FR2627264A1 - Drying plant for textiles etc. - has separating and flow control system for exhaust air to recycle major portion of air to heating equipment for re-use - Google Patents

Abstract

At least part of the heated air produced by the plant is recycled to pass through the heating assembly (7) of the plant. The plant includes an extractor fan (4) whose turbulent exhaust flow is divided to form two linear flows. The larger of the two linear flows is passed via a valved conduit (9) back to the heating equipment. The smaller flow, controlled to be the minimum necessary to remove drying vapours, is passed via another valved conduit (10) to atmosphere. ADVANTAGE - Reduced heat loss to atmosphere.

Description

PROCESS FOR MINIMIZING LOSSES
OF THERMAL ENERGY ON AIR REJECTED BY
DRYING FACILITIES AND INCREASE PRODUCTIVITY
OF THESE FACILITIES AND FACILITIES IMPLEMENTING
THIS PROCESS.

 The present invention relates to a method, as well as the installations implementing it, making it possible to minimize the losses of thermal energy on the air discharged by the drying installations and the permanent recycling on these devices, in partially open circuit, air they use as thermal fluid and / or for the evacuation of the drying steam they produce.

 In the following description, the invention will be more particularly described in the case of installations used for drying textile articles, (for example an installation comprising a rotary drum drier), and which reject large quantities of hot air and therefore exhibit very poor thermal performance. It is obvious that the invention is not limited to this particular application, but that it could be implemented in other technical fields where similar problems arise.

 In the field of laundering of textile articles, the drying operations use large quantities of air which, after raising to the necessary high temperatures, are discharged outside at barely lower temperatures. Under these conditions, in addition to the thermal energy absorbed by the change of state from water to vapor, such installations consume in pure loss the thermal energy contained by the exhaust air. This thermal energy lost on the necessary air is often two to four times greater than that useful for the only change of state from water to vapor. This is more particularly the case, without this observation being limiting in the application. of the present invention, when laundry is dried using rotary drum dryers, apparatuses through which the ambient air is sucked in and passes successively over a heating coil and then through the mass of linen, moving in a rotating drum , leaving it by convection a very small part of the heat supplied in the heating coil, heat which allows drying. The air is rejected by an exhaust fan to the outside of the installations with all of it (excluding radiation losses ) of the heat supplied by the heating coil, at a high temperature (900C on average), i.e. approximately 75% of this heat on the air, resulting in a significant loss of energy, and approximately 25% contained by r the heat of evaporation of the water in the dried laundry (sensible heat + latent heat).

 In order to limit these significant losses of thermal energy, it has been proposed to preheat the necessary fresh air by circulating it, against the current, through an exchanger (tubular or plate or wheeled) heated by air. extraction, but such a device is bulky and has a low efficiency.

 It has also been proposed to recover the heat (sensitive and latent) discharged by such devices by treating the air and the vapor which they reject in exchangers of various types heating cold water. However, given the large volumes of air used and necessary for convection, such exchangers have significant powers, the losses on the exhaust air remaining high. Their size and cost are also high and if such exchangers make it possible to use the rejected heat to produce hot water (for example), they do not make it possible to reduce the significant thermal energy needs of these devices, needs driven to approximately 75% by the losses on the 'hot air rejected, The use of such exchangers therefore does not lead to a reduction in the unit heat requirements of these devices.

 Finally, it has been proposed to permanently recycle part of the extracted hot air on the heating coil of these devices and to reject only the other part, in order to reduce the energy lost on the air. This attractive solution due to its simplicity, however, has a major drawback in that the devices offered to date do not allow precise adjustment of the volumes recycled and rejected, which still results in large volumes of hot air being rejected. and still poor performance in terms of the thermal energy requirements of these devices and their drying times.

 The present invention relates to an improvement made to this latter method which makes it possible to solve these problems.

