This application claims the priority of United Kingdom Application No. 0821763.0 filed Nov. 28, 2008, the entire contents of which are incorporated herein by reference.
The present invention relates to a cleaning appliance, such as a vacuum cleaner.
Vacuum cleaners are designed to separate dirt and dust from an airflow. In a typical vacuum cleaner an airflow generator (for example, a motor and fan unit) generates an airflow which draws dirt- and dust-laden air into the vacuum cleaner through a dirty air inlet. The airflow then passes through a form of separating apparatus to remove dirt and dust from the airflow. Some vacuum cleaners make use of a porous bag through which the dirty air is sucked so that the dirt and dust is retained in the bag while cleaned air is exhausted to the atmosphere. In other vacuum cleaners, cyclonic separators are used to separate dirt and dust from the airflow.
Irrespective of the type of separating apparatus used, there is a risk of a small amount of dirt and dust passing through the separating apparatus and being carried to the airflow generator. It is undesirable for dirt and dust particles to pass through the fan of an airflow generator because the fan may become damaged or may operate less efficiently. In order to reduce this problem, some vacuum cleaners include a fine filter in an airflow path between the separating apparatus and the airflow generator. This filter is commonly known as a pre-motor filter and is used to extract fine dirt and dust particles remaining in the airflow after it has passed through the separating apparatus.
During normal operation of a vacuum cleaner, fine dirt and dust may be deposited on the pre-motor filter and, after a period of time, it could become blocked. Blockages reduce the efficiency at which a vacuum cleaner operates. Therefore, the pre-motor filter will occasionally need to be replaced or cleaned in order to maintain the performance of the vacuum cleaner. In order to allow cleaning or replacement of the pre-motor filter, it is common for such filters to be removable from a vacuum cleaner.
It is also known to provide a filter downstream of the airflow generator. This is known as a post-motor filter, and is typically employed to filter carbon dust which may be generated by brushes on the motor, as well as allergens and any microscopic particles of dirt and dust remaining in the airflow. After a period of use, the post-motor filter may need to be cleaned or replaced. Typically, the post-motor filter will need such attention much less frequently than does the pre-motor filter.
It is beneficial to permit the user to be able to monitor the condition of both the pre-motor filter and the post-motor filter, and to remove and replace them as required. To this end, access to both of the filters may be provided. However, it is more important that the user checks the pre-motor filter as it gets dirtier than the post-motor filter. By providing access to both filters, there is a risk that the user will check only the post-motor filter and neglect the pre-motor filter. This could lead to detrimental performance of the cleaner, and possibly even damage to the motor and fan.
The invention provides a cleaning appliance comprising a main body housing a motor and fan for generating a fluid flow, a removable pre-motor filter located upstream of the motor and fan and a removable post-motor filter located downstream of the motor and fan, wherein the post-motor filter is not accessible or removable from the main body until the pre-motor filter is removed from the main body.
By preventing release of, or access to, the post-motor filter until the pre-motor filter is removed, the user is directed to check the pre-motor filter first every time. Thus, the condition of the filter that is more likely to be dirty is monitored by the user, before the user goes on to check the other filter.
Preferably, the pre-motor filter is located in its own housing, removable from the main body and the post-motor filter is not accessible or removable from the main body until the pre-motor filter housing is removed. The pre-motor filter housing may be releasable from the main body by a manually-operable catch.
Advantageously, the post-motor filter is located in its own housing on the main body having an openable door. The door may be connected to the post-motor filter housing by a hinge arranged to permit the door to pivot about its rotational axis and to move axially along the rotational axis. A catch may be provided to hold the door closed.
Preferably, a portion of the pre-motor filter housing, such as its catch, may be arranged to obscure or make inaccessible the catch for the door of the post-motor filter housing.
Separating apparatus for separating dirt and dust from the airflow may be provided and releasably held on the main body. The post-motor filter may not be accessible or removable until the separating apparatus is removed from the main body. However, the pre-motor filter may be removed and replaced regardless of whether the separating apparatus is held on the main body or removed from it.
At least one of the filters, and preferably both of them, may be washable. The filter may comprise one or more layers of filter media delimited by a deformable rim.
The term “cleaning appliance” is intended to have a broad meaning, and includes a wide range of machines having a main body, a fluid flow generator and a head for travelling over a surface to clean or treat the surface in some manner. It includes, inter alia, machines which only apply suction to the surface so as to draw material from the surface, such as vacuum cleaners (dry, wet and wet/dry), as well as pressure washing machines and shampooing machines.
The invention will now be described, by way of example, with reference to the accompanying drawings, in which:
a is a front perspective view of part of the cleaner of
b is a perspective view of the pre-motor filter housing of
Like reference numerals refer to like parts throughout the specification.
With reference to
Separating apparatus 10 is releasably held on the main body 2. The separating apparatus 10 comprises a separator 11 and a collecting chamber 12. The separating apparatus 10 is supported on the main body 2 above the outlet ports 9 and lies adjacent the spine 7. The interior of the separating apparatus 10 is in communication with the dirty air inlet 6 through ducting 13 adjacent the spine 7. The separating apparatus 10 can be removed from the main body 2 for emptying and for maintenance.
