BR102014004615B1 - HAIR DRYER WITH NOISE REDUCTION - Google Patents

Description

"NOISE REDUCING HAIR DRYER" [001] The present invention contemplates a hair dryer with low noise emission, increased energy efficiency due to improvements in aerodynamic performance, improvements resulting from the use of a flow impeller. (8), ie radial part, axial part.

BACKGROUND OF THE INVENTION

Inside these fans, the air flow is turbulent which causes the dryer to make noises during operation. In some cases, the noises are loud, which brings discomfort to users, or even hearing health problems.

In view of this, a hair dryer has been developed that improves the air flow inside the dryer housing, reducing the level of noise emitted during the operation of the equipment. Changing the impeller internal system does not affect the external characteristics of the dryer.

TECHNICAL STATE

Ordinary hair dryers work with an impeller positioned inside their carcass that causes internal air flow. The impeller sucks in air from the back of the dryer, throwing it to the front. The air, after passing through the fan, goes through an electrical resistance that heats it. Thus, air exits the dryer at high speed and is heated. The heated air allows to accelerate the process of water evaporation and moisture removal from wet hair, as well as to shape and shape the hair.

Household dryers use axial type impellers (Figure 14) which suck and propel air in a direction parallel to the axis of rotation. Axial impellers have low compression capacity and are used in low power airflow dryers. In this assembly, the air flow increases proportionally with increasing impeller rotation to a maximum air flow limit where stalling occurs. From this rotation, any increase in rotation will not increase flow, but will generate more turbulence and noise-causing vortices.

Professional dryers, on the other hand, require greater air flow and compression using radial impellers (figure 16), which draw air in parallel direction and propel perpendicular to the axis of rotation.

[007] With radial impellers, stalling is reduced because air is propelled by centrifugal force, so impellers can operate at higher speed and consequently generate greater air flow.

[008] There are also winding impellers that draw air from the sides and propel the air tangentially to the direction of rotation in front of the dryer. In this case the motor and impeller are mounted perpendicular to the air flow. These impellers are in disuse and their working principle is very similar to radial impellers.

US 6,011,903 discloses an axial flow hair dryer comprising a circular body with a transition portion that gently reduces the diameter of the carcass to an outlet. A first ventilation step generates an axial air flow through the housing. An external duet has two axial extensions held by the housing near the initial transition portion, and an air outlet housing introduces air exiting the housing to an external duet. The casing and outer duet form two additional air inlets that extend between the axial extensions in a smooth arc toward the outlet of the main casing. The document discloses other configurations for mounting the hair dryer, but none relates to the use of mixed type impeller according to the present invention.

Another example is document CN 2741418, which discloses a constructive arrangement in hair dryer capable of achieving cost savings as it does not require heat-proof materials for the external casing of the dryer, improving air efficiency. compressed, reducing the noise. However, the dryer does not use a mixed type impeller and its assembly differs from the present patent application.

WO 2012/069983 discloses a hair dryer comprising a first sound absorbing means or sound insulation means positioned internally in the housing, interposed between the rear portion and the fan, other than the present invention, which is not It comprises no foam to absorb noise.

All the aforementioned documents are defined as general state of the art which aid in understanding the present invention.

DESCRIPTION OF THE FIGURES

[0013] Figure 1 shows the front view and cross section of the noise reduction hair dryer, with details of the core components mounted within the housing (1) of the noise reduction hair dryer.

[0014] Figure 2 shows the cross section, as shown in Figure 1, of the housing (1) of the noise reduction hair dryer, with emphasis on the insulating chamber (6) formed between the housing and the dryer core.

Figure 3 shows the core (20) of the noise reduction hair dryer.

Figure 4 shows the partial cross-section as shown in Figure 1, where you can see the noise-reducing hair dryer core system (20) inside the housing (1) and the basic parts that make up the core (20) of the dryer, which are respectively air inlet (12), flow direction (9) and internal fairing (2).

Figures 5 and 6 show, respectively, the air flow within the dryer core (20) and the air flow alignment scheme within the flow director (9).

Figures 7, 8 and 9 show, respectively, side, front and isometric views of the proposed noise reduction hair dryer impeller.

