KR20100087177A - Electric cleaner - Google Patents

Abstract

An electric vacuum cleaner capable of compressively elastically supporting an electric blower in an electric blower case and preventing noise and vibration caused by the operation of the electric blower is proposed. The elastic support 45 is an anti-vibration support part for preventing vibration by the electric blower 21, and includes an inner circumference ring 66 provided in the electric blower case 23 and an outer circumference provided near the center of gravity of the electric blower 21. A ring 67 and a coil spring 68, one end of which is fixed to the inner ring 66 and the other end of which is fixed to the outer ring 67, is a spring member to which a compressive force F is applied.

Description

Electric vacuum cleaner {ELECTRIC CLEANER}

The present invention relates to an electric vacuum cleaner including an electric blower case accommodating an electric blower and an anti-vibration support part that isolates vibration generated by the electric blower.

In general, an electric vacuum cleaner uses negative pressure generated by the operation of an electric blower housed in a vacuum cleaner body, and is accumulated on a surface to be cleaned such as a floor together with air from an inlet provided at the tip of a dust collecting hose connected to the vacuum cleaner body. The dust is sucked in, dust is captured by a high-speed separation dust removal means or a filter provided in the vacuum cleaner body, and the surface to be cleaned is cleaned.

In electric blowers used in electric vacuum cleaners, unnecessary pressure fluctuations are always caused in the air, which is the working fluid, and these pressure fluctuations propagate to surroundings and often generate noise. For example, periodic pressure fluctuations occur in the space due to the movement of the rotor blades of the fan portion, and the pressure fluctuations propagate as noise. In an electric blower, mechanical vibrations due to fluid vibrations such as surging and unbalance of the rotor occur. The dustproof support which prevents the noise and vibration of such an electric blower preferably supports the position having a small amplitude sufficiently softly. In addition, the dustproof support portion needs to support the weight of the electric blower in the radial direction and to support the suction force generated by the operation of the electric blower in the axial direction.

Therefore, Patent Document 1 is provided between a spring member provided between the center of gravity of the electric blower and the vacuum cleaner body via a circumferential ring provided in the vacuum cleaner body, and a gap between the motor and the vacuum cleaner body. An electric vacuum cleaner for elastically supporting an electric blower in a vacuum cleaner body is disclosed, using a shock absorbing front elastic body and a shock absorbing front elastic body provided with a gap between the fan outer periphery and the main body.

 Patent Document 1: Japanese Patent Laid-Open No. 5-84194

The electric blower of the conventional electric vacuum cleaner disclosed in Patent Document 1 is elastically supported in the vacuum cleaner body by a coil spring applied with a tension force, and the force applied radially to the electric blower is flexibly supported, but in the axial direction of the electric blower. Since the applied force is strongly supported with an increase in the axial displacement, it is possible to prevent the vibration generated by the operation of the electric blower from being transmitted to the vacuum cleaner body.

However, in order to apply a tensile force to the coil spring, it is necessary to extend the coil spring longer than the free length. Then, in the case where a sufficient distance between the inner surface of the electric blower accommodating chamber and the electric blower cannot be obtained, the coil spring cannot be elongated to tensilely support the electric blower.

For example, an electric blower is accommodated in an electric blower case, and this electric blower case is accommodated in an electric vacuum cleaner main body, and the noise and vibration by the operation of an electric blower are prevented. In the case where the coil spring is stretched to elastically support the electric blower in the electric blower case, it is difficult to attain both the separation distance between the electric blower and the electric blower case necessary for the extension of the coil spring and the miniaturization of the electric blower case. .

In order to improve the convenience of the electric vacuum cleaner, it is necessary to make the vacuum cleaner main body and the electric blower case lightweight. However, in the electric blower case which is thin and lightweight using resins such as ABS, sufficient rigidity is not obtained, and it is difficult to elastically support the electric blower in the electric blower case with a coil spring.

In addition, when a viscoelastic material such as rubber or urethane is disposed around the electric blower for vibration and soundproofing, it is suitable to reduce the resonance peak component of the electric blower, but the effect is not sufficiently obtained in the frequency range other than the resonance peak component. .

The present invention proposes an electric vacuum cleaner capable of compressively elastically supporting the electric blower in the electric blower case to prevent noise and vibration caused by the operation of the electric blower.

In order to solve the above problems, the present invention provides an electric blower that sucks dust-containing air into an electric vacuum cleaner, an electric blower case for accommodating the electric blower, and an electric blower case formed in the radial direction of the electric blower. An electric vacuum cleaner including a dustproof support for elastically supporting the electric blower by an applied compressive force is proposed.

