EP1050618A1 - Heat exchanger for laundry drier - Google Patents

Abstract

The plate ends which are surrounded by the gas current are dislocated in relation to each other in the manner of steps. The dislocation is selected in such a way that the gas current is applied to the heat exchanger plates (2) in accordance wi their heat exchange performance.

Description

The invention relates to a heat exchanger with a plurality of heat exchanger plates arranged one above the other for a gas stream in a household clothes dryer where the gas stream immediately in front of and / or behind the heat exchanger plates at an angle to their level runs.

There are tumble dryers or washer dryers which operate on the condensation principle work in which the laundry to be dried is in contact with one particular heated process gas stream or process air stream is brought to the Absorbs moisture from the laundry. This process gas stream is then in one Cooled heat exchanger, whereby the moisture contained in the process gas condenses and can be dissipated. The dried process gas is then usually again warmed and again led to the laundry to be dried.

The process gas stream in the tumble dryer is usually not exclusively straight, but because of the structural conditions in the device it is also angled or curved. This is particularly disadvantageous when or shortly before entering the heat exchanger. Due to the curved process gas flow occur in particular, but also behind Heat exchanger plates have adverse flow losses, which include energy consumption increase. In addition, it can happen that the gas flow after a Curvature is distributed unevenly in its guidance over the cross section. The heat exchanger plates of the heat exchanger can be caused by an uneven distribution of the Gas flow are applied unevenly, which results in the achieved heat exchange performance is reduced.

From DE 196 44 711 A1 a clothes dryer is known, in which in a curved Gas channel are arranged in front of the heat exchanger flow guide, which is the gas channel divide into individual flow spaces in the direction of flow and thus the gas flow at Output of the gas channel or at the input of the heat exchanger via the Equalize cross-section. The heat exchanger should be better used in this way become. The required flow guide and their attachment in front of the heat exchanger however, represent an additional expense that disadvantageously affects the manufacturing costs elevated.

The invention has for its object a heat exchanger of the aforementioned To create a way in which the flow loss of the gas stream is reduced and the heat exchange performance is increased and can be produced easily and inexpensively.

According to the invention, this object is achieved in that ends around which the gas stream flows the heat exchanger plates are arranged offset in steps. Both Gas flow ends of the heat exchanger plates at the inlet and at the outlet of the heat exchanger may be arranged offset in steps, but with a step-like offset at the inlet of the heat exchanger a much greater reduction the flow resistances and better control of the distribution of the gas flow leaves. Nevertheless, a step-like offset at the outlet of the heat exchanger can also occur contribute to a reduction in flow resistance. Of those from Gas flow around the ends at the inlet and / or at the outlet must be in accordance with the invention Heat exchangers may not all be staggered, it can for example, only the top or bottom may be offset.

The heat exchange can, for example, by conduction through the heat exchanger plates, which in this case is preferably solid and made of a good heat-conducting material are, by spraying the heat exchanger plates with a liquid or in particular can be achieved by using hollow heat exchanger plates made by a Heat exchange medium are flowed through. Suitable as a heat exchange medium especially the ambient air of the dryer.

Advantageously, the offset between the gas flow ends of the individual Heat exchanger plates selected so that the gas flow corresponds to the heat exchanger plates their heat exchange performance. That way, a better one Utilization of the heat exchangeability of the heat exchanger and thus a higher heat exchange performance can be achieved. If the same size heat exchanger plates are used be, which accordingly have an equal heat exchange capacity the offset for this purpose can be set so that the on the surfaces of each Heat exchanger plates passing partial flows of the air flow are the same size. In general, the offset is advantageously set so that individual partial flows in the spaces between the heat exchanger plates at the end of the heat exchanger be cooled to the same temperature. The gas flow upstream of the heat exchanger can its cross section with respect to both the flow rate and the flow direction be different. The optimally set offset between the heat exchanger plates can therefore increase, decrease or change over their stack and can be experimental or by numerical simulation, especially after a Finite element method can be determined. As a benchmark for heat exchange performance A heat exchanger plate can use the surface of which the gas flow flows be taken into account, which can be taken into account that by setting an offset in turn can change the length of the plate and thus its area. When setting the The distance between the individual plates can also be offset between the plates to be changed.

