RU2388400C2 - Motor-fan and electric vacuum cleaner that uses it - Google Patents

Abstract

FIELD: personal use articles. ^ SUBSTANCE: inventions relate to electric vacuum cleaner and motor-fan used in it. Motor-fan comprises electric motor with rotary shaft, centrifugal fan fixed on rotary shaft of electric motor with multiple blades arranged separately between a pair of opposite plates, and diffuser having multiple blades, every of which is arranged on the side of outer peripheral section of centrifugal fan opposite to outlet holes for air formed on peripheral surface of centrifugal fan. Each of fan blades has the front end section, which is arranged so that it is linearly inclined from one end of final section of fan blade to its other end. Fan blades have section between the front disk plate arranged on side of inlet air hole and back plate arranged opposite to front plate and having the same diametre as diametre of front plate. The first end of front end section of fan blade is arranged on section displaced from outer peripheral end of front plate to the side of centrifugal fan axis, and the second end of front end section of fan blade is arranged on section displaced relative to the first end of front plate to the side of centrifugal fan axis. In version of motor-fan front end section may be curvilinearly inclined from one end of final section of fan blade to its other end. Electric vacuum cleaner comprises vacuum cleaner body and motor-fan arranged in vacuum cleaner body and having electric motor with rotary shaft. ^ EFFECT: fan with engine and electric vacuum cleaner using this fan may suppress or reduce generation of excessive noise even in case vacuum cleaner operates under conditions of low air consumption and in the area of high frequencies. ^ 3 cl, 12 dwg, 2 tbl, 1 ex

Description

FIELD OF THE INVENTION

The present invention relates to a motor fan (electric motor driven fan) having an improved fan blade shape, and to an electric vacuum cleaner using a motor fan.

State of the art

Typically, an electric vacuum cleaner includes a motor fan and dust collecting means located within the body of the vacuum cleaner. An electric vacuum cleaner sucks in dust that accumulates on the surface and must be removed together with air by the suction force of the electric motor fan, while the sucked air and dust must be separated by means of dust collection. Separated dust accumulates in the dust collection means, and clean air from which dust is removed is discharged to the outside.

The motor fan includes an electric motor and a discharge element rotated by an electric motor. A centrifugal type of fan is used as such a blower element, and the motor-fan is equipped with a diffuser to evenly control the flow of air leaving the centrifugal fan.

The motor fan used for the electric vacuum cleaner is required to reduce noise to protect the user from unwanted noise.

As one of the countermeasures to reduce noise, a centrifugal fan 51 was proposed here, as shown in FIG. 11, in which the fan blade 52 is designed so that its outer diameter is smaller than the diameter of the round fan plate 53. This type of centrifugal fan has excellent noise characteristics under normal operating conditions. However, compared with traditional and conventional centrifugal fans, in which the fan blade has the same outer diameter as the fan disk plate, there is such a problem that the proposed centrifugal fan 51 produces undesirable noises in low air flow conditions and at high frequencies.

To suppress high-frequency noise produced by a centrifugal fan, a motor fan is also provided with a diffuser that slopes in the direction of the outer circumference, for example, as in Patent Document 1 (Japanese Patent Application, Published Patent Application Laid-Open No. 2002-115698).

Disclosure of invention

The present invention has been made in view of the circumstances described above that we have encountered in the prior art, and the object of the present invention is to suppress or reduce excessive noise during operation of a motor fan and an electric vacuum cleaner using a motor fan, even if the vacuum cleaner is operated under conditions low air flow and in the high frequency region.

To solve this problem, the present invention provides a motor fan, comprising an electric motor with a rotating shaft; a centrifugal fan with many fan blades located separately between a pair of opposing plates, the centrifugal fan mounted on a rotating shaft of an electric motor; and a diffuser with many blades (diffuser blades), each of which is located on the outer peripheral section of the centrifugal fan so that they are opposite the air exit portions formed on the peripheral surface of the centrifugal fan, while each of the fan blades has an inclined section made with almost linear inclination from one lateral end portion towards another lateral end portion of the fan blade.

In the object described above, it is desirable that the fan blades are located in the area between the front plate located on the side of the inlet air hole and the rear plate located opposite the front plate and having the same diameter as the diameter of the front plate, with one end of the front end portion the fan blade is located on a section offset from the outer peripheral end of the front plate towards the axis of the centrifugal fan, and the other end of the front end section of the vein blade the tiller is located in a section offset from the first end of the front plate towards the axis of the centrifugal fan.