1 is a perspective view showing an appearance of an electric vacuum cleaner according to a first embodiment of the present invention.
Fig. 2 is a longitudinal sectional view showing the vacuum cleaner main body of the electric vacuum cleaner according to the first embodiment of the present invention.
3 is a partially cutaway perspective view of the electric blower case and the electric blower of the electric vacuum cleaner according to the first embodiment of the present invention.
Fig. 4 is a diagram showing a relationship between the compression force applied to the coil spring of the electric vacuum cleaner according to the first embodiment of the present invention and the vibration transmitted from the electric blower to the electric blower case.
Fig. 5 is a diagram showing a relationship between the compression force applied to the coil spring of the electric vacuum cleaner according to the first embodiment of the present invention and the vibration transmitted from the electric blower to the electric blower case.
It is a figure which shows the relationship between the compression force applied to the coil spring of the electric vacuum cleaner which concerns on the 1st Embodiment of this invention, and the vibration transmitted from the electric blower to the electric blower case.
The perspective view which showed the electric blower case of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.
Fig. 8 is a partially cutaway perspective view of the electric blower case and the electric blower of the electric vacuum cleaner according to the second embodiment of the present invention.
9 is a perspective view showing an electric blower case and an electric blower of the electric vacuum cleaner according to the second embodiment of the present invention.
The perspective view which showed the outer periphery ring of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.
It is a perspective view which shows the other example of the suction side case member of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.
It is a rear view which shows the other example of the suction side case member of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.
It is a perspective view which shows the other example of the exhaust side case member of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.
It is a perspective view which shows the other example of the exhaust side case member of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.
It is a perspective view which shows the other example of the outer peripheral ring of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.
It is a rear view which shows the other example of the outer peripheral ring of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of the electric vacuum cleaner which concerns on this invention is described with reference to drawings.

[First Embodiment]

A first embodiment of an electric vacuum cleaner according to the present invention will be described with reference to FIGS. 1 to 6.

1 is a perspective view showing an appearance of an electric vacuum cleaner according to a first embodiment of the present invention.

As shown in FIG. 1, the electric vacuum cleaner 1 according to the present embodiment includes a vacuum cleaner main body 2, a dust collecting hose 3, a handle operating pipe 4, a gripper 5, and an operation unit 6. , Extension tube 7 and suction port 8.

The vacuum cleaner main body 2 has the connection opening 2a with which one end of the dust collecting hose 3 was detachably connected. The vacuum cleaner main body 2 also includes a power cord 11. A power plug 12 is formed at the free end of the power cord 11.

The dust collecting hose 3 is flexible and is formed in a substantially cylindrical shape which is bent and stretched. One end of the dust collecting hose 3 is detachably connected to the connection port 2a and communicates with the inside of the vacuum cleaner main body 2.

One end of the handle operating tube 4 is provided at the other end of the dust collecting hose 3, and is in fluid communication with the inside of the vacuum cleaner body 2 through the dust collecting hose 3.

The gripping portion 5 is gripped by the user of the electric vacuum cleaner 1 for the operation of the electric vacuum cleaner 1. The grip part 5 is provided so that it may be bent and protruded toward the one end part of the handle operation pipe 4 with which the dust collection hose 3 was provided from the other end of the handle operation pipe 4.

The operation part 6 is provided in the holding part 5. When the user of the electric vacuum cleaner 1 operates the operation unit 6, the electric vacuum cleaner 1 is set to a plurality of driving modes. The operation unit 6 includes an off switch 6a for stopping operation of the electric vacuum cleaner 1 and an on switch 6b for starting operation of the electric vacuum cleaner 1.

 The extension pipe 7 is elastically extended and is formed in a substantially cylindrical shape. One end of the extension tube 7 is detachably connected to the other end of the handle operation tube 4, and is in fluid communication with the inside of the vacuum cleaner body 2 via the handle operation tube 4 and the dust collecting hose 3.

The suction port 8 is detachably connected to one end of the extension tube 7, and is in fluid communication with the inside of the vacuum cleaner body 2 through the extension tube 7, the handle operating tube 4, and the dust collecting hose 3. .

It is a longitudinal cross-sectional view which shows the vacuum cleaner main body of the electric vacuum cleaner which concerns on 1st Embodiment of this invention.

As shown in FIG. 2, the vacuum cleaner main body 2 of the electric vacuum cleaner 1 includes a main body case 15, a dust separation dust collecting part 16 detachably mounted in the main body case 15, and a main body case 15. ) Is provided with a cover case 17 provided to be openable and closeable.

 On the front side of the main body case 15, a dust collecting chamber 19 in which the dust separating dust collecting unit 16 is detachably mounted is formed. The upper opening 20 of the dust collecting chamber 19 is sealed by the cover case 17.

