DD226923A1 - METHOD AND DEVICE FOR WELDING WET GOOD - Google Patents

Abstract

The invention relates to a method and a device for dewatering of wet material, in particular of laundry after the washing process, using mechanical pressure. It is an object of the invention to allow a more intensive Entwaesserung of wet material. The invention has for its object to provide a method and an apparatus for dewatering of wet material, with which it is possible, even in cycle times of three or less minutes to ensure a residual moisture content below 50%. This object is achieved according to the invention by a method which provides that the material is additionally exposed to the mechanical pressure of a dielectric alternating field heating and a vacuum. The device suitable for carrying out this method is characterized in that a pressing station is assigned at least one vacuum chamber and one high-frequency generator. Fig. 1

Description

Title of the invention:

Method and device for dewatering wet material

Field of application of the invention:

The invention relates to the dewatering of wet material, in particular of laundry after the washing process. The product is exposed to mechanical pressure in a pressing station. The term "dewatering" also includes the removal of other aqueous liquids from an enriched (wet) material.

Characteristic of the known technical solutions:

It is known from a wet treatment process (continuous or discontinuous) coming Good, for example, issued from a washing laundry, prior to thermal drying in a convection and / or contact dryer initially subject to mechanical dewatering. The good is usually flushed with a considerable amount of splash water in a pressing device and dehydrated so far under the application of mechanical pressure, as it allows the binding of the liquid to the estate. Experience has shown that this mechanical drainage is considerably less expensive than the thermal drying by supplying heat and evaporating or vaporizing the liquid.

For applying the mechanical pressure on the material essentially two procedures are in use. In the simplest case, in a cylindrical, preferably kreiszylindri-view. Preßbehälter with a flow-through pad a pressing

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retracted stamp and pressed under high pressure against the good (see Z. B. DE-OS 3 041 994).

Secondly, it is known to apply the mechanical pressure on the material by means of a membrane attached to a preferably bell-shaped carrier, which is pressed by a pressure medium against the material. The good can also be located in a container in which the membrane support is lowered (DE-OS 2,852,923). However, it can also be covered as in an upstream station preformed cake of the bell-shaped membrane carrier (DD-PS 112 483).

In both procedures used in the press station, the pad as a load-absorbing counter-pressure bearing. The pad can be formed with appropriate support as a perforated conveyor belt.

A disadvantage of such presses that the achievable residual moisture contents in the estate are generally still higher than 50 to 52%. Also, the dewatering effect is largely determined by the pressing time. In modern, high-productivity wet-treatment and drying processes, the available cycle times are often less than three minutes, which in some cases leads to even higher residual moisture contents. With such short cycle times, which often allow only an effective pressing time (i.e., the time the material is under maximum pressure) of about two minutes, the mechanically possible dewatering effect due to the premature degradation of the mechanical pressure is not achieved. The outflow of liquid from the estate is relatively slow and thus limits the possible dehydration effect.

Object of the invention:

It is an object of the invention to allow an intensive drainage of wet material.

Explanation of the essence of the invention:

The invention has the object of providing a method and an apparatus for dewatering wet material, such. As laundry after the washing process to create, with which it is possible to ensure a residual moisture content below 50% even in cycle times of three or less minutes.

This object is achieved by a method which provides that the material is exposed in addition to the mechanical pressure of a dielectric alternating field heating and a vacuum.

This method is further developed by the items 2 to 11 of the invention claim.

The device suitable for carrying out this method is characterized in that a pressing station is assigned at least one vacuum chamber and a high-frequency generator.

Further essential features of the invention include the points 13 to 29 of the invention.

The advantage of the method according to the invention is that a very low and very evenly distributed residual moisture can be achieved in the estate. Since the dielectric heating is based on the utilization of dielectric losses in the material and those in water are generally much higher than in the material to be drained, in this way a balance of the moisture distribution is brought about in the material. In addition, only the water contained in the estate heats up very much, but the good itself less.

The vaporizing as a result of the dielectric heating liquid is discharged because of the voltage applied to the good quickly from this. However, the vacuum also promotes the removal of the non-evaporating liquid. In addition, the lowering leads

the total pressure in the good to an increase in the drying potential, d h. the difference between air temperature and cooling limit temperature. All this together causes a significant increase in the drying rate.

In the case of goods with a high proportion of liquid contained in capillaries, for example in the case of textile material, the dielectric heating also causes a drying of the capillaries, as a result of which the material can be brought to low final moisture contents,

One consequence of the achievable low residual moisture is that the good in subsequent drying processes less energy must be supplied. This can go so far that, for example, a tumble dryer for tumbling only needs to be used for loosening up, since the laundry already has the optimum input moisture for a deficiency process after pressing.

