EP0260371A2 - Electrical hair dryer - Google Patents

Abstract

An electric hair dryer with an axial impeller (8) and a hollow cylindrical electrical heating element (12) arranged behind and approximately coaxially with the axial impeller (8) in the flow direction of the air, in which air can flow through the heating element (12) in the radial direction and so on is arranged that a first partial air flow from the axial fan wheel (8) in an approximately axial direction directly into the interior of the heating element (12) and a second partial air flow from the outside through the heating element (12) into the interior of the heating element (12) is conveyable With regard to its function, it is optimized in that a constriction zone (26), preferably a venturi-ring constriction zone (26) for the first partial air flow, is formed on the inside of the inflow edge of the heating element (12) facing the axial fan wheel (8). This creates a pressure difference in the slipstream of the inflow edge of the heating element (12) between the inside and the outside of the heating element (12), so that air is sucked in through the heating element (12) from the outside inwards and the heating element (12) burns out here prevented.

Description

The invention relates to an electric hair dryer or the like. According to the preamble of claim 1.

Even if the invention is described here and in the following in the first place for an electric drying dryer, it is of more general importance for all correspondingly designed electric fan heaters in which air flowing through is conveyed by means of an axial impeller and heated by means of a cylindrical heating element.

The known, previously described electric hair dryer (US-PS 43 28 818) has an elongated housing of substantially circular cross-section. The axial impeller sucks in air through the air inlet openings on the rear side of the housing and blows it through the heating element. Since this heating element is of hollow cylindrical design and is arranged coaxially or approximately coaxially with the axial impeller, the axial impeller conveys a partial air flow in an approximately axial direction directly into the interior of the heating element on the one hand, and on the other hand a second partial air flow first from the outside around the heating element and then with a radial component the heating element into the interior of the heating element. From the interior of the heating element, the heated air flows axially out of the front air outlet. The axial impeller has a disk-shaped hub, on which radially protruding fan blades are arranged in the usual way. The outside diameter of the axial impeller is considerably larger than the outside diameter of the heating element. As a result, the housing is expanded like a bubble in the central area, ie in the area of the axial impeller and heating element. The heating element itself is fixed to the front and rear support rings in the housing, the support rings being made of electrically insulating material, which in this case is of limited elasticity. The outflow-side support ring directly adjoins the inside wall of the housing with its outside, so that an essentially closed annular space is formed between the outside of the heating element and the inside wall of the housing. Through this shape of the housing and the arrangement of the heating element in this housing, the air flow from the axial impeller, namely the second partial air flow, is directed radially into the interior from the outside in a substantially uniform distribution over the length of the heating element through the heating element.

In a manner known per se, the heating element itself can consist of heating wires extending parallel to one another in the axial direction or a corresponding heating resistor network. Specifically, however, the known electric hair dryer has a heating element made of ban-shaped, electrical resistance material, as is known in detail from the prior art (DE-PS 25 39 201).

In the known electric hair dryer from which the invention is based, the electric drive motor, the axial impeller and the heating element are arranged one behind the other in the direction of the longitudinal axis of the housing. The electric drive motor is therefore in front of the axial impeller in the direction of air flow. This elongated arrangement of the individual parts of the hair dryer leads to an overall elongated housing, which in turn corresponds to the use of this hair dryer at the same time as a styling brush. In a conventional electric hair dryer with a pistol-like housing design, this arrangement would result in a very elongated head part of the housing.

Functionally, it has been shown that the well-known electric hair dryer is often noticed because the heating element burns out. The area of the heating element near the inflow edge of the heating element is particularly affected. In terms of function, the known hair dryer is still not optimal, since the heating element can only be switched on or off, so that the temperature of the escaping air can only be changed by changing the speed of the axial impeller.

Electric hair dryers with a pistol-shaped housing are of course also known from practice (see, for example, the Krups 410 type, which has been on the market for many years). These classic hair dryers have a head part of the housing, which is slightly frustoconical in shape, with a slightly smaller diameter from the air inlet to the air outlet. The axial impeller is located in the housing directly at the air inlet. The electric drive motor of the axial impeller is coaxial with it in the flow direction behind the axial impeller. The electric drive motor thus extends approximately coaxially into a hollow cylindrical electrical heating element, which is also arranged downstream of the axial impeller. This results in a rather compact and fluidically optimized design. Here, however, the cylindrical heating element, which is designed as a ring of parallel, axially directed heating wires or as a heating resistor network, is regularly arranged at a radial distance from the inner wall of the housing, so that the outer, second partial air flow flows essentially parallel to this heating element towards the air outlet . The heating element is of course also penetrated by air flow with a radially directed component. In practice, it has been shown that these known electric hair dryers fail only very rarely due to the heating element burning out, which is probably due to the fact that the heating element must be kept at an overall lower temperature than in the known electric hair dryer because of the overall lower heat exchange which the invention is based on. As a result, the risk of the heating element burning out is also less great.