The offset of ends of the heat exchanger plates around which the gas flow flows can be selected in this way be that the gas flow essentially perpendicular and effective for this Flow cross-section enlarged at the inlet to and / or at the outlet from the heat exchanger becomes. For this purpose, the area in which the gas flow Flow around the ends of the heat exchanger plates are as perpendicular to the course as possible aligned of the gas flow, so that in particular for those striking at an angle Gas flow effective entry openings between the ends of the heat exchanger plates be enlarged.

During operation, the heat exchanger plates can be caused by fluff or other contaminants be occupied, whereby the heat transfer to the gas flowing past and thus the Heat exchange performance is deteriorated. The heat exchanger plates are therefore often like this mounted so that they can be removed especially for cleaning. Through the Stair-shaped arrangement of the flowed ends and / or different gas deflection parts However, the heat exchanger plates can be different, so that the Heat exchanger plates are not mixed up and only reinstalled at a certain point may be. In this case, the heat exchanger advantageously has safety devices that a reinsertion of each heat exchanger plate only on one for allow this allowed position. These security devices can for example Protrusions or other design measures may be used for each heat exchanger plate are different and with counterparts in the heat exchanger or the place where the Heat exchanger plates are installed, interact.

In a further development, the heat exchanger plates have gas flow around them Ends gas deflection parts, which essentially correspond to the desired gas flow follow, with only a few ends around which the gas stream flows have gas deflection parts can. In this way, the flow losses can be further reduced because the gas flow strikes the heat exchanger plates at an angle or flows away from them at an angle and must be redirected in any case. In addition, with these gas deflection parts also the distribution of the gas flow to the individual heat exchanger plates or their gaps are influenced. These gas deflection parts can also be shaped differently for each plate to take into account their arrangement and also to determine the proportion of the gas flow with which the plate in question flows against shall be. To improve the outflow, the ends of the heat exchanger plates similar gas deflection parts can be arranged.

The heat exchanger plates advantageously form channels, each of two plates and delimited by a gas deflection part at at least one end around which the gas flow flows and that of a liquid or gaseous heat exchange medium can be flowed through. With the channel-shaped design of the heat exchanger plates with two plates as top and bottom are usually on the edges of the plate anyway spacers are provided for the panels that cover the channel on the sides to lock. The spacers can be made of different materials and after various processes such as injection molding or extrusion become. The formation of these spacer elements as gas deflection parts requires therefore no or only a little additional effort, so that the flow around one Simply end the heat exchanger plates with an already existing component by a shape other than gas deflection part a reduction in flow resistance can be achieved.

At least two gas deflection parts can be combined into one part and individually adapted to the flow requirements for the respectively assigned heat exchanger plate his. Each of the gas deflection parts can be located at the same end of the heat exchanger plates are arranged to be combined into one part, or the Gas deflection parts at the front and rear ends of the heat exchanger plates be combined into one part. The production in particular from plastic can be greatly simplify in this way. In addition, it can be provided that the Heat exchanger plates are held by the gas deflection parts so that on them Way the heat exchanger plates can be easily combined into a stack, which is easier to handle. For this purpose, the gas deflection parts can, for example the front and / or the rear ends of the heat exchanger plates with each other to be connected by striving. The struts can only on the lateral ends of the gas deflection parts and / or distributed over their length, so that the gas deflection parts together with the struts form a kind of grille, which at the front and / or rear ends of the heat exchanger plates can be placed. Still is it is possible to provide such a grid at the inlet and at the outlet of the heat exchanger and connect laterally with the help of side panels, so that a Frame is formed in which the heat exchange plates can be held.

