KR20150031444A - A cleaning appliance - Google Patents

Abstract

The present invention relates to a cylinder-type cleaning apparatus. The cleaning device includes a bottom-engaging rolling assembly including a body and a body and a pair of bottom-engaging wheels for separating dirt from the dirty fluid stream. The rearmost point of the separating device is disposed in parallel with or behind the center point of the wheel.

Description

{A CLEANING APPLIANCE}

The present invention relates to cleaning devices and particularly to vacuum cleaners.

Cleaning devices such as vacuum cleaners are well known. Many vacuum cleaners are either of the "upright" type or the "cylinder" type (sometimes called a canister or barrel machine in some countries). Cylinder vacuum cleaners typically include a motor-driven fan unit for drawing a dirty airflow into a vacuum cleaner, and a separator such as a cyclonic separator or pocket for separating dirt and dust from the air stream And a body that holds the body. The dirty air flow is introduced into the body through a suction hose and a wand assembly connected to the body. The body of the vacuum cleaner is dragged by the hose as the user moves through the room. The cleaning tool is attached to the remote end of the hose and wand assembly.

For example, GB 2407022 describes a cylinder vacuum cleaner having a body that supports a cyclonic separator. Such a vacuum cleaner has two main wheels, one on each side of the rear part of the main body, and a castor wheel located under the front part of the main body so that the vacuum cleaner is dragged across the surface.

EP1129657 describes a cylinder vacuum cleaner in the form of a spherical body connected to a suction hose and a wand assembly. The spherical volume of the spherical body comprises a pair of wheels positioned one on each side of the body, an electric blower for drawing fluid flow through the vacuum cleaner, and a dust bag for separating dirt and dust from the fluid stream, do.

WO2010 / 112887 describes a cylinder vacuum cleaner having a generally spherical assembly connected to the chassis to improve the maneuverability of the vacuum cleaner on the floor surface. Such spherical assemblies include a pair of domed wheels connected to the body and the body. The separating device is disposed in front of the spherical assembly. The chassis includes a support for supporting a separator of the vacuum cleaner. The support is positioned on the inlet duct for transferring the dirty air stream to the separator.

The present invention relates to a cylinder-type cleaning device comprising: a separating device for separating dirt from a dirty fluid stream; and a floor-engaging rolling assembly comprising a body and a pair of bottom-engaging wheels And a rear end point of the separating device is disposed in parallel with or behind the center point of the wheel.

Such a device is advantageous because it helps to move the center of gravity of the cleaning device backwards, which improves the stability and compactness of the device.

The separating device is preferably in the form of a cyclonic separating device having at least one cyclone. Other forms of separator may be used, and examples of suitable separator techniques include a filter bag, a porous container, a static separator, or a liquid-based separator.

In certain embodiments, the separation device may be a cyclonic separation device. The cyclonic separating device may comprise a first cyclonic separating unit and a second cyclonic separating unit. The first cyclonic separating unit may be disposed upstream of the second cyclonic separating unit. In a preferred embodiment, the first cyclonic separation unit comprises a single low-efficiency cyclone. Preferably a dust collector, which may be formed integrally with the first cyclonic separating unit low efficiency cyclone. Ideally, the second cyclonic separating unit comprises a plurality of second cyclones arranged in parallel. The second cyclonic separating unit may be more efficient than the first cyclonic separating unit.

The plurality of second cyclones may be divided into at least a first set of second cyclones and a second set of second cyclones. The fluid inlets of the first set of cyclones may be disposed within the first group and the fluid inlets of the second set of cyclones may be disposed within the second group of spaced apart from the first group along the axis.

Separating the cyclones of the second cyclonic separating unit into first and second sets, respectively disposed around the common axis and having grouped fluid inlets, may allow this set of cyclones to be spaced along the axis. This allows both the number and size of the cyclones of the second cyclonic separating unit to be selected for optimal separation efficiency and cleaning efficiency within the dimensional constraints of the separating apparatus. Providing a common dust collector for each of the sets of cyclones may facilitate emptying and cleaning of the second cyclonic separating unit.