The invention is based on the object of optimizing the known electric hair dryer described at the outset with regard to its function.

The above-mentioned object is achieved in a generic electric hair dryer with the features of the characterizing part of claim 1. According to the invention, it was first recognized that the weak place for the burning through of the heating element is the area near the inflow edge of the heating element, because it lies to a certain extent in the slipstream of the inflow edge or the support ring usually present here. It has been recognized that in this area the second, outer partial air flow has practically no radially directed movement component. Such a radially directed movement component already in this area is now forced on the outer partial air flow in accordance with the invention in that the inner, first partial air flow is guided through a constriction zone. This increases the flow velocity and reduces the static pressure in the first partial air flow. It is precisely at this point that a pressure difference arises between the outer annular space and the constriction zone, so that air is sucked into the interior of the heating element from the outer partial air flow through the heating element. As a result, the area near the inflow area of the heating element is very specifically cooled by air with a radially directed movement component. The result is that the heating element in the hair dryer according to the invention practically no longer burns through, although it has a relatively high temperature due to the intensive interaction with the air flow.

• Fig. 1 im Längsschnitt ein erstes Ausführungsbeispiel eines erfin­dungsgemäßen elektrischen Haartrockners,
• Fig. 2 einen Schnitt durch Fig. 1 entlang der Linie II - II,
• Fig. 3 ausschnittweise, in vergrößerter und stark schematisierter Darstellung den Bereich der Einschnürungszone im Gehäuse des Haartrockners aus Fig. 1,
• Fig. 4 ausschnittweise, teilweise geschnitten, den Bereich des Heiz­elements eines weiteren Ausführungsbeispiels eines elek­trischen Haartrockners,
• Fig. 5 in Fig. 4 entsprechender Darstellung ein drittes Ausfüh­rungsbeispiel eines Haartrockners und
• Fig. 6 in Fig. 4 entsprechender Darstellung ein viertes Ausfüh­rungsbeispiel eines Haartrockners.

Further advantageous embodiments of the invention are described in the claims subordinate to claim 1. They are explained in more detail below in connection with the explanation of preferred exemplary embodiments of the invention with reference to the drawing. In the drawing shows

• 1 shows in longitudinal section a first embodiment of an electric hair dryer according to the invention,
• 2 shows a section through FIG. 1 along the line II-II,
• 3 shows a detail, in an enlarged and highly schematic representation, of the region of the constriction zone in the housing of the hair dryer from FIG. 1,
• 4 a section, partially in section, of the area of the heating element of a further exemplary embodiment of an electric hair dryer,
• Fig. 5 in Fig. 4 corresponding representation of a third embodiment of a hair dryer and
• Fig. 6 in Fig. 4 corresponding representation of a fourth embodiment of a hair dryer.

The electric hair dryer shown in FIGS. 1, 2 and 3 in a first exemplary embodiment, which is generally a preferred example for electric fan heaters, initially has a housing 1, 2. The housing 1, 2 is made of plastic in the exemplary embodiment shown here and is divided into a half-shell shape into a front housing part 1 with a molded front handle part 1ʹ and a rear housing part 2 with a molded rear handle part 2ʹ. Overall, in the exemplary embodiment shown here and preferred in this respect, the housing 1, 2 is shaped like a pistol, as is widespread in the case of electric hair dryers known from practice and explained at the beginning.

The housing 1, 2 initially has a front air outlet 3 with air outlet openings 23 in the form of a plug-on cap which is latched onto the front housing part 1. In a corresponding manner, the housing 1, 2 is provided on the rear housing part 2 with a rear air inlet 4 with air inlet openings 24 in a cap shape. There are of course a large number of alternatives here, some of which are known from the prior art.

