RU2430674C1 - Electric vacuum cleaner - Google Patents

Abstract

FIELD: personal use articles.

SUBSTANCE: invention relates to an electric vacuum cleaner, in which the electric ventilator is elastically suspended in its body to suppress noise and vibration that occur in process of the electric fan operation. An elastic support 45 is a vibration insulation support that suppresses vibration caused by an electric fan 21, and comprises an inner ring 66, installed near the centre of gravity of the electric fan 21, an outer ring 67, installed in a body 23 of the electric fan, and a spiral spring 68 compressed with force F, one end of which is fixed in the inner ring 66, and the other one - on the external ring 67. The electric vacuum cleaner comprising a body; a fan body installed in it, an electric fan installed in the fan body and made with the possibility of air suction; and a vibration insulation support installed in the electric fan body and elastically supporting the electric fan by means of a compression force applied to the electric fan in the radial direction, differing by the fact that the vibration insulation support is installed on the inner surface of the electric fan body and comprises an external ring, rigidity of which exceeds the rigidity of the electric fan body.

EFFECT: increased efficiency of operation.

7 cl, 16 dwg

Description

FIELD OF THE INVENTION

The invention relates to an electric vacuum cleaner comprising a housing with an electric fan located therein and a shock absorbing suspension that isolates the vibration generated by the electric fan.

State of the art

A conventional electric vacuum cleaner sucks in dust that accumulates on the surface to be cleaned, for example on the floor, together with air through a suction hole located at the front end of the dust suction hose connected to the vacuum cleaner body by means of a vacuum created by an electric fan located in the vacuum cleaner body. Dust is captured by a dust removal unit or a high-speed compartment filter located in the vacuum cleaner body.

When an electric fan is used in an electric vacuum cleaner, excessive pressure changes always occur, which often create noise. For example, when a fan blade moves, periodic pressure changes occur that propagate in the form of noise. In the electric fan as a result of the unbalance of the rotor, in addition to the vibration of the fluid, mechanical vibration occurs. The shock-absorbing suspension, which isolates the noise and vibration of the electric fan, sufficiently holds the position with a low vibration amplitude. The shock absorbing suspension must also support the weight of the electric fan in the radial direction, and in the axial direction, the suction force generated by the electric fan.

JP 5-841941 describes an electric vacuum cleaner in which an elastic element is used located between the center of gravity of the electric fan and the vacuum cleaner body and mounted by means of an external additional ring located on the vacuum cleaner body, absorbing the rear elastic body located between the engine and the vacuum cleaner body with a gap, and a shock-absorbing front elastic body located between the outer surface of the fan and the casing with a gap, providing an elastic suspension of electric th fan in the vacuum cleaner body.

The electric fan of an electric vacuum cleaner described in JP 5-841941 is resiliently suspended in a vacuum cleaner body by means of a spiral tension spring. In this case, the fan in the radial direction is softly supported, while the force applied to the electric fan in the axial direction is rigidly supported with increasing axial displacement, thereby preventing the vibration caused by the electric fan from passing to the vacuum cleaner body.

However, when a tensile force is applied to the coil spring, its length exceeds the length of the spring in the free state. If it is not possible to provide sufficient space between the electric fan and the inner surface of its housing, the coil spring cannot be stretched to a degree sufficient to resiliently support the electric fan.

There is also a situation where, for example, an electric fan is installed in its housing, which in turn is located in the housing of an electric vacuum cleaner to isolate noise and vibration resulting from the operation of the electric fan. When the coil spring is stretched to resiliently support the electric fan in its housing, it is very difficult to provide the necessary distance for the spiral spring to stretch between the electric fan and its housing and reduce the size of the electric fan housing.

To improve ease of use, the vacuum cleaner housing and the electric fan housing must be lightweight. However, the case of an electric fan, made, for example, of a copolymer of acrylonitrile butadiene and styrene, with small dimensions and weight will not have sufficient rigidity, and it will be difficult to resiliently support the electric fan in its case with a spiral tension spring.

Using the case of an electric fan made of a viscoelastic material, such as rubber or urethane, to isolate noise and vibration allows you to reduce the resonant component of the electric fan, but in the frequency range other than resonance, sufficient advantages cannot be achieved.

Disclosure of invention

An object of the invention is to provide an electric vacuum cleaner in which an electric fan can be resiliently supported in its housing to isolate noise and vibration caused by the operation of an electric fan.