The fluid inlets of the sets of cyclones may be arranged in one of a number of different configurations. For example, the inlet may be arranged in a spiral arrangement extending about an axis. Preferably, the first group of fluid inlets are generally disposed in a first annular configuration, and the second group of fluid inlets are generally disposed in a second annular configuration spaced from the first annular configuration along the axis. Each such annular arrangement is preferably substantially orthogonal to the axis. The annular arrangement is preferably of substantially the same size. In each annular arrangement, the fluid inlet is preferably positioned substantially within a common plane. Alternatively, the fluid inlets may each be located in a plurality of different planes, each preferably substantially orthogonal to the axis.

In a particular embodiment, the rearmost point of the second cyclonic separating unit may be disposed in parallel with or behind the center point of the wheel. In a particular embodiment, the rearmost point of the low-efficiency cyclone may be disposed in parallel with or behind the center point of the wheel. In a particularly preferred embodiment, the rearmost viewing point of the low-efficiency cyclone may be arranged in parallel with or behind the center point of the wheel.

In a particularly preferred embodiment, the cleaning device may be implemented such that it is tipped on its side and encouraged to return to the upright position. This may be achieved by ensuring that the center of gravity of the separating device is as low as possible. In a most preferred embodiment, the cleaning device is a self-standing cleaning device. This means that if the cleaning device is tipped on the side or rear, it will automatically self-erect again in the upright position.

The wheels are arranged one on each side of the body. Each wheel is preferably substantially the same height as the individual abutment of the body of the rolling assembly so that the rolling assembly may have a rim that may have a relatively continuous outer surface, . During use, the cleaning device may be pulled along the surface in the upright position so that it rolls along the surface on the rim of the wheel.

Most preferably, each wheel has a domed or generally domed outer surface. As used herein, the term "dome" will be taken to mean that the wheel has a curved side. Most preferably, the wheel is substantially hemispherical in shape or forms part of the hemisphere. Of course, the wheel may have a stepped exterior surface or may have more than one flat portion, which can be regarded as a domed shape as long as they still form a rolling assembly with the body.

As used herein, the term "rolling assembly" is intended to include an assembly capable of rolling on its side or rear surface when the cleaning device is tipped over from the upright position. Therefore, this does not include assemblies that contain only standard wheels. These standard wheels will allow the cleaning device to move on the surface in the upright position, but will not allow it to roll on the side if the cleaning device is turned upside down. Thus, the term "rolling " does not include the standard movement of a wheel rolling on their rims, tires or running edges.

Thus, the plurality of exterior and / or shims of the rolling assembly are preferably rounded, curved, or generally curved so that the overall shape of the rolling assembly looks substantially spheroidal or spherical in shape . This configuration allows the cleaning machine to roll on the curved surface.

It has been found that it is very advantageous to allow the cleaning appliance to roll on its side and backside during use. This is because a cleaning device with a standard wheel occurs when it is turned upside down on its side, so that when the cleaning device is turned upside down, the cleaning device does not get stuck on its side. With the present invention, the user is able to continue to use the cleaning device even if it is turned over, and it becomes even more possible for the cleaning device to roll back to its upright position due to the pulling and rotating force applied to the measuring system during subsequent use .

Although the rolling assembly has an outer surface that is generally spheroidal or spherical in shape, it may further have a recessed portion capable of receiving at least a portion of the cyclonic separating device. Any other surface features of the recess and body, such as handles, plug collar, and flat bottom surface on the body, do not preclude the fact that the body and wheel together are considered to be a rolling assembly as a whole. In fact, the rolling assembly may be a rolling assembly within the meaning of the term "rolling assembly" and is considered to be a substantially spherical or rotationally elliptical shape having a plurality of protrusions, recesses, cutouts or flattened portions. This will be applied so long as the overall appearance of the rolling assembly can be considered to be generally spherical or rotational oval so that the cleaning device can be rolled when tipping over its side or back side. Rolling assemblies are generally considered rotating elliptical, even if they have recesses, because their overall appearance is in the form of spheroids, spheres, or balls that can be accommodated by the separating device.

