EP1510613A1 - Heat accumulator for a device for dewrinkling garments by means of a heatable air flow - Google Patents

Abstract

The air heater for smoothing the wrinkles out of clothes has two elongated sinusoidal electrical heater elements (10,11) side-by-side. Typically they form W-shapes and pass through a stack of straight fins (13) which may heat air and act as heat storage elements (9). There are terminals (11) at the ends of the heaters in contact with conductor wires (15) and thermostats (12).

Description

The present invention relates to a heat accumulator for a device for smoothing of garments by means of a heatable from the heat storage air flow and a device equipped with such a heat accumulator for smoothing Garments.

In a device for straightening garments with a blower is a high Performance advantageous because the entire surface of the garment with a heated Air flow is applied. However, especially in private households is the connection performance an electrical power supply limited so that the heat output from This reason may already be limited. Since the clothes to be smoothed on the Device usually at the beginning only trimmed and subsequently removed need arise, treatment breaks in which the high heat output is not required is and with the heat storage heat energy can be collected to at given maximum power consumption of the device as fast as possible smoothing to achieve. Further, with a reduction in maximum power consumption the sizing of the heaters in the device can be reduced so that the costs can be reduced.

DE 199 13 642 A1 discloses a device for straightening articles of clothing. which has a fan and a heatable heat storage. For straightening In the garment to be smoothed, an air flow is released by means of the heat accumulator heated air passed. During treatment breaks, in which the to be smoothed Garment is removed or applied, by heating the heat accumulator Heat energy stored to a higher during the treatment process To provide heat energy available.

The present invention is based on the object, a heat storage and a To provide a device for straightening garments of the type mentioned above, with little effort a more effective use of the heat storage and a better smoothing of the clothes can be achieved.

According to the invention, this object is achieved by a heat accumulator having the features of claim 1 and a device having the features of claim 10. The subclaims each define preferred and advantageous embodiments of the present invention.

According to the invention, the heat storage at least one heating element, which at Installation of the heat accumulator in the device for smoothing garments transversely to the flow direction of an air stream which can be generated in the device. The airflow can be created with a blower and will be in the garment to be smoothed directed to heat and tension it from the inside. By the action of Heat is straightened the taut garment. The heat storage is preferred provided with ribs which are at least substantially parallel to the flow direction of Run air flow and give off the heat to the passing air stream. By arranging the at least one heating element transversely to the air flow, the Heat is more evenly distributed across the cross-section of the air stream and a more even Temperature distribution of the air flow over the cross section can be achieved. Furthermore, this can be achieved to achieve a desired heat distribution over the Cross section reduces the number of heating elements and / or the size of the heating elements become. Likewise, the amount of heat-conducting material in the heat storage be reduced, which is required for the distribution of heat across the cross section. The heat storage can thus be made easier and cheaper.

As a rule, in such devices, a maximum temperature for the air flow given, which may not be exceeded even in limited areas in the air flow. Such a maximum temperature for the air flow is in particular for safety reasons intended to prevent personal injury and / or property damage. By the more uniform temperature distribution achieved with the present invention can the heat storage on observance of a maximum value for the local air temperature charged a higher temperature and thus stored a higher amount of heat, since due to the lower dispersion of the temperature values in the air flow, the average temperature the heat accumulator closer to the maximum allowable temperature can be brought up.

The at least one heating element is in particular perpendicular to the flow direction arranged. Preferably, the heating element is a tubular heater and is the heat storage preferably made of a material having a high thermal conductivity and a high specific heat capacity such as aluminum. The heating element can in a pourable material of the heat storage, such as aluminum, be poured into the heat storage, creating a very good heat transfer is achieved. Furthermore, a heating element can also be in a depression on a surface the heat accumulator, such as a channel, are arranged, wherein the Heating element to improve the heat transfer can also be pressed. For mechanical security, the edges of a recess for the arrangement of the Heating element at least partially bent over the heating element.

The at least one heating element is preferably meandering to a small Number and in particular a single heating element already a uniform Distribution of heat dissipation over the cross section of the air flow to achieve. At a Meandering form is used to alternate straight sections with bent or kinked sections from. In this case, a first embodiment is conceivable in which the heating element in Serpentine is laid over an active surface and the two ends of the heating element in With respect to the effective surface are arranged diametrically opposite each other. In this first embodiment the individual straight sections of the heating element are preferably parallel aligned to a uniform heat input per unit area of Achieve effective area. The effective area corresponds in particular to the cross-sectional area the heat storage perpendicular to the flow direction.

In a second preferred embodiment, the heating element is meandering and are the two ends of the heating element on the same side of an at least substantially rectangular active surface arranged. This page is also referred to as Connected side. In this second embodiment may preferably be provided Be that vertical sections of the heating element, which are located between the connection side and the side opposite this side, towards converge towards the connection side or their distance to the connection side reduced. By this arrangement is laying at a low cost and Production of the heating element reaches a very good heat distribution over the cross section.