An electric blower accommodating chamber 22 in which the electric blower 21 is accommodated is formed at the rear side of the main body case 15. The electric blower case 23 covers the electric blower 21 and is accommodated in the electric blower accommodation chamber 22. The electric blower case 23 includes a suction side case member 25 and an exhaust side case member 26. The electric blower case 23 is held by the mounting portion 27 provided on the front side of the electric blower accommodation chamber 22 and the mounting portion 28 provided on the rear side of the electric blower accommodation chamber 22. A front cover support member 29 is provided between the electric blower case 23 and the mounting portion 27, and a rear cover support member 30 is provided between the electric blower case 23 and the mounting portion 28. do. The front cover support member 29 and the rear cover support member 30 are elastic bodies such as rubber or silicone.

 In the front side of the electric blower accommodation chamber 22, the cylindrical connection air passage 33 which has the front surface opening 32 is formed. The front opening 32 is opened into the dust collecting chamber 19. The sealing ring 34 is mounted to the front opening 32. The seal ring 34 is packed between the dust separating dust collecting part 16 and the connecting air passage 33. The grating member 35 is provided in the connection air passage 33. A connecting opening 37 is formed in the rear wall 36 of the connecting air passage 33. The connection opening 37 is in fluid communication with the electric blower 21 covered by the electric blower case 23.

The dust separation dust collecting unit 16 includes a dust separating unit 39 for separating coarse dust from dust-containing air in an inertial separation method, a dust collecting unit 40 for collecting coarse dust separated by the dust separating unit 39, and a dust separating unit. A net filter 41 through which dust-containing air from which coarse dust has been separated by 39 passes, and a pleated filter 42 for separating and collecting fine dust from the dust-containing air. The pleated filter 42 is accommodated in the filter housing case 43 formed integrally with the dust separation unit 39.

When the user of the electric vacuum cleaner 1 operates the on switch 6b, the electric vacuum cleaner 1 starts operation. When the operation of the electric vacuum cleaner 1 is started, the electric blower 21 operates, and a negative pressure acts on the inside of the vacuum cleaner main body 2. This negative pressure is applied to the suction port 8 from the connection port 2a via the dust collecting hose 3, the handle operation pipe 4, and the extension pipe 7. Thereafter, the electric vacuum cleaner 1 sucks dust accumulated on the surface to be cleaned such as the floor from the suction port 8 together with air to clean the surface to be cleaned. The dust-containing air sucked by the inlet 8 is separated into air and dust by the dust separating dust collecting unit 16 accommodated in the vacuum cleaner body 2. The separated dust is collected by the dust collecting part 40 and the pleated filter 42. On the other hand, the separated air is sucked by the electric blower 21 and discharged from the vacuum cleaner main body 2.

Fig. 3 is a perspective view partially showing the electric blower case and the electric blower of the electric vacuum cleaner according to the first embodiment of the present invention.

3 shows only the casing of the electric blower 21.

As shown in FIG. 3, the electric blower case 23 of the electric vacuum cleaner 1 accommodates the electric blower 21 compression-elastically supported by the elastic support 45. The elastic support 45 elastically supports the electric blower 21 in the axial direction and the radial direction.

The electric blower 21 includes a motor (not shown), a centrifugal fan (not shown) rotated by the motor, and a diffuser (not shown) provided on the outer circumference of the centrifugal fan. The electric blower 21 has an inlet 21a through which air is sucked by underpressure caused by the operation of a centrifugal fan, and an exhaust port 21b through which the sucked air is exhausted. The electric blower 21 sucks air from the inlet 21a by rotating the centrifugal fan when the motor is operated. Air sucked by the electric blower 21 passes from the centrifugal fan to the diffuser to cool the motor. The electric blower 21 exhausts the air which cooled the motor through the exhaust port 21b.

 The electric blower case 23 is formed in a substantially closed end cylindrical shape using synthetic resin such as ABS. The electric blower case 23 includes a suction side case member 25 and an exhaust side case member 26.

 The suction side case member 25 is formed in the cylindrical shape of the sealed end which one side opened. The suction port side bottom wall portion 47, which is the bottom of the suction side case member 25, has a case suction port 48. The case inlet 48 is in fluid communication with the connecting air passage 33 of the vacuum cleaner body 2 and in fluid communication with the inlet 21a of the electric blower 21. Inlet inlet ribs 49 are formed in case inlet 48 continuously from inlet-side bottom wall portion 47. The inlet rib 49 is in contact with the seal 50 provided in the inlet 21a of the electric blower 21. The seal 50 is formed in an annular shape using an elastic body such as rubber. The seal 50 has a hole 50a which communicates between the case suction port 48 and the suction port 21a. The seal 50 partitions the inside of the electric blower case 23 into the intake port 21a side and the exhaust port 21b side of the electric blower 21. The suction side case engaging flange portion 52 is formed at an end portion of the suction side case member 25 at the opening side.