The thermal drying of the material is thus shifted by the residence time of the material is used in the device according to the invention to dry already thermally. In addition, the material supplied thermal energy is used in the form of Nachverdampfungseffektes. This re-evaporation begins as soon as the hot material leaves the device. Particularly intense it occurs when shaking laundry in the drum dryer, since all laundry here float freely in the air flow and a large evaporation surface is formed.

The achievable very low final moisture contents continue to cause a significant increase in performance when mangling laundry. In the hot-runner mangle only relatively little moisture must be dried, so that a high throughput speed is possible.

Working Example:

The invention will be explained in more detail with reference to an embodiment. The explanation of the device according to the invention is based on the example of a equipped with a high-frequency generator press

 The drawings show in

1 shows a device according to the invention in a schematic, sectional side view and

Fig. 2: a plan view of a vacuum chamber.

With the invention, a method is proposed / in which acts on the material to be dewatered in a known manner mechanical pressure. In addition, however, the mechanical material is exposed to a vacuum and a dielectric alternating field heating. The term dielectric alternating field heating includes heating by means of microwaves and heating in a high-frequency condenser field. Thus, both vacuum and dielectric alternating field heating are effects which substantially enhance the effect of mechanical pressure on removing the liquid from the material.

With regard to the use of the two additional effects with respect to the time of application of the mechanical pressure, the invention provides various possibilities. The dielectric alternating field heating preferably starts with the application of the mechanical pressure.

In another implementation of the method is provided that the dielectric alternating field heating begins after the application of the mechanical pressure, preferably at a time which corresponds approximately to the achievement of the maximum mechanical pressure.

The vacuum can also be applied at the time when the mechanical pressure is applied to the material. Here, however, it is preferred that the vacuum is applied only after the application of the mechanical pressure, but even before reaching the maximum mechanical pressure. The time is chosen so that, taking into account the necessary time for the construction of the vacuum, the vacuum reaches its extreme value together with the mechanical pressure.

The effect of the vacuum on the material has the consequence that the outflow of the liquid and resulting from the dielectric heating steam is facilitated from the pressurized Good. Preferably, this vacuum is applied to the side of the material, after which the liquid flows out.

The vacuum is inventively maintained beyond the removal of the mechanical pressure addition. This facilitates the removal of the press ram from the estate.

The vacuum to be applied in carrying out the method according to the invention is a rough vacuum, which is carried out with a minimal absolute value.

-3 lute pressure of 10 bar is defined.

An inventive device suitable for carrying out the method is shown schematically in FIG. It has a pressing station 1, in which the dewatering process is carried out. The pressing station 1 initially consists essentially of a press container 2, a ram 3 and an even closer to describing, load-absorbing pad.

The Preßbehälter 2 has a cylindrical, preferably a circular cylindrical shape. Its base corresponds to that of the press ram. 3

In the illustrated example, the pressure vessel 2 is provided in a particularly advantageous manner with a double-walled jacket 4,

which contains an annular vacuum chamber 5. This is connected via openings 5 in the jacket 4 with the interior of the press container 2 containing the material 7 to be dehydrated. The openings 6 extend to a height above the base, which corresponds to the height of the maximum compressed material 7. The jacket 4 further has on its outer side an opening which serves as evacuation opening 8 for the vacuum chamber 5. This is connected by an at least partially flexible suction 9 via a valve IO with an evacuation device in the form of a pump 11. In the suction line 9 opens a vent line 12 with a vent valve 13. In another embodiment of the invention, the vacuum chamber 5 can also be omitted.

The ram 3 is equipped with a channel system 14, which is connected via a vent valve 15 to the atmosphere. By means of a preferably hydraulic drive, the press ram 3 can be given a translational movement along its axis and the mechanical pressure required for the dewatering process can be exerted on the product 7. The Preßbehälter 2 and the ram 3 can be releasably connected to each other by means not shown, sufficiently well-known locking elements.

The pad for the pressure vessel 2 may be formed as a perforated plate. In the illustrated example, a perforated, preferably metallic conveyor belt 16 is provided as a base, which cooperates with a arranged below the pressing container 2 vacuum chamber 17. The conveyor belt 16 is endless and runs over the drive and guide rollers 18. The latter are suitable for giving the conveyor belt 16 an interval movement.

The vacuum chamber 17 is simultaneously formed as a liquid collecting container. For this reason, the vacuum chamber 17 has at its lowest point a drain opening 19 for the liquid and significantly higher an evacuation port 20, which via a

Suction line 21 with a valve 22 is also connected to the pump 11. To the drain opening 19, a line 23 is connected to a check valve 24.