Preferably, at least four are straight in the aforementioned second embodiment Sections of the heating element that converge in pairs towards the terminal side, and are the pairs of the respective sections running together nested. This means that the straight sections of the heating element in divide two adjacent groups and that all sections of a group with all sections of the other group depending on the reference direction either an angle between 0 and 90 degrees or an angle between 90 and 180 degrees or either include a straight or an obtuse angle. In particular, the in Referring to converging straight sections an angle below 20 degrees a, wherein the angle may be for example 10 degrees.

In the second embodiment, the heating element can in particular be axisymmetric be designed. When the heat storage in its cross section perpendicular to the flow direction is also axisymmetric, can also be provided that the Symmetry axes of the heat accumulator and the heating element are superimposed.

The heat storage can also have a plurality of heating elements, which also different Have heating power to the heat storage with the highest possible To heat the number of different total heat outputs. Several heating elements are preferably congruent with respect to the flow direction one above the other arranged.

With several heating elements in the heat storage these are in relation to the flow direction distributed so that they total closer to the air upstream end of the Heat accumulator are arranged as at the downstream air end. So that can be taken into account that of the airflow at the upstream end Heat again later to the downstream end the heat storage is discharged, so that due to the uneven distribution of Heating elements on the height of the heat storage parallel to the flow direction in the result a more even heat distribution is achieved. For example, a heating element poured in the middle of the center and another heating element on the upstream end pressed into a channel.

With several congruently arranged heating elements, the gap between the heating elements filled in the direction of the height of the heat accumulator or with Be provided walls, so that the first flowing past a heating element air can flow laminar and does not form behind this heating element flow vortex.

Fig. 1

eine schematische Vorderansicht einer erfindungsgemäßen Vorrichtung zum Glätten von Kleidungsstücken mit einem erwärmbaren Wärmespeicher,

Fig. 2

eine perspektivische Ansicht des Wärmespeichers,

Fig. 3

eine Aufsicht des Wärmespeichers, und

Fig. 4

eine Ansicht der Stirnseite des Wärmespeichers.

An embodiment of the invention is shown purely schematically in the drawings and will be described in more detail below. Show:

Fig. 1

a schematic front view of a device according to the invention for smoothing garments with a heatable heat storage,

Fig. 2

a perspective view of the heat storage,

Fig. 3

a top view of the heat store, and

Fig. 4

a view of the front of the heat storage.

The device shown schematically in Figure 1 is used for smoothing shirt-shaped Garments and has a lower part 2 with a inflatable body 1 attached thereto. The inflatable body 1 is shirt-shaped, consists of a flexible and air-permeable material and has an opening at the bottom, which is connected to a fan 5, 6 in the lower part 2 is. The blower is composed of a fan 6 and a drive motor 6 and can inflate the inflatable body 1 to generate an air flow that of a heater 7 in the lower part 2 can be heated. In the air duct 4 is still between the fan 6 and the heater 7 an electrically heated Heat accumulator 8 is arranged, at which an air flow generated by the blower 5, 6 in thermally conductive compound passes by, so that it releases heat energy from the heat storage 8 receives or can be heated by the heat storage 8.

On the lower part 2 is still above a button band 3 along the inflatable body 1 arranged. With the help of the button band 3, the button bar or the Buttonhole strip of a buttoned shirt or corresponding edges of a longitudinal to opening garment to be fixed by clamping to the garment to be able to stretch.

For smoothing an advantageously moist garment on the inflatable body. 1 arranged and in a smoothing phase by inflation of the inflatable body 1 by means of the blower 5, 6 stretched from the inside, with a heated air flow passed into the inflatable body 1 becomes. The air flow is by means of the heat accumulator 8 and optionally by means of Heating device 9 is heated. The heat accumulator 8 is heated before the smoothing phase, wherein it is ensured that the heat accumulator 8 at most to a maximum Storage temperature is heated. In the smoothing phase can then be the heating of the heat storage 8 shut off and the heater 7 are operated, so that the air flow from the heat stored in the heat accumulator 8 and that of the heater 7 heat emitted is heated. The heating power for heating the airflow Thus, in the smoothing phase, the connection performance or maximum power consumption of Exceed device.

