FR2640857A1 - Hairdryer with an air exit flow of modifiable form - Google Patents

Abstract

The air exit system 6 comprises a nozzle 12 which is initially cylindrical. The nozzle 12 is made from material which can be deformed reversibly. The temporary deformation is controlled by an inner reinforcement consisting of two cylindrical ungulate elements 11. By rotating the manoeuvring ring 8 in the direction F, the ungulate elements 11 are moved apart, giving rise to the flattening and the extension of the initially cylindrical end of the deformable nozzle 12. As the perimeter of the cross section of the nozzle is substantially constant, a stream of air of highly elongate shape is obtained without greatly reducing the area of the cross section of the stream of air, which prevents the increase in the speed and in the temperature of the exit air and improves comfort in use.

Description

 The present invention relates to an air circulation hair dryer, for household or professional use, providing an air jet whose shape can be varied.

 In known hair dryers of this category, the shaping of the air flow is obtained in different ways.

 Some hair dryers use two or more accessories constituting as many air outlet nozzles, removable, and allowing to have an equal number of forms of air flow. The disadvantage is obviously to multiply the number of accessories and, despite this, to have only a small number of forms of air flow, because the outlet section of each accessory cannot be modified. In addition, if during a drying operation, it is desired to modify the shape of the air flow, it is necessary to manipulate the nozzles near the heating resistors which are then at high temperature, which is preferable to 'to avoid.

 Other hair dryers, described in particular in US-A-4 232 454, FR-A- 1 546 750 and FR-A- 2 530 132, each use a pair of flaps which pivot inside the dryer -hair around their rear edges adjacent to two opposite internal walls of the duct. These shutters can be operated simultaneously symmetrically by an adjustment button placed at the top of the device. We can thus more or less restrict the free section of the air duct, in a direction which is orthogonal to both the air jet and the pivot axis of the flaps, that is to say that obtains a more or less flattened air jet between the flaps while the dimension of the passage section is substantially maintained parallel to the pivot axes. In these devices, the flattening of the jet is not compensated by an increase in its larger transverse dimension, there is necessarily a sharp reduction in the area of the air passage section, and correspondingly, a sharp increase in the speed of the air in line with the outlet orifice. Simultaneously, an increase in the air temperature is observed as a result of the increased pressure drops due to the presence of the flaps in the flow and the corresponding reduction in the air flow rate while the heating power remains constant.

These two phenomena, increase in air speed and temperature when the jet is shaped according to a flat profile, both contribute to reducing the comfort of use of the device.

 The object of the present invention is to provide a hair dryer with flowable flow making it possible to overcome, to a very large extent, the disadvantages of hair dryers of this type known previously described.

 The present invention relates to a hair dryer comprising means for heating and circulating an air flow, as well as means for modeling the flow to modify the geometry of the air jet emitted by an air outlet nozzle and means for controlling the flow modeling means, characterized in that, as flow modeling means, the nozzle is reversibly deformable, and the control means comprise means for adjustable positioning of certain regions of the nozzle .

 The hair dryer according to the invention makes it possible to obtain at will a continuous variation of the shape of the outlet air jet, which can range, for example, from a round jet to an enlarged oblong or rectangular jet.

 As the shaping of the jet results from the deformation of a nozzle, the perimeter of the flow passage section varies little. When the jet is flat, certain parts of the nozzle come out of the circle corresponding to the round jet. The cross-sectional area of the jet is therefore little reduced when the jet is flattened, and consequently the speed and the temperature of the outlet jet are little increased.

 Other features and advantages of the invention will emerge during the description which follows, relating to an embodiment of the invention.

In the accompanying drawings, given by way of nonlimiting examples
- Figures 1 and 2 are perspective views of a hair dryer according to the invention, showing the outlet nozzle respectively in cylindrical configuration and in flattened configuration
- Figure 3 is an exploded perspective view of the nozzle and the operating system of the hair dryer of Figures 1 and 2
- Figure 4 is a sectional view, on an enlarged scale, of the front part of the hairdryer of Figures 1 to 3, by the plane of symmetry of the housing
- Figure 5 is a view similar to Figure 4, but according to an axial section plane perpendicular to that of Figure 4, the upper half-view representing the position "round jet" and the lower half-view the position "jet dish"
- Figure 6 is a half view in axial section of the control ring; and
- Figures 7 and 8 are two partial views along arrow VII in Figure 4, the control ring and the deformable nozzle having been removed.

 In all that follows, the term “front part of the hairdryer” means the part close to the air outlet, and likewise the front part of a member is the part closest to the air outlet.

