DE2156100B2 - THIN DRYER - Google Patents

Description

The invention relates to a nozzle dryer for moving webs with at least one as a slot nozzle formed air nozzle on at least one side of the web, in which the nozzle mouth on one side runs out into a nozzle lip, which is guided over a greater length parallel to the web.

Such a nozzle arrangement can be found in DT-PS 6 94 088, for example. At the one there described device for drying a paper or fabric web printed with gravure printing ink, over the printed side of which is blown with cold, warm or otherwise prepared air or over them sucked away, the procedure is that the web to be dried one or more consecutively Negative pressure zones created by sucking off the air and then one or more by inflating passes through overpressure zones generated by compressed air, which are closed off from the negative pressure zones.

Thus, in the device according to the DT-PS

6 94 088 took advantage of the fact that in the zone of negative pressure the paint solvent vapors were loosened and also are partially discharged and in the subsequent zone through the overpressure on the web The blown air is easily torn away from the surface of the printed ink and allowed to continue.

Furthermore, DT-OS 14 60 687 describes a heat treatment chamber for flat goods, especially textiles, with a cross-flow fan as a circulation device known for a gaseous or vaporous treatment medium in which the outlet of the fan opens directly on the material to be treated and where the treatment medium is tangential to this slides along and is optionally kept turbulent by vortex elements in the area of the goods.

Furthermore, from the journal "Proceedings of the third International Heat Transfer Conference", August

7-12, 1966, Chicago, Illinois papers 41-80, volume II,

Pages 274 to 278 an investigation into the heat transfer between an isothermal surface and a two-dimensional wall beam known, in the case of a beam that is on the one hand through free

■ Mixture spreads and on the other hand of a solid Wall is limited, the local heat transfer coefficients are determined under different flow conditions became. In the arrangement described there, a gas flow hits the surface approximately perpendicularly

ι which the heat transfer should take place, and is then deflected by about 90 ° through a nozzle slot guided essentially parallel to the surface to be treated. From the curves shown there the local heat transfer coefficients result

■ at a distance from the point of impact of the vertically fed Air jet, regardless of the gas velocity and thus the Reynolds number and the in each case used nozzle a first maximum of the heat transfer coefficient when entering the

ι narrow slit and a second maximum just behind the exit from the nozzle slot. Even with large Reynolds numbers, the length of the Slit itself starting with the first maximum a sharp decrease in the heat transfer coefficient to observe. The investigation there, however, only focuses on the heat transfer coefficient received, without possible mechanical effects of the impinging air jet on the to be treated Area to be taken into account, as is the case with a

> Moist paper web can occur.

Namely, in the paper industry and the printing industry, the problem arises while avoiding one physical contact with the wet paper or with the fresh printing ink ensures effective drying

ι to perform without the risk of deformation the surface of the web to be dried.

The object of the invention is therefore to provide a nozzle dryer for moving webs of the type indicated above Kind to improve so that the heat transfer at

ι the same power consumption of the nozzle dryer increased or with the same heat transfer, the required power can be reduced without the risk there is a deformation of the moving web, for example by fluttering.

The solution according to the invention consists in providing a nozzle dryer as described in the preamble of the main claim designated type so that the length of the nozzle lip is 40 to 90 times the width of the Is nozzle slot and that the air throughput through the slot nozzle is so large that in the space between Nozzle lip and orbit set a flow with a Reynolds number from 4000 to 8000.

For the features specified in the main claim, protection is only claimed in their entirety.

In a further embodiment of the invention, the length of the nozzle lip is 60 times the width of the The nozzle slot and the distance between the web and the nozzle lip corresponds approximately to the width of the Nozzle slot, so that at an exit speed of the air from the nozzle slot of approximately 4300 m / min there is a flow with a Reynolds number of 5000 in the space between the nozzle lip and the path up to 7000.

It is particularly advantageous if the nozzle lip ends in a sharp edge.

With the nozzle dryer according to the invention, it is possible in an advantageous manner with a given input power of the dryer a maximum drying effect

achieve without undesired wave formation occurring on the webs to be treated.