In another aspect of the present invention, there is also provided an electric vacuum cleaner comprising a vacuum cleaner body and a motor fan that is housed in a vacuum cleaner body, the motor fan having the structure mentioned above.

The present invention provides a motor fan capable of suppressing or reducing excessive noise during operation.

In addition, according to the present invention, there may be proposed an electric vacuum cleaner equipped with such a motor fan to suppress or reduce excessive noise, even if the vacuum cleaner operates in low air flow and in the high frequency region.

Brief Description of the Drawings

In the accompanying drawings:

figure 1 is a side view, half in section, showing the design of one of the embodiments of the motor fan according to the present invention;

2A is a plan view schematically showing the structure of a diffuser used for a motor fan of an embodiment of the present invention described above.

2B is a bottom view schematically showing a diffuser structure;

3 is a perspective view schematically showing the structure of a centrifugal fan used for a motor fan according to the present invention;

4 is a longitudinal sectional view schematically showing the structure of a centrifugal fan used for a motor fan;

5 is a plan view schematically showing a fan blade of a centrifugal fan;

6 is a perspective view showing an external configuration of an electric vacuum cleaner according to another embodiment of the present invention;

7 is a graph showing the results of a noise assessment test conducted using a motor fan according to the present invention in a state where low air flow is realized; the graph shows the relationship between voltage and noise level;

Fig. 8 is a graph showing the results of a noise assessment test conducted using one embodiment of a motor fan according to the present invention in a state where low air flow is realized; the graph shows the relationship between frequency and noise value;

Fig. 9 is a graph showing the results of a noise assessment test conducted using one embodiment of a motor fan according to the present invention in a state where maximum air flow is realized; the graph shows the relationship between voltage and noise level;

10 is a graph depicting the results of a noise assessment test conducted using a motor fan according to the present invention in a state where maximum air flow is realized; the graph shows the relationship between frequency and noise value;

11 is an illustrated longitudinal sectional view schematically showing the structure of a centrifugal fan used in a conventional fan motor.

The implementation of the invention

An embodiment of a motor fan according to the present invention will be described below with reference to the accompanying drawings.

Figure 1 is a side view, in partial section, showing the structure of the motor fan according to the present invention.

As shown in figure 1, the motor fan 1 contains a centrifugal fan or fan 2 made of metal, an electric motor 4 for rotating the centrifugal fan 2 through the shaft 3, and a housing 5 used as a casing containing the centrifugal fan 2 and the electric motor 4, together with attached elements, if any.

The housing 5 includes a fan casing 6 covering the centrifugal fan 2, and an engine casing 7 containing an electric motor.

As the electric motor 4, a brush type motor is used. The engine cover 7 has a structure located at the bottom, which includes a portion formed by the rear disc plate 11 and a portion of the fan housing 7 that is open and is a neck 12 through which the electric motor 4 is installed in the engine cover 7.

The central portion of the rear plate 11 forms an axial-shaped protrusion in the axial direction from the rear side of the surface of the engine casing 7, forming a portion 12b serving as a support for the bearing into which the bearing 12a is mounted.

The frame 8 is fixed to the neck 12 of the casing 7 of the engine with screws 14 so that it is perpendicular to the rotating shaft 3 of the engine 4.

The frame 8 has a bridge structure, which also has many elongated elements located radially from the rotating shaft 3 of the motor 4. The inner peripheral side of the lower end of the section of the fan casing 6 is combined with the engine casing 7, forming a motor-fan case 5.

In addition, the inner peripheral sections of the casing 7 of the engine, the frame 8 and the casing 6 of the fan can be made in such a way as to have the same size. The frame 8 protrudes forward at the location of its central portion in the form of a cylinder so as to form a portion 13b serving as a support for the bearing and having an open part in the form of a through hole (not shown) through which the rotating shaft 3 passes. The bearing 13a is placed in the portion 13b serving as a support for the bearing.

The centrifugal fan 2 and the diffuser 21 are closed by the fan casing 6. The fan casing 6 is provided on the central portion of its front surface with an inlet neck 6a opposite the inlet window 31 of the centrifugal fan 2, while the entire rear surface of the fan casing 6 is provided with a rear open portion (not shown) so as to provide a substantially cylindrical shape all configuration.

On the other hand, the motor 4 consists of a stator 15 fixed to the motor casing and a rotor 16 located inside the stator 15. Both end sections of the rotary shaft 3 of the rotor 16 are supported by rotation bearings 12a and 13a. A nozzle of blown air (not shown), like an outlet, is open on the peripheral surface near the rear surface of the casing 7 of the motor in the radial direction.