 The exhaust side case member 26 is formed in the cylindrical shape of the sealed end which one side opened. The exhaust port side bottom wall portion 54, which is the bottom of the exhaust side case member 26, has a case exhaust port 55. The case exhaust port 55 is spaced apart from the exhaust port 21b of the electric blower 21 and is in fluid communication with the exhaust port 21b. An exhaust side case engaging flange portion 57 is formed at an end of the opening side of the exhaust side case member 26. The suction side case member 25 and the exhaust side case member 26 are integrated by a fastening member (not shown) such as a screw that secures the suction side case coupling flange portion 52 and the exhaust side case coupling flange portion 57. Are combined as an enemy.

 The cylindrical portion of the exhaust side case member 26 includes a large diameter cylindrical portion 58 and a small diameter cylindrical portion 59. The large diameter cylindrical portion 58 is formed continuously from the exhaust side case engaging flange portion 57. The diameter of the large diameter cylindrical portion 58 is larger than the diameter of the cylindrical portion of the suction side case member 25. The small diameter cylindrical portion 59 is formed continuously from the large diameter cylindrical portion 58. The diameter of the small diameter cylindrical portion 59 is substantially the same as the diameter of the cylindrical portion of the suction side case member 25.

An annular stepped surface 61 facing the opening of the exhaust side case member 26 is formed between the large diameter cylindrical portion 58 and the small diameter cylindrical portion 59. On the other hand, the inner diameter of the exhaust side case engaging flange portion 57 is formed larger than the inner diameter of the suction side case engaging flange portion 52. Due to this difference in inner diameter, the suction side case engaging flange portion 52 is formed with an annular stepped surface 62 so as to face the step surface 61 of the exhaust side case member 26. The cylindrical spacer 64 and the elastic support 45 are held between the stepped surface 61 and the stepped surface 62. Accordingly, the radial displacement of the elastic support 45 is constrained by the large diameter cylindrical portion 58 of the exhaust side case member 26, but the axial displacement of the elastic support 45 is the stepped surface 61 and the stepped surface. Constrained by 62.

 The elastic support 45 is a dustproof support that prevents vibration caused by the operation of the electric blower 21. The elastic support 45 includes an inner circumferential ring 66, an outer circumferential ring 67, and a coil spring 68.

The inner circumference ring 66 is provided on the outer circumference of the motor portion 21c near the center of gravity of the electric blower 21. On the outer surface of the inner circumference ring 66, the convex portion 70 into which the coil spring 68 is fitted protrudes outward in the radial direction.

 The outer circumferential ring 67 is held between the stepped surface 61 of the exhaust side case member 26 and the stepped surface 62 of the suction side case engaging flange portion 52 with the cylindrical spacer 64 interposed therebetween. It is provided in the inner periphery of the side case member 26. On the inner surface of the outer circumferential ring 67, a convex portion 73 into which the coil spring 68 is fitted protrudes radially inward. The convex portion 73 of the outer circumferential ring 67 and the convex portion 70 of the inner circumferential ring 66 are spaced apart from each other.

 The coil spring 68 is an elastic support member provided with a compressive force F and is provided between the convex portion 70 of the inner circumferential ring 66 and the convex portion 73 of the outer circumferential ring 67. One end of the coil spring 68 is fitted into the convex portion 70 of the inner circumferential ring 66, and the other end thereof is fitted into the convex portion 73 of the outer circumferential ring 67. The coil spring 68 is disposed between the inner circumference ring 66 and the outer circumference ring 67 with a number of three or more required, for example, four spaced apart at radial equal intervals. In particular, the coil spring 68 that applies the compressive force F in the radial direction of the electric blower 21 elastically supports the electric blower 21 in the electric blower case 23. Instead of the coil spring 68, the elastic support 45 is constructed using other types of springs or elastic bodies, such as leaf springs or torsion bars, which can exert a compressive force F between the inner ring 66 and the outer ring 67. You may.

 The elastic support 45 applies the compression force F to the coil spring 68 to support the electric blower 21. Therefore, the separation distance between the inner circumference ring 66 and the outer circumference ring 67 provided with the coil spring 68 can be configured to be narrower than the separation distance required when exerting a tensile force on the coil spring of the same diameter. As a result, since the separation distance between the electric blower case 23 and the electric blower 21 can be configured to be as narrow as possible, and the outer diameter of the electric blower case 23 can be made small, the size and weight of the electric blower case 23 can be reduced. It becomes possible.

4 to 6 show a relationship between the compression force applied to the coil spring of the electric vacuum cleaner according to the first embodiment of the present invention and the vibration transmitted from the electric blower to the electric blower case.

4 to 6, the vertical axis represents the vibration acceleration of the electric blower case 23 when OdB = 1.Om / sec ² .

