JPH1068397A - Electric blower - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the generation of noises and to improve efficiency by forming a plurality of volute walls for dividing wind from a fan on the fan side of a diffuser and a plurality of guide vanes for guiding the wind from the fan to the reverse surface of the diffuser on the outer peripheral surface of the diffuser and by forming a gap between each volute wall and each guide vane. SOLUTION: Guide vanes 17 each of which has a slanting plane 16 slanting toward an electric motor side from a fan side or a diffuser surface side are formed on the outer peripheral portion of a diffuser 14 fixed to the end plate of a blower by screws. Volute walls 19 are annularly disposed on a flat portion 20 on the surface of the diffuser 14 inside the guide vanes 17 and the fan is housed in a space surrounded by the volute walls 19. Wind from the fan is divided and straightened by a plurality of volute rooms 21 formed by the volute walls 19. The flat portion 20 formed in this way between the volute walls 19 and the guide vanes 17 smoothly merges and introduces air flow to the slanting planes 16 to prevent the generation of noises.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an electric blower used for a vacuum cleaner or the like.

[0002]

2. Description of the Related Art Conventionally, the diffuser of an electric blower is
As disclosed in JP-A-3-78600 (F04D 29/44), an exhaust rib formed on the back surface of the diffuser and an inclined passage formed on the outer peripheral surface of the diffuser and guiding wind from the fan to the back side of the diffuser are formed. As disclosed in JP-A-7-35097 (F04D 29/44),
There is a known type having a volute wall formed on an upper surface of a diffuser and an exhaust rib formed on a rear surface of the diffuser.

[0003] The former has a wide operating range of air flow because there is no volute wall on the diffuser upper surface, but the maximum efficiency is low and surging is likely to occur. The latter has a narrow operating range of air flow because it has a volute wall. It has the characteristics that the maximum efficiency is high and surging hardly occurs.

[0004] For this reason, Japanese Patent Application Laid-Open No. 60-247093 (F04D
As shown in (25/08), a volute wall is formed on the diffuser upper surface, and an exhaust passage is formed on the back surface,
There is a diffuser having an inclined passage formed on the outer peripheral surface of the diffuser for guiding the wind from the fan to the back side of the diffuser, and having both of the above two features.

However, since the diffuser has the same number of volutes as the number of inclined passages and also has a shape which also serves as the inner peripheral wall of the inclined passage of the volute wall, the wind discharged from the fan is divided into the number of volute walls. Immediately after turning, most of the air is guided to the inclined passage connected to the outlet of the volute wall, and the exhaust gas is exhausted to the outlet of the exhaust passage while being divided by the volute wall.

Accordingly, the wind noise generated when the wind discharged from the fan contacts the volute wall and the wind noise generated at the entrance of the inclined passage have the same frequency, and there is a disadvantage that noise increases.

For this reason, by increasing the number of the volute walls and the number of inclined passages continuous with the volute walls, the frequency of the noise when the wind from the fan contacts the volute walls is increased, and the discomfort due to the noise is reduced. However, this configuration has a problem that the angle of the inclined passage becomes large, which causes surging and a reduction in efficiency.

[0008]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned drawbacks, and has as its object to provide an electric blower capable of reducing noise and improving efficiency.

[0009]

SUMMARY OF THE INVENTION The present invention comprises an electric motor having a built-in stator and a rotor, and a blower having a built-in fan and a diffuser. The blower is formed on the side surface of the diffuser so as to face the outer periphery of the fan. A plurality of volute walls for dividing the wind from the fan, guide vanes formed on the outer peripheral surface of the diffuser to guide the wind from the fan to the back of the diffuser, and an exhaust passage formed on the back of the diffuser; A gap is formed between the wall and the guide vane.

Further, the present invention comprises an electric motor having a stator and a rotor therein, and a blower having a fan and a diffuser therein. The fan is formed on a side surface of the diffuser so as to face the outer periphery of the fan, and the air from the fan is formed. A plurality of volute walls, a guide wing formed on the outer peripheral surface of the diffuser to guide the wind from the fan to the back surface of the diffuser, and an exhaust passage formed on the back surface of the diffuser, wherein the number of the volute walls is reduced. The number of guide wings is different.