In addition, the diffuser 21 is fixed on the suction front side of the frame 8.

As shown in FIG. 2A, the diffuser 21 comprises a circular plate 22 having a substantially disk shape; an opening 23 located in the center of the circular plate 22 through which the shaft 3 passes; holes for screws 24a and 24b through which screws are inserted to fix the diffuser 21 to the frame 8; a plurality of circular arc-shaped vanes 25 oriented in the vertical direction in a portion close to the outer peripheral portion of the diffuser 21, so that the plurality of vanes 25 are positioned on the outer peripheral portion of the fan 2; and a plurality of circular arc shaped vanes 26 oriented in a vertical direction on the rear surface of the circular plate 22, each of the plurality of vanes 26 forming a spiral shape.

In addition, the diffuser 21 is inserted into the outer peripheral portion 13b, which serves as a support for the bearing, made in the frame 8 so that it is opposite the frame 8, then the diffuser is attached to the frame 8 with screws.

As shown in FIGS. 3-5, the centrifugal fan 2 comprises a front side disk plate 32 on which the inlet window 31 is located and a plurality of vanes 34. Fan blades 34 are located between the front side disk plate 32 located on the side of the inlet window 31 for air intake, and a rear side disk plate 33 having the same diameter as the front side disk plate 32 and located opposite it.

The blade 34 is provided with a plurality of mounting protrusions 34a. The mounting protrusions 34a are inserted into the mounting holes 32a and 33a, and then the mounting protrusions are minted to secure the blades. As a result, each fan blade 34 is locked in such a state that the fan blade 34 is inserted between the front side disk plate 32 and the rear side disk plate 33.

An air inlet 31 is provided in the central portion of the front side disk plate 32, while an outlet 35 is formed in the portion between the outer peripheral end portions 32b and 33b of the front side disk plate 32 and the rear side disk plate 33.

In the front end portion 34b of the fan blade 34, one side of the blade end portion 34b1 is positioned on the inner side (relative to the axial center side of the fan) of the outer peripheral portion 32b of the edge of the front side disk plate 32, while the other end portion 34b2 is located on the inside of the outer a peripheral portion 33b of the edge of the rear side of the disk plate 33. Those. the front end portion 34b of the fan blade 34 is linearly inclined from one side of the end portion 34b1 to the other side of the end portion 34b2 so that the other side of the end portion 34b2 is located on a portion that is offset from one side of the end portion 34b1 toward the axial center of the fan.

Thus, as shown in FIG. 4, provided that the diameter of the front side disk plate 32 is d1 and the diameter of the rear side disk plate 33 is d2, the diameter of the circle on which one side of the end portion 34b1 is located is d3, and the diameter the circle on which the other side of the final section 34b2 is located is d4, the following relationships are established:

d1 = d2, d1> d3, d3> d4.

In this regard, the shape of the front end portion 34b of the fan blade 34 is not limited to the straight line shape, as disclosed in the present embodiment. Other shapes can also be selected, for example, such as a curved shape, as well as a shape combining a curved and straight shape, a shape combining a straight shape with another straight shape, since in these cases the combined shape is almost a straight shape.

In the motor fan 1 in accordance with the design described above, when the shaft 3 is rotated, the centrifugal fan 2 also rotates, sucking in air. The sucked air passes from the inlet neck 6a, made on the front side of the surface of the fan casing 6, and exits through the outlet section 35 of the centrifugal fan 2. Then, the air passes through the sections between the blades 25 having an arcuate shape along the inner peripheral surface of the fan casing 6 and forms a flow that extends axially. Furthermore, on the back surface of the circular plate portion 22, this air passes through the portions between the blades 26 of an arc shape toward the center of the diffuser 21 in the form of a swirl movement.

Then, the air leaving the outlet openings 35 of the centrifugal fan 2 is uniformly straightened, and then it is supplied to the engine 4 by the diffuser 21. After the air supplied to the engine 4 cools it, it exits out of the casing 7.

According to the results of the noise assessment test conducted by the inventors of the object of the application, the noise level of the motor fan of this embodiment of the invention can be reduced in comparison with a conventional motor fan in which the outer diameter of the fan blade is the same as the fan disk plate, and the motor operates -fan of this embodiment of the invention can be performed in a quiet and calm mode.

