EP0166406A2 - Method and apparatus for drying fibrous material - Google Patents

Abstract

Fibrous material is dried in a vessel 1 by passing vapor through the same which is circulated in a circulation conduit 26, superheated in a continuous flow heater 20 and circulated by a fan 16. A vacuum pump 31 is connected to the circulation conduit 26 by a pressure control valve 32.

Description

The invention relates to a method for drying fiber material or the like, in particular following a liquid treatment such as dyeing the fiber material and while the fiber material remains in the treatment container, in which the fiber material may first be used for mechanical dewatering to a residual moisture content with air and / or Steam flows through and is finally dried while applying a vacuum and introducing steam, the moisture removed from the fiber material being removed to the vacuum pump or to a condenser assigned to the vacuum pump.

Such a method is known (DE-OS 19 27 651). There, textile fiber material such as yarn in the form of cross-wound bobbins is dyed in a treatment container and then dried without being transferred to another container. An introductory mechanical dewatering is provided for this purpose, in which air and / or steam flows through the fiber material and entrains undevaporated moisture from the fiber material in droplet form. A simultaneous vacuum in the container encourages the droplets to detach from the fiber material.

After this mechanical dewatering, residual moisture remaining in the fiber material is removed by means of final thermal drying. Air heated in the container is likewise passed through the fiber material under vacuum, which on the one hand supplies heat to evaporate the residual moisture and on the other hand absorbs water vapor from the fiber material and Vacuum pump leads away. This moisture is deposited in a condenser in front of the vacuum pump or condenses in the vacuum pump itself, for example if it is a water ring pump. During this finished drying, steam is not introduced into the container or into the fiber material to be dried, or only in a small amount in addition to the heated drying air. This steam is essentially not overheated and, in addition to a limited supply of heat to the fiber material, serves to avoid local overdrying and thus to even out the finished drying.

Finished drying by means of heated air requires not only an air heater but also a comparatively large output vacuum pump which processes the comparatively large amounts of air required for the desired fast finished drying. In addition to the corresponding system costs, there are comparatively high operating costs, which result on the one hand from the high vacuum pump output to be provided and on the other hand from the fact that a correspondingly large amount of exhaust air at a higher temperature occurs behind the vacuum pump.

Accordingly, the object of the invention is to carry out the known method in such a way that the fiber material can be quickly and easily finished dried with a comparatively low outlay on installation and operating costs.

This object is achieved in that continuously and exclusively superheated steam is passed through the fiber material during the finished drying, which feeds the heat required for evaporation of the residual moisture and flows out with the residual moisture evaporated from the fiber material.

A flow of heated air is thus dispensed with in the finished drying according to the invention, which already leads to a simplification of the system. Steam and possibly superheated steam are usually available in those factories in which fiber material is dried. Overheating can also be achieved by lowering the pressure with the vacuum pump. A decisive advantage of carrying out the process without using drying air is that the vacuum pump does not have to process any corresponding amounts of air and that moist warm air does not have to be emitted. Rather, the vacuum pump only sucks in water vapor that can be used in operation after it has been condensed into hot water. The amount of waste steam or condensate obtained can be kept low and essentially limited to the amount of residual moisture to be removed, because, according to the following explanations, it is possible to finish drying without additional live steam.

In the case of such a particularly expedient process implementation, the steam is passed in a circuit through the fiber material and an intermediate superheater, a steam portion corresponding to the formation of steam from residual moisture being drawn off from the circuit to the vacuum pump. The heat required to evaporate the residual moisture is transported from the reheater to the fiber material by means of the cycle steam. It can be seen that this circulated steam can easily be formed by evaporated residual moisture, so that, if necessary, not only a supply for superheated drying air but also a steam supply from the outside can be dispensed with. This is possible because an initial evaporation of the residual moisture can be carried out by means of a correspondingly strong pressure reduction in the container by means of the vacuum pump. In this context, it is advantageous if, during the mechanical dewatering preceding the finished drying by means of air and / or steam, this medium has already been preheated by appropriate heat emission, if necessary to close to the boiling point corresponding to the vapor pressure curve.