It is desirable that the number of the volute walls be substantially a multiple of the number of blades of the fan, and more preferable that the number be a prime number that is substantially a multiple of the number of blades.

Further, the present invention comprises an electric motor containing a stator and a rotor, and a blower containing a fan and a diffuser. The fan is formed on a side surface of the diffuser so as to face the outer periphery of the fan, and the air from the fan is formed. A plurality of volute walls, a guide vane formed on the outer peripheral surface of the diffuser to guide wind from a fan to the back surface of the diffuser, and an exhaust passage formed on the back surface of the diffuser; And discontinuously formed.

It is preferable that the inclined surface of the guide vane has a substantially triangular shape whose area gradually increases from the upstream side to the downstream side of the airflow from the fan.

Further, the inclined surface of the guide vane has a substantially triangular shape whose area gradually increases from the upstream side to the downstream side of the airflow from the fan, and the fan side surface of the diffuser is formed as It is desirable to incline gradually downward from the surface toward the outer diameter portion of the diffuser.

[0015]

Embodiments of the present invention will be described below in detail with reference to the drawings.

Reference numeral 1 denotes an electric blower, which comprises an electric motor 2 and a blower 3.

First, the electric motor 2 will be described. Reference numeral 4 denotes a bottomed cylindrical bracket having an open end, on which a stator 5 and a rotor 6 are housed. ing. Reference numeral 8 denotes a brush holding portion fixed to the bracket 4, and makes the carbon brush 9 held inside elastically contact the outer peripheral surface of the commutator 10 of the rotor 6.

Reference numeral 11 denotes ball bearings which are press-fitted and fixed to the bottom surface of the bracket 4 and the center of the end plate 7, respectively, and rotatably support both ends of a rotating shaft 12 of the rotor 6 respectively. 13
Is a ball bearing 11 of the rotating shaft 12 and a fan to be described later.
A sleeve which is disposed between the fan 22 and the ball bearing 11 and serves as a space maintaining means for maintaining a space between the fan 22 and the ball bearing 11.

Next, the blower 3 will be described.

Reference numeral 14 denotes a diffuser which is fixed to the end plate 7 with screws 15. The diffuser 14 is provided with an electric motor 2 on the outer periphery of the diffuser 14 from the side of a fan 22 (to be described later) (surface of the diffuser 14).
Inclined surface inclining toward the side (diffuser 14 back side)
A guide wing 17 having 16 is formed over the entire circumference (eight in the present embodiment), and the inclined surface 16 of the guide wing 17 is
As viewed from the top, the air flow is formed in a substantially triangular shape whose area gradually increases from the upstream side of the air flow (toward a fan 22 described later) to the downstream side. Reference numeral 18 denotes an exhaust passage formed on the back surface of the diffuser 14, which is formed in the same number as the guide vanes 17 continuously with the guide vanes 17.

Reference numeral 19 denotes a volute wall which is annularly disposed on the surface of the diffuser 14 with a flat portion 20 provided between the diffuser 14 and the guide blade 17. A fan 22 which will be described later is provided in a space surrounded by the volute wall 19. And the volute wall 19
Fan 22 by a plurality of volute chambers 21 formed by
It divides the wind from the rectifier and rectifies it. In the present embodiment, 18 volute walls 19 are formed, and the inner diameter of the annularly arranged volute walls 19 is 97 mm, and the outer volute diameter is 111 mm.

The surface of the diffuser 14 is gradually inclined downward (0.1 mm in the present embodiment) from the inner diameter of the volute wall 19 toward the outer periphery, and is higher than the upper surface A of the entrance of the guide vane 17. Since the upper surface B on the inner diameter side of the outlet portion is at a high position, the airflow discharged from the fan 22 described later
In addition to being easy to flow to the inclination of 17, backflow of air from the vicinity of the guide blade 17 outlet to the diffuser 14 surface side can be prevented.

Reference numeral 22 denotes a fan fixed to the rotating shaft 12 of the rotor 6 extending through the diffuser 14. The front shroud 24, the rear shroud 25 and the front and rear shroud 25 have an air inlet 23 at the center of the fan 22. It is composed of a plurality of blades 26 (eight in this embodiment) fixed between the shrouds 24 and 25.