A household clothes dryer equipped with a heat exchanger according to the invention can also be set up so that the gas flow flows around the heat exchanger plates Ends pivotable gas deflection parts are articulated and that he is a heating device for heating the gas stream and has a controller that is set up in this way is that they sense the temperature of the gas stream and depending on the sensed temperature with the help of the gas deflection parts the flow resistance of the heat exchanger can change for the gas flow. In this way, even with constant power Heating device affects the temperature of the gas flow and within certain limits be managed. For example, at the beginning of the drying process, when the Temperature is still far below the target temperature, the gas flow by increasing the Flow resistance of the heat exchanger are throttled very much, so that the Gas flow flowing through the heat exchanger and cooled there is low and the temperature of the gas flow increases faster. When the target temperature is reached, the gas deflection parts can be aligned so that the flow losses are as low as possible, whereby they are pivoted again when the gas flow temperature drops to throttle the gas flow and raise the temperature. The heater the household dryer can also be designed so that at maximum continuously Heating power of the gas stream its target temperature with a slight throttling reached by the gas deflection parts. This way both can be exceeded as well as falling below the target temperature of the gas flow by adjusting the Gas deflection parts can be counteracted.

In any case, by using the gas deflection parts to influence the Gas flow temperature the number of switching operations required to control the Heating device can be reduced.

Fig. 1

eine schematische Schnittansicht eines erfindungsgemäßen Wärmetauschers gemäß einer ersten Ausführungsform und

Fig. 2

eine Ansicht des Einlaßbereichs einer zweiten Ausführungsform des erfindungsgemäßen Wärmetauschers.

Further details, features and advantages of the invention result from the following description of two exemplary embodiments of a heat exchanger according to the invention with reference to the drawings. Show in it

Fig. 1

is a schematic sectional view of a heat exchanger according to the invention according to a first embodiment and

Fig. 2

a view of the inlet area of a second embodiment of the heat exchanger according to the invention.

FIGS. 1 and 2 each have a heat exchanger 1 for a gas stream S in a clothes dryer shown. The heat exchanger 1 is essentially made of heat exchanger plates 2 formed, between which the gas flow S flows and on the surface the heat exchange to the gas takes place. The ends of the Heat exchanger plates 2 limit inlet openings.

In addition, walls are shown which form a channel 5 for the gas stream S. The channel 5 runs in front of the inlet of the heat exchanger 1 essentially in a right one Angle so that the gas flow S obliquely with respect to the levels of the heat exchanger plates 2 meets the inlet of the heat exchanger 1. By redirecting the Gas flow S shortly before the inlet, the gas flow S in channel 5 is distributed unevenly on the one hand and, on the other hand, undergoes a throttling that reduces the energy consumption of the tumble dryer elevated.

The heat exchanger plates 2 are attached to their side edges on side parts 6, the combine the heat exchanger plates 2 into a stack that is in one piece can be removed for cleaning, for example.

According to the invention, therefore, in particular those that are flown by the gas stream S and in the Figures each of the ends of the heat exchanger plates 2 shown on the left are arranged in a step-like manner the lower heat exchanger plates 2 protrude further into the channel 5. For Achieve a uniform heat exchange performance of the heat exchanger plates 2 these have the same length, so that their rear ends also have an offset. The Gas stream S therefore strikes inlet openings of the valve over its entire width Heat exchanger 1, so that the gas flow S its direction of flow before flowing into only needs to change the heat exchanger 1 to a lesser extent. The flow losses and the Energy consumption is reduced in this way. In addition, is set by the Offset between the individual flow ends of the heat exchanger plates 2 achieved that the gas flow evenly on the individual heat exchanger plates 2nd distributed, the heat exchange performance is the same in the present embodiment. In general the offset is set so that the gas flow S on the heat exchanger plates 2 distributed according to their heat exchange performance. For heat exchange with the gas flow S can in this embodiment all of the aforementioned methods be used.