In Figure 2, the heat storage 8 is shown in perspective in detail. The heat accumulator 8 comprises a storage body 9, which consists of cast aluminum and ribs 13 which are aligned parallel to the flow direction of the air flow within the air channel 4 with built-in heat accumulator 8. In the storage body 9, a first heating element 10 and a second heating element 11 are provided in heat-conducting connection to the storage body 9. Both heating elements 10, 11 are tubular heaters. Further, the storage body 9 has two electrically connected in series thermostats 12, which interrupt the power as soon as the corresponding switching temperature is exceeded. A first of the two thermostats 12 has a switching temperature corresponding to the intended storage temperature. The switching temperature of the other second thermostat 12 is above the storage temperature at a maximum temperature at which no material damage occurs, so that the second thermostat 12 ensures safety in case of failure of the first thermostat 12.
The two heating elements 10, 11 are connected to each other at first terminal ends and to a terminal end of the series circuit of the thermostats 12. The other second terminal ends of the heating elements 10, 11 and not connected to the heating elements 10, 11 connected end of the series circuit of the thermostats 12 are guided with separate lines 15 to a control device, which can operate in this way, the two heating elements 10, 11 independently of each other. Both heating elements 10, 11 are meandering and have straight portions which either adjoin the terminal ends or are connected to one another via curved sections. Furthermore, the two heating elements 10, 11 have different heating powers, so that a total of three different heating levels can be realized by individual or collective operation of the heating elements 10, 11.

In Figure 3, the heat storage 8 is shown in plan. The flow direction runs while perpendicular to the plane of the drawing. The terminal ends of the two heating elements 10, 11 are arranged at the upper edge of the rectangular storage body 9, which also Connection side is called. The side opposite the connection side is in Following free page called. From the connection ends run the heating elements 10, 11 in outer straight sections downwards, wherein they are not perpendicular to the connection side, but slightly inclined outwards. With the narrow sides, which extend between the connection side and the free side, close the outer straight sections approximately at an angle of 5 degrees.

On the free side close to both outer straight sections arc sections which are bent inwards and return to the connection side. At these bow sections Join inner straight sections that extend to the connection side extend back and substantially parallel to the outer straight sections are with which they are connected via the respective arc section. The inner straight Sections close to the adjacent narrow side of the storage body. 9 also an angle of about 5 degrees. However, it can also be provided the inner straight sections have a different angle and, for example, a smaller one Angle as the outer straight sections with the adjacent narrow sides lock in. The upper ends of the inner straight sections are over a middle one Arc section connected together.

The storage body 9 further has fastening projections 14 which are at least partially Internal thread may have to the storage body 9 by means of screw to attach to the air duct 4 can.

FIG. 4 shows a plan view of the connection side of the heat accumulator 8. The Flow direction is parallel to the drawing plane with respect to this representation up. This means that the lower edge of the heat accumulator in the drawing is first acted upon by the air flow and thus upstream. The first heating element 10 is arranged at the lower edge of the storage body 9, whereas the second heating element 11 is poured approximately centrally with respect to the height. The first Heating element 10 is pressed into a channel on the underside of the storage body 9.

Claims (10)

Heat accumulator (8) for a device for smoothing garments by means of an air stream heatable by the heat accumulator (8), characterized in that the heat accumulator (8) comprises at least one elongate heating element (10, 11), the longitudinal axis of the heating element (10, 11) runs transversely to a flow direction of an air stream which can be generated in the device when the heat accumulator (8) is installed in the device. Heat accumulator (8) according to claim 1, characterized in that the longitudinal axis of the heating element (10, 11) extends at least substantially perpendicular to the flow direction. Heat storage (8) according to claim 1 or 2, characterized in that the heating element (10, 11) has a width transverse to the flow direction which is at least substantially equal to or greater than a height of the heating element (10, 11) parallel to the flow direction. Heat storage device (8) according to one of the preceding claims, characterized in that the heating element (10, 11) is arranged meander-shaped in the heat accumulator (8). Heat accumulator (8) according to claim 4, characterized in that the heat accumulator (8) is rectangular across the flow direction, both ends of a heating element (10, 11) on a connection side of the heat accumulator (8) are arranged, the course of the heating element (10, 11) is axially symmetrical with respect to an axis of symmetry perpendicular to the connection side and centered to the connection side, wherein at least two mutually symmetrical, straight portions of the heating element (10, 11) extending from the connection side to an opposite free side of the heat accumulator (8) extend, diverge towards this free side. Heat accumulator (8) according to claim 5, characterized in that all mutually symmetrical, straight portions of the heating element (10, 11) extending from the connection side to the opposite free side of the heat accumulator (8), diverge towards this free side , Heat accumulator (8) according to one of the preceding claims, characterized in that the heat accumulator (8) has at least two heating elements (10, 11), which are viewed congruently arranged one above the other in the flow direction. Heat accumulator (8) according to claim 7, characterized in that a heating element (10) is arranged in the flow direction at the upstream end of the heat accumulator (8). Heat accumulator (8) according to claim 7 or 8, characterized in that a heating element (11) in the flow direction in the middle of the heat accumulator (8) is arranged and at least one further heating element (10) is arranged in the flow direction upstream thereof. Apparatus for smoothing garments with a blower (5, 6) for producing an air flow within an air duct (4) and one in the air duct (4) arranged heat accumulator (8) according to one of claims 1 to 9.

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