 In general, the method according to the invention consists in continuously recycling on the appliance's heating coil at least a majority of the hot air extracted and it is characterized in that, at the outlet of the fan extraction, the flow of hot air discharged in turbulent regime is subdivided into two linear elementary flows with the minimum of turbulence, one, the most important, being recycled directly to the heating coil, the other, very minor , having a flow rate set to the minimum necessary for the evacuation of the drying vapors, means for adjusting the flow rate being provided on the two conduits for circulation of the two flows.

 If the minority part of the air can be discharged to the outside with the steam produced by the drying, it can possibly be envisaged to recycle this part of air also on the heating assembly of the installation, after condensation of the drying vapor contained by this minority party through an exchanger.

 Such a method makes it possible to have a rigorous adjustment of the two air flows and to minimize the quantity of air rejected, without loss of the flow passing through the device and necessary for the transmission of heat by convection of the air at product (laundry) to dry.

 Such a process allows the reduction of more than 90% of the volume of exhaust air compared to that necessary for convection drying and therefore a thermal energy saving of 90% on the energy lost compared to sensible heat. total necessary to air used. It thus becomes possible to use more powerful exhaust fans and thus increase the air speeds, therefore the exchange powers by convection and reduce the drying times and energy consumption.

The recycled air penetrates through the heating coil without appreciable loss of temperature, the energy saving on the air is further increased and it
results, at least 90% of the same air mass compared
port to the total air used being recycled per
manence, a very large increase in temperature
of air at the outlet of the heating coil and
shorter drying time due to increased
corresponding to the temperature differential as well
entrained between the air and the water to be evaporated contained by the machine, hence a significant saving in the unit rate
radiation losses from the device, these losses
being proportional to the duration of the operation or any
simply at the unit drying time.

This increase in temperature of the outgoing air
of the heating coil causes an increase of
temperature at all points of the installation and, from
this fact these temperatures are higher than those of
condensation of the drying steam produced.

The drying steam is constantly evacuated
the ratio between the gas volume (air +
steam) evacuated and that recycled on the device.

Incidentally, by reducing in large propor
the air volumes released by the
drying outside the premises, air requirements
local costs are also reduced, resulting in savings
heating in the cold season and better control
air conditioning in summer.

The invention also relates to the installations making it possible to implement such a method, method
which, as said before, reduces to a minimum
mum the volume of hot air exhausted outside by
drying apparatus, minus the volume of va
fear of drying mixed with this air, which consists in continuously recycling iodine, during the drying operation, the greatest possible amount of the volume of air expelled from the device by its exhaust fan on its heating coil. The installations thus designed are characterized in that they comprise, downstream of the exhaust fan, means making it possible to divide into two elementary flows of linear regime, the flow of hot air rejected in turbulent regime, one, the more important, being recycled directly on the heating coil, the other, minority, having a flow reduced to the minimum necessary for the evacuation of the drying steam, these means being essentially constituted by two ducts of different section, arranged downstream of the installation's extraction fan, these two ducts being arranged in parallel and one inside the other over part of their length, at least one of the ducts being connected to an associated distribution box é to the heating assembly and making it possible to convey a majority of the extracted air, the other, by means of which the remaining part of the extracted air and vapor is evacuated, being associated with the preceding of so that the air flow inside these ducts is carried out in linear mode, manual or automatic adjustment means (flaps) being provided inside each of the circuits.

Advantageously and in practice, according to the invention
- one of the two ducts at the outlet of the extractor has a smaller section than the other and is positioned inside the duct of larger section
- The two ducts are, at the outlet of the extractor, straight and parallel to each other along a length sufficient to establish in this zone a linear regime of air passage;
- one of the two sheaths crosses the other after the zone described above, when one of these sheaths is positioned inside the other
- the sheath used for the direct recycling of the hot extract air opens into a distribution and distribution box of hot air recycled on the heating coil
- the two ducts open out inside a distribution and diffusion box of hot air on the heating coil, this box comprising compartments so that the air and the vapor rejected by the second duct are treated by a condenser exchanger allowing a lowering of temperature and a sufficient dehydration of the air rejected in this case, the hot air recycled directly without passing by the exchanger is recycled on the heating coil by the compartment of the box having the most large section and the air leaving the exchanger through the other small section compartment
- the recirculation and distribution box of the recycled air on the appliance's heating coil is not tightly mounted therewith; on the contrary, a slight space is reserved between the external heating surface of said box and the suction surface of the battery in order to allow, if necessary, cleaning the latter surface but also and above all, on the periphery of this surface, the contributions of fresh ambient air if necessary.