Fig. 4 shows the relationship between the vibration acceleration and the frequency of the electric blower case in the case of using a compression elastic support having four coil springs to which 8N compression force is applied.

Fig. 5 shows the relationship between the vibration acceleration and the frequency of the electric blower case in the case of using a compression elastic support having four coil springs to which a compression force of 20 N is applied.

Fig. 6 shows the relationship between the vibration acceleration and the frequency of the electric blower case in the case of using a compression elastic support having eight coil springs to which a compression force of 20 N is applied.

The relationship between the vibration acceleration and the frequency of the electric blower case 23 shown in FIG. 4 is an observation result obtained using the coil spring 68 having the spring constant k1 = 2N / mm, and is shown in FIGS. 5 and 6. The relationship between the vibration acceleration and the frequency of the electric blower case 23 is an observation result obtained using the coil spring 68 having the spring constant k2 = 5 N / mm. The mass of the electric blower 21 is about 1 kg. When the electric blower 21 is operated, vibrations with a peak at almost 462 Hz occur. The rigidity of the electric blower case 23 according to the present embodiment is approximately two times or three times the spring constant k2 of the coil spring 68.

As shown in FIG. 4, the vibration transmitted from the electric blower 21 to the electric blower case 23 through the coil spring 68 to which the initial compressive force FOA = 8N is applied is 1.71 dB = 1.22 m / sec ² at 462 Hz. Has an acceleration peak.

As shown in FIG. 5, the vibration transmitted from the electric blower 21 to the electric blower case 23 through the coil spring 68 to which the initial compressive force FOB = 20N is applied is −3.15 dB = 0.69 m / sec ² at 462 Hz. Has an acceleration peak of.

As shown in FIG. 6, the vibration transmitted from the electric blower 21 to the electric blower case 23 through the coil spring 68 to which the initial compressive force FOB = 20N is applied is 16.4 dB = 6.58 m / sec ² at 488 Hz. Has an acceleration peak.

From the comparison between FIG. 4 and FIG. 5, when the initial compressive force applied to the coil spring 68 is increased, the vibration transmitted from the electric blower 21 to the electric blower case 23 through the elastic support 45 is more reliable. It is clear that it can be prevented. The effect of dustproof is provided in a wide frequency band of approximately 50Hz to 800Hz, and the effect of dustproof is particularly significant at the acceleration peak of the electric blower 21 observed at 462Hz.

In addition, from the comparison between FIG. 5 and FIG. 6, even if the initial compressive force applied to the coil spring 68 of the elastic support 45 is the same, if the number of uses of the coil spring 68 is changed, the elastic support 45 is used. It is clear that the vibration transmitted from the electric blower 21 to the electric blower case 23 can be effectively prevented.

This observation result shows that the electric blower case 23 is extended radially outward and deformed by the compressive force F applied to the coil spring 68, and the initial stress is applied to the electric blower case 23 so that the electric blower case is apparent. The main reason is that the stiffness of 23 changes, that is, the resonance frequency of the electric blower case 23 changes due to stress hardening. Therefore, by adjusting the compression force F applied to the coil spring 68, the resonance frequency of the electric blower case 23 can be changed, and the vibration transmitted from the electric blower 21 to the electric blower case 23 can be prevented.

In particular, when the thickness of the electric blower case 23 cannot be sufficiently secured due to the miniaturization and weight reduction of the electric blower case 23, the compression force F applied to the coil spring 68 of the elastic support 45 and the rigidity of the electric blower case 23 , If necessary, by selecting the number of coil springs 68 to be used, the resonance frequency of the electric blower case 23 is changed, and the vibration transmitted from the electric blower 21 to the electric blower case 23 is effectively prevented. It can prevent.

In the electric vacuum cleaner 1 according to the present embodiment, the spring coefficient of the coil spring 68 is almost 5 N / mm, the number of coil springs 68 is four, and the initial compression force applied to the coil spring 68 is approximately 20 N. Is preferably.

 According to the electric vacuum cleaner 1 which concerns on this embodiment, the electric blower 21 is compression-elastically supported in the electric blower case 23, and the noise and vibration by the operation of the electric blower 21 are prevented.

Second Embodiment

A second embodiment of the electric vacuum cleaner according to the present invention will be described with reference to FIGS. 7 to 16.

In this embodiment, the same code | symbol is attached | subjected to the same structure as 1st Embodiment, and the overlapping description is abbreviate | omitted.

It is a perspective view which shows the electric blower case of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.

As shown in FIG. 7, the electric blower case 23A of the electric vacuum cleaner 1A includes a suction side case member 25A and an exhaust side case member 26A. The electric blower case 23A is made of synthetic resin such as ABS.

 The suction side case member 25A covers a part of the centrifugal fan portion 21d and the motor portion 21c of the electric blower 21, and the exhaust side case member 26A covers another portion of the motor portion 21c. .