Reference numeral 27 denotes a fan cover for covering the diffuser 14 and the fan 22, which is press-fitted and fixed to the end plate 7, and has an intake port 28 formed substantially at the center of the fan cover 27.

The air flow discharged from the fan 22 is divided into the number of the volute walls 19, rectified in the volute chamber 21, and forcibly guided to the guide blades 17. Because a flat portion 20 is formed between the flat portion 17 and
The air flow divided by the volute wall 19 smoothly merges while turning to the outer peripheral side of the diffuser 14 to guide the wing 17
And the noise can be reduced, and the efficiency can be improved.

Further, since the number of the volute wall 19 and the number of the guide vanes 17 are different, a wind noise generated when a wind discharged from a fan 22 to be described later comes into contact with the volute wall 19 and a wind noise generated at the entrance of the guide vane 17 The frequency of the generated wind noise is different, and noise can be reduced. In this embodiment, 17 volute walls 19,
Although the number of blades of fan 22 was set to eight, as a result of the experiment,
It is most efficient if the volute wall 19 is formed to be approximately a multiple of the number of blades of the fan 22. However, if the volute wall 19 is formed to be 16 times, which is just twice the blade, the fan 22 and the volute wall 19 can be rotated when the fan 22 rotates. There is a problem that wind noise is generated at the same time in eight places and noise is increased.
It is desirable that the number of the volute walls 19 be about a multiple of the number of blades of the fan 22.

Further, when the number of the volute walls 19 is a prime number close to a multiple of the number of blades, wind noise does not occur at two or more places between the fan 22 and the volute wall 19 when the fan 22 rotates. It is most desirable that the number of the volute walls 19 be a prime number close to a multiple of the number of blades.

The 17 volute walls 19 and the fan 22
Assuming that the number of blades is eight and the number of guide blades 17 is eight, the number of volute walls 19 is substantially a multiple of the number of blades of the fan 22 and the number of guide blades 17 is substantially the same as the number of blades of the fan 22 As a result, the flow rate of the wind discharged from the fan 22 is the fastest and the flow can be efficiently rectified at the outlet of the fan 22 where surging is likely to occur. Is approximately the same as the number of blades of the fan 22 (6 to 11), the conversion efficiency from dynamic pressure to static pressure is the best,
A reduction in the blowing efficiency can be prevented and noise can be reduced.

Further, since the upper surface of the guide vane 17 is substantially triangular, the area of the air passage gradually increases from the guide vane 17 toward the exhaust passage 18, thereby improving the conversion efficiency from dynamic pressure to static pressure and surging. Generation can be prevented and the blowing efficiency can be improved.

Further, since the surface of the diffuser 14 is inclined gradually downward from the inner diameter of the volute wall 19 toward the outer periphery, the upper surface of the outlet portion is higher than the upper surface of the inlet portion of the guide blade 17, and The discharged air flow is guided by the guide wings 17.
And the backflow of air from the exit of the guide vane 17 to the surface of the diffuser 14 can be prevented.

In the above embodiment, the volute wall 19
The diameter of the circle surrounded by is 97 mm, the outer diameter of the volute is 111 mm, and the maximum outer diameter of the diffuser is 138.3 mm
Assuming that the diameter of the circle surrounded by the volute wall 19 is A, the diffuser maximum outer diameter is A × 1.35
A × 1.45 and the maximum outer diameter of the volute wall 19 is A × 1.13 to A × 1.24.

If the volute chamber 21 is too long, it tends to become a resistance when the air volume changes, and the performance deteriorates.
Although there is a problem that the outer diameter of the fan cover 27 increases, as a result of an experiment, by setting the above value, it is possible to prevent performance degradation due to generation of turbulence and to prevent the motor from being enlarged.

[0033]

According to the first aspect of the present invention, since the space is formed between the volute wall and the guide vanes, the air flow divided by the volute wall smoothly merges while turning to the outer peripheral side of the diffuser. As a result, the noise is reduced and the efficiency can be improved.

According to the second aspect of the present invention, since the number of the volute walls and the number of the guide vanes are different, the wind noise generated when the wind discharged from the fan contacts the volute walls and the wind noise generated at the guide vane inlet portion. Since the frequency of the wind noise is different, noise can be reduced by suppressing amplification of the frequency.