This problem is solved in an electric vacuum cleaner containing an electric fan for suctioning dust-containing air; a fan case in which the electric fan is located, and an elastic support which is formed in the case of the electric fan and elastically supports the electric fan by a compressive force applied to the electric fan in the radial direction.

Brief Description of the Drawings

1 shows an electric vacuum cleaner according to a first embodiment of the invention, a perspective view;

figure 2 - casing of an electric vacuum cleaner according to the first embodiment of the invention, a view in vertical section;

figure 3 - casing of an electric fan and an electric fan of an electric vacuum cleaner according to the first embodiment of the invention, a perspective view with a partial section;

figure 4 - the ratio between the compressive force acting on the coil spring in an electric vacuum cleaner according to the first embodiment of the invention, and the vibration transmitted from the electric fan to its housing;

figure 5 - the ratio between the compressive force acting on the coil spring in an electric vacuum cleaner according to the first embodiment of the invention and the vibration transmitted from the electric fan to its housing;

Fig.6 is the relationship between the compressive force acting on the coil spring in an electric vacuum cleaner according to the first embodiment of the invention, and the vibration transmitted from the electric fan to its housing;

7 is a perspective view of an electric fan housing of an electric vacuum cleaner according to a second embodiment of the invention;

on Fig - the case of the electric fan and the electric fan of the electric vacuum cleaner according to the second variant embodiment of the invention, a perspective view with a partial section;

Fig. 9 is a perspective view of an electric fan housing and an electric fan of an electric vacuum cleaner according to a second embodiment of the invention;

figure 10 is an outer additional ring in an electric vacuum cleaner according to a second embodiment of the invention, a perspective view;

11 is a suction part of the housing of an electric vacuum cleaner according to a second embodiment of the invention in another embodiment, a perspective view;

Fig.12 is the same, rear view;

in Fig.13 - the exhaust part of the housing of the electric vacuum cleaner according to the second variant embodiment of the invention in another embodiment, a perspective view;

on Fig - another embodiment of the exhaust part of the housing of an electric vacuum cleaner according to the second variant embodiment of the invention, a perspective view;

on Fig - another embodiment of the outer additional ring of an electric vacuum cleaner according to the second variant embodiment of the invention, a perspective view;

on Fig is another embodiment of the outer additional ring of an electric vacuum cleaner according to the second variant embodiment of the invention, rear view.

The implementation of the invention

A first embodiment of an electric vacuum cleaner according to the invention is shown in FIGS. 1-6.

Figure 1 shows a perspective view of an electric vacuum cleaner view according to a first embodiment of the invention.

As shown in FIG. 1, the electric vacuum cleaner 1 comprises a housing 2, a dust suction hose 3, a nozzle 4, a handle 5, a control unit 6, a telescopic rigid adapter 7, and a suction port 8.

The vacuum cleaner body 2 has a connecting hole 2a to which the first end of the dust suction hose 3 is removably connected. The housing 2 of the vacuum cleaner also contains a power cord 11, at the free end of which there is a plug 12.

The dust suction hose 3 is flexible and has an elongated substantially cylindrical shape. The first end of the dust suction hose 3 is removably connected to the connecting hole 2a to communicate with the inside of the vacuum cleaner body 2.

The first end of the operating pipe 4 is located at the other end of the dust suction hose 3 and is in fluid communication with the inside of the vacuum cleaner body 2 through the hose 3.

When using an electric vacuum cleaner 1, the user holds it by the handle 5. The handle 5 is made curved and protrudes from the second end of the pipe 4 in the direction of its end, on which the hose 3 is located.

A control unit 6 is located on the handle 5, with which the user can set various operating modes of the electric vacuum cleaner 1. The control unit 6 contains a button 6a to turn off the electric vacuum cleaner 1 and a button 6b to turn it on.

The telescopic rigid adapter 7 is extendable and has an elongated substantially cylindrical shape. The first end of the adapter 7 is removably connected to the second end of the pipe 4 and is in fluid communication with the inside of the vacuum cleaner body 2 through the pipe 4 and the hose 3.

The first end of the adapter 7 is removably connected to the suction hole 8, and it is in fluid communication with the inside of the vacuum cleaner body 2 through the adapter 7, pipe 4 and hose 3.

Figure 2 shows the housing of an electric vacuum cleaner in a vertical section.

As shown in FIG. 2, the housing 2 of the electric vacuum cleaner 1 comprises a housing 15, a dust separator and a dust collecting unit 16 removably mounted in the housing 15, and an opening cover 17 located on the housing 15.