25 A of suction side case members are formed in the cylindrical shape of the sealed end which one side opened. The suction side case member 25A includes a suction port side bottom wall portion 47A formed in a disc shape. The sealing member 75 is provided in the center part of 47 A of suction inlet side wall parts. The front cover support member 29 is provided in the ring-shaped step portion 76 formed at the periphery of the inlet side bottom wall portion 47A.

 The exhaust side case member 26A is formed in a tubular shape having a substantially square cross section orthogonal to the axial direction.

Fig. 8 is a perspective view partially showing the electric blower case and the electric blower of the electric vacuum cleaner according to the second embodiment of the present invention.

In FIG. 8 only the casing of the electric blower 21 is shown.

As shown in FIG. 8, the electric blower case 23A of the electric vacuum cleaner 1A accommodates the electric blower 21 compression-elastically supported by the elastic support 45A. The elastic support 45A elastically supports the electric blower 21 in the axial direction and the radial direction.

 The suction side case member 25A is formed in the closed end cylindrical shape which opened one side. The suction port side bottom wall portion 47A, which is the bottom of the suction side case member 25A, has a seal member mounting hole 77. The seal member 75 is fitted into the seal member mounting hole 77. A suction side case flange portion 79 is formed at an end of the suction side case member 25A on the opening side. A suction side case coupling portion 80 is provided near the outer circumference of the suction side case flange portion 79. The suction side case engaging portion 80 protrudes toward the opening of the suction side case member 25A.

The seal member 75 is composed of two truncated conical hollow bodies whose small diameter sides are joined to each other. The small diameter portion 75a, which is the contact portion of the two truncated cone hollow bodies, is fitted into the seal member mounting hole 77. One truncated cone hollow body 75b disposed inside the electric blower case 23A has a large diameter opening 75c having a flange. The large diameter opening 75c is in contact with the periphery of the suction port 21a of the electric blower 21. The other truncated conical hollow body 75d disposed on the outside of the electric blower case 23A has a large diameter opening 75e having a flange. The large diameter opening 75e is in fluid communication with the connecting air passage 33 of the vacuum cleaner body 2. The vent passage 75f formed in the small diameter portion 75a of the seal member 75 provides fluid communication between the connecting air passage 33 of the vacuum cleaner body 2 and the inlet 21a of the electric blower 21. do. The seal member 75 divides the inside of the electric blower case 23 into the inlet port 21a side and the exhaust port 21b side of the electric blower 21.

 The exhaust side case member 26A is formed in a closed end rectangular cylindrical shape having one side opening and a substantially square cross section perpendicular to the axis. The exhaust port side bottom wall portion 54A, which is the bottom face of the exhaust side case member 26A, includes a bearing insertion convex portion 82 that supports the bearing housing portion 21e of the electric blower 21. The bearing housing portion 21e houses a bearing (not shown) for rotatably supporting a rotor (not shown) of a motor (not shown). The bearing insertion convex portion 82 supports the bearing housing portion 21e with the motor support member 83 interposed therebetween. The rear cover support member 30 is provided on the outer circumference of the bearing insertion convex portion 82. The side wall of the exhaust side case member 26A has a case exhaust port 55A spaced apart from the exhaust port 21b of the electric blower 21. A groove-shaped exhaust side case engaging portion 84 is formed at an end portion of the exhaust side case member 26A on the opening side. The suction side case member 25A and the exhaust side case member 26A are integrally fitted with a part of the suction side case coupling portion 80 fitted into the exhaust side case coupling portion 84. The exhaust side case member 26A and the suction side case member 25 are joined by fastening members (not shown) such as screws.

 The cylinder part of the exhaust side case member 26A includes a large rectangular cylinder portion 86 and a small rectangular cylinder portion 87. The large rectangular cylinder portion 86 forms a cylinder portion on the opening end side of the exhaust side case member 26A. The length of the side of the large rectangular cylinder part 86 is the same as the diameter of the cylindrical cylinder part of 25 A of suction side case members. The small rectangular tube portion 87 is formed continuously from the large rectangular tube portion 86.

Between the large rectangular cylinder part 86 and the small rectangular cylinder part 87, 61A of square frame shapes which face the opening part of 26 A of exhaust side case members are formed. An elastic support 45A is held between the stepped surface 61A and the suction side case flange portion 79. Therefore, the radial displacement of the elastic support 45A is constrained by the suction side case engaging portion 80 and the large rectangular cylindrical portion 86, while the axial displacement of the elastic support 45A is the stepped surface 61A and the suction side. It is constrained by the case flange portion 79.