 As shown in FIGS. 1 and 2, the hair dryer produced in accordance with the invention comprises a housing 1, formed of two half-shells 2, inside which are arranged a heating element 3 and a fan 3 ′, known in themselves- same, which it was not considered useful to represent in detail, nor their connection to the power supply. Switching the hair dryer on and off is controlled by a switch 4.

The hair dryer has an air outlet system 6 comprising (see also Figure 3)
- A tubular support 7 which carries the other elements of the system and which is itself fixed to the front part of the housing 1
- Two substantially rigid cylindrical tabs 11 arranged in a manner substantially symmetrical with respect to the axial plane of joint of the half-shells 2 and articulated to the support 7 to take different orientations with respect to this plane
- An air outlet nozzle 12, reversibly deformable by the action of the tabs 11 serving as a movable frame and which support certain regions 12c of the nozzle 12
a control ring 8 which can rotate about its axis in order to move two slides 9 guided by the tubular support 7, and controlling the pivoting of the tabs 11.

 The tubular support 7 is fixed to the housing 1 by means of two lugs 13 carried internally each by one of the half-shells 2 and two lugs 14 carried internally by the tubular support 7. The lugs 13 are assembled with the lugs 14 by screws 15 (Figure 5).

 The support 7 is provided with two diametrically opposite slots 16 each intended to receive a hinge tab 17 (FIGS. 3 to 5) carried by one of the tabs II in the middle of its rear edge 11a and directed radially inwards. The engagement of each articulation lug 17 in the corresponding slot 16 thus gives each tab 11 an assembly articulated along a tangential axis relative to the support 7.

 As shown in particular in FIG. 5, each tab 11 is thus movable between a rest position in which it lets the nozzle 12 take its natural cylindrical shape (upper part of FIG. 5) and a position spread radially outwards in which it gives the nozzle 12 a profile which passes from a circular shape in the vicinity of the half-shells 2 to a flattened rectangular shape at the free end, as shown in perspective in FIG. 2.

 As shown in particular in Figure 3, the tabs 11 have a circumferential dimension which decreases from their rear edge 11a semicircular to a front edge 11b As shown in the lower part of Figure 5, in position away from the tab 11, the distance between the tab 11 and the axis of the nozzle increases from the articulation provided by the tab 17 to the free end llb of the tab. In any plane perpendicular to the axis of the nozzle, the circumferential dimension of the tab is such that the perimeter of the nozzle in this plane is the same in the two extreme positions of the tabs.

 The free end llb of each tab 11 is engaged in a pocket 12a (Figures 4 and 5) formed inside the nozzle 12. In addition, each tab 11 has a longitudinal stiffener lld and two island holes in which s engage corresponding lugs 12b of the inner wall of the nozzle 12 for axially fixing the nozzle 12 to the tabs 11. This axial fixing is completed by two tabs 11f directed radially outwards, these tabs engaging in two slots 12d provided in the rear part of the nozzle.

 In their rear part, the two tabs 11 completely surround the air passage and the tubular support 7. The adjacent end pairs îlc (see also FIG. 7) of the rear edges lîa of the tabs 11 partially cover the sliders 9 and each have a tab 18 directed radially inwards.

Each slide 9 has in its radially outer face a slot 19 which receives the two tabs 18 belonging to a pair of adjacent ends llc.

 The slides 9 slide in axial slides 21 which are formed in the radially outer face of the tubular support 7. The two slides 21 are diametrically opposite and offset by 900 relative to the slots 16.

 As shown in FIGS. 7 and 8, the slides 9, by sliding in their slide 21, drive the tabs 18 and thus control the pivoting of the tabs ll around their tangential pivot axis defined by the tabs 17.

 The sliding of the slides 9 is controlled by a control ring 8 which surrounds the tubular support 7, the slides 9, the fixed end of the nozzle 12, and the rear edges of the tabs 11. The control ring 8 comprises at this effect an internal flange 22 in which are made two diametrically opposite helical grooves 23 in each of which is engaged a lug 24 of one of the slides 9. A rear edge 30 of the ring 8 is in abutment against a shoulder 31 of the half-shells 2 (Figure 4). An internal flange 25 of the ring 8, disposed in front of the flange 22, prevents the ring 8 from moving forward because it abuts against an external flange 27 presented by the tubular support 7 between the slides 21.

Thus, the ring 8 is prevented from moving in axial translation, but can rotate around the axis of the nozzle and thus control the sliding movement of the slides 9 by action of the helical grooves 23 on the lugs 24.