An axial fan wheel 8 is arranged in the housing 1, 2 and is driven by an electric drive motor 9. The axial impeller 8 has a central hub 5, which in the embodiment shown here is shaped like a bowl, for example, and has an insertion opening for a drive shaft 17 extending from the drive motor 9. Blower blades not provided with reference numerals project radially from the hub 7 in a manner known per se. In the direction of flow of the air behind and approximately coaxially with the axial impeller 8, a hollow cylindrical electrical heating element 12 is also arranged in the housing 1, 2. Due to the arrangement of the heating element 12 in the housing 1, 2, the heating element 12 is traversed by air in the radial direction, in such a way that a first partial air flow I (FIG. 3) from the axial impeller 8 in an approximately axial direction directly into the interior of the heating element 12 is promoted, while a second partial air flow II is first conveyed approximately parallel to the heating element 12 along the outside of the heating element 12 and then through the heating element 12 into the interior of the heating element 12.

In the exemplary embodiment shown here and preferred in this respect, the outflow edge of the heating element 12 is close to the air outlet 3 of the housing 1, 2 directly on the inner wall of the housing 1, 2, i. H. here of the housing part 1, arranged so that an essentially closed annular space 27 is formed between the outside of the heating element 12 and the inner wall of the housing. As in the exemplary embodiment shown here, this annular space can be designed to be tapered, but it can also have a constant diameter.

Furthermore, the exemplary embodiment shown in FIGS. 1 to 3 is preferred insofar as the heating element 12 is held in the housing 1, 2 via end rings 13, 13ʹ made of electrically insulating and preferably also elastic material.

It applies to the heating element 12 that basically all types of construction can be used here, if only it is ensured that air can flow through the heating element 12 from the outside inwards. The embodiment shown here and preferred in this respect, however, has a heating element 12, which consists of a band-shaped electrical resistor Material consists, wherein the individual heating tapes are arranged parallel to the axis of the heating element 12 and each enclose an angle with the apparent jacket. In the exemplary embodiment shown here, each heating band of the heating element 12 is mutually connected at its ends to the respectively adjacent heating band and is curved around its longitudinal axis. The heating tapes are arranged at a short distance from each other. In particular, reference is made to US-PS 43 28 818 on the one hand, and to DE-PS 25 39 201 on the other hand.

As can be seen in FIG. 1, the connection areas at the ends of the heating tapes are perforated for the heating element 12 used here specifically, in such a way that the perforation openings are arranged with radially outwardly projecting pins or teeth 33 on the support rings 13, 13 ' come into engagement.

In the schematic, enlarged representation of FIG. 3, it can be seen particularly clearly that an annular nozzle-like, preferably venturi-ring-like constriction zone 26 for the first partial air flow I is formed on the inside of the inflow edge of the heating element 12 facing the axial fan wheel 8. 3 by the arrows in the partial air flows I and II, the constriction zone 26 near the inflow wheel of the heating element 12, namely on the support ring 13, leads to the fact that the speed of the air in the partial air flow I increases and the static pressure is reduced here. This also applies at the end of the constriction zone 26, i.e. at the downstream end of the support ring 13, so that here the pressure inside the heating element 12 is lower than outside the heating element 12, which in turn leads to air from the outer partial air flow II through the Heating element 12 is sucked in here. This is indicated by the curved arrow at this point. As a result, the heating element 12 can no longer overheat and burn through at this previously critical point.

As FIG. 3 shows very clearly, it applies to the preferred embodiment in this respect that the inflow edge of the heating element 12 or the corresponding support ring 13 is thickened towards the central longitudinal axis of the heating element 12. This thickening of the support ring 13, which is rounded toward the inside, results in a practically turbulence-free constriction of the partial air flow I in the region of the constriction zone 26. The constriction effect is strongest due to this design of the support ring 13 on the support ring 13, so that the lowest static pressure also occurs at this point.

Fig. 1 shows that in the embodiment shown here, the axial impeller 8 has a hub 7 with a diameter that is greater than or equal to the inner diameter of the constriction zone 26. This construction has the advantage that air is really only blown into a free space by the axial impeller 8 and does not meet at the end face on an area that is hydraulically locked to form the constriction zone 26. That would result in considerable turbulence.