A dust collector 19 is located in front of the casing 15, to which the dust separation and dust collecting unit 16 is removably connected. The upper opening 20 of the dust collector 19 is closed by a cover 17.

A chamber 22 is formed in the rear part of the casing 15, in which an electric fan 21 is located. A fan housing 23 is located in the chamber 22 and closes the electric fan 21. The fan casing 23 includes a suction part 25 and an exhaust part 26. The fan casing 23 is held by a fastener 27 located on the front side of the chamber 22, and a fastener 28 located on the rear side of the chamber 22. Between the housing 23 of the fan and the fastening element 27 there is a support element 29 of the front cover, and between the body 23 of the fan and a fastening element 28 is disposed a support member 30 of the back cover. The support element 29 of the front cover and the support element 30 of the back cover are resilient, made, for example, of rubber or silicone.

In front of the chamber 22, there is a connecting cylindrical air channel 33 having a front hole 32. The front hole 32 is open towards the dust collector chamber 19. The front hole 32 is sealed with a ring 34 that is located between the dust separation and dust collection unit 16 and the air channel 33. In the air channel 33 is installed the grill 35. In the rear wall 36 of the air channel 33, a connecting hole 37 is made. The connecting hole 37 is fluidly coupled to an electric fan 21 closed by a housing 23.

The dust separating and dust collecting unit 16 includes a dust separator 39, which separates the coarse dust from the incoming stream by inertial separation, a dust collector 40, which collects the coarse dust separated by the dust separator 39, a mesh filter 41 through which dusty air without coarse dust separator 39 passes, and pleated filter 42 separating and collecting fine dust from dusty air. The pleated filter 42 is installed in the housing 43, made in one piece with the dust separator 39.

When the user of the electric vacuum cleaner 1 presses the switch 6b, the electric vacuum cleaner 1 starts its operation. When you turn on the electric vacuum cleaner 1, the electric fan 21 starts to work, and a vacuum occurs inside the vacuum cleaner body 2. A vacuum through the connecting hole 2a, hose 3, nozzle 4 and telescopic adapter 7 is also created in the suction hole 8. The electric vacuum cleaner 1 draws in dust collected on the surface being cleaned, for example on the floor, together with air through the suction hole 8 and cleans this surface. The dusty air sucked through the suction port 8 is divided into dust and air by a dust separation and dust collecting unit 16 installed in the vacuum cleaner body 2. Separated dust is collected in the dust collector 40 and on the pleated filter 42. The air separated from the dust is sucked in by the electric fan 21 and discharged from the vacuum cleaner body 2.

FIG. 3 shows a housing of an electric fan 21 according to a first embodiment of the invention.

As shown in FIG. 3, an electric fan 21 is located in the fan housing 23 of the electric vacuum cleaner 1, which is resiliently suspended by the elastic support 45. The elastic support 45 resiliently supports the electric fan 21 along the axis and in the radial direction.

The electric fan 21 comprises a motor (not shown), a centrifugal fan (not shown) rotated by the motor, and a diffuser (not shown) mounted on the outer surface of the centrifugal fan. The electric fan 21 has a suction port 21a through which air is sucked in due to the vacuum generated by the centrifugal fan, and an exhaust port 21b through which air exits. When the engine is running, the electric fan 21 rotates the centrifugal fan and draws air through the suction port 21a. The air drawn in by the electric fan 21 exits the centrifugal fan through the diffuser and, cooling the engine, air is discharged through the outlet 21b.

The fan housing 23 is made of synthetic plastic, for example a copolymer of acrylonitrile butadiene and styrene, and has a substantially cylindrical shape with a closed end. The fan housing 23 includes a suction portion 25 and an exhaust portion 26.

The suction portion 25 of the housing is made in the form of a cylinder with a closed end and one open side. The bottom 47 of the suction portion 25 of the housing has a suction port 48. The suction port 48 is in fluid communication with an air passage 33 located in the vacuum cleaner body 2, and in fluid communication with the suction port 21 a of the electric fan 21. In the suction port 48, protrudes from the bottom 47 flange 49. The flange 49 of the suction hole abuts against a seal 50 located in the suction hole 21a of the electric fan 21. The seal 50 is made of an elastic material, such as rubber, and has an annular shape. Opening 50a of seal 50 provides communication between the suction port 48 of the housing and the suction port 21a of the fan. A seal 50 separates the inside of the fan casing 23 into a part with a suction port 21 a and a part with an outlet 21 b of the electric fan 21. A connecting flange 52 is formed at the open end of the casing suction part 25.