As a load-receiving elements, the vacuum chamber 17 star-shaped struts 25, which are additionally reinforced by a stiffening ring 26 (Fig. 2).

Both the Preßbehälter 2 and the vacuum chamber 17 have sealing elements 27 and 28, with which they rest against the conveyor belt 16, and the two vacuum chamber ^ 5 and 17 both against each other and against the atmosphere seal. Likewise, the interior of the press container 2 is sealed against the atmosphere. Also contributes to this is an unillustrated sealing element (for example, an elastic sleeve) between the outer edge of the press ram 3 and the inside of the shell 4 at.

The invention further provides for the device a high-frequency generator 29, which is connected to the ram 3. Thus, the ram 3 acts as an electrode; the other electrode is formed by the metallic conveyor belt 16. High-frequency generator 29 and conveyor belt 16 may, as in Fig. 1, grounded or be connected to each other directly by a metallic conductor.

The pressing device is formed in this way simultaneously as a high-frequency capacitor arrangement. The high-frequency generator 29 operates at an internationally fixed frequency, for example 13.56, 27.12 or 40.68 MHz.

The device according to the invention works as follows:

The material to be dewatered 7, for example, coming from the washing process laundry, is flooded with a high proportion of moisture in the interior of the press container 2 and there is distributed as a result relatively evenly. The punch 3 is in

retracting the pressure vessel 2 "and exerts mechanical pressure on the material 7. This starts removal of the liquid adhering only loosely to the material 7. The large quantity of liquid accumulating in this phase flows through the perforation of the conveyor belt 16 into the vacuum chamber 17, which simultaneously serves as a liquid collecting container / and is discharged from there through the drain opening 19 into the conduit 23.

As already mentioned, the method is preferably carried out so that simultaneously with the application of the mechanical pressure on the Good 7 by retracting the press ram 3 in the Preßbehälter 2, the dielectric alternating field heating begins. For this purpose, the high-frequency generator 29 is put into operation, whereby in. The device builds up a high frequency alternating electric field. As a result, in particular, the liquid particles contained in the Good 7 are vibrated and heated. Thus, the temperature of the liquid and the goods 7 increases. Since, as is known, liquid with a higher temperature can be removed more easily, the high-frequency electric field favors the mechanical dewatering. If the limit of mechanical dewatering is achieved by the ram 3, the high-frequency field causes the further drying of the material 7 by means of thermal effects. The supplied high-frequency energy heats the Good 7 so far that the liquid contained evaporates and evaporates. This also applies to liquid contained in capillaries.

The action of the high-frequency electric field produces heat in each individual volume element. As a result, a uniform heating is possible over the entire volume of the goods 7 from the inside. When dry, substances such. As well as textile fibers, only relatively low radio frequency energy and therefore heat up only slowly. With moist substances, essentially only the liquid contained absorbs high-frequency energy. This physical behavior means that over prolonged residence in the high-frequency capacitor field no overheating of the goods 7 can occur. The described

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In addition, regularities lead to equalization drying, since moist areas absorb more high-frequency energy and consequently dry more.

During the first mechanical dewatering phase, the pump 11 has been put into operation in good time, that in the two vacuum chambers 5 and 17, a negative pressure is generated, which reaches its predetermined value with the onset of the maximum mechanical pressure, which should be at a minimum at about 10 bar (rough vacuum).

The ventilation valves 13 and 15 are closed in this case; the interior of the press container 2 is also secured by the mentioned, not shown sealing elements between the inner wall of the press container 2 and the press ram 3 against air flowing in from the outside. The check valve 24 prevents the backflow of liquid and air from the conduit 23 into the vacuum chamber 17.

The nearly all sides of the Good 7 applied vacuum causes the intensive interaction of mechanical pressure, negative pressure and high-frequency electric field, the removal of the stronger bond to the Good 7 and stored in the finer capillaries liquid. This is sucked from the vacuum chambers 5 and 17 of the pump 11. .

After completion of the dewatering process (for example towards the end of the available cycle time), the vent valve 15 is first opened for the channel system 14 in the ram 3, whereby the negative pressure in the estate 7 can degrade from above. The valve 10 is closed before the vacuum in the vacuum chamber 5 collapses with the opening of the venting valve 13. The still working pump 11 maintains the vacuum in the vacuum chamber 17 upright, so that the dehydrated Good 7 still firmly adheres to the conveyor belt 16. The already mentioned locking elements now cause the pressing container. 2

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is raised together with the ram 3 and the Good 7 releases. By closing the valve 22 and / or stopping the pump 11 and opening the valve 10, the negative pressure in the vacuum chamber is abruptly compensated. The material 7 is conveyed by the conveyor belt 16 to the next processing step (eg tumble dryer). In parallel, the ram 3 is lowered with the Preßbehälter 2 until the latter is seated on the conveyor belt 16, the lock released and the ram 3 raised again. Then new Good 7 can be introduced into the Preßbehälter 2 in the next cycle.