The invention and the advantages which it brings will however be better understood thanks to the exemplary embodiments given below for information but not limitation and which are illustrated by the appended diagrams in which
- Figures 1 and 1a, 2 and 2a illustrate two embodiments of an installation allowing the implementation of the method according to the invention and in which a majority of the air is recycled to the heating coil, l the other part being, for its part, evacuated outside;
- Figure 3 illustrates a variant in which the two air circuits are recycled to the heating coil.

 If reference is made to the appended diagrams and more particularly to FIGS. 1 and 2, the method according to the invention is therefore implemented on a drying installation, designated by the general reference (1) and which comprises, an enclosure ( 2) inside which the material to be dried is placed (for example arranged inside a drum (3). With this enclosure (2) is associated an extraction fan (4), also designated in the present description by the expression "extractor", which puts the device under vacuum and ensures the circulation of hot air through the material to be dried.

The air extracted by the fan (4) is discharged through a duct.

 In accordance with the method according to the invention, at the outlet of the installation, downstream of the fan (4), the flow of hot air discharged in turbulent regime is subdivided into two elementary linear flows having the minimum of turbulence, one of which , the most important, is recycled directly to the heating coil (7) of the installation. This is obtained, in accordance with the invention, by providing downstream of the extractor (4) (fan) an assembly comprising two sheaths (5,6), appearing to be parallel and of different section. These two ducts (5,6) are nested one inside the other over a length (L) sufficient to establish in this zone a linear regime of air passage. One of the ducts allows the direct recycling of the hot air extraction and opens inside a distribution box (8) and diffusion of hot air recycled on the heating coil (7). The other duct allows either to reject the minority portion of air with the steam produced by drying outside the installation, or possibly, to recycle this portion of air also on the heating assembly of the 'installation after condensation of the drying steam contained in this minority part by passage through an exchanger (see Figure 3).

 In the embodiment illustrated in FIGS. I and 1a, the exhaust duct (6) of small dimension, arranged concentrically inside the duct (5), allows the evacuation of the minor part of the air. The recycling of hot air to the heating coil (7) is obtained by a conduit (5a), which opens into the interior of the conduit (5) downstream of the zone L. This conduit (5a) opens to the 'interior of a distribution box (8) for recycling the air extracted from the heating coil (7).

 In the second exemplary embodiment illustrated by FIGS. 2 and 2a, the recycling circuit is obtained by the conduit (6) which crosses the conduit (5) downstream of the zone L and also opens out inside the distribution box. (8). The minority part of the extracted air is evacuated by a duct (5b) arranged in the extension of the duct (5) and which is of smaller section.

 In these two exemplary embodiments, adjustable flaps (9, 10) are provided inside each of the circuits to adjust the air flow rates and have a linear speed.

 Optionally, as can be seen from the diagram illustrated in FIG. 3, the two conduits allowing the circulation of the two flows can open out inside the distribution box (8). The latter is then produced in two parts so that the air and the vapor rejected by the circuit carrying the minority flow are treated beforehand in a condenser exchanger (11) allowing a lowering of temperature and a sufficient dehydration of the rejected air. .

The main air flow is recycled directly by the compartment (12) of the box (8) having the largest section, while the air leaving the exchanger (11) is recycled by the other compartment (13) of lower section.

 In all the embodiments, it is preferable that the box (8) for diffusing and distributing the recycled air on the heating battery (7) of the device is not mounted in leaktight manner with the latter. This can be achieved, as illustrated in the diagrams, by providing a slight space between the external heating surface of the box (8) and the suction surface of the battery (7). This not only makes it possible to clean the battery, but also and above all, ensures the supply of fresh ambient air that may be necessary.