In addition, even if the voltage is changed to change the rotation speed, the noise level of the motor fan of this embodiment can be reduced compared to a traditional fan motor in which the outer diameter of the fan blade is the same as the fan disk plate and the motor is running -fan of this embodiment of the invention can also be performed in a quiet and calm mode.

Moreover, since the front end portion 34b of the fan blade 34 is formed so that it is linearly inclined from one side of the end portion 34b1 to the other side of the end portion 34b2, this may provide the ability of the motor fan to reduce the generation of excessive noise even in the case of if the vacuum cleaner works in conditions of low air consumption and in the high frequency region, as a result of which the motor-fan can be produced at low cost with excellent efficiency in mass production.

According to the present embodiment of the invention, the motor fan becomes possible to suppress or reduce excessive noise even if the vacuum cleaner operates in low air flow conditions and in the high frequency region.

As shown in FIG. 6, a motor fan 1 of the present invention is assembled inside the cleaner body 42 of the cleaner 41. The windward side of the motor fan 1 is provided with dust collecting means 43 including a dust collecting section 43a of a centrifugal type and a pleated filter 43b for collecting dust . A hose 44, an extension pipe 45, and a nozzle 46 are connected to the windward side of the dust collecting means 43, which are collected in the cleaner body 42.

The vacuum cleaner 41, in which the motor-fan 1 is assembled, can suppress or reduce excessive noise even if the vacuum cleaner operates in low air flow and in the high frequency region, i.e. even if the cross-sectional area on the air flow path narrows due to dust that is collected in the dust collecting means 43, the vacuum cleaner 41 can operate in a calm and quiet mode. In addition, the vacuum cleaner 41 can easily operate with a low noise level even in the event of a change in the supply voltage.

According to the present embodiment of the vacuum cleaner, the generation of excessive noise can be suppressed or reduced even if the vacuum cleaner is operated at low air flow and at high frequencies.

An example embodiment of the invention

Noise levels during low air flow and maximum flow were measured using a motor fan (example) according to the present invention, which is shown in FIG. The measured values were compared with those of a traditional motor fan (comparative example), which is shown in Fig. 11.

(1) Test conditions for noise assessment

1) Air consumption: low (degree of vacuum: large), and the maximum mode of air consumption (degree of vacuum: small).

2) Measurement method: in the mode when there was a low air flow, the motor was placed on the urethane so that the carbon brushes of the engine were directed horizontally, while in the regime with the maximum air flow, the motor was mounted on the wrapping tube in such a way so that the carbon brushes of the engine are directed horizontally.

The microphone for determining the noise level was installed at a height of 1 meter from the center of the longitudinal dimension of the engine. Low air flow was realized by opening the angle of the gate of the passage opening of the flow control valve so that the air flow Q was set to the flow rate of 1.3 m ³ / min when the operating supply voltage was 100 V. In the mode when the angle of the valve of the passage of the valve is recorded, the operation of measuring noise.

Measurement of the degree of vacuum was performed on the windward side of the fan.

3) Environmental conditions when measured: the ambient temperature was 24 ° C, humidity - 48%, air pressure - 729 mm Hg.

(2) Results

1) The results obtained during the noise assessment test, which was performed in the low air flow mode, are shown below in table 1 and Fig.7.

From the test results shown in table 1, it becomes clear that in the low air flow mode (flow rate Q = 0.76 m ³ / min, supply voltage 40 V) the noise value produced by the motor-fan in the Example is 81.1 dB, while as the noise value in the Comparative Example is 83.4 dB.

When the supply voltage is 60 V and the air flow Q is 0.99 m ³ / min, the noise value produced by the fan motor in the Example is 89.5 dB, while the noise value in the Comparative Example is 91.8 dB.

In addition, when the supply voltage is 80 V and the air flow Q is 1.16 m ³ / min, the noise value produced by the fan motor in the Example is 88.3 dB, while the noise value in the Comparative Example is 90.8 dB.

Moreover, when the supply voltage is 100 V and the air flow Q is 1.3 m ³ / min, the noise value produced by the fan motor in the Example is 96.1 dB, while the noise value in the Comparative Example is 94.5 dB.

Thus, it can be confirmed that in the case when the low air flow mode (flow rate Q = 0.76 m ³ / min) is realized, the noise produced by the fan motor in the Example is lower than the similar indicators in the Comparative example, and the motor The fan shown in the Example line can be operated with low noise.

In addition, as confirmed by the results shown in Fig. 7, in the low airflow mode, the noise values produced by the fan-motor in the Example were obviously lower than those in the Comparative Example, over the entire range of supply voltages, even if the voltage changed to change fan speed.