The rotational axes of the wheels may be inclined upwardly with respect to the bottom surface on which the cleaning device is located, so that the rim of the wheel engages the bottom surface when the cleaning device is in the upright position. The inclination angle of the rotation axes is preferably in the range of 0 to 15 degrees, more preferably in the range of 3 to 8 degrees. This advantageously improves the stability of the cleaning device.

The separating device is preferably removably received within the recess so that it can be removed for emptying. The recess therefore provides a support for the separating device on the body of the rolling assembly. When this is accommodated in the recess, the longitudinal axis of the separating device is tilted vertically, preferably at an acute angle, as the device moves along a substantially horizontal plane. This angle is preferably from 0 degrees, or from 20 degrees, or from 30 degrees, or from 35 degrees, or from 40 degrees, or from 45 degrees to 50 degrees, or from 55 degrees, or from 60 degrees, Lt; RTI ID = 0.0 > 70. ≪ / RTI > The separating device is preferably located within the recess by lowering it from above, until it is docked in the recess.

Preferred features of the present invention will now be described by way of non-limiting example only with reference to the accompanying drawings, in which:
1 is a front perspective view from above of a vacuum cleaner;
2 is a front perspective view of the body of the vacuum cleaner;
3 is a rear perspective view of the body of the vacuum cleaner;
4 is a side view of the body of the vacuum cleaner;
5 is a rear view of the body of the vacuum cleaner;
6 is a bottom view of the body of the vacuum cleaner;
7 is a front perspective view as viewed from above of the wheel-removed body;
8 is a rear perspective view of the body of the vacuum cleaner from which the separating device is removed;
9 is a front perspective view of the body of the vacuum cleaner from which the separating device is removed;
10 is a rear view of the body of the vacuum cleaner from which the separating device is removed;
11 is a cross-sectional view through the back view of the body of the vacuum cleaner;
Figure 12 is a cross-sectional view through the side view of the body of the vacuum cleaner;
13 is a perspective view of the separating device;
14 is a side view of the second embodiment showing the body of the vacuum cleaner; And
15 is a side view of the third embodiment showing the body of the vacuum cleaner.

1 shows an external view of a cleaning appliance in the form of a vacuum cleaner 1. Vacuum cleaner 1 is typically a cylinder or canister type having a body 2 that is pulled behind the hose and wand assembly during use. Figures 2-6 show more detail of the body 2. [

The body (2) comprises a separating device (4) for separating dirt and dust from the air flow. The separating device 4 is preferably in the form of a cyclonic separating device. The separating device 4 is housed in a bottom-engaging rolling assembly 6 such that it is at least partially nested and docked in the rolling assembly 6. [ The separating device 4 is removable from the rolling assembly 6 so that any dirt collected by the separating device 4 may be emptied.

The rolling assembly 6 includes a main body 8 and two wheels 10, 12. The two wheels 10, 12 are for engaging the bottom surface and are rotatably connected to each side of the body 8 one by one. During use, the vacuum cleaner 1 can thus be pulled and move on the edge 14 of the wheels 10, 12.

The plurality of external and / or shims of the rolling assembly 6 may be rounded, curved, or generally curved such that the overall shape of the rolling assembly 6 is substantially spheroidal or spherical in shape, . This shape allows the vacuum cleaner 1 to roll on the curved surface during use of the vacuum cleaner 1. This may occur, for example, if the vacuum cleaner 1 is tapped on its side or tapped back. In the illustrated embodiment, the curved surface 16 of the body 8 is positioned towards the rear of the rolling assembly 6. This means that if the vacuum cleaner 1 is back-tapped during use, it can roll on the curved surface 16. The wheels 10 and 12 are positioned one on each side of the rolling assembly 6 so that if the vacuum cleaner 1 is tipped on its side during use it can roll on the individual wheels 10 and 12.

Most preferably, the vacuum cleaner 1 is designed such that if it is tipped over one or more curved surfaces of the rolling assembly 6 during use, it is also forced to return to the upright position shown in Figures 1-3. This may be achieved by ensuring that the center of gravity of the vacuum cleaner 1 is as low as possible.

