrode, while the hot one HF electrode above the estate was constructed to be height adjustable. The danger of electrical flashovers in the event of brief moisture release the good was acute. The use of fixed frequency generators deteriorated basically the efficiency. On the other hand, large areas High frequency dryer due to the high capacities required of working capacitors <40 pF not in the natural resonance of the requ drying frequencies fluctuate. There is also an adjustable height bare hot HF electrode above the material cannot be optimally shielded without further increase of the resonant circuit capacities.

The object of the invention is through the high frequency drying Elimination o. G. Make defects usable to increase the drying time shorten the mechanical and thermal load on the solid significantly lower the energy efficiency and reproducibility to improve the decorability of the drying process.

The object is achieved in that the drying good on a poorly conductive inflow floor, preferably made of art material with a low dielectric constant ε 10.

The inflow floor is in the continuous single and multi-chamber dryer designed as a conveyor belt on which the items to be dried are electro magnetic field is drawn. The hot electrode is tight under the inflow floor, is designed as a sieve and is rigidly fixed, whereby between the HF electrode and the inflow floor always a dry air gap of one or a few millimeters as a barrier against electrical arcing remains.  

The ground electrode is above the items to be dried and adjustable in height arranged, is also designed as a sieve and causes the same moderate electromagnetic penetration of the drying goods.

A pot or box-shaped ground electrode works around the HF electrode as a shield and as an air condenser for adjustment the resonance frequency and has a bottom made as a sieve. Rolling or grinding on the (pot- or box-shaped) ground electrode serve as a support for the inflow floor and at the same time ensure that Stabilization of the air gap between the HF electrode and the inflow floor. The sieve-like design of the electrodes ensures even distribution air flow through the material to be dried.

Large-area high-frequency dryers are equipped with several working capacitors built up side by side or in a row, each individually or in groups as to the resonance circuits of various RF generator assemblies belong.

Continuous multi-chamber dryers are used for process optimization the variation of electrode spacing, field strength, resonance frequency and thus energy absorption for the various working capacitors varies.

The even distribution of the drying goods both on the conveyor belt the continuous dryer as well as on the fixed inflow floor for batch batch dryers is by generating a flow beds achieved by vibrators.

The amplitude and frequency of the vibration should be adjustable. The conveyor belts have a plastic edge that prevent the lateral loss of drying material during vibration. The layer thickness of the material to be dried is limited by the height adjustment bare wipers. The air flow is only intended to remove the resulting Ensure water vapor, but do not build a fluidized bed.

The temperature of the air flow only depends on the required saturation pressure or equilibrium vapor pressure and temperature sensitivity of the material to be dried.

With multi-chamber dryers, each chamber can have its own air flow be charged.

Resonance frequency, field strength in the material to be dried, air flow in the individual chambers and layer thickness of the material to be dried are measurement, control and adjustable.  

Water evaporation is primarily based on the principle of dielectric heating with selective amplification for water. Resonance frequencies f _R in the interval 1 MHz <f _R <50 MHz are preferably used.

Embodiments

The device is explained with reference to two drawings.

Fig. 1 represents a simplified schematic diagram.

The material to be dried 1 is situated on a low conductive gas distributor plate 2 of plastic material with a low dielectric constant ε 10. The Ausströmboden 2 is carried out in a continuous single or multi-chamber dryer as a conveyor belt, is pulled causing the material to be dried 1 through the elec tromagnetic field. A good uniform distribution of the goods 1 both on the conveyor belt of the continuous dryer and on the fixed inflow floor 2 for discontinuous batch dryers is known to be achieved by producing a vibrating fluidized bed by vibrators 3 . Furthermore, the height-adjustable wipers 4 limit the layer thickness of the material 1 . The hot HF electrode 5 is located just below the inflow floor 2 and is designed as a sieve. It is rigidly fixed, so that between it and the inflow floor 2 there is always a dry air gap of one or a few millimeters as a barrier against electrical flashovers.

The measuring electrode 6 above the good 1 is adjustable in height, also designed as a sieve, and ensures the uniform electromagnetic penetration of the good 1 .

The pot-shaped or box-shaped ground electrode 7 acts as a shield and as an air capacitor for adjusting the resonance frequency and also has a bottom made as a sieve.

The rollers or grinders 8 serve as a support for the inflow base 2 and at the same time ensure the stabilization of the air gap. The sieve-like design of the electrodes also ensures better uniform distribution of the air throughput through the drying material 1 . The air flow only has to ensure that the evaporating water molecules are removed. The temperature of this air flow can be set depending on the required saturation vapor pressure and temperature sensitivity of the goods 1 . In multi-chamber dryers, each chamber 9 can be supplied with its own air throughput.

Large high-frequency dryers generally require several working condensers sensors side by side or one behind the other to move through appropriate rows switch the total capacitance of the resonant circuit low hold. The problem of a multiple series connection remains the division the high frequency voltage and therefore the lower field strength per Working capacitor.