If drying is carried out in this way with steam flowing in the circuit, it is expedient to draw off the steam portion at a point to the vacuum pump located behind the fiber material and the circulation device and in front of the reheater. The vapor portion is expediently drawn off to the vacuum pump via a pressure control valve that opens when the pressure rises in the circuit. On the one hand, good steam circulation through the reheater and on the other hand sufficient steam discharge to the vacuum pump is ensured while maintaining the intended operating vacuum in the treatment tank or in the circuit.

Since short drying times can be achieved with the method according to the invention, it makes sense to carry out the drying in the treatment container because of the comparatively small amount of work involved, since with comparatively short drying times a high liquid treatment capacity still remains available. The method according to the invention is not only suitable for drying yarns or textile piece goods, but very generally for drying flowable material, which can also be, for example, paper stock or a wood fiber material.

The invention also relates to a device for carrying out the above-described method with a container that can flow through the fiber material, a circuit line in which the container, a circulating device and a water heater are installed, and a branch line connected to the circuit line with a vacuum pump and possibly a condenser and if necessary, a live steam supply line opening into the circuit line.

Such a device with a condenser and a live steam feed line is already known (DE-OS 20 10 605). There, the live steam supply line opens into the circuit via a steam cooler, which is used for mechanical dewatering and not for finished drying. The steam is expanded so that it has a large specific volume at low density, so that despite a comparatively small amount of steam that is passed through the textile material to be dried, it is flowed through at a high speed, which is responsible for mechanical dewatering by entrainment has been recognized by water droplets as appropriate. Despite the high flow rate, the vacuum pump is not heavily loaded because the amount of steam to be processed is small and is condensed in front of the vacuum pump. For final drying, however, heated air is also used here, which is even supplied under excess pressure, heat being intermittently supplied to the fiber material by means of circulated air under excess pressure and then residual moisture is evaporated from the fiber material by connecting the vacuum pump and is removed to the vacuum pump. The circuit line with the heater and the circulation device on the one hand and the branch line with the vacuum pump on the other hand can thus be connected or shut off alternately, however, this method of operation does not enable the method according to the invention, in which, in the interest of rapid drying, the fiber material flows continuously with superheated steam and thereby a proportion of steam is derived to the vacuum pump.

The known device is modified according to the invention in such a way that the branch line is provided with a pressure regulating valve for regulating the negative pressure applied by the vacuum pump in the circuit line.

This measure creates the possibility to flow exclusively through the fiber material during the final drying and at the same time to branch off a portion of the cycle steam to the vacuum pump.

Expedient refinements and developments of the device consist in the fact that the continuous-flow heater is a steam-operated heat exchanger, that a continuous-flow cooler is installed in the branch line, which is a water-operated heat exchanger that enters the circuit line behind the container and in front of the branch line to the vacuum pump Drainage tank with a liquid drain is installed and that the branch line is connected to the circulation line behind the circulating device and before the instantaneous water heater.

An embodiment of the invention is explained below with reference to a schematic drawing of a plant for dyeing and drying textile material.

The system shown has a container 1 with a lid 2, an inlet 3 for treatment liquid, an outlet 4, a connection 5 for introducing a drying medium and a nozzle 6 for connecting compressed air. Furthermore, the fiber material to be treated, for example yarn in the form of a cheese 7, is shown in the container 1. The container 1 is formed in a known manner and the fiber material 7 is arranged such that there is a flow connection between the inlet -3, the connection 5 and the nozzle 6 on the one hand and the outlet 4 on the other hand only through the fiber material 7.

The outlet 4 is connected via an outlet line 8 to the inlet connection 9 of a dewatering container 10 with a lower liquid outlet 11 and an upper gas outlet 12.

A line 13 extends from the gas outlet 12 and is connected via a changeover valve 14 either to the suction line 15 of a blower 16 or to a bypass line 17 bypassing the blower 16. A blower is on the blower 16 Line 18 connected, in which the bypass line 17 opens.

The blow line 18 leads via a connecting line 19 to a continuous-flow heater 20, which is designed as a steam-heated heat exchanger, to which a heating steam feed line 21 and a condensate drain 22 are connected.