In use, the motor and fan unit 3 draws dirty air into the vacuum cleaner 1 via the dirty air inlet 6. The dirty air is carried to the separating apparatus 10 via the ducting 13 adjacent the spine 7. The separating apparatus 10 includes an upstream cyclone 14 in the collecting chamber 12. An air inlet 15 is formed in the cylindrical side wall 16 of the collecting chamber 12. When the separating apparatus 10 is held on the main body 2 of the vacuum cleaner 10, the air inlet 15 is in communication with the dirty air inlet 6 and forms a communication path between the ducting 13 adjacent the spine 7 and the interior of the upstream cyclone 14. The air inlet 15 is arranged tangentially to the upstream cyclone 14 so that the incoming air is encouraged to follow a helical path around the interior of the upstream cyclone.
A shroud 17 is located inwardly of the cylindrical side wall 16 of the upstream cyclone 14. The shroud 17 comprises a cylindrical wall having a plurality of through-holes. The shroud 17 provides a communication path between the upstream cyclone 14 and a downstream cyclone assembly.
The downstream cyclone assembly comprises a plurality of downstream cyclones 18 arranged in parallel. In this embodiment, seven downstream cyclones 18 are provided. Each of the downstream cyclones 18 has a diameter smaller than that of the upstream cyclone 14. Therefore, the downstream cyclones 18 are able to separate smaller particles of dirt and dust from the partially-cleaned airflow than the upstream cyclone 14. Separated dirt and dust exits the downstream cyclones 18 and passes into the collecting chamber 12.
Cleaned air then flows back up through the downstream cyclones 18 and enters a duct 19. The cleaned air then passes from the duct 19 to a pre-motor filter 20. The pre-motor filter 20 serves to trap any fine dust or microscopic particles which have not been separated by the two cyclonic separation stages 14, 18. The downstream side of the pre-motor filter 20 communicates with the fan and motor unit 3. This unit 3 accommodates a fan impeller which is driven by a motor to generate the suction airflow. The outlet of the fan and motor unit 3 communicates with a post-motor filter 21. The post-motor filter 21 serves to trap any remaining particles in the airflow, as well as carbon particles from the motor. Air then exits the post-motor filter 21 and is exhausted from the vacuum cleaner 1 through the outlet ports 9.
A handle 22 is located over the separating apparatus 10 and is arranged to allow a user to carry the vacuum cleaner 1. When the separating apparatus 10 is released from the main body 2, as is shown in
Through use over a period of time, one or both of the pre-motor filter 20 and the post-motor filer 21 may become clogged with dust or dirt. Continued use would lead to a restriction in the airflow through the filters 20, 21, thereby causing a reduction in the efficiency of the vacuum cleaner 1. In order to alleviate this, any filter that becomes clogged must be replaced or washed. Usually, the pre-motor filter 20 will need to be replaced or washed more frequently than the post-motor filter 21; this is simply because the post-motor filter is downstream of the pre-motor filter and therefore receives an airflow that is less dirty. It is important that the user is directed to remove, and check the condition of, the pre-motor filter 20 first.
With reference to
When the pre-motor filter housing 24 has been released from the main body 2 of the vacuum cleaner 1, the pre-motor filter 20 may be removed from the housing for replacement by a new filter, or for cleaning, as shown in
When the pre-motor filter 20 has been washed and dried, or when the user has acquired a new filter, the filter can simply be replaced in the pre-motor filter housing 24. A lip 20c on the deformable rim 20b assists the user in replacing the pre-motor filter 20 in the correction orientation in the pre-motor filter housing 24. The housing 24 can then be slotted back into its location near the motor and fan unit 3. The catch 25 is biased so as to re-engage automatically when the housing 24 is replaced on the main body 2 of the vacuum cleaner 1.
When the pre-motor filter housing 24 is removed from the main body 2 of the vacuum cleaner 1, a second catch 28 on the main body becomes visible and accessible, as shown in
The second catch 28 comprises a flange 31 extending from the door 29 of the housing 30. The flange 31 is bent downwardly so as to engage with a lip 32 on the post-motor filter housing 30. The flange 31 is biased inwardly so as to retain the door 29 in a closed position against the post-motor filter housing 30. In order to release the catch 28, the user needs to pull on the flange 31 so that it flexes outwardly, away from the lip 32. The door 29 can then be opened.