Fig. 7 shows a developed view in which the wheels 10, 12 are removed. 8 to 10 show views of the rolling assembly 6 from which the separating device 4 has been removed. It can be seen that each wheel 10, 12 of the rolling assembly 6 is substantially hemispherical in shape or forms part of a hemisphere. The wheels 10, 12 are domed or generally domed. Of course, the wheels 10,12 may have stepped outer surfaces or may have one or more flattened portions, but are still substantially hemispherical in shape and may still be substantially spherical or < RTI ID = 0.0 > Thereby forming the assembly 6.

The side 20 of the rolling assembly 6 which is below the wheels 10 and 12 and thus concealed during use of the vacuum cleaner 1 is rounded or curved so that they are in contact with the inner surface 22 of the wheel 10, As shown in Fig. This provides the maximum space inside the body 8 in which to place the components of the vacuum cleaner 1. Of course, such a feature is not essential and the side 20 may be molded in some other way that it is flat, has a step, or does not follow the contour of the inner surface 22 of the wheel 10,12.

In these figures it can be seen that the rolling assembly 6 has an outer surface on which the vacuum cleaner 1 is generally rotationally elliptical which is capable of rolling during use of the vacuum cleaner 1. It will also be appreciated that the body 8 has a recess 18 at least capable of receiving a portion of the separating device 4. [ Other surface features of the body 8, such as the recess 18 and the handle 24, the plug collar 26 and the flat bottom surface 28 on the body 8, allow the rolling assembly 6 to rotate substantially It does not depart from the fact that it is elliptical. In fact, the rolling assembly 6 may be a rolling assembly 6 having a plurality of protrusions, cuts or flattened portions, and still being considered substantially spherical or rotationally elliptical and within the meaning of the present application. This will be so long as the overall appearance of the rolling assembly 6 can generally be regarded as spherical or oval. The presence of the recess 18 also means that the rolling assembly 6 is generally regarded as a rotating elliptical because its overall appearance is in the form of a spheroid, ball or ball in which the separating device 4 is docked.

The axes of rotation of the wheels 10 and 12 are tilted upwardly with respect to the bottom surface on which the vacuum cleaner 1 is located so that the edges 14 of the wheels 10 and 12 engage the bottom surface. The rotational axes of the wheels 10, 12 are preferably in the range of 0 to 15 degrees, more preferably in the range of 6 to 10 degrees, and in this embodiment around 3 degrees. In alternate embodiments, the rotational axes of the wheels may be horizontal.

When the separating device 4 is received in the rolling assembly 6, the longitudinal axis of the separating device 4 is tilted so that it is at an angle in the range of 0 to 60 degrees from the vertical. This arrangement allows the separating device 4 to be simply docked by lowering the separating device 4 onto the rolling assembly 6 from above. In this regard, the rolling assembly 6 does not extend around any top surface of the separating device 4 when the separating device 4 is housed in the rolling assembly 6. [ It can be seen that the rearmost point 32 of the separator 4 is arranged side by side or in line with the line L which extends vertically through the center point 34 of the wheel 10, Preferably, the other components of the separating device 4 are also arranged behind the line L. This will be discussed in more detail later.

It can be seen that when the separating device 4 is housed in the rolling assembly 6, a part of the separating device 4 is still visible and forms part of the outer surface of the vacuum cleaner 1. The size and depth of the recess 18 may vary, but will be sized to accommodate the separating device 4 of the desired size. In the embodiment shown in the figures, the separating device 4 is housed in the recess 18 so that the gap visible between the separating device 4 and the rolling assembly 6 when the vacuum cleaner 1 is viewed from the side To be present. This side view can best be seen in FIG. In the embodiment shown in the figures, it can be seen that the separating device 4 is housed in the rolling assembly 6 along most of its length. Ideally, the separating device 4 is accommodated in the rolling assembly 6 along at least 50% of its length. In the most preferred embodiment the separating device 4 is accommodated in the rolling assembly 6 along at least 90% of its length.

8, 9 and 10, it can be seen that the recess 18 includes a plurality of molded recesses 36. The shaped recess portion 36 is shaped to receive the correspondingly shaped portion of the separating device 4, thereby allowing the separating device 4 to be housed closely in the recess 18. [ This is because the contours of the recess 18 and the molded recess 36 closely match the external shape of the portion of the separating device 4 housed within the recess 18 and the recess 36. Such a molded recess 36 will be discussed in more detail later.