The constriction zone 26 on the inside of the inflow edge of the heating element 12 can be designed in various ways. For example, an annular constriction edge could be inserted in this area, so that a further axial flow path for a further partial air flow would remain coaxially in the interior of the heating element 12. This would be expedient if very high air temperatures were not desired at the air outlet 3, since only a relatively small partial air flow would interact with the heating element 12. For the application of an electric hair dryer according to the invention, however, it is recommended that a guide cone which fills the interior of the heating element 12 up to the constriction zone 26 is arranged at least in the region of the inflow edge of the heating element 12. Through this conduction of the air flow, an intensive interaction with the heating element 12 is achieved while leaving a sufficiently large axially flowing partial air flow I.

Fig. 1 shows that the embodiment of an electric hair dryer shown here is constructed approximately as is usual for known electric hair dryers of another type. To this extent, it also applies here that the electric drive motor 9 is arranged in the flow direction of the air behind and coaxially with the axial impeller 8 and at least partly inside the heating element 12. This arrangement of the electric drive motor 9 leads to a good use of space inside the housing 1, 2 and thus to a small overall length of the head part of the housing 1, 2, as is aimed for pistol-shaped hair dryers. This arrangement of the drive motor 9, however, gives another possibility, which can be seen particularly clearly in FIG. 1, namely that the guide cone is now formed by the drive motor 9 or a cap 21 covering the drive motor 9 at least at the upstream end. In the exemplary embodiment shown here, the cap 21 consists of electrically insulating, in particular plastic, material and is at the same time designed as a holder and socket for the drive motor 9. The drive motor 9 is, as it were, inserted into the cap 21. In the exemplary embodiment shown here, the cap 21 itself is held approximately coaxially in the housing 1, 2 by means to be explained later and bears a tongue 25 projecting forward in the flow direction of the air, that is to say into the heating element 12, the function of which is also explained in more detail later .

The traffic cone or the drive motor 9 or, in the exemplary embodiment shown here, the cap 21 covering the drive motor 9 has radially projecting ribs 31, 32 for holding the inflow edge of the heating element 12 or the corresponding support ring 13. In the exemplary embodiment shown here, this is realized in such a way that the ribs 32 each have an approximately axially running, possibly undercut support edge, onto which the support ring 13 is pushed or possibly also snapped on. It is also essential here that the ribs 31, 32 extend radially beyond the inflow edge of the heating element 12 to the inside wall of the housing 1, 2 extend. This also applies to all of the exemplary embodiments shown in the figures. With this design of the ribs 31, 32 it is achieved that the cap 21 or the drive motor 9 can be arranged essentially coaxially in the housing 1, 2 without problems and with structurally simple means. In addition, the ribs 31 also serve as guide ring blades for the air flow of the axial impeller 8, as can be seen particularly well from FIGS. 1 to 3. For this purpose, the ribs 31 are chamfered on the upstream side.

As shown in FIG. 1, in the preferred exemplary embodiment shown here, the housing 1, 2 is frustoconical in shape, with a slightly decreasing diameter from the air inlet 4 to the air outlet 3. This results in a slight acceleration of the air flow towards the air outlet 3. Otherwise, the preferred conical ring shape of the annular space 27 with the end closed towards the air outlet 3 also results in this manner.

The fact that the electric drive motor 9 is arranged at least partially in the interior of the heating element 12 means that the inner, first partial air flow 1 is of additional importance for the cooling of the drive motor 9. The relatively cool partial air flow I, which is cool because it does not flow through the heating element 12, mixes in the interior of the heating element 12 with the partial air flow II guided from the outside through the heating element 12, so that ultimately an air flow at the mixing temperature leads to the front Air outlet 3 leaves. Due to the relatively small inner diameter of the housing 1, 2, the annular space 27 has a relatively small width, so that the partial air flow II flows here with a fairly high axial flow velocity. The flow resistance for the partial air flow I in the constriction zone 26 is quite low and in the exemplary embodiment shown here is approximately in the order of magnitude of the flow resistance for the partial air flow II when flowing through the heating element 12 with a radially directed movement component.

Fig. 2 shows a further preferred embodiment of a hair dryer, which is characterized in functional terms by the fact that the temperature of the air emerging from the air outlet 3 can be set in a variety of ways. Here it applies that the heating element 12 consists of two relatively short sections 12ʹ, 12ʺ of the same or approximately the same diameter arranged one behind the other in the flow direction of the air, that, preferably, the sections 12ʹ, 12ʺ via two end support rings 13, 13ʹ and a central support ring 13ʺ are held in the housing 1, 2 and that, preferably, one and / or the other section 12ʹ or 12ʺ can be switched on electrically. The heating element 12 can be controlled here, as in the exemplary embodiment explained above, by means of a multi-contact switch 5 by actuating its slide 6, as is known per se. The switch 5 is arranged in the embodiment shown here in the handle part 2ʹ.