 A semicircular mounting recess 27a is formed in the mounting portion 27 of the vacuum cleaner main body 2, and a semicircular mounting recess 28a is formed in the mounting portion 28. 23A of electric blower cases fit the front cover support member 29 to the installation recessed part 27a of the installation part 27, and the rear cover support member (A) to the installation recessed part 28a of the installation part 28. 30 is held inside the vacuum cleaner body 2 fitted.

9 is a perspective view showing an electric blower case and an electric blower of the electric vacuum cleaner according to the second embodiment of the present invention. In Fig. 9, the electric blower case 23A is shown with the exhaust side case member 26A omitted.

It is a perspective view which shows the outer periphery ring of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.

9 and 10, the suction side case coupling portion 80 of the suction side case member 25A is formed in a square frame shape in which corner portions are chamfered in an arc shape or a linear shape, and an elastic support ( 45A) is inserted into it.

 The elastic support 45A is a dustproof support that prevents vibration caused by the operation of the electric blower 21. The elastic support 45A includes an inner circumferential ring 66A, an outer circumferential ring 67A, and a coil spring 68A.

The inner circumference ring 66A is provided on the outer circumference of the motor portion 21c near the center of gravity of the electric blower 21. On the outer surface of the inner circumferential ring 66A, the convex portion 70 into which the coil spring 68A is fitted protrudes outward in the radial direction. The flange 71 is formed in the inner circumferential ring 66A. As for the inner circumference ring 66A, the flange 71 is fastened by the fastening member 72, such as a screw, and is fixed to the outer periphery of the motor part 21c.

 The outer circumferential ring 67A is provided along the inner circumference of the suction side case engaging portion 80, and the stepped surface 61 of the exhaust side case member 26A and the suction side case flange portion 79 of the suction side case member 25A are provided. Is maintained between). The outer circumferential ring 67A is formed of a metal member, for example, a strip-shaped iron plate, as a heat resistant member, and has an annular rigidity higher than the tube portion of the electric blower case 23A.

The outer circumferential ring 67A includes an annular reinforcing ring portion 89 and a spring engaging recess 90 provided toward the corner portion of the suction side case coupling portion 80 from an arc of the reinforcing ring portion 89. The reinforcing ring portion 89 has a portion in contact with the inner circumferential surface of the suction side case coupling portion 80. In the suction side case coupling portion 80 of the suction side case member 25A, a coupling recess 91 for holding the spring coupling recess 90 is formed. The spring engaging recess 90 of the outer circumferential ring 67A and the convex portion 70 of the inner circumferential ring 66A are spaced apart from each other.

 A compression force F is applied to the coil spring 68A, and a coil spring 68A is provided between the convex portion 70 of the inner circumferential ring 66A and the spring engaging recess 90 of the outer circumferential ring 67A. One end of the coil spring 68A is fitted into the convex portion 70 of the inner circumferential ring 66A, but the other end thereof is fitted into the spring engaging recess 90 of the outer circumferential ring 67A. The coil spring 68A is disposed between the inner circumference ring 66A and the outer circumference ring 67A with the number of three or more required, for example, four spaced apart radially at equal intervals. In particular, the coil spring 68A to which the compression force F is applied radially to the electric blower 21 elastically supports the electric blower 21 in the electric blower case 23A. Instead of the coil spring 68A, the elastic support 45A is formed by using another type of spring or elastic body such as a leaf spring or a torsion bar capable of applying a compressive force F between the inner ring 66A and the outer ring 67A. You may.

 The elastic support 45A applies the compression force F to the coil spring 68A to support the electric blower 21. Accordingly, the separation distance between the inner circumferential ring 66A with the coil spring 68A and the outer circumferential ring 67A may be smaller than the necessary separation distance when a tensile force is applied to the coil springs having the same diameter. As a result, the separation distance between the electric blower case 23A and the electric blower 21 can be configured to be as narrow as possible, and the outer diameter of the electric blower case 23A can be made small, so that the electric blower case 23A can be made smaller and lighter. Become.

 The electric blower case 23A is made of synthetic resin for reducing the weight of the vacuum cleaner body 2. Thereby, the electric blower case 23A can be heated by the heat generation of the motor of the electric blower 21, or the like. Therefore, the elastic support 45A includes a rigid outer ring 67A that is higher than the electric blower case 23A, so that the compression force F of the coil spring 68 prevents deformation of the electric blower case 23A, and the electric The holding position of the blower 21 can be maintained. Therefore, the electric vacuum cleaner 1A which concerns on this embodiment prevents the performance fall by the change of the holding position of the electric blower 21. FIG.

It is a perspective view which shows the other example of the suction side case member of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.

It is a rear view which shows the other example of the suction side case member of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.