The second way, resonance frequency and field strength in simple To keep the required size is the connection of the individual Working capacitors on their own HF generator assemblies, see above that several, largely independent generators in large areas Dryers are used. This is also the prerequisite in continuous multi-chamber dryers, energy absorption to discharge for the purpose of optimization also through different resonance to vary frequencies.

Fig. 2 illustrates the basic structure of such a multi-chamber dryer according to the Invention.

Via a conveyor device 14 and the first scraper 4 a, the entry into the first chamber 9 a takes place. In each chamber 9 a-c 9, the air flow rate are adjusted individually.

The measuring electrodes 6 are individually adjustable in height, and each working capacitor has its own generator. The working capacitors are part of the respective resonant circuit.

The material to be dried 1 is drawn on the conveyor belt 10 , consisting of inflow floor 2 , drive shaft 11 and the vibration waves 12 , far past the wipers 4 through the working capacitors and leaves the outlet 13 dried the system.

The following can be controlled or regulated:

• Resonance frequency, inter alia, by the height adjustment of the ground electrodes 6 ,
• Field strength in the good 1 by height adjustment of the ground electrodes 6 ,
• - air flow in the individual chambers,
• - vibration amplitude and
• - Layer thickness of the material 1 by adjusting the wipers 4 .

Since dielectric heating is to act primarily for water evaporation, resonance frequencies f _R in the interval 1 MHz <f _R <50 MHz are required.

List of the reference numerals used

1 item to be dried
2 inflow floor
3 vibrator
4 wipers
5 HF electrode
6 ground electrode
7 pot or box-shaped ground electrode
8 rolls or loops
9 (ac) chamber for air supply
10 conveyor belt
11 drive shaft
12 vibrator shaft
13 discharge
14 conveyor

Claims (5)

1. Device for high-frequency drying of solids and bulk goods, characterized in that the material to be dried ( 1 ) on a poorly conductive inflow floor ( 2 ), preferably made of plastic, with a low dielectric constant ε 10, this inflow floor ( 2 ) in a continuous single and multi-chamber dryer is designed as a conveyor belt ( 10 ), on which the drying good ( 1 ) is pulled through the electromagnetic field, the hot HF electrode ( 5 ) is located just below the inflow floor ( 2 ), is designed as a sieve and is rigidly fixed , whereby between the HF electrode ( 5 ) and the inflow floor ( 2 ) there should always be a dry air gap of one or a few millimeters as a barrier against electrical flashovers, the ground electrode ( 6 ) arranged above the material to be dried ( 1 ) and adjustable in height, also as Sieve is carried out and causes the uniform electromagnetic penetration of the drying material ( 1 ),
the pot-shaped or box-shaped ground electrode ( 7 ) acts as a shield and as an air condenser for setting the resonance frequency and has a bottom made as a sieve,
where rollers or loops ( 8 ) on the ground electrode ( 7 ) serve as a support for the inflow base ( 2 ) and at the same time ensure the stabilization of the air gap between the HF electrode ( 5 ) and the inflow base ( 2 ),
the sieve-like design of the electrodes ( 5 , 6 , 7 ) ensures the uniform distribution of the air throughput through the material to be dried,
whereby large-area high-frequency dryers with several working capacitors are built next to or behind one another, each belonging individually or in groups to the resonant circuits of different high-frequency generator assemblies and
being in continuous multi-chamber dryers to optimize the process, the variation of the electrode spacing, field strength, resonance frequency and thus energy absorption for the different working capacitors is varied. 2. Apparatus according to claim 1, characterized in that the equal distribution of the drying material ( 1 ) both on the conveyor belt ( 10 ) of the continuous dryer and on the fixed inflow floor ( 2 ) for discontinuous batch dryers by generating a fluidized bed with vibrators ( 3 ) is reached
the amplitude and frequency of the vibration should be adjustable,
wherein the conveyor belts ( 10 ) have an edge limitation made of plastic, which prevent the lateral loss of drying material ( 1 ) during vibration and
the layer thickness of the material to be dried ( 1 ) being limited by height-adjustable scrapers ( 4 ). 3. Apparatus according to claim 1, characterized in that the air flow only ensures the removal of the water vapor produced and does not build up a fluidized bed,
the temperature of the air flow only depends on the required saturation or equilibrium vapor pressure and the temperature sensitivity of the material to be dried ( 1 ) and
with multi-chamber dryers each chamber ( 9 ) can be supplied with its own air flow. 4. The device according to claim 1, characterized in that the resonance frequency, field strength in the material to be dried ( 1 ), air throughput in the individual chambers ( 9 ) and layer thickness of the material to be dried ( 1 ) can be measured, controlled and regulated. 5. The device according to claim 1, characterized in that the Wasserver vaporization takes place primarily on the principle of dielectric heating, selectively reinforced for water and preferably resonance frequencies f _R in the interval 1 MHz <f _R <50 MHz are used.