FIG. 2 shows a second embodiment in which the gas stream S flows against it Have ends of the heat exchanger plates 2 gas deflection parts 4, with which further reduce the flow losses when the gas flow S enters the heat exchanger 1 become. In addition, the design of the individual gas deflection parts 4 equalizes the distribution of the gas flow S on the individual heat exchanger plates 2 are so that the heat exchange performance of the heat exchanger 1 is optimally used becomes.

In this exemplary embodiment, the heat exchanger plates 2 are designed as channels and are flowed through by air as a heat exchange medium, which the tumble dryer of its surroundings. For this purpose, the heat exchanger plates 2 each have two plates 3 on, which are made of a good heat-conducting material and in particular metal. The plates 3 are at the front ends of gas deflection parts which are flowed against by the gas stream S. 4 and sealing at the rear ends, not shown in the figures, via spacers connected to each other and thus form closed channels through which the heat exchange medium or the cooling air flows perpendicular to the plane of the drawing can.

The gas deflection parts 4 and the spacers at the rear ends are mutually connected by struts 7 and in this way form a grid, for example as one-piece molded part can be made of plastic. These grids are designed that it continues to be attached to side parts 6, for example by means of the struts 7 can be. In this way, the heat exchanger plates 2 and Plates 3 can be easily combined into a stack by the front and the rear ends of a grid with gas deflection parts 4 or with spacers is placed and these grids are laterally connected to side parts 6, so that in this way a frame is formed in which the heat exchange plates 2 and the plates 3 are held.

Due to the inventive step-shaped arrangement of the flow ends Heat exchanger plates 2 can thus reduce the flow losses of the gas stream S and better utilization of the heat exchanger 1 can be achieved, wherein through the use of gas deflection parts 4, in particular when used simultaneously as a spacer for the plates 3, a further reduction in flow losses can be achieved with little effort.

Claims (8)

Heat exchanger (1) with a plurality of heat exchanger plates (2) arranged one above the other for a gas stream (S) in a household clothes dryer, in which the gas stream (S) runs directly in front of and / or behind the heat exchanger plates (2) at an angle to their plane, characterized in that Ends of the heat exchanger plates (2) around which the gas stream (S) flows are arranged offset in a step-like manner. Heat exchanger according to claim 1, characterized in that the offset between ends of the individual heat exchanger plates flowed around by the gas stream (S) (2) is chosen so that the gas flow (S) the heat exchanger plates (2) accordingly their heat exchange performance. Heat exchanger according to claim 1 or 2, characterized in that the Offset of ends of the heat exchanger plates (2) around which the gas stream (S) flows to the gas flow (S) essentially perpendicular and effective for this flow cross-section enlarged at the inlet to and / or at the outlet from the heat exchanger (1) becomes. Heat exchanger according to one of claims 1 to 3, characterized in that the heat exchanger plates (2) can be removed and that the heat exchanger (1) has safety devices that reinstall each Only allow the heat exchanger plate (2) in a position permissible for this Heat exchanger according to one of claims 1 to 4, characterized in that the heat exchanger plates (2) have gas deflecting parts at the ends around which the gas stream (S) flows (4) have the desired gas flow profile essentially consequences. Heat exchanger according to claim 5, characterized in that the heat exchanger plates (2) Channels for a liquid or gaseous heat exchange medium form, each of two plates (3) on at least one flowed around by the gas stream (S) Be limited by a gas deflection part (4). Heat exchanger according to claim 4 or 5, characterized in that at least two gas deflection parts (4) are combined into one part and individually for the respectively assigned heat exchanger plate (2) adapted to the flow requirements are. Household clothes dryer with a heat exchanger according to one of claims 1 to 4, characterized in that on the heat exchanger plates (2) from Gas flow (S) around swiveling ends articulated gas deflection parts (4) are and that he has a heater for heating the gas stream (S) and a Control, which is set up so that it uses the temperature Gas deflection parts (4) the flow resistance of the heat exchanger (1) for the Gas flow (S) can change.

Images