The flow path through the continuous-flow heater 20 which continues the connecting line 19 is connected to the connection 5 of the container 1 via a supply line 23. A live steam feed line 24 opens into the feed line 23 and can be shut off via a shut-off valve 25.

According to the above description and the illustration, the lines 8, 13, 15, 18, 19 and 23 form a circuit line 26 into which the container 1, the dewatering container 10, the blower 16 and the water heater 20 are switched on.

A branch line 27 is connected to the circuit line 26 or its blow line 18 and is connected to a vacuum pump 31 via a flow cooler 28 with a cooling water inlet 29 and a cooling water outlet 30. A pressure control valve 32 is installed in the branch line 27 between the circuit line 26 and the flow cooler 28. This can be set to a desired negative pressure, which is then maintained in the circuit line 26 by means of the vacuum pump 31. Because of the flow resistances within the circuit line 26, of course, the same negative pressure does not exist at all points in the circuit.

• Zunächst wird das Fasermaterial 7 in den Behälter 1 eingebracht, der daraufhin mittels der Vakuumpumpe 31 evakuiert wird. Dann wird über den Zulauf 3 Färbeflotte in den Behälter 1 eingeführt. Die Einwirkung der Färbeflotte auf das Fasermaterial 7 kann durch Zirkulation der Färbeflotte durch das Fasermaterial 7 hindurch in bekannter Weise erhöht werden. Auch kann mit pulsierenden Druckstößen gearbeitet werden, die beispielsweise über den Stutzen 6 aufgebracht werden können. Mittels in den Behälter 1 einströmender Druckluft kann die Färbeflotte nach der vorgesehenen Einwirkungszeit aus dem B_e- hälter 1 herausgedrückt werden oder auch zum Entwässerungsbehälter 10 und dessen Flüssigkeitsaustritt 11 ablaufen. In entsprechender Weise wird das Fasermaterial 7 gewaschen, wozu das Waschwasser über den Anschluß 3 in den Behälter eingeleitet werden kann. Ggf. werden mehrere Färbevorgänge und/oder Waschvorgänge durchgeführt.

With the system described above, textile fiber material can be dyed and dried in the following way:

• First, the fiber material 7 is introduced into the container 1, which is then evacuated by means of the vacuum pump 31. Then 3 dye liquor is introduced into the container 1 via the inlet. The action of the dye liquor on the fiber material 7 can be increased in a known manner by circulation of the dye liquor through the fiber material 7. It is also possible to work with pulsating pressure surges which can be applied, for example, via the nozzle 6. Inflow means in the container 1 the compressed air, the dye liquor after the intended time of exposure of the B _e - are pressed out container 1 or to the drainage container 10 and drain the liquid outlet. 11 The fiber material 7 is washed in a corresponding manner, for which purpose the washing water can be introduced into the container via the connection 3. Possibly. several dyeing operations and / or washing operations are carried out.

After washing, the fiber material.7 is dried in the container 1. This drying is carried out in two stages by first performing mechanical dewatering and then thermally drying. In both cases, a vacuum which promotes drying is maintained in the container 1 by means of the vacuum pump 31.

For mechanical dewatering, steam and / or compressed air are introduced into the container 1 via the live steam supply line 24 or the nozzle 6. These media remove moisture from the fiber material 7 in the form of entrained droplets. This moisture is separated in the dewatering container 10 or flows with the corresponding position of the switch valve 14 via the bypass line 17 and the branch line 27 to the vacuum pump 31, whereby in the case of dewatering by means of air a separation as well as a condensation takes place if steam is used as a mechanical dewatering medium . The steam supplied via the live steam feed line 24 not only has a mechanical dewatering effect but also, if appropriate, in connection with a partial condensation in the fiber material 7, a preheating of the fiber material and the residual moisture still remaining in it.