Figures 10 to 13 show the parts that make up the dryer core, which are respectively air inlet (12), motor fairing (4), flow direction (9) and internal fairing (2).

Figures 14 and 15 show front and side view of a common axial hair dryer impeller.

Figure 16 shows a schematic front view of the radial impeller of a common hair dryer.

DETAILED DESCRIPTION OF THE FIGURES

Figure 1 shows the front view and cross section of the hair dryer. Air is drawn through the air inlet (10), drawn in by the impeller (8) which is rotated by the electric motor (5) positioned within the motor fairing (4). Thus, an air flow is generated in the compression area (7), which flows through the internal cavities of the flow director (9) until it passes through the resistive elements (3) positioned inside the inner fairing (2). The air exits, heated, through the air outlet (11). This system is built into the housing (1) and is acoustically insulated by the air that is still between the outer housing (1) and the fairing surrounding the impeller, forming an air insulating chamber (6). The small and large impeller blades (8) occupy the same area as the compression region (7).

[0023] Figure 2 shows in the cross-section of the noise-reducing hair dryer housing (1) the air inlet (10), the air outlet (11), with emphasis on the air insulating chamber (6 ) formed between the housing and the dryer core.

Figure 3 shows the core (20) of the noise-reducing hair dryer with cold air inlet (10) and heated air outlet (11).

[0025] Figure 4 shows a partial cross section of the noise-reducing hair dryer as shown in Figure 1, highlighting the core (20) mounted within the hair dryer housing. In this view, in addition to the cold air inlet (10) and hot air outlet (11), we can see the external parts of the dryer operating core, which are: air intake (12), motor fairing (4), flow direction (9) and internal fairing (2).

[0026] Figure 5 shows a schematic drawing of the air flow within the noise-reducing hair dryer core (20). Highlighting the electric motor (5), mounted within the motor fairing (4), which rotates the impeller (8) positioned inside the air inlet (12) causing an air flow in the compression area (7), this compressed air , flows through the flow controller (9), through the inner fairing (2) to the air outlet (11). For engine cooling, part of the air flow (7) pushed forward is deflected into the engine fairing (4).

Figures 5 and 6 show, respectively, the air flow within the dryer core and the air flow alignment scheme within the flow direction (9).

Figure 6 shows an internal view of the flow aligner (9) and the mixed impeller (8). The air being propelled by the large (101) and small (102) fins tend to come out with an unfavorable rotational motion to the flow. In this view it is possible to observe the air flow alignment (7) as it passes through the channels between the fins (103) and (104) of the flow director (9).

Figure 7 shows the side view of the mixed impeller of the proposed noise reduction hair dryer.

[0030] Figure 8 is a front view of the mixed impeller of the proposed noise reduction hair dryer.

Figure 9 shows the isometric view of the mixed impeller of the proposed noise reduction hair dryer.

Figures 10, 11, 12 and 13 show the parts that make up the dryer core, which are respectively air inlet (12), motor fairing (4), flow direction (9) and internal fairing (2). ).

Figures 14 and 15 show front and side view of a common axial hair dryer impeller.

Figure 16 shows the front view of a radial impeller (40) which, when rotating, causes an air flow in the direction perpendicular to the axis of rotation.

DESCRIPTION OF THE INVENTION

The present model of noise reduction hair dryer is mounted with a mixed flow impeller as it features both an axial and a radial impeller.

This impeller operates in three stages.

In the first, air is drawn with flow parallel to the axis of rotation. In the second, the air flow goes perpendicular to the axis (radial direction), which compresses the air. In the third and last stage, the air flow is propelled parallel to the axis of rotation directing the flow forward of the dryer.

In the end, the air flow caused by the impeller has a direction parallel to the axis of rotation. However, air flow at the impeller outlet has a significant component of tangential displacement to the axis of rotation, which is converted to parallel or axial flow using static fins (103) and (104) within the flow director. (9).

The impeller is manufactured by the plastic injection process, and its shape has been determined after extensive studies and aerodynamic performance testing.

The mixed flow impeller (8) and static fins (103) were designed with the aid of compressor design and optimization software, and their shapes and surfaces were generated by algorithms powered by conditions of use such as engine speed. , power, diameter, desired compression ratio and desired flow.