1, the vacuum cleaner 10 includes a flexible hose 38 extending between the body 2 and the swivel coupling 40 for connection to the wand assembly 42. The wand assembly 42 is connected to a cleaner head 44 which includes a suction opening 46 which is the passage through which a dirty air flow is led into the vacuum cleaner 1. The flexible hose is connected to the body (2) by a swivel joint (47) which engages the inlet duct (48). The inlet duct 48 is connected to the polluted air inlet duct 70 which conveys the contaminated air from the inlet duct 48 to the separator 4. The swivel joint 47 will be discussed in more detail later. The cleaner head 44, the hose 38 and the wand assembly 42 are omitted in the remainder of the drawings for purposes of clarity only.

To control the vacuum cleaner 1 on the floor surface, the user grips and moves the wand handle 49, which moves the hose 38, the wand assembly 42, the swivel coupling 40 and the swivel joint 47 By this connection, the vacuum cleaner 1 is drawn on the floor surface. This in turn causes the wheels 10, 12 of the rolling assembly 6 to rotate and move the vacuum cleaner 1 on the floor surface.

11 and 12, a suction source 50 for drawing air from the cleaner head 44 to the separating device 4 is located within the body 8 at a position below the separating device 4, Lt; / RTI > Since the suction source 50 is relatively heavy, placing it under the separating device 4 provides a relatively low center of gravity for the vacuum cleaner 1. As a result, the stability of the vacuum cleaner 1 is improved. In addition, it becomes easier to handle and manipulate the vacuum cleaner 1. Preferably, the suction source 50 of the vacuum cleaner 1 and / or other components, if this is tapped over one or more curved surfaces of the rolling assembly 6 during use, To return to the upright position shown in FIG. This may be achieved by ensuring that the body 2 has a low center of gravity.

The separating apparatus 4 will now be described in more detail with reference to Figs. 11, 12 and 13. Fig. The separating device 4 is a cyclonic separating device. It includes an outer bore 52 having an outer wall 54 that is substantially cylindrical in shape. The lower end of the outer bore 52 is closed by a base 56 pivotally attached to the outer wall 54. The base 56 is held in a closed position by a catch 58 engaging the lip 60 located on the outer wall 54. In the closed position, the base 56 is sealed against the lower end of the outer wall 54. The catch 58 is resiliently deformable such that when the separating device 4 is removed from the rolling assembly 6 to be emptied, the downward pressure applied to the uppermost portion of the catch 58 will push it away from the lip 60 And move it away from it. In this case, the base 56 will fall away from the outer wall 54.

The specific overall shape of the cyclonic separating device 4 may vary depending on the size and type of the vacuum cleaner 1 to be used therein. For example, the overall length of the separating device 4 may be increased or decreased relative to the diameter of the device, or the shape of the base 56 may be, for example, flat or generally frustro-conical. can be changed.

The separating device 4 further comprises a second cylindrical wall 62. The second cylindrical wall 62 is positioned radially inwardly of the outer wall 54 and is spaced from it to form an annular chamber 64 therebetween. The second cylindrical wall 62 abuts the base 56 (when the base 56 is in the closed position) and is sealed against it. The cylindrical chamber 67 is defined by a second cylindrical wall 62, a base 56 and a chassis 69. The annular chamber 64 generally includes an outer wall 54, a second cylindrical wall 62, a base 56, a top wall 66 positioned at the top of the outer bean 52, Shaped horseshoe shaped shroud 68 that forms a hosel.

The contaminated air inlet duct 70 provides a passageway through the cylindrical chamber 67 for conveying contaminated air from the inlet duct 48 to the upper end of the outer bin 52, (44) through the hose (38) and the wand assembly (42).

The end 72 of the inlet duct 48 is in fluid communication with the annular chamber 64. In a particular embodiment, the end 72 of the inlet duct 48 is formed within the wall 74 that attaches to the membrane 68. The end 72 of the inlet duct 48 is disposed tangentially to the outer bore 52 to ensure that the incoming contaminated air is forced to follow the helical path around the annular chamber 64. Therefore, the annular chamber 64 serves as a low-efficiency cyclone.

