AU2004224922B2 - Improvements in vacuum cleaners - Google Patents

Improvements in vacuum cleaners Download PDF

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Publication number
AU2004224922B2
AU2004224922B2 AU2004224922A AU2004224922A AU2004224922B2 AU 2004224922 B2 AU2004224922 B2 AU 2004224922B2 AU 2004224922 A AU2004224922 A AU 2004224922A AU 2004224922 A AU2004224922 A AU 2004224922A AU 2004224922 B2 AU2004224922 B2 AU 2004224922B2
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AU
Australia
Prior art keywords
filter
vacuum cleaner
filter arrangement
seal
arrangement according
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AU2004224922A
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AU2004224922A1 (en
Inventor
Danny Bone
Eric Cockburn
Barry Pears
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Black and Decker Inc
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Black and Decker Inc
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Publication date
Priority claimed from AU2003231582A external-priority patent/AU2003231582B2/en
Application filed by Black and Decker Inc filed Critical Black and Decker Inc
Priority to AU2004224922A priority Critical patent/AU2004224922B2/en
Publication of AU2004224922A1 publication Critical patent/AU2004224922A1/en
Application granted granted Critical
Publication of AU2004224922B2 publication Critical patent/AU2004224922B2/en
Anticipated expiration legal-status Critical
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  • Filters For Electric Vacuum Cleaners (AREA)

Description

P O1PER\ArI\I 2529390 d1iv doN-27/10/4 1A SImprovements in Vacuum Cleaners 00 N This application is a divisional application derived from Australian Patent Application No. 2003231582, the entire contents of which are incorporated herein by reference.
O The present invention relates to improvements in the filter arrangements used in N vacumn cleaners and in particular to improvements in the filter arrangements used in hand held battery operated vacuum cleaners.
O
In many known vacuum cleaners a motor powered either by a mains electricity supply or a battery pack, which may be rechargeable, rotatingly drives a fan. The fan generates an airflow within which particles of dust and debris to be collected by the vacuum cleaner become entrained. The airflow generally enters the vacuum cleaner via an inlet nozzle and passes through a filter so that panicles of dust and debris entrained in the airflow are removed from the airflow by the filter and are collected in a collecting chamber. A problem with this type of vacuum cleaner is that alter some vuse the pores of the filter can become blocked by particles of dust and debris which tend to bind together to form relatively large conglomerations. Once the filter becomes blocked the airflow through it is reduced and the suction power of the vacuum cleaner is reduced.
In its simplest form the filter can be a piece of woven polyester material supported in a frame and located between a collecting chamber and the fan. Such a simple filter will filter out the majority of particles of dust and debris from the airflow drawn into the fan some of which particles then drop into the collecting chamber. However, such simple filters do tend to become blocked relatively quickly and can be ineffective to filter out smaller particles of dust and debris from the airflow.
Improved filters are known in which the filter comprises a concertina of filter material, in order to increase the surface area of the tilctr whist not taking up too much space within the vacuum cleaner. However, these can also become blocked through use and the folds in the concertina of filter material provide crevices in which conglomerations of panticles of dust and debris can accumulate. In such filters the filter material has to be made of materials which maintain their shape once folded, P \OPERRSH 1252930-W I pa dc4)Ol 6 2 which can increase the expense of the filter material used, particularly if a fine filter is required.
It is important that the filter arrangement used in the vacuum cleaner is effectively sealed within the housing of the vacuum cleaner so that none of the airflow within which dust and debris is entrained leaks around the sides of the filter. It is desirable that all the airflow through the fan passes through the filter so that all the particles of dust and debris entrained in the airflow are filtered out and collected in a collecting chamber. Such a seal for a filter will have to be effective throughout the lifetime of the vacuum cleaner and may have to withstand regular disassembly of the parts of the vacuum cleaner surrounding it in order that the collecting chamber can be emptied and possibly so that the filter itself can be cleaned.
In some vacuum cleaners the filter is regularly removed from the housing of the vacuum cleaner so that it can be cleaned. In such vacuum cleaners it is desirable to be able to remove and replace the filter easily and without reducing the strength of any seal between the filter and components of the vacuum cleaner surrounding it.