 Compared to previous solutions, the method according to the invention, as well as the installations allowing its implementation, has many advantages. In fact, most of the air necessary for the drying apparatus being the hot exhaust air continuously recycled on the heating coil, this mass of air is practically the same and its temperature is raises quickly in all points of the installation, particularly in the drying apparatus, which results in a large increase in temperature differences between the liquid to be evaporated and the hot drying air without requiring a higher temperature for the battery heating. This rise in temperature results in a faster heat exchange between the hot air and the liquid to be evaporated, therefore faster drying.

 Furthermore, this high drying air temperature, rapidly close to that of the heating coil, becomes higher than that of condensation of the recycled drying steam until the end of drying, thus, no condensation results from recycling with the hot air from part of the drying steam.

 Furthermore, the volume of air discharged onto the appliance and not recycled directly to the heating coil is reduced to a minimum and is adjustable at will. The unit energy consumed is therefore the most reduced since it is equal to that necessary for the total heat d 'evaporation plus the sensible heat on the non-recycled air plus the unit losses by radiation from the installation which are reduced due to a shorter drying time.

 Finally, in applications other than the drying of textile articles, for example in the case of drying wood, the method according to the invention also has additional advantages. In fact, in such a case, the proportion of drying steam recycled on the drying apparatus with hot air increases the speed of the heat exchange necessary for drying and also promotes the phenomena of osmosis which also increase this speed and avoid surface desication of the permeable fibers and, consequently, their subsequent bursting during operation under the effect of internal vapor pressure.

 Of course, the invention is not limited to the embodiments described above but it covers all the variants produced in the same spirit. Thus, if in the above examples, the two conduits (5,6) are arranged concentrically, this is not imperative and another arrangement could be adopted insofar as it makes it possible to obtain a linear flow of the flows . Thus, one could provide a shift of the conduits relative to each other, or even make them tangent or have at the limit a partitioning. Likewise, the cross section of the conduits is not necessarily circular. Furthermore, the two conduits (5,6) can be mounted so that the interpenetration distance L is adjustable.

Claims (6)

 1 / A process making it possible to minimize the losses of thermal energy on the air discharged by the drying installations and to increase the productivity of these installations, which consists in continuously recycling on the heating battery (7) of the appliance (1) at least part of the extracted hot air, characterized in that, at the outlet of the exhaust fan (4), the flow of hot air discharged in turbulent regime is subdivided into two linear elementary flows having the minimum of turbulence, one, the most important, being recycled directly to the heating coil (7), the other, very minor, having a flow rate set to the minimum necessary for the evacuation of drying vapors, means for adjusting the flow being provided on the two conduits for circulation of the two flows.  2 / A method according to claim 1, characterized in that the minority of air is discharged to the outside with the steam produced by drying.  3 / A method according to claim 1, characterized in that the two air flows are recycled to the heating assembly (7) of the installation.  4 / Installation for the implementation of the method according to one of claims 1 to 3, characterized in that it comprises, downstream of the extraction fan (4) means for dividing into two elementary flows of linear regime , the flow of hot air rejected in turbulent regime, one, the most important, being recycled directly to the heating coil (7), the other, a minority, having a flow reduced to the minimum necessary for the evacuation of the drying steam, these means essentially consisting of two ducts (5,6) of different section, arranged downstream of the extraction fan (4) of the installation (1), these two ducts (5,6) being arranged parallel and one inside the other over a part (L) of their length, at least one of the sheaths being connected to a distribution box (8) associated with the heating assembly (7 ) and allowing a majority of the extracted air to be transported, the other, through which the part is evacuated ie the remaining extracted air and vapor, being associated with the previous one so that the air flow inside these ducts is carried out in linear mode, adjustment means (9,10) (flaps ) manual or automatic, being provided inside each of the circuits.  5 / Installation according to claim 4, characterized in that the two circuits carrying the two elementary flows open into a box (8) for distributing and diffusing the hot air on the heating coil (7) .  6 / Installation according to one of claims 4 and 5, characterized in that the box (8) for diffusing and distributing the recycled air on the heating coil (7) of the installation is mounted in a leaktight manner with it.