As described above, the membrane 68 serves as a fluid outlet for the annular chamber 64. Curtain 68 has a monolithic wall 76 and a skirt portion 78 that hangs from the monolithic wall 76. The skirt portion 78 also hangs from the wall portion 74 attached to the membrane 68. The skirt portion 78 is tapered outward in the direction toward the outer wall 54. [ A large number of perforations 80 are formed in the membrane 68. The only fluid outlet from the annular chamber 64 is formed by the perforations 80 in the membrane 68. A passage 82 is formed between the membrane 68 and the second cylindrical wall 62. The passage 82 communicates with the plurality of second stage cyclones 84 through a plenum chamber 85. [

The second stage cyclone 84 is disposed in two layers, a first layer 86 and a second layer 88 disposed on the first layer 86. This second stage cyclone 84 is arranged to have a parallel air flow therethrough. The second stage cyclone 84 in each of the layers 86, 88 is circumferentially disposed about the plenum chamber 85. Each second stage cyclone 84 has a tangential inlet 90 in communication with the plenum chamber 85. Each second stage cyclone 84 is identical to the other second stage cyclone 84 and includes a cylindrical upper portion 92 and a tapered portion 94 that hangs therefrom. The tapered portion 94 of each second stage cyclone 84 is conical in shape and terminates in a conical opening 96. The second stage cyclone 84 extends into and communicates with a cylindrical chamber 67 bounded by a second cylindrical wall 62. This cylindrical chamber 67 serves as a dust collector for the dust separated by the second stage cyclone 84. [ A vortex finder 98 is provided at the upper end of each second stage cyclone 84 to allow air to escape the second stage cyclone 84. [ Each of the vortex finders 98 communicates with an outlet duct 100 passing between the second stage cyclones 84 to provide a clean air outlet 102 located on the side of the separating device 4. When the separating device 4 is docked on the rolling assembly 6, the clean air outlet 102 is concealed from the field of view and connected to the suction source inlet duct 104.

In the preferred embodiment there are 28 second stage cyclones 84 disposed in two layers 86, 88 of the 14 second stage cyclones 84. Each set of fourteen second stage cyclones 84 is disposed in a ring centered on the longitudinal axis X1 of the outer bore 52. [ Each second stage cyclone 84 has an axis C that tilts downward and toward axis X1. The axes C may all be inclined to the axis X1 at the same angle or alternatively the second stage cyclone 84 in the first layer 86 may be inclined to the second stage cyclone 84 in the X1 axis at different angles. The second stage cyclone 84 may be considered to form the second cyclonic separating unit, while the annular chamber 64 forms the first low-efficiency cyclonic separating unit.

In the second cyclonic separating unit, each second stage cyclone 84 has a smaller diameter than the annular chamber 64, and thus the second cyclonic separating unit is more finer than the first cyclonic separating unit and the dust The particles can be separated. This also has the advantage that it is challenged as an air flow which has already been cleaned by the first cyclonic separating unit, so that the amount and average size of the trapped particles is smaller than otherwise. The separation efficiency of the second cyclonic separation unit is higher than that of the first cyclonic separation unit.

As stated above, the body 8 of the rolling assembly 6 includes a suction source 50 in the form of a motor-driven fan unit. The body 8 further includes a cable rewind assembly 106 for rewinding and storing a portion of the electric cable that provides power to the motor of the fan unit 50 within the body 8. [ The fan unit 50 includes a motor and an impeller driven by a motor for drawing a dirty airflow into and through the vacuum cleaner 1. The fan unit 50 is housed in a motor bucket 108. The motor bucket 108 is connected to the main body 8 so that the fan unit 50 does not rotate when the vacuum cleaner 1 is steered on the floor surface. A post motor filter assembly (110) is positioned within the body (8) around and above the suction source (50). The post motor filter assembly 110 is of a serpentine type, which allows it to be wound around the motor bucket 108 to achieve almost all of the space within the rolling assembly 6. A plurality of perforations are formed in a portion of the motor bucket 108 surrounded by the post motor filter assembly 110. Seal 112 separates cable reel assembly 106 from motor bucket 108.