The invention is intended in the following with the aid of exemplary embodiments and with the aid of the drawings are explained in more detail. The drawings show in

pig. 1 is a schematic plan view of a dryer with above and below the to be dried Nozzles arranged in the path,

pig. 2 is a schematic side view of such a device Dryer,

Fig. 3 is a graphic representation of the power requirement for different Reynolds numbers and different L / D ratios,

FIG. 4 shows an enlarged section through an air nozzle along the line 4-4 of FIG Representation of the air flow between the nozzle and the web and in

FIG. 5 shows a view similar to FIG. 4 for reproducing a preferred embodiment Use in the arrangement according to FIG. 1.

In Figs. 1 and 2 of the drawing, a web 1 is shown reproduced horizontally through a drying zone from a roller 2 to a take-up roller 3 runs, with a plurality of air nozzles 4 is arranged above and below the web. Each air nozzle 4 contains an air chamber 5 which extends across the full width of the web 1 and closed ends and a central inlet channel 6.

The various nozzles 4 extend over the full width of the web and can be in any desired Be spaced so that a gap remains between two adjacent nozzles, the is larger than the width of a nozzle, so that alternating arrangement of the nozzles above and below the path the control of the path is possible and an immediate disturbance between the on the air currents impinging on opposite sides of the web is avoided.

The air chamber 5 of each air nozzle 4 has, according to the illustrated embodiment, one in general rectangular cross-section with an outlet opening in the form of a slot 7, which extends over the full Length of the chamber extends from one edge to the other.

The slot 7 is between an inwardly bent flange 8 which acts as a nozzle lip Surface 9 of the chamber 5 and an inwardly curved angled nozzle plate 10 formed, which the adjacent Edge part of the corresponding side 11 of the chamber 5 forms.

The plate 10 is generally tangential to the curved surface of the nozzle flange 8, without Consider the space of the slot 7 between them.

The surface 9 of each chamber 5 is flat and extends parallel to the general plane of the web 1 below Leaving an intermediate space 12 which corresponds approximately to the width of the nozzle slot 7.

The optimal ratio of the total free-hanging length of the area 9 in Direction opposite to the web movement to the slot width to achieve more favorable drying of the Track with minimum power and at air speed p, on the order of about 5000 m / min is generally approximately 60.

The practical width of the slot 7, which generally corresponds to the space 12, should be in Range from 1 mm to 3.2 mm.

The Dractic horsepower that is required to generate the necessary air flow is between 3 PS / m- 'to 8 PS / m' of the track in the Yrockenzone.

In general, within practical limits, the higher the temperature of the nozzle incoming air, the lower the power for a given velocity of the flow of pleasure in It has to be in contact with the web, but the higher the efficiency for a given drying effect is required.

In general, in the working area of the system, the greater the length of the nozzle lip Area 9 in the direction of orbital movement for a given distance, the less power for a given drying effect is required.

The air emerging through the nozzle slot 7 flows in a laminar flow along the curved one Surface of the nozzle edge flange 8 until it reaches the flat surface 9 of the air chamber 5.

The air continues to flow in a turbulent flow between the surface 9 and acting as a nozzle lip of the web 1 and in contact therewith in a direction opposite to the direction of travel of the web through the dry zone.

After the air has passed the edge of the surface 9 acting as a nozzle lip opposite the curved surface Has reached nozzle flange 8, it flows away from the web 1, losing its pressure and is out of the Dryer discharged through suitable devices not shown.

If the rear edge of the surface 9 acting as a nozzle lip in the running direction of the web is sufficient is rounded to create a Coanda effect, the air follows the curvature, as shown in Figure 4 and tries to lift the web upwards in a wavy pattern, which in a dryer with multiple nozzles on each side of the web results in the desired planar movement of the web and the Control of the web will be disturbed by the next following air nozzle on the other side.

This difficulty can be avoided by using a sharp edge 13 on the rear edge the surface 9 acting as a nozzle lip, as shown in FIG. 5 is reproduced. This creates the Coanda effect essentially avoided.