The exhaust part 26 of the housing is made in the form of a cylinder with a closed end and one open side. Bottom 54, i.e. the lower surface of the outlet portion 26 of the housing has an outlet 55. The outlet 55 is located at a distance from the outlet 21b of the electric fan 21 and is in fluid communication with the outlet 21b. A connecting flange 57 is formed at the open end of the outlet portion 26 of the housing. The suction portion 25 of the housing and the outlet portion 26 of the housing are interconnected by fasteners (not shown), for example, bolts connecting the connecting flange 52 of the suction portion of the housing and the connecting flange 57 of the exhaust portion of the housing.

The cylindrical portion of the outlet portion 26 of the housing includes a cylinder 58 of large diameter and a cylinder 59 of small diameter. The cylinder 58 of large diameter departs from the connecting flange 57. The diameter of the cylinder 58 of large diameter exceeds the diameter of the cylindrical part of the suction part 25 of the housing. Small diameter cylinder 59 extends from large diameter cylinder 58. The diameter of the cylinder 59 of small diameter is essentially equal to the diameter of the cylindrical part of the suction part 25 of the housing.

Between the large diameter cylinder 58 and the small diameter cylinder 59, an annular stepped surface 61 is formed, facing the opening of the outlet portion 26 of the housing. Moreover, the inner diameter of the connecting flange 57 of the exhaust part of the housing is larger than the internal diameter of the connecting flange 52 of the suction part of the housing. Due to this difference in inner diameters, an annular stepped surface 62 is formed on the connecting flange 52 of the suction portion of the housing, facing the stepped surface 61 of the outlet portion 26 of the housing. A cylindrical spacer 64 and an elastic support 45 are installed between the stepped surfaces 61 and 62. Thus, the radial displacement of the elastic support 45 is limited by the cylinder 58 of the large diameter of the outlet part 26 of the housing, and the axial displacement of the elastic support 45 is limited by the stepped surfaces 61 and 62.

The elastic support 45 is a vibration isolating support that absorbs vibration caused by the operation of the electric fan 21. The elastic support 45 comprises an inner ring 66, an outer ring 67, and a coil spring 68.

An inner ring 66 is located on the outer surface of the engine 21c near the center of gravity of the electric fan 21. A protrusion 70, which locks the coil spring 68, extends radially outward from the outer surface of the inner ring 66.

The outer ring 67 is located between the stepped surface 61 of the outlet portion 26 of the housing and the stepped surface 62 of the connecting flange 52 of the suction portion of the housing through a cylindrical spacer 64 on the inner surface of the outlet portion 26 of the housing. A protrusion 73 securing the coil spring 68 extends radially inward from the inner surface of the outer ring 67. The protrusion 73 on the outer ring 67 and the protrusion 70 on the inner ring 66 are spaced apart from one another.

The coil spring 68 is an elastic support element compressed by force F, which is installed between the protrusion 70 on the inner ring 66 and the protrusion 73 on the outer ring 67. One end of the coil spring 68 is located on the protrusion 70, and the other on the protrusion 73. The required number three or more, for example four, coil springs 68 are evenly distributed in the circumferential direction between the inner ring 66 and the outer ring 67. For example, a coil spring 68 to which a compressive force is applied in the radial direction from the electric fan 21 ment F, elastically supports the electric blower 21 in the fan housing 23. The elastic support 45 may comprise a different type of spring or elastic element, for example, instead of a coil spring 68, a leaf spring or a torsion bar can be used, to which a compressive force F acting between the inner ring 66 and the outer ring 67 can be applied.

The elastic support 45 creates a compressive force F in the coil spring 68 to hold the electric fan 21. Thus, the distance between the inner ring 66 and the outer ring 67 where the coil spring 68 is installed may be less than the distance necessary to create a tensile force in the coil spring same diameter. As a result, the distance between the electric fan 21 and its casing 23 is minimized, and the outer diameter of the fan casing 23 is also reduced, therefore, the size of the fan casing 23 is reduced, and the weight is reduced.

Figures 4-6 show the relationship between the compressive force acting on the coil spring of an electric vacuum cleaner according to a first embodiment of the invention and the vibration transmitted from the electric fan to the electric fan case.

In the graphs given in these figures, the ordinate axis shows the acceleration of the fan casing 23 during its vibration, where 1 dB = 1.0 m / s ² .