The overheating problem, which was explained in detail at the beginning with regard to the heating element 12, is solved in the exemplary embodiment according to FIG. 4 for the first section 12 ′ of the heating element 12 in exactly the same way as previously explained. The overheating problem correspondingly occurring in section 12ʺ is solved in the exemplary embodiment shown here in that the central support ring 13ʺ is thickened to form an annular nozzle-like constriction zone 26ʺ towards the central longitudinal axis of the heating element 12. At this point, the overheating problem is not quite as great because the annular space 27 is already considerably smaller in diameter than in section 12ʹ, so that the partial air flow II already has a relatively strong radially directed movement component anyway.

5 shows a further, another alternative exemplary embodiment, in which case it now applies that a further heating element 12a is arranged coaxially in the interior of the heating element 12 and, preferably, optionally one and / or the other heating element 12 or 12a is electrically switchable. In the same way as in the previously explained exemplary embodiment, the temperature of the air at the air outlet 3 can be controlled here by optionally switching the sections or the heating elements on and off electrically. The inner heating element 12a shown here forms with its support ring 13a the ring edge previously explained as a possibility for designing the constriction zone 26 near the inflow edge of the heating element 12.

In the hair dryer shown in FIG. 5, it can occasionally occur that temperature problems occur with the inner heating element 12a, since there the pressure difference in the slipstream of the support ring 13a may not be sufficiently large. 6 finally shows an alternative solution, which is characterized in that the inflow edge or support ring 13a of the inner heating element 12a lies behind the inflow edge or the support ring 13 of the outer heating element 12 in the direction of flow. In this way, the venturi-like constriction zones 26 are arranged axially offset from one another.

1 shows that in the exemplary embodiment shown here and preferred in this respect, a temperature safety switch 10 is mounted in the first partial air flow I on the drive motor 9 or on the cap 21 inside the heating element 12. The temperature safety switch 10, which can be designed as a thermostat, as a bimetallic switch or the like, is located on the tongue 25 of the cap 21 in the exemplary embodiment shown here. The tongue 25 is provided with two brass eyelets 18, on which the wiring of the temperature safety switch 10 is attached and which also serve to mechanically mount the temperature safety switch 10 on the tongue 25. The proximity of the temperature safety switch 10 to the drive motor 9 in the inner partial air flow I means that its temperature is very precisely the temperature to which the drive motor 9 is also exposed. Since the temperature safety switch 10 lies in the inner partial air flow I, it will normally be cooled and can switch to a relatively low level temperature must be set. A temperature of 80 to 90 ° C is possible as the switching temperature after the tests carried out. As soon as the air flow through the interior of the heating element 12 decreases or decreases, the temperature increases very quickly here and the temperature safety switch 10 responds. This position of the temperature safety switch 10 thus leads to a particularly high level of safety for the electric hair dryer shown.

1 and 2 also show that the drive motor 9 in the exemplary embodiment shown here is a DC motor with a low supply voltage, since this is supplied with current via a full-wave rectifier with four diodes 11. This can be, for example, a DC voltage of 15 V. The four diodes 11 of the full-wave rectifier are electrically connected to solder connection points 14, 14ʹ or 15ʹ or 15, which in the exemplary embodiment shown here are arranged on the support ring 13 and on the support ring 13ʹ. These connection points 14, 15 serve to connect electrical lines for supplying the drive motor 9 on the one hand and the electrical heating element 12 on the other.