In addition, as shown in Fig. 8, as a result of measuring the relationship between the noise frequency and the noise level in the case when the low air flow rate mode is implemented at a supply voltage of 60 V, it was confirmed that the noise values produced by the fan motor in the Example, were lower than those in the Comparative Example, in almost the entire frequency range.

In particular, in the frequency range showing a peak value that has a frequency of 10 kHz and higher, the noise values produced by the fan motor in the Example were obviously lower than those in the Comparative Example, thus, it was confirmed that the suppression of excessive noise or its reduction can be effectively achieved.

2) The results obtained during the noise assessment test, which was carried out in the mode when the maximum air flow was realized, are shown below in table 2 and in Fig. 9.

From the test results shown in table 2, it becomes clear that in the maximum air flow rate (flow rate Q = 1.68 m ³ / min, supply voltage 40 V), the noise produced by the motor-fan in the Example is 82.1 dB, while as the noise value in the Comparative Example is 81.6 dB.

When the supply voltage is 60 V and the air flow Q is 2.18 m ³ / min, the noise value produced by the fan motor in the Example is 87.6 dB, while the noise value in the Comparative Example is 88.2 dB.

In addition, when the supply voltage is 80 V and the air flow Q is 2.62 m ³ / min, the noise value produced by the fan motor in the Example is 89.6 dB, while the noise value in the Comparative Example is 89.6 dB.

Moreover, when the supply voltage is 100 V and the air flow Q is 3.00 m ³ / min, the noise value produced by the fan motor in the Example is 92.0 dB, while the noise value in the Comparative Example is 91.6 dB.

Thus, it can be confirmed that in the case when the maximum air flow rate (flow rate Q = 1.68-3.00 m ³ / min) is realized, there is a significant difference in noise level in the Example and in the Comparative example, even if the voltage was changed to change the speed fan rotation.

In addition, as confirmed by the results shown in Fig.9, there is no significant difference in noise level between the Example and the Comparative Example in the entire range of supply voltages in the maximum air flow rate mode.

Moreover, as shown in FIG. 10, as a result of measuring the relationship between the noise frequency and the noise level when the maximum air flow rate is implemented at a supply voltage of 60 V, it was confirmed that there is no significant difference in noise level between Example and A comparative example in the entire frequency range.

It should be noted that the present invention is not limited to the embodiment described here, and many other changes and modifications can be made without departing from the scope of the attached claims.

Claims (3)

1. A motor fan containing
electric motor with a rotating shaft;
a centrifugal fan with many blades located separately between a pair of opposing plates, the centrifugal fan mounted on a rotating shaft of an electric motor; and
a diffuser containing a plurality of blades, each of which is located on the side of the outer peripheral portion of the centrifugal fan opposite the air outlet openings formed on the peripheral surface of the centrifugal fan,
wherein each of the fan blades has a front end portion, which is made in such a way that it is linearly inclined from one end of the end portion of the fan blade to its other end, while
the fan blades have a section between the front disk plate located on the side of the inlet air hole and the rear plate opposite the front plate and having the same diameter as the diameter of the front plate, with the first end of the front end portion of the fan blade located in the section offset from the outer peripheral end of the front plate toward the axis of the centrifugal fan, and the second end of the front end portion of the fan blade is located on a section offset by relative to the first end of the front plate towards the axis of the centrifugal fan. 2. A motor fan containing
electric motor with a rotating shaft;
a centrifugal fan with many blades located separately between a pair of opposing plates, the centrifugal fan mounted on a rotating shaft of an electric motor; and
a diffuser containing a plurality of blades, each of which is located on the side of the outer peripheral portion of the centrifugal fan opposite the air outlet openings formed on the peripheral surface of the centrifugal fan,
wherein each of the fan blades has a front end portion, which is designed so that it is curved inclined from one end of the end portion of the fan blade to its other end, while
the fan blades have a section between the front disk plate located on the side of the inlet air hole and the rear plate located opposite the front plate and having the same diameter as the diameter of the front plate, with the first end of the front end portion of the fan blade located on the section offset from the outer peripheral end of the front plate toward the axis of the centrifugal fan, and the second end of the front end portion of the fan blade is located on a section offset by relative to the first end of the front plate towards the axis of the centrifugal fan. 3. An electric vacuum cleaner comprising a vacuum cleaner body and a motor fan located in a vacuum cleaner body, including an electric motor with a rotating shaft and made in accordance with claim 1 or 2.

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