The main body 8 further includes an air exhaust port 114 for discharging the cleaned air from the vacuum cleaner 1. This can best be seen in FIG. The discharge port 114 is formed in the side 20 of the body 8 so that the discharge port 114 is concealed from view when the wheels 10 and 12 are in place, (20) and the inner surface (22) of the wheel (10, 12). In a preferred embodiment, the discharge port 114 includes a plurality of exit holes 116. In alternative embodiments, the discharge port 114 may be provided on another portion of the body. In Fig. 10, the discharge port 114 is positioned on the outer surface 30 of the body 8.

In use, the fan unit 50 is activated by the user, for example, by depressing the button 118 located on the upper surface of the body 8 of the rolling assembly 6. This causes the dirty air flow to be sucked into the vacuum cleaner 1 through the suction opening 46 in the cleaner head 44. The dirty air passes through the hose 38 and the wand assembly 42 and enters the inlet duct 48 through the swivel joint 47. The dirty air is then passed to the contaminated air inlet duct (70) of the separator (4). Due to the tangential placement of the end 72 of the contaminated air inlet duct 70, the air flow follows a helical path relative to the outer wall 54. Larger scum and dust particles are deposited and collected within the annular chamber 64 by cyclonic action.

The partially-cleaned air flow leaves the annular chamber 64 through the perforations 80 in the membrane 68 and enters the passage 82. The airflow then passes into the plenum chamber 85 and from there through their inlets 90 into the second stage cyclone 84 where additional cyclonic separation still removes some of the dirt and dust trapped in the air stream Remove. These dirt and dust are deposited in the cylindrical chamber 67 when the cleaned air leaves the second stage cyclone 84 through the eddy current finder 98 and enters the outlet duct 100. The air flow then passes through the suction source inlet duct 104 into the body 8 of the rolling assembly 6.

The inlet duct 104 directs the air flow into the fan unit 50. Airflow is discharged from the motor discharge duct into the motor bucket 108. The airflow then passes outside the motor bucket 108 and past the post motor filter assembly 110. Finally, the air flow follows the curvature of the body 8 to the outlet hole 116 of the discharge port 114, from which the cleaned air flow is discharged from the vacuum cleaner 1.

The separating device 4 comprises a handle 24 for facilitating separation of the separating device 4 from the vacuum cleaner 1. The user releases the handle 24 from the handle catch 122 on the body by pressing the catch release button 120 so that the detachment device 4 is removed from the vacuum cleaner 1 to be emptied. A handle catch 122 during normal use keeps the detachment device 4 attached to the body 8. Any suitable handle catch and catch release button may be used.

The user separates the separating device 4 from the vacuum cleaner 1 in order to collect the collected dirt and dust from the separating device 4. [ While holding the separator device 4 with the handle 24, the user presses the button 120 which causes the bar to push against the catch 58. The downward pressure applied to the catch 58 causes the catch 58 to move away from the lip 60 on the outer wall 54 of the outer bore 52 and the base 56 is moved away from the outer wall 54 So that dirt and dust collected in the device 4 can be removed therefrom.

The flexible hose 38 includes a hose cuff 124 that sealingly engages the connector 126 of the swivel joint 47. The connector 126 is a rotatable connector and is arranged to rotate sealingly about an axis X2 parallel to at least the first portion 128 of the inlet duct 48. To allow for this rotation, the connector 126 may rotate about the first portion 128 or about the first partial cuff 130 secured to the start of the inlet duct 48. This arrangement allows the swivel joint 47 to swivel the connector 126 around the inlet duct 48 if the user pulls the hose 38 and the wand assembly 42 in a specific direction during use Ensuring that the vacuum cleaner ensures greater stability than when the joint is secured.