In a next step the impeller was adapted to the injection process, where the blade inclination angle was kept constant to enable the injection process and mold extraction.

Since the results of computational aerodynamic simulations are not accurate, dozens of impeller prototypes were made with slight variations in the inclination angles, surface area and amount of impeller blades until the chosen feature set was reached.

[0043] In the performance tests, the proposed architectural dryer has its supply voltage reduced to the point where its flow equals the other existing models to have its noise emission measured, 0 noise was measured in decibel scale, a logarithmic scale, [0044] The percentage difference in sound power, shown in Table 1, is required by equation (1): where P (IB and Pd & are the powers of the proposed dryer only and compared, respectively, in decibel scale, and WW and "are, respectively, the absolute sound powers of the compared dryer and the reference, in this case the proposed one.

By rewriting formula (1) by making the antiIogarithm we can determine the absolute sound power ratio: (2) The percentage ratio can then be given by formula (3): (3) In Table 1 we show the values obtained in some comparative tests among the main professional dryers available in the market.

In order to reduce air drag in the inner ducts, the inside of the dryer features geometry that reduces clogging and eliminates vortex and turbulence generation points.

In order to keep the motor and electrical resistance in their positions within the dryer housing, supports are constructed. These supports and internal electrical wiring obstruct the air flow generated by the impeller.

In the present invention, stator mounts were used to provide mechanical support to the aerodynamically shaped motor. The aerodynamic shape of these supports, besides minimizing the formation of vortices and aerodynamic drag, help to redirect the flow generated in the tangential impeller to the axial direction, thus favoring the increase of flow with the reduction of noise.

Another limitation to air flow is caused by imperfections within the carcass with the formation of steps or corners.

These imperfections are eliminated, or at least minimized, by enclosing the motor and wiring it into fairings within the dryer core.

This eliminates steps and smoothes the abrupt variation in cross-sectional size along the interior of the housing.

Finally, the inner assembly, called the dryer core (Figs. 3 and 4), is placed inside the outer housing of the dryer (1). The core and the housing m are separated by air »This means that the noise propagated and emitted to the outside is significantly reduced» [0054] Noise test for same flow in different hair dryers [0055] In this comparative test the dryer The proposed architecture has its supply voltage reduced to the point where its flow equals that of its competitors so that its noise emission can be measured.

Table 1 [0056] Conclusion: By equating the flow generated by manipulating the supply voltage of the proposed noise reduction hair dryer, it is possible to confirm a better acoustic aero performance for the same flow when compared to the existing models that emit, 4.06dB, which corresponds to a sound power 155% higher than the one generated by the proposed model.

[0057] In view of our experiments and in particular of the above, we find that the present noise reduction hair dryer has advantages for users and can be considered an advance over the current state of the art.

Claims (6)

1) "NOISE REDUCING HAIR DRYER" consisting of an insulating core (20) mounted within a hair dryer housing (1) with air flow (7) generated by the rotation of an impeller (8) positioned inside the core (20), wherein said core is comprised of an air inlet (12), a flow driver (9), an engine fairing (4), an internal fairing (2), motor (5) and resistive element (3), characterized in that said impeller (8) is of mixed, axial and radial type, further including large blades (101) and small blades (102), according to figures 6 to 9, which when rotating creates an air flow (7) in the axial direction passing through the vane (103) of the flow director (9), said impeller (8), together with the other components, mounted within a dryer core (20). "DRYER" according to claim 1 or 2, characterized in that the outer casing (1) has an area of still air as acoustic insulation (6) which absorbs noise generated by the motor (5), impeller (8) and air flow (7). "DRYER" according to any one of the preceding claims, characterized in that the mixed impeller (8) is made of thermoplastic material by the injection process, machining or assembled by specific parts. "DRYER" according to any of the preceding claims, characterized in that the operating core (20) is manufactured separately or integrally with the outer housing (1). Dryer according to any one of the preceding claims, characterized in that the core (20) and the outer housing (1) are separated by a still air insulating chamber (6). "DRYER" according to any of the preceding claims, characterized in that the insulating chamber (6) is not filled with insulating material.