The subsequent finished drying is a thermal drying in which the fiber material 7 flows through with steam and is heated in coordination with the negative pressure applied by means of the vacuum pump 31 such that the residual moisture evaporates. The steam produced in the fiber material 7 is circulated through the circuit line 26 when the changeover valve 14 is in the position shown and the fan 16 is running, this steam being overheated in the water heater 20. This leads to further evaporation of residual moisture, and a corresponding proportion of steam is removed from the circuit via branch line 27 and discharged to vacuum pump 31. The pressure control valve 32 causes this vapor portion to be transferred to the vacuum pump. It is possible to influence the course of the finished drying in the course of the drying time by changing the setting of the pressure control valve 32 and the heat supply in the continuous-flow heater 20 in order to adapt to the degree of drying of the fiber material 7 and to dry the fiber material 7 just as quickly and gently to reach.

It can be seen that the finished drying can be carried out entirely without the supply of live steam, so that the live steam supply line 24 with the shut-off valve 25 and also the bypass line 17 with the changeover valve 14 may be omitted; because by means of the vacuum pump 31 residual moisture can already be evaporated from the fiber material 7 at the beginning of the finished drying, this steam can be circulated through the circuit line 26 by means of the blower 16 and heat is transported from the water heater 20 to the fiber material 7.

The system shown and described corresponds to a test system which is intended to do so within 30 minutes Drying 2 kg of yarn containing 2.5 kg of water. A flow heater 20 of 2.5 m ² heat exchanger area is provided. The blower 16 is for a conveyance of 8 m3 / min. and a pressure difference of 0.1 bar. The cycle steam has a density of 0.3 kg / m ³ , a pressure of 0.5 bar and a temperature of 80 ° C.

In another design, the fan 16 delivers 17.5 m3 / min. under a differential pressure of 0.1 bar. The density is 0.13 kg / m ³ , the pressure is 0.203 bar and the temperature is 60 ° C.

The above information is naturally exemplary and can be varied within wide limits.

Claims (10)

1. A method for drying fiber material or the like., In particular following a liquid treatment such as dyeing the fiber material and while the fiber material remains in the treatment tank, in which the fiber material optionally first flows through with air and / or steam for mechanical dewatering to a residual moisture content and drying is carried out with the application of a vacuum and the introduction of steam, the moisture removed from the fiber material being discharged to the vacuum pump, characterized in that during the final drying, exclusively and superheated steam is passed through the fiber material, which supplies the heat required to evaporate the residual moisture and with the residual moisture evaporated from the fiber material. 2. The method according to claim 1, characterized in that the steam in the circuit is passed through the fiber material and an intermediate superheater, a steam fraction corresponding to the formation of steam from residual moisture being drawn off from the circuit to the vacuum pump. 3. The method according to claim 2, characterized in that the steam portion is drawn off at a point in the circulation direction behind the fiber material and the circulation device and in front of the reheater to the vacuum pump. 4. The method according to claim 2 or 3, characterized in that the steam portion is drawn off to the vacuum pump via a pressure control valve which opens when the pressure rises in the circuit. 5. Device for carrying out the method according to claims 2 to 4 with a receptacle (1) through which the fiber material (7) can flow, a circuit line (26) into which the container (1), a circulating device (16) and a water heater (20) are installed, and a branch line (27) connected to the circuit line (26) with a vacuum pump (31) and possibly a condenser (28) and possibly a live steam supply line (24) opening into the circuit line (26), thereby characterized in that the branch line (27) is provided with a pressure regulating valve (32) for regulating the negative pressure in the circuit line (26) applied by the vacuum pump (31). 6. The device according to claim 5, characterized in that the flow heater (20) is a steam-operated heat exchanger. 7. Apparatus according to claim 5 or 6, characterized in that a continuous cooler (28) is installed in the branch line (27). 8. The device according to claim 7, characterized in that the flow cooler (28) is a water-operated heat exchanger. 9. Device according to one of claims 5 to 8, characterized in that in the circuit line (26) behind the container (1) and in front of the branch line (27) to the vacuum pump (31), a dewatering container (10) with a liquid drain (11) is installed. 10. Device according to one of claims 5 to 9, characterized in that the branch line (27) behind the circulating device (16) and before the water heater (20) is connected to the circuit line (26).

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