Claims (15)

1. Electric hair dryer or the like. With a housing (1, 2) with a rear air inlet (4) and a front air outlet (3), arranged in the housing (1, 2), driven by an electric drive motor (9) Axial fan wheel (8) and with a hollow cylindrical, electrical heating element (12) arranged in the direction of flow of the air behind and approximately coaxially to the axial fan wheel (8) in the housing (1, 2), the heating element (12) being in the radial direction of air flowable and arranged in the housing (1, 2) so that a first partial air flow (I) from the axial fan wheel (8) in an approximately axial direction directly into the interior of the heating element (12) and a second partial air flow (II) initially approximately parallel to the heating element (12) along the outside of the heating element (12) and then through the heating element (12) into the interior of the heating element (12), wherein, preferably, the outflow edge of the heating element (12) close to the air outlet (3) of the housing (1 , 2) immediately the inner wall of the housing (1, 2) is arranged so that between the outside of the heating element (12) and the inner wall of the housing (1, 2) a substantially closed annular space (27) is formed on the outflow side, the heating element preferably via the end Support rings (13, 13ʹ) made of electrically insulating, preferably elastic material are held in the housing (1, 2) and wherein, preferably, the heating element (12) consists of band-shaped, electrical resistance material, the individual heating bands of which are parallel to the axis of the heating element (12) are arranged and each enclose an angle with its apparent jacket and are alternately connected at their ends to the respectively adjacent heating tape, characterized in that on the inside of the inflow edge of the heating element (12) facing the axial impeller (8) there is an annular nozzle-like, preferably venturi annular nozzle-like constriction zone (26) for the first partial air flow (I) is formed. 2. Hair dryer according to claim 1, characterized in that the leading edge of the heating element (12) or the corresponding support ring (13) is thickened towards the central longitudinal axis of the heating element (12). 3. Hair dryer according to claim 1 or 2, characterized in that the axial impeller (8) has a hub (7) with a diameter which is greater than or equal to the inner diameter of the constriction zone (26). 4. Hair dryer according to claim 1 to 3, characterized in that at least in the area of the inflow edge of the heating element (12) an inside of the heating element (12) up to the constriction zone (26) cross-sectional filling cone is arranged. 5. Hair dryer, in particular according to claims 1 to 4, wherein, preferably, the heating element (12) consists of band-shaped, electrical resistance material, the individual heating tapes are arranged parallel to the axis of the heating element (12) and each enclose an angle with its apparent jacket and are alternately connected at their ends to the adjacent heating tape, characterized in that the electric drive motor (9) is arranged in the direction of flow of the air behind it and coaxially to the axial impeller (8) and at least partially in the interior of the heating element (12). 6. Hair dryer according to claims 4 and 5, characterized in that the guide cone is formed by the drive motor (9) or a drive motor (9) at least at the upstream end covering cap (21). 7. Hair dryer according to one of claims 4 to 6, characterized in that the traffic cone or the drive motor (9) or the drive motor (9) covering cap (21) radially projecting ribs (31, 32) for holding the leading edge of Has heating element (12) or a corresponding support ring (13). 8. Hair dryer according to claim 7, characterized in that the ribs (31, 32) extend radially beyond the inflow edge of the heating element (12) to the inner wall of the housing (1, 2). 9. Hair dryer according to claim 7 or 8, characterized in that the ribs (31, 32) are simultaneously designed as guide ring blades (31) for the air flow of the axial impeller (8). 10. Hair dryer according to one of claims 1 to 9, characterized in that the housing (1, 2) is frustoconical with a slightly decreasing diameter from the air inlet (4) to the air outlet (3). 11. Hair dryer according to one of claims 1 to 10, characterized in that the heating element (12) consists of two relatively short, in the flow direction of the air arranged one behind the other sections (12ʹ, 12ʺ) of the same or approximately the same diameter that, preferably, that Sections (12ʹ, 12ʺ) on two end support rings (13, 13ʹ) and a central support ring (13ʺ) are held in the housing (1, 2) and that, preferably, optionally one and / or the other section (12ʹ or 12ʺ) is electrically switchable. 12. Hair dryer according to claim 11, characterized in that the central support ring (13ʺ) to form an annular nozzle-like constriction zone (26ʺ) to the central longitudinal axis of the heating element (12) is thickened. 13. Hair dryer according to one of claims 1 to 12, characterized in that a further heating element (12a) is arranged coaxially inside the heating element (12) and, preferably, optionally one and / or the other heating element (12 or 12a) electrically can be switched on. 14. Hair dryer according to claim 13, characterized in that the inflow edge or support ring (13a) of the inner heating element (12a) lies in the flow direction behind the inflow edge or support ring (13) of the outer heating element (12). 15. Hair dryer according to claim 5 and possibly one of claims 6 to 14, characterized in that on the drive motor (9) or on the cap (21) inside the heating element (12), a temperature safety switch (10) in the first partial air flow (I ) is attached horizontally.

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