Figure 4 shows the relationship between acceleration and vibration frequency of the electric fan housing, when the compressed elastic support contains four coil springs, to which a compression force of 8H is applied.

Figure 5 shows the relationship between acceleration of vibration and the frequency of the body of the electric fan when the compressed elastic support contains four coil springs, to which a compression force of 20H is applied.

Figure 6 shows the relationship between vibration acceleration and the frequency of the electric fan casing when the compressed elastic support contains eight coil springs, to which a compression force of 20H is applied.

The relationship between acceleration and vibration frequency of the fan casing 23 shown in FIG. 4 was obtained as a result of testing with a coil spring 68 of stiffness k1 = 2 N / mm, and the relationships between acceleration and vibration frequency of the fan casing 23 shown in FIGS. 5 and 6 obtained as a result of tests with coil springs 68 stiffness k2 = 5 N / mm The mass of the electric fan 21 is about 1 kg. When the electric fan 21 is operating, vibration is generated with the main peak at a frequency of 462 Hz. The stiffness of the fan casing 23 is substantially two or three times greater than the stiffness k2 of the coil spring 68.

As shown in FIG. 4, the vibration transmitted from the electric fan 21 through the coil spring 68, to which the initial compression force FOA = 8H is applied, to the fan casing 23, has an acceleration peak of 1.71 dB = 1.22 m / s ² at 462 Hz.

As shown in FIG. 5, the vibration transmitted from the electric fan 21 through the coil spring 68 to which the initial compression force FOB = 20H is applied to the fan casing 23 has an acceleration peak of 3.15 dB = 0.69 m / s ² at 462 Hz.

As shown in FIG. 6, the vibration transmitted from the electric fan 21 through the coil spring 68, to which the initial compression force FOB = 20H is applied, to the fan casing 23, has an acceleration peak of 16.4 dB = 6.58 m / s ² at 488 Hz.

From a comparison of FIGS. 4 and 5, it is clear that the greater the initial compression force applied to the coil spring 68, the more reliably damped the vibration transmitted from the electric fan 21 through the elastic support 45 to the fan housing 23. The advantage of vibration isolation is manifested in a wide frequency range, mainly from 50 to 800 Hz, and is especially noticeable at the peak acceleration of the electric fan 21, observed at a frequency of 462 Hz.

From a comparison of FIGS. 5 and 6, it is clear that the vibration transmitted from the electric fan 21 through the elastic support 45 to the fan housing 23 cannot be effectively suppressed even by using a similar initial compressive force applied to the coil spring 68 of the elastic support 45 when the number of spiral springs 68 changed.

It is assumed that the main factor explaining the test results is the change in the resonance frequency of the fan casing 23, since the fan casing 23 is deformed by the compression force F applied from the coil spring 68, and also that the initial pressure acting on the fan casing 23 changes it rigidity, increasing it. Thus, the compression force F applied to the coil spring 68 can be adjusted to change the resonant frequency of the fan casing 23 to absorb the vibration transmitted from the electric fan 21 to the fan casing 23.

In particular, if it is not possible to ensure that the fan casing 23 is of sufficient thickness due to requirements to reduce its weight and size, the compression force F and the stiffness of the fan casing 23 applied to the coil spring 68 of the elastic support 45 are controlled, and the number of coil springs 68 used is selected, as a result, the resonant frequency of the housing 23 can be varied to provide effective damping of the vibration transmitted from the electric fan 21 to the fan housing 23.

In the electric vacuum cleaner 1 according to this embodiment, it is preferable that the stiffness of the coil spring 68 is essentially 5 N / mm, the number of coil springs 68 is 4, and the initial compression force applied to the coil spring 68 is essentially 20H.

In the electric vacuum cleaner 1 according to the invention, the electric fan 21 is resiliently supported in its housing 23 for damping the noise and vibration caused by the operation of the electric fan 21.

7-16 show a second embodiment of an electric vacuum cleaner according to the invention.

In this embodiment, the same components as in the first embodiment have the same reference numbers.

7 shows a perspective view of an electric fan case of an electric vacuum cleaner according to a second embodiment of the invention.

As shown in FIG. 7, the fan housing 23A of the vacuum cleaner 1A includes a suction portion 25A and an exhaust portion 26A. The fan case 23A is made of synthetic plastic, for example a copolymer of acrylonitrile butadiene and styrene.

The suction portion 25A of the housing covers the centrifugal fan 21d and part of the engine 21c, and the exhaust portion 26A of the housing covers the other parts of the engine 21c.