 FIG. 4 also shows a metal or plastic insert 32 trapped in a housing 33 defined by the half-shells 2 and which has a boss 34 which, engaged in a recess 36 in the ring 8, limits to a fraction of a turn the rotation of the ring 8 about its axis.

 As regards the manufacture of the various components of the system, the deformable outlet nozzle 12 can be made of a flexible material of the silicone elastomer type or any other flexible material.

 The tubular support 7, the control ring 8, the slides 9 can be produced by molding in thermoplastic material. The tabs or frames 11 can also be produced by molding in thermoplastic material, but they can also be produced from a metal (steel, stainless steel, etc.) by cutting and stamping.

 FIGS. 4 and 5 show a tranquilization grid for the air flow 28 fixed to the support ring 7.

The operation of the device is as follows
In the extreme position shown in Figure 1, where the deformable nozzle 12 is cylindrical and the section of the circular air outlet, the tabs 17 and 18 of the tabs 11 are located in the same plane perpendicular to the air flow. The two cylindrical tabs 11 have their axes combined and are therefore located on the same ideal cylinder.

 When the control ring 8 is turned in the direction of the arrow F (FIG. 2), under the action of the ramps or grooves 23 on the lugs 24 of the sliders 9, the latter move together towards the outlet, causing their displacement the legs 18 of the frames 11 and therefore pivoting them radially outward. The axes of the reinforcements 11 which were initially combined, now form an angle A.

Under the action of the reinforcements 11, the nozzle 12 is deformed and the air outlet section then takes a rectangular or oblong shape depending on whether the ring 8 has been completely or only partially turned.

 Of course, the invention is not limited to the exemplary embodiments which have just been described, and many modifications can be made to them without departing from the scope of this invention.

 Thus the pivoting means of the armatures 11 could be produced differently.

 Similarly, the means for actuating an armature 11 could be produced differently. In particular, instead of providing two pairs "slide 9 - legs 18", one could be limited to a single couple, and, in this case, the operating ring 8 could be replaced by a control button acting directly on the couple preserved.

Claims (10)

 1. Hair dryer comprising means (3, 3 ') for heating and circulating an air flow, as well as means for modeling the flow to modify the geometry of the air jet emitted by a nozzle (12) of air outlet, and means (8, 9, 11) for controlling the flow shaping means (11), characterized in that, as flow shaping means, the nozzle (12) is deformable so reversible, and the control means comprise means (11) for adjustable positioning of certain regions of the nozzle (12).  2. Hair dryer according to claim 1, characterized in that the perimeter of the passage section inside the nozzle (12) has a value substantially independent of the position of the control means (8, 9, 11 ).  3. Hair dryer according to one of claims 1 or 2, characterized in that, in a first position of the control means (8, 9, 11), the nozzle (12) has a substantially cylindrical shape.  4. Hair dryer according to one of claims 1 to 3, characterized in that the control means comprise an armature (11) movable radially supporting said regions of the nozzle (12).  5. Hair dryer according to claim 4, characterized in that the frame (11) comprises two elongated members mounted in the nozzle (12) symmetrically with respect to an axial plane of the duct, and which can take different orientations with respect to said axial plane.  6. Hair dryer according to claim 5, characterized in that the two elongated members are two cylindrical tabs (11) whose circumferential dimension decreases towards the orifice of the nozzle.  7. Hair dryer according to one of claims 5 or 6, characterized in that each elongated member (11) is pivotally mounted about an axis oriented tangentially with respect to the nozzle (12).  8. Hair dryer according to claim 6, characterized in that each tab (11) is articulated relative to a housing (2) of the hair dryer along an axis substantially tangent to the middle of a rear edge (lia) of l 'tab (11), while in the vicinity of at least one of the ends (lake) of said rear edge (lia) the tab (11) is coupled to an actuator (9) movable in substantially axial direction .  9. Hair dryer according to claim 8, characterized in that each cylindrical tab (11) comprises a hinge tab (17) substantially located in the middle of the rear edge (lia) of the tab (11) and penetrating into a conjugate orifice (16) integral with the housing (2), and at least one actuating tab (18) near one of the two ends (lac) of the rear edge (la) of the tab (11) and penetrating into a conjugate recess (11) carried by the actuating member (9).  10. Hair dryer according to one of claims 8 or 9, characterized in that the actuating member (9) is a slide movable in axial translation relative to the nozzle (12) by means of a lug (24) penetrating into a helical groove (23) of a ring (8) movable in rotation about the axis of the nozzle.