The door 29 is attached to the main body 2 of the vacuum cleaner 1 by a hinge 33, which is shown in more detail in
The hinge 33 is provided with a cam 36. In this embodiment, the cam 36 comprises a lug 37 on the end portion of the pin 34 nearest the spine 7 of the main body 2. A co-operating tapered portion 38 is formed in the sleeve 35 of the hinge 33. The cam 36 is arranged so that, as the door 29 is swung from the closed to the open position, the tapered portion 38 of the sleeve 35 bears against the lug 37, thus constraining the sleeve to move linearly as it is further rotated. The cam 36 urges the sleeve 35 of the hinge 33, and hence the door 29, away from the spine 7 of the main body 2. The door 29 moves by a combination of rotational and translational motion: the door pivots about the rotational axis 39 of the hinge and also moves along this axis. Hence, when manufacturing the vacuum cleaner 1 there is no need to provide sufficient clearance for the door 29 to open fully, as it automatically moves away from the main body 2 and any obstructions associated with it. This can be seen in the perspective view of
Conventionally, the post-motor filter housing 30 and its door 29 has had to be located further forward on the main body 2 so that, when the door opens, it is clear of the spine 7 that extends upwardly from the main body 2, and any other components on the main body. This arrangement of the hinge 33 permits the post-motor filter housing 30 to be located close to the spine 7, allowing for a more compact cleaner 1 to be made.
When the post-motor filter housing 30 has been opened, as shown in
The filter housings 24, 30 and respective catches 25, 28 are arranged so that the catch 28 of the post-motor filter housing 30 is not accessible, let alone releasable, while the pre-motor filter housing 24 is in place on the main body 2. Thus, the first catch 25 must be released, and the pre-motor filter housing 24 removed, before the second catch 28 may be operated by the user. However, when replacing the filters 20, 21, the catches 25, 28 may be re-engaged in either order. For example, the user may decide to replace the post-motor filter 21 and then close the door 29; followed by replacement of the post-motor filter housing 24. It is just as simple for the user firstly to replace the pre-motor housing 24, re-insert the post-motor filter 21 in its housing 30, and then close the door 29. The position of the pre-motor housing 24 and the first catch 25 with respect to the post-motor filter housing 30 gives sufficient clearance for the door 29 to be closed; the flange 31 does not impinge on the pre-motor filter housing 24 during closing of the door. When the door 29 has been closed, it resumes its position behind the catch 25 of the pre-motor filter housing 24, and so cannot be released again until the pre-motor filter housing has been removed from the main body 2.
The first catch 25 may be released, and the pre-motor filter housing 24 removed, while the separating apparatus 10 is attached to the main body 2 of the vacuum cleaner 1, as shown in
The invention is not limited to the detailed description given above. Variations will be apparent to the person skilled in the art. For example, alternative arrangements of the cam 36 may be employed. The hinge 33 may incorporate a screw thread arranged so that, as the door 29 turns, it also moves along the axis 39 away from the spine 7 of the main body 2. Alternatively, a rack and pinion arrangement may be provided.
The hinge 33 need not incorporate a cam 36. The pin 34 is longer than the sleeve 35, and extends beyond the sleeve, away from the spine 7 when the door is in the closed position. Thus, if a hinge without a cam is employed, the user can elect to slide the door 29 axially along the rotational axis 39 in order that the door may open clear of any obstructions.
The hinge has been described with reference to opening the post-motor filter housing 30. However, similar hinge arrangements may be employed to provide access for other components. For example, the pre-motor filter housing 24 may be connected to the main body 2 by such a hinge arrangement. A cover permitting access to the motor and fan may also be hingedly connected in this way. Such an arrangement gives the user access to components that may need attention without adding to the overall size of the cleaner.
The first catch 25 for the pre-motor filter housing 24 and the second catch 28 for the post-motor filter housing 30 have been described as separately and independently manually operable. However, the second catch 28 may be automatically released in dependence on removal of the pre-motor filter housing 24. This may be effected by, for example, a protrusion on the pre-motor filter housing 24 arranged so that, as the housing is lifted, the protrusion bears against the flange 31, flexing it away from the lip 32 on the post-motor housing 30. In this manner, the second catch 28 and hence the door 29 are automatically released. Alternatively, the second catch may be mechanically linked to the pre-motor filter housing 24. As a further alternative, an electromechanical arrangement may be employed wherein the second catch 28 is held in a locked position until such time as the pre-motor filter housing 24 is removed. A Hall sensor arrangement is suitable for this purpose.
The separating apparatus need not be a cyclonic separator. Other forms of separating apparatus could be used, for example, a porous bag or filter. Additionally, the separating apparatus need not be located in the collecting chamber. A separate collecting chamber may be provided.
The cleaning appliance need not be an upright vacuum cleaner. The invention is applicable to other types of vacuum cleaner, for example, cylinder machines, stick-vacuums or hand-held cleaners. Further, the present invention is applicable to other types of cleaning appliances, for example, a wet and dry machine or a carpet shampooer.
Number | Date | Country | Kind |
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0821763.0 | Nov 2008 | GB | national |
Number | Name | Date | Kind |
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6289553 | Dyson | Sep 2001 | B1 |
20050125939 | Hansen et al. | Jun 2005 | A1 |
Number | Date | Country |
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1 177 757 | Feb 2002 | EP |
62-123756 | Aug 1987 | JP |
2004-510452 | Apr 2004 | JP |
2005-516711 | Jun 2005 | JP |
WO-9930602 | Jun 1999 | WO |
WO-03068041 | Aug 2003 | WO |
WO-2008015377 | Feb 2008 | WO |
Number | Date | Country | |
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20100132155 A1 | Jun 2010 | US |