According to the third aspect of the present invention, by setting the number of the volute walls to be substantially a multiple of the number of the blades of the fan, the air blowing efficiency can be improved.

According to claim 4 of the present invention, when the number of volute walls is a prime number close to a multiple of the number of blades,
Wind noise does not occur at two or more locations between the fan and the volute wall when the fan rotates, and noise can be reliably reduced. According to claim 5 of the present invention,
Since the volute wall and the guide vane are formed discontinuously, the air flow divided by the volute wall smoothly merges while turning to the outer peripheral side of the diffuser and is guided to the guide vane, so that noise can be reduced and efficiency can be reduced. The frequency of the wind noise generated when the wind discharged from the fan contacts the volute wall and the frequency of the wind noise generated at the entrance of the guide vane are different, so the amplification of the frequency is suppressed and the noise is reduced. it can.

According to the sixth aspect of the present invention, the air passage area is gradually increased from the guide vanes toward the exhaust passage, and the efficiency of conversion from dynamic pressure to static pressure is improved. Efficiency can be improved.

According to the seventh aspect of the present invention, the area of the air passage gradually increases from the guide vanes toward the exhaust passage, and the efficiency of conversion from dynamic pressure to static pressure is improved. Efficiency can be improved. In addition, the upper surface of the outlet portion is higher than the upper surface of the inlet portion of the guide blade, so that the airflow discharged from the fan is easy to flow on the inclination of the guide blade, and the reverse flow of air from the guide blade outlet to the diffuser surface side. Can be prevented.

[Brief description of the drawings]

FIG. 1 is a perspective view of a diffuser used in an electric blower according to an embodiment of the present invention.

FIG. 2 is a top view of the same.

FIG. 3 is a bottom view of the same.

FIG. 4 is a sectional view of the same.

FIG. 5 is a partially cutaway view of the electric blower.

[Description of Signs] 2 Electric motor 3 Blower 5 Stator 6 Rotor 14 Diffuser 16 Inclined surface 17 Guide wing 19 Volute wall 22 Fan

Claims (7)

[Claims] An electric motor having a stator and a rotor therein;
A plurality of volute walls formed on the fan side surface of the diffuser, facing the outer periphery of the fan, and dividing the wind from the fan, and formed on the outer peripheral surface of the diffuser, from the fan. Guide wings that guide the wind to the back of the diffuser,
An electric blower, comprising: an exhaust passage formed on a back surface of the diffuser; and an interval formed between the volute wall and a guide vane. 2. An electric motor containing a stator and a rotor,
A plurality of volute walls formed on the fan side surface of the diffuser, facing the outer periphery of the fan, and dividing the wind from the fan, and formed on the outer peripheral surface of the diffuser, from the fan. Guide wings that guide the wind to the back of the diffuser,
An electric blower, comprising: an exhaust passage formed on the back surface of the diffuser; and the number of the volute walls is different from the number of guide vanes. 3. The electric blower according to claim 2, wherein the number of said volute walls is substantially a multiple of the number of blades of a fan. 4. The electric blower according to claim 2, wherein the number of said volute walls is a prime number which is substantially a multiple of the number of blades of a fan. 5. A plurality of motors each including a stator and a rotor, and a blower including a fan and a diffuser, the plurality of fans being formed on a side surface of the diffuser so as to face the outer periphery of the fan and dividing the wind from the fan. A volute wall, a guide vane formed on the outer peripheral surface of the diffuser and guiding the wind from the fan to the back surface of the diffuser, and an exhaust passage formed on the back surface of the diffuser, the volute wall being discontinuous with the guide vane. An electric blower characterized by being formed. 6. The inclined surface of the guide vane has a substantially triangular shape whose area gradually increases from the upstream side to the downstream side of the airflow from the fan. An electric blower according to claim 5. 7. An inclined surface of the guide vane is formed in a substantially triangular shape whose area gradually increases from an upstream side to a downstream side of an air flow from a fan, and a fan side surface of the diffuser is formed with a volute wall inner portion. The electric blower according to claim 1, 2 or 5, wherein the electric blower is gradually inclined downward from the bottom toward the diffuser outer diameter portion.