As shown in FIG. 11 and FIG. 12, the suction side case member 25B is provided with the engagement recessed part 91A and the female screw part 92 which protrude radially outward from the substantially cylindrical cylinder part. The engagement recess 91A holds the spring engagement recess 90 of the outer circumference ring 67A. A fastening member (not shown) for fastening the suction side case member 25B and the exhaust side case member 26A is screwed to the female screw portion 92.

 The suction side case member 25B maintains the outer circumference of the annular reinforcement ring portion 89 of the outer circumference ring 67A over almost the entire circumference. As a result, the action of the compression force F of the coil spring 68A is divided evenly over approximately the entire circumference of the suction side case member 25B.

It is a perspective view which shows the other example of the exhaust side case member of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.

As shown in FIG. 13, the outer circumferential ring 67A of the elastic support 45A may be provided in the exhaust side case member 26B. In this case, the exhaust side case member 26B has an engagement recess 91B for holding the spring engagement recess 90 in the outer circumferential ring 67A.

In particular, in the electric blower case 23A, the elastic support 45A can be held by the suction side case member 25A or the exhaust side case member 26B, and the elastic support 45A can be held in accordance with the assembly characteristics. The case member can be appropriately selected.

It is a perspective view which shows the other example of the exhaust side case member of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.

It is a perspective view which shows the other example of the outer peripheral ring of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.

As shown in FIGS. 14 and 15, the outer ring 67B of the elastic support 45B includes a screw mounting portion 94 (fastening portion) on the reinforcing ring portion 89. The screw mounting portion 94 of the outer circumferential ring 67B is fixed to the exhaust side case member 26C by a fastening member such as a screw.

 By the compression force F of the coil spring 68A, the reinforcing ring portion 89 of the outer circumferential ring 67B receives a force directed toward the inside of the electric blower case 23A. However, since the reinforcing ring portion 89 is integrally fixed to the exhaust side case member 26C by the screw mounting portion 94, deformation due to the compression force F of the coil spring 68A or the vibration of the electric blower 21 is prevented. Suppressed.

It is a rear view which shows the other example of the outer peripheral ring of the electric vacuum cleaner which concerns on 2nd Embodiment of this invention.

As shown in Fig. 16, the outer circumferential ring 67C is formed of an aluminum alloy by die casting. The outer circumference ring 67C is formed in a substantially square frame shape and the inner circumference is formed in a circular shape.

The three coil springs 68A are spaced apart at equal intervals of about 120 degrees.

The electric blower case 23A is made of synthetic resin to reduce the weight of the vacuum cleaner body 2. Thereby, the electric blower case 23A can be heated by the heat generation of the motor of the electric blower 21, or the like. Therefore, the elastic support 45A has a higher rigid outer ring 67C than the electric blower case 23A, thereby suppressing the deformation of the electric blower case 23A by the compression force F of the coil spring 68. The holding position of the electric blower 21 can be maintained. Therefore, the electric vacuum cleaner 1A which concerns on this embodiment can suppress the performance fall by the change of the holding position of the electric blower 21. FIG.

According to the electric vacuum cleaner 1A according to the present embodiment, the electric blower 21 can be compressed and elastically supported in the electric blower case 23A to prevent noise and vibration caused by the operation of the electric blower 21. Can be.

The electric vacuum cleaner 1 or 1A according to the present invention is not limited to the box-shaped electric vacuum cleaner 1 or 1A, and may be an electric vacuum cleaner 1 or 1A such as an upright type, a stick type or a pocket type.

Claims (7)

As an electric vacuum cleaner,
With the vacuum cleaner body,
An electric blower case housed in the vacuum cleaner body,
An electric blower accommodated in the electric blower case and sucking air;
And an anti-vibration support provided in the electric blower case and elastically supporting the electric blower by a compressive force applied in a radial direction of the electric blower. The electric vacuum cleaner according to claim 1, wherein the resonance frequency of the electric blower case is changed by the compressive force applied from the dustproof support. The electric vacuum cleaner of Claim 1 in which the said dustproof support part is provided in the inner periphery of the said electric blower case, and contains the outer periphery ring which has higher rigidity than the said electric blower case. According to claim 3, wherein the dust-proof support portion comprises an elastic support member is applied a compressive force,
The outer circumferential ring includes a concave portion coupled to one end of the elastic support member and an annular portion in contact with the inner circumferential surface of the electric blower case. The electric vacuum cleaner according to claim 4, wherein the electric blower case includes a coupling recess for holding the recess. The electric vacuum cleaner according to claim 5, wherein the annular portion of the outer ring includes a fastening portion fixed to the electric blower case by a fastening member. 5. The electric blower case according to claim 4, wherein the electric blower case comprises: a substantially cylindrical cylinder portion in which the annular portion of the outer circumferential ring is fitted;
An electric vacuum cleaner comprising: a concave portion of the outer circumferential ring that is fitted and protrudes radially outwardly from the tube portion.

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