According to the present invention, there is provided a filter arrangement for a vacuum cleaner for filtering particles of dust and debris from an airflow passing through the vacuum cleaner in which the filter arrangement has a first coarse filter to pre-filter the air flow and a second fine filter, a peripheral rim via which it is fitted to a first housing part of a vacuum cleaner, and an annular seal element made of a resilient material surrounding said rim, the seal element including a portion for forming a seal with the first housing part P \OPER\RSH\I25293I Ispa d-O I Ak S3 and a portion for forming a seal between the coarse and fine filters.
The present invention further provides a vacuum cleaner including a filter arrangement as defined above. In its preferred embodiment, there is provided a battery powered hand-held vacuum cleaner including a first housing portion which houses a C 5 battery pack, a motor and a fan and a second housing portion which includes a nose cone, wherein the battery pack powers the motor which rotatingly drives the fan to generate an airflow which enters the vacuum cleaner through the nose cone and passes through the dual filter arrangement into the fan.
The dual filter arrangement of the preferred embodiment to be described herein in greater detail filters particles of dust and debris from an airflow passing through the vacuum cleaner, and includes a coarse pre-filter and a fine primary filter which is located rearwardly of the pre-filter in the direction of flow of the airflow. With such an arrangement, the pre-filter will prevent a proportion of the particles of dust and debris entrained in the airflow from reaching the primary filter and thus will reduce the blocking of the primary filter. Furthermore, the use of a coarse pre-filter means that the size of particle reaching the primary filter will be of more uniform diameter than if the pre-filter was not present, because all particles reaching the primary filter will have diameters less than the diameter of the pores in the pre-filter. It has been found that particulate material of more uniform diameter is more resistant to binding than particulate material of greatly varying diameter. This further reduces the tendency of the primary filter to Sbecome blocked because the particulate matter incident on it is less inclined to S bind together to form the conglomerated masses of dust and debris particles o which are responsible for the blocking up of the filter. In this way the majority of 00 particles of dust or debris incident on the primary filter will fall away from the surface thereof and can be collected.
SPreferably, the diameter of the pores of the pre-filter is set at a substantially uniform value, preferably at a value within the range 0.75mm to c- 1.75mm and in particular a value of 1mm. It would generally be expected that using such large diameter pores would not deflect particulate matter of smaller size, such as average sized dust particles from the airflow. However, the pre-filter with an array of substantially uniform diameter pores with a diameter set at a value within this preferred range -serves to deflect a significant amount of particles of dust and debris picked up in a standard manner by a vacuum cleaner and entrained in an airflow passing through it irrespective of the particle size. When the particles entrained in the airflow hit the pre-filter, their momentum is reduced or eliminated and the airflow is often insufficiently strong to recapture such particles which then fall out of the airflow and can be collected. This significantly reduces the volume of particulate material which reaches the primary filter and so will reduce blocking of the primary filter further.
In order to reduce the volume taken up by the dual filter arrangement without decreasing its performance it is preferred that the pre-filter is formed with a recess within which the primary filter is received.
In a preferred embodiment the pre-filter includes an open box shaped structure in which the array of pores is located in at least one of the sides of the structure and more preferably the array of pores is located in all five sides of the structure.
The pre-filter may conveniently be made from a moulded plastics material.
Preferably, such plastics material will comprise a low friction material, such as polypropelene, and may be an anti-static compound such as achieved by mixing carbon with polypropylene.
In order to provide a seal between the pre-flter and co-operating parts of the vacuum o cleaner housing to ensurc that aUl of the airflo'v within which dust and debris is 00 entrained passes throuigh the dual filter arrngemenit, it is preferred that the pre-filter has a peripheral rim via which it is coupled to the primary filter and/or to a housing part of a vacuumr cleaner, wherein a peripheral seal element made of a resilient material surrounds said rim.
It is preferred that said scal clcmcni includes a first rearnyardly extending resilient 0 portion which extends around the periphery of the rim of the pre-fifter towards the primary filter and which surrounds the periphery of the primary filter when the dual filter arrangement is fittedl to a vacuum c~leaneT. This helps to provide a closure bctwccn the peripheries of the pre-filter and the primary filter which is preferably sealed by ensuring that the first rearwardly extending resilient portion extends Tearwardly beyond the primary filter to engage a first housing part of a vacuum cleaner to form a seal therewith when the dual filter arrangement is filled to a vacuum cleancr. This also provides a seal between the dual filter arrangement and the first housing part.
it is further preferred that the seal element includes a second rearwardly extending resilient portion which extends around the periphery of the rim of the pre-filter towards the primary filter to engage a peripheral rim of the primary filter to fchrm a scal thcrcw-,ith when the dual filter arrangement is fitted to a vacuum cleaner. This provides further sealing between the pre-filter and the primary filter to prevent dust laden airflow leaking therebetween.