The suction portion 25A of the housing is made in the form of a cylinder with a closed end and one open side. The suction portion 25A of the housing comprises a disk-shaped bottom 47A. In the center of the bottom 47A there is a sealing element 75. On the ring-shaped step 76 formed on the outer edge of the bottom 47A, a support element 29 of the front cover is installed.

The outlet portion 26A of the housing has a tubular shape of a substantially square cross section.

FIG. 8 shows a housing of an electric fan 21 according to a second embodiment of the invention.

As shown in FIG. 8, an electric fan 21 is installed in the fan housing 23A of the electric vacuum cleaner 1A, which is resiliently suspended on an elastic support 45A. The elastic support 45A resiliently holds the electric fan 21 in axial and radial directions.

The suction portion 25A of the housing is made in the form of a cylinder with a closed end and one open side. The bottom 47A, that is, the lower surface of the suction portion 25A of the housing, has a mounting hole 77 into which a sealing element 75 is inserted. A flange 79 is formed at the open end of the suction portion 25A of the housing. A connecting portion 80 protrudes into the outer edge of the flange 79 of the suction portion of the housing. the open side of the suction portion 25A of the housing.

The sealing element 75 consists of two elements in the form of a hollow truncated cone, interconnected by small bases. The small diameter portion 75a, which is the support for the two indicated elements, is attached to the mounting hole 77 for the sealing element. One hollow truncated cone shaped element 75b located inside the fan housing 23A has a large diameter hole 75c with a flange. A large diameter hole 75c is adjacent to the outer edge of the suction hole 21a of the electric fan 21. Another hollow truncated cone shaped element 75d located outside the fan housing 23A has a large diameter hole 75e with a flange. A large diameter hole 75e is communicated in fluid with a connecting air channel 33 located in the housing 2 of the vacuum cleaner. The ventilation duct 75f formed by the small-diameter portion 75a of the sealing member 75 communicates with the air duct 33 located in the cleaner body 2 to the suction opening 21a of the electric fan 21. The sealing member 75 divides the inside of the fan housing 23 into a part with a suction opening 21a and a part with the outlet 21b of the electric fan 21.

The outlet portion 26A of the casing is cylindrical in shape with a substantially square cross section with one closed end and one open side. The bottom 54A, that is, the lower surface of the outlet portion 26A of the housing, comprises a bearing protrusion 82 that supports the bearing housing 21e of the electric fan 21. The bearing housing 21e accommodates a bearing (not shown) that rotates a rotor (not shown) of an engine (not shown). The bearing protrusion 82 supports the bearing housing 21e through a motor support member 83. On the outer surface of the bearing protrusion 82, a back cover support member 30 is located. The side wall of the outlet portion 26A of the housing has an outlet 55A located at a distance from the outlet 21b of the electric fan 21. At the open end of the outlet portion 26A of the housing, a connecting portion 84 is formed in the form of a groove. The suction portion 25A of the housing and the outlet portion 26A of the housing are connected using the connecting portion 80 of the suction portion of the housing inserted into the connecting portion 84 of the exhaust portion of the housing. The outlet portion 26A of the housing and the suction portion 25 of the housing are connected by fasteners (not shown), for example screws.

The outlet portion 26A of the housing comprises a portion 86 of a large cross section and a portion 87 of a small cross section, the portion 86 being located on the side of the open end of the outlet portion 26A of the housing. The length of the side of the square forming the cross section of section 86 is equal to the diameter of the cylinder of the suction portion 25A of the housing. Section 87 of a small cross section departs from section 86 of a large cross section.

Between sections 86 and 87, a square stepped surface 61A is formed facing the opening of the outlet portion 26A of the housing. Between the stepped surface 61A and the flange 79 of the suction portion of the housing is an elastic support 45A. Thus, the radial displacement of the elastic support 45A is limited by the connecting portion 80 of the suction portion of the housing and the portion 86 of the exhaust portion of the housing, and the axial displacement of the elastic support 45A is limited by the stepped surface 61A and the flange 79 of the suction portion of the housing.

A semicircular cutout 27a is made in the fastener 27 of the vacuum cleaner body 2, and a semicircular cutout 28a is made in the fastener 28. The fan casing 23A is installed in the vacuum cleaner casing 2 by means of a front support member 29 mounted in a cutout 27a of the fastener 27 and a rear support member 30 installed in the cutout 28a of the fastener 28.

Fig. 9 shows a perspective view of an electric fan housing and an electric fan of an electric vacuum cleaner according to a second embodiment of the invention with the exhaust portion 26A of the housing removed.