With a sharp trailing edge 13, the air tends to to follow the web 1 when they have the space 12 between the surface 9 acting as a nozzle lip and the web 1 leaves.

The next adjacent air chamber 5 with a nozzle slot 7 is a bit from the rear edge 13 removed that is substantially larger than the width of the air chamber, by an even gap to create, through which the air exiting at high speed over the edge 13 from the Dry zone can be peeled off.

On its way over the space 14 between two adjacent nozzles 4, the web 1 is passed through a nozzle 4 guided on the other side of the web, as determined by the alternating arrangement of the nozzles.

The air exiting under the rear edge 13 enters the space 14 and releases the web 1, so that it is then excluded from the position control through the air nozzle on the other side of the web.

The turbulent flow of the air in contact with the web 1 and the surface 9 leads to a Heat transfer to the web, which causes an evaporation of moisture from the web with high

r.

Speed.

In general, the power required for a given heat transfer or drying effect depends on the Reynolds number to represent the turbulence and the L / D ratio, where L is the length of surface 9 in the direction of web movement and D is the distance between surface 9 and the Lane 1 mean.

The graph according to FIG. 3 of the drawings shows the L / D ratio on the abscissa and the mass flow rate or power requirement on the ordinate for two Reynolds' numbers in curves A and B, showing the most practical range for the application of the invention. Curve A applies to a Reynolds number of 10,000 and curve B to a Reynolds number of 5000.

From the curves it can be seen that the most favorable conditions for the lowest power consumption with an L / D ratio between about 40 and 100 with a Reynolds number are generally below 10,000. For a Reynoldsian Number of 4000, the lowest power is required with an L / D ratio of around 65.

It is beneficial to keep the COP below 3.00, since the efficiency drops rapidly with increasing power consumption. Expressed in horsepower per m ^{2 of} power consumed, the value should in practice be between 3 and 8.

In the depicted air nozzle, there is a loss of air velocity immediately after leave the slot in the size range of about 300m / min for every 1.6 mm along the length of the run curved nozzle until the air reaches the space 12 between the web and the flat surface 9 where it becomes turbulent and continues on the other side of the air chamber 5.

The turbulent air impinges on the web 1 and releases heat from the web when it absorbs moisture away. In this process, the air cools down and loses speed as it moves out of the room 12 moved in the direction of the trigger.

The optimal air speed at the nozzle slot 7 is generally above 7900 m / min, although below under other favorable conditions, a speed of 1000 m / min can also be satisfactory.

The exact slot width is mainly a matter of practical consideration of what is required L / D ratio and the available air velocities.

When designing a dryer, several factors are dictated, such as, for example Speed of the web, the approximate amount of moisture to be removed from it, the general Space requirements for the dryer, the available capacities, the available air speeds and the possibilities for heating the air to the desired working temperature.

Once the initial conditions have been determined, it is possible to use a simple formula to determine the approximate numbers and sizes of the air nozzles required, the most favorable Reynolds number and the distance L for the surface 9 and the width D for the slot.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Nozzle dryer for moving web with at least one air nozzle rented out as a slot nozzle on at least one side of the web, in which the nozzle mouth runs out on one side into a nozzle lip which is guided over a greater length parallel to the web, characterized in that the length (L) of the nozzle lip is 40 to 9C times the width (D) of the nozzle slot and that the air throughput through the slot nozzle is so great that a flow with a Reynolds number of 4000 to 8000 is established in the space between the nozzle lip and the web. 2. Nozzle dryer according to claim 1, characterized in that the length (L) of the nozzle lip is 60 times the width (D) of the nozzle slot and that the distance of the web from the nozzle lip of the width (D) of the nozzle slot corresponds approximately, so that at At an exit speed of the air from the nozzle slot of approximately 4300 m / min, a flow with a Reynolds number of 5000 to 7000 is established in the space between the nozzle lip and the web. 3. nozzle dryer according to claim 1 or 2, characterized in that the nozzle lip in one sharp edge ends.