As mentioned above, it can be seen in Figures 8-10 that the recess 18 includes a plurality of molded recesses 36. [ The molded impression 36 is configured to receive the second stage cyclone 84 shaped to correspond to each second stage cyclone (not shown) hidden from view when the separating device 4 is housed on the rolling assembly 6 84 are housed in a molded recessed portion 36 that closely matches the outer shape thereof. Thus, in the illustrated embodiment, there are two rows of molded recessed portions 36 corresponding to the first and second layers 86, 88 of the second stage cyclone 84. [

It can be seen in Figures 14 and 15 that a different amount of separating device 4 can be hidden from view when the separating device 4 is housed or docked in the recess 18 of the rolling assembly 6. [ 14, when the vacuum cleaner 1 is viewed from the side, at least one fifth of the width of the low-efficiency cyclone (the annular chamber 64) at the point of maximum depth P of the impression 18 is detected by the rolling assembly 6). ≪ / RTI > In Fig. 15, the ratio of the low-efficiency cyclone concealed from the field of vision is larger, in this case 4/5. A preferred embodiment in which at least one half of the low efficiency cyclone (annular chamber 64) is hidden from view by a portion of the rolling assembly 6 at the point of maximum depth P of the recess 18 is shown in Figure 4 Respectively.

As discussed previously, the rearmost point 32 of the separator 4 is arranged in parallel with or behind the vertical line L which dissects the center point 34 of the wheels 10, 12 . In general, the handle 24 is not considered part of the separation device in terms of such features. In the preferred embodiments, as shown in Figures 4 and 15, the rearmost cyclone viewing point 131 (when the separating device is housed within the rolling assembly 6) is aligned with or parallel to the line L . In other words, point 131 is the point at which the upper end of the outer wall 54 of the low-efficiency cyclone meets the second stage cyclone 84 when it intersects the rolling assembly 6. Preferably, the top edge 132 of the second cyclonic stage coincides with the curved surface 16 of the body 8. Again, this can be observed in FIGS. 4 and 15. FIG.

The body 8 may further comprise a second handle 134 which coincides with the handle 24 and forms a smooth curved surface when the separating device 4 is received in the rolling assembly 6. [ This second handle 134 is also curved so that it does not obstruct the rolling assembly 6 that is rolling. This means that if the separating device is tapped back, it will not get stuck and will be able to stand upright on its own.

The present invention is not limited to the specific details for carrying out the invention provided above. Modifications will be apparent to those skilled in the art.

Claims (14)

As a cylinder type cleaning device,
A separation device for separating dirt from the dirty fluid stream; And
A floor-engaging rolling assembly comprising a body and a pair of bottom-engaging wheels,
Wherein a rearmost point of the separating device is disposed in parallel with or behind the center point of the wheel. The method according to claim 1,
Wherein the separating device comprises a first cyclonic separation unit having a low efficiency cyclone and a second cyclonic separation unit having a plurality of second cyclones. 3. The method of claim 2,
Wherein a rearmost point of the second cyclonic separation unit is disposed in parallel with or behind the center point of the wheel. The method according to claim 2 or 3,
Wherein a last point of the low-efficiency cyclone is disposed in parallel with or behind the center point of the wheel. 5. The method according to any one of claims 2 to 4,
Wherein the last visible point of the low-efficiency cyclone is disposed in parallel with or behind the center point of the wheel. 6. The method according to any one of claims 1 to 5,
Wherein the cleaning device is implemented to encourage it to return to an upright position if tipped on its side. 7. The method according to any one of claims 1 to 6,
Wherein the wheels are disposed one on each side of the body. 8. The method according to any one of claims 1 to 7,
Wherein the rotational axes of the wheel are inclined upwardly with respect to a bottom surface on which the cleaning device is located. 4. The method according to any one of claims 1 to 3,
Wherein the rotational axes of the wheel are inclined upwardly with respect to a bottom surface on which the cleaning device is located. 9. The method according to any one of claims 1 to 8,
Each wheel having a domed outer surface. 10. The method according to any one of claims 1 to 9,
Wherein the first cyclonic separation unit is disposed upstream of the second cyclonic separation unit. 11. The method according to any one of claims 1 to 10,
Wherein the rolling assembly is substantially spheroid or spherical in shape. 12. The method according to any one of claims 1 to 11,
Wherein the rolling assembly has at least one protrusion. 13. The method according to any one of claims 1 to 12,
Wherein the cyclonic separating device is removably received within the recess in the rolling assembly. 14. The method according to any one of claims 1 to 13,
Wherein the longitudinal axis of the cyclonic separating device is tilted such that it lies at an angle within a range of 0 to 60 degrees from vertical.

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