Figure 10 shows a perspective view of the outer ring of an electric vacuum cleaner according to a second embodiment of the invention.

As shown in FIGS. 9 and 10, the connecting portion 80 of the suction portion 25A of the housing has a cross-sectional shape with rounded or chamfered corners in which the elastic supports 45A are mounted.

The elastic support 45A is a vibration isolating support that dampens the vibration resulting from the operation of the electric fan 21. The elastic support 45A comprises an inner ring 66A, an outer ring 67A, and a coil spring 68A.

The inner ring 66A is located on the outer surface of the motor 21c near the center of gravity of the electric fan 21. The protrusion 70, on which the coil spring 68A is fixed, protrudes radially outward from the outer surface of the inner ring 66A. A flange 71 is formed on the inner ring 66A. The inner ring 66A is attached to the outer surface of the engine 21c by means of a flange 71 fixed by a fastener 72, for example a screw.

An outer ring 67A is installed along the inner surface of the connecting portion 80 of the suction portion of the housing, which is located between the stepped surface 61 of the outlet portion 26A of the housing and a flange 79 of the suction portion 25A of the housing. The outer ring 67A is made of metal, for example of heat-resistant steel tape, and has a higher stiffness than the stiffness of the fan casing 23A.

The outer ring 67A consists of connecting ring parts 89 and spring recesses 90 protruding from the connecting ring parts 89 toward the corners of the connecting portion 80 of the suction portion of the housing. The connecting annular portion 89 comprises a portion adjacent to the inner surface of the connecting portion 80 of the suction portion of the housing. At the connecting portion 80 of the suction portion 25A of the housing, an engagement means 91 is formed with a recess 90 for the spring. The recess 90 in the outer ring 67A and the protrusion 70 on the inner ring 66A are spaced apart and facing one another.

A compression force F is applied to the coil spring 68A, which is installed between the protrusion 70 on the inner ring 66A and the recess 90 in the outer ring 67A. One end of the coil spring 68A is fixed by the protrusion 70 on the inner ring 66A, and its other end is the recess 90 in the outer ring 67A. The coil springs 68A are evenly distributed around the circumference between the inner ring 66A and the outer ring 67A, the number of springs being three or more, for example four. The coil spring 68A, radially loaded with compression force F, elastically supports the electric fan 21 in its housing 23A. The elastic support 45A may comprise a different type of spring or elastic element, for example, instead of a coil spring 68A, a leaf spring or torsion bar can be used, to which a compression force F acting between the inner ring 66A and the outer ring 67A can be applied.

The elastic support 45A creates a compressive force F in the coil spring 68A to hold the electric fan 21. Thus, the distance between the inner ring 66A and the outer ring 67A where the coil spring 68A is installed may be less than the distance necessary to create a tensile force in the coil spring. same diameter. As a result, the distance between the electric fan 21 and its casing 23A is minimized, and the outer diameter of the fan casing 23A is also reduced, therefore, the size of the fan casing 23A is reduced, and the weight is reduced.

To reduce the weight of the housing 2 of the vacuum cleaner, the fan housing 23A is made of synthetic plastic. This can lead to heating of the fan casing 23A as a result of heat generation, including from the electric fan motor 21, therefore, the elastic support 45A contains an outer ring 67A, the rigidity of which is greater than the stiffness of the fan casing 23A. As a result, deformation of the fan casing 23A from the action of the compression force F of the coil spring 68 supporting the electric fan 21 in a predetermined position is prevented. Thus, in this embodiment, the performance of the electric vacuum cleaner 1A is prevented due to a change in the position of the electric fan 21.

11 and 12 show another embodiment of a suction portion of an electric vacuum cleaner body according to a second embodiment of the invention.

As shown in FIGS. 11 and 12, the housing suction portion 25B has an engagement means 91A and an internal thread member 92 projecting radially outward and having a substantially cylindrical shape. In the engaging means 91A, a spring recess 90 is provided on the outer ring 67A. A fastener (not shown) is screwed into the female thread element 92, by which the suction portion 25B of the housing and the outlet portion 26A of the housing are connected.

The suction portion 25B of the housing contacts substantially the entire outer surface of the connecting ring portion 89 of the outer ring 67A, therefore, the response of the coil spring 67A from the action of the compression force F is substantially uniformly distributed over the entire surface of the suction portion 25B of the housing.