Claims (29)

4L invention claim: 1. A method for dewatering wet material, in particular of
Washing after the washing process, wherein the material is applied in a pressure vessel with mechanical pressure,
characterized by that the material (7) in addition to the mechanical pressure of a dielectric alternating field heating and a vacuum is exposed. 2. The method according to item 1, characterized in that the dielectric alternating field heating begins with the application of the mechanical pressure. 3. The method according to item 1, characterized in that the dielectric alternating field heating begins after the application of the mechanical pressure. 4. The method according to item 3, characterized in that the dielectric alternating field heating begins at a time which corresponds approximately to the achievement of the maximum mechanical Drukkes. 5. The method according to item 1, characterized in that the vacuum on the material (7) is applied to the downstream side of the liquid. 6. The method according to the items 1 and 3, characterized in that the vacuum is applied simultaneously with the application of the mechanical pressure. 7. The method according to item 1, characterized in that the vacuum between the application of the mechanical pressure and
is applied to reach the maximum pressure. 8 · The method of item 1, characterized in that the vacuum up to about the removal of the mechanical pressure on the material _s (7) also is maintained. 9. The method according to the items 1 to 8, characterized in that the vacuum is a rough vacuum with a minimum pressure of 10 ~ ³ bar. 10. The method according to points 1 to 7, characterized in that the dielectric alternating field heating is achieved by means of microwaves. 11. The method according to points 1 to 7, characterized in that the dielectric alternating field heating is performed in a high-frequency capacitor field. 12. Device for dewatering wet material, in particular laundry after the washing process, for carrying out the method according to item 1, which has a pressing station with a cylindrical press container, a flow-through, load-absorbing pad and a retractable into the press container press ram, characterized by in that the pressing station (1) is assigned at least one vacuum chamber (5; 17) and a high-frequency generator (29). 13. The device according to item 12, characterized in that the high-frequency generator (29) with two the Good (7) between them, electrically isolated from each other elements of the pressing station (1) is connected to a high-frequency rKondensatoranordnung. 14. The device according to item 13, characterized in that the elements included in the high-frequency capacitor arrangement of the ram (3) and the base of the pressing container (2). 15. The device according to item 14, characterized in that the high-frequency generator (29) is connected to the ram (3) and both high-frequency generator (29) and pressure vessel (2) are grounded. 16. The device according to item 12, characterized in that the high-frequency generator (29) is designed as a microwave generator. 17. The device according to item 16, characterized in that the microwave generator (29) in the Preöstempel (3) is arranged. 18. Device according to item 12, characterized in that below the pressing container (2) a vacuum chamber (17) is arranged. 19. The device according to item 12, characterized in that the jacket of the pressing container (2) as an annular vacuum chamber (5) is formed, which is connected via openings (6) with the interior of the pressing container (2). 20. The device according to item 19, characterized in that the openings (6) are arranged only in an area above the base, which corresponds to the height of the maximum compressed material (7). 21. Device according to the points 12 and 18, characterized in that the under the pressing container (2) arranged vacuum chamber (17) is designed as a liquid collecting container. 22. Device according to items 12 and 18 to 21, characterized in that the vacuum chambers (5, 17) are sealed off from each other and from the atmosphere by sealing elements (27; 23. Device according to the points 12 and 18 to 21, characterized in that the pressing container (2) is sealed from the atmosphere. 24. Device according to items 12, 13 and 22, characterized in that the sealing elements (27, 28) represent the electrical insulation of the elements included in the high-frequency capacitor arrangement. 25. Device according to the points 12, 18 and 21, characterized in that under the pressing container (2) arranged vacuum chamber (17) at its lowest point has an opening (19) for discharging the liquid and much higher an evacuation port (20) , 26. Device according to item 12, characterized in that each vacuum chamber (5; 17) is controllably arranged on an evacuation device (11). 27. The device according to item 12, characterized in that each vacuum chamber (5; 17) is connected to a ventilation valve (13). 28. The device according to item 12, characterized in that the ram (3) is equipped with a channel system (14) which is open both to the atmosphere and to the interior of the pressing container (2). 29. The device according to item 28, characterized in that the channel system (14) to the atmosphere is lockable. For this 2 pages drawings