On Fig shows another embodiment of the exhaust part of the housing of the electric vacuum cleaner according to the second variant embodiment of the invention.

As shown in FIG. 13, the outer ring 67A of the elastic support 45A may be located in the outlet portion 26B of the housing. In this case, the outlet portion 26B of the housing comprises an engaging means 91B in which a recess 90 of the outer ring 67A is located.

Thus, the elastic support 45A can be held in the fan housing 23A by either its suction part 25A or its exhaust part 26B, the choice depending on the mounting characteristics.

On Fig shows another embodiment of the exhaust part of the housing of the electric vacuum cleaner according to the second embodiment of the invention, and on Fig - corresponding to this option, the outer ring of the electric vacuum cleaner.

As shown in FIGS. 14 and 15, the outer ring 67B of the elastic support 45B includes a threaded fastener 94 (connecting member) located on the connecting ring portion 89 of the outer ring 67B. The threaded element 94 of the outer ring 67B is attached to the outlet portion 26C of the housing by means of a fastener, for example, a screw.

The compression force F of the coil spring 68A causes the forces to be transmitted to the connecting ring portion 89 of the outer ring 67B. However, the connecting ring portion 89 is attached to the outlet portion 26C of the housing by the element 94, thereby preventing deformation caused by the compressive force F of the coil spring 68A or the vibration of the electric fan 21.

16 shows another embodiment of the outer ring of an electric vacuum cleaner according to a second embodiment of the invention.

The outer ring 67C shown in the back of FIG. 16 is made of aluminum alloy by injection molding. This ring 67C has a substantially square outer contour and a circular inner contour.

At equal angular intervals of about 120 °, the same coil springs 68A are installed.

To reduce the weight of the vacuum cleaner housing 2, the fan housing 23A is made of synthetic plastic, which can lead to heating of the electric fan housing 23A due to heat generation, in particular from the fan motor 21. With this in mind, the elastic support 45A contains an outer ring 67C, the rigidity of which exceeds the rigidity of the fan casing 23A, as a result of which the deformation of the fan casing 23A is prevented and the predetermined position of the electric fan 21 is maintained under the action of the compressed coil spring 68A. Thus, in this embodiment, the performance of the electric vacuum cleaner 1A does not decrease due to changes in the position of the electric fan 21.

In the electric vacuum cleaner 1A according to this embodiment of the invention, the electric fan 21 is elastically supported in the fan casing 23A, suppressing the noise and vibration resulting from the operation of the electric fan 21.

The electric vacuum cleaner according to the invention can be made not only of the type described above, but also in the form of a vertical vacuum cleaner, a handle vacuum cleaner or a portable electric vacuum cleaner.

Claims (7)

1. An electric vacuum cleaner comprising a housing, a fan housing installed therein, an electric fan mounted in the fan housing and configured to suck in air, and a vibration isolating support mounted in the electric fan housing and elastically supporting the electric fan by a compressive force applied to the electric fan in the radial direction, characterized in that the vibration isolating support is located on the inner surface of the housing of the electric fan and win the outer ring, the rigidity of which is greater than the rigidity of the electric blower case. 2. The electric vacuum cleaner according to claim 1, characterized in that the resonant frequency of the housing of the electric fan is variable depending on the compression force acting from the side of the vibration isolating support. 3. The electric vacuum cleaner according to claim 2, characterized in that the vibration isolating support contains a compressed elastic element, and the outer ring contains a recess for fixing one end of the elastic element and an annular part adjacent to the inner surface of the electric fan casing. 4. The electric vacuum cleaner according to claim 3, characterized in that the electric fan housing has a gearing means for holding said recess. 5. The electric vacuum cleaner according to claim 4, characterized in that the annular part of the outer ring contains a connecting element attached to the body of the electric fan by a fastening element. 6. The electric vacuum cleaner according to claim 5, characterized in that the casing of the electric fan comprises a substantially cylindrical part into which the annular part of the outer ring is inserted, and engagement means corresponding to a recess on the outer ring and protruding radially outward from the cylindrical part. 7. An electric vacuum cleaner comprising a housing, a fan housing installed therein, an electric fan mounted in the fan housing and configured to suck in air, and a vibration isolating support elastically supporting the electric fan by means of a coil spring, the compressive force of which is applied to the electric fan in the radial direction characterized in that the fan casing is made with the possibility of deformation under the action of the compression force applied from the coil spring in this way this ensures a change in the resonant frequency of the fan casing to damp the vibration transmitted from the electric fan to the fan casing.

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