In a preferred embodiment the seal element may include a substantially radially outwardly extending resilient portion which extends around the periphery of the rim of the pre-fdter to engage a second housing part of a vacuum cleaner to forni a seal therewith when thc dual filter arrangement is fitted to a vacuum cleaner. Preferably, a radially inwardly extending wall is provided on the second housing paxt of the vacuum cleaner and a front facing surface of the radially outwardly extending resilient port-ion engages a rearwardly facing surface of said wall to form a seal therebetwecn.
I 0 It is further prcfcrrcd that in use of the vacuum cleaner the seal between the radially outwardly extending resilient portion and the radially inwardly extending wall is O reinforced by a pressure differential generated by an underpressure located in front of C) the dual fiier arrangement.
Alternatively, the sealing element may include a substantially radially outwardly cxtending resilient portion which extends around the periphery of the rim of the prefilter wherein the periphery of the radially outwardly extending resilient portion is arranged such that it does not engage the second housing part of the vacuum cleaner 0 10 when the vacium cleaner is not in use but when the vacuum cleaner is in use a pressure differential generated by an underpressure located in front of the dual filter arrangement urges the periphery of the radially outwardly extending resilient portion into engagement with the second housing part to form a seal therewith. Since the seal is not in frictional engagement with the second housing part when the second housing pan is removed it provides for easier removal of that second housing part.
The second housing part referred to may include the wall of a removable nose cone of the vacuum cleanet through which dust and debris are sucked into the vacuum cleaner.
The seal element may be made of any resilient sealing material, such as rubber, neoprene, siliconcs or other suitable clastomers.
Conveniently, the seal element may by moulded around the periphery of the rim of the pre-filter.
In a preferred embodiment the pre-filter is releasably latched to a first housing portion of a vacuum cleaner by a latching arrangement against a biasing force generated by the real element. Preferably, at least one cam surface is located between co-operating latching parts of the latching arrangement, such that the movement of at least one of the latching parts over the cam surface during the unlatching movement causes the seal element to lie compressed beyond the degree of O compression of the seal element when the pre-filter is latched to the first housing portion. Thus, the seal element has the dual function of providing sealing and of o providing resilient biasing of the latching arrangement, thus providing a potential 00 reduction of component parts.
In a preferred embodiment at least one keyhole shaped aperture is Sprovided in the rim of the pre-filter through which can be releasably latched a cooperating latch element which extends from the first housing portion. The or each latch element may comprise a peg with an enlarged head which can fit within the widened portion of the aperture and a stem which can fit within the narrow portion of the aperture. In this preferred embodiment the cam surface may surround the aperture and may comprise at least one ridge over which the co-operating latch element must ride when moving into or out of the latched position.
Preferably, the primary filter has a peripheral rim via which it is releasably latched between the pre-filter and the first housing portion.
The first housing portion of the vacuum cleaner referred to above may be a housing portion which surrounds an inlet to a fan of the vacuum cleaner.
The present invention will now be described with reference to preferred embodiments illustrated in the accompanying drawings, in which: Figure 1 shows a longitudinal cross-section of a hand held battery powered vacuum including a dual filter system according to the present invention.
Figure 2 shows a front perspective view of a primary filter used in the dual filter system of the vacuum cleaner of Figure 1.
Figure 3 shows a rear perspective view of the primary filter shown in Figure 2.
Figure 4 shows a side view of the primary filter shown in Figures 2 and 3.
Figure 5 shows a side perspective view of a pre-filter used in the dual filter system of the vacuum cleaner of Figure 1.
Figure 6 shows a bottom view of the pre-filter shown in Figure Figure 7 shows a top view of the pre-filter shown in Figures 5 and 6 and shows an array of filter holes provided in the front surface of the pre-filter.
Figure 8 shows a longitudinal cross-section of the pre-filter shown in Figures 5 to 7.
8 8 Figure 9 shows a side view of the pre-filter shown in Figures 5 to 8 and shows an array of filter holes provided in all the side surfaces of the pre-filter.
o Figure 10 shows an enlarged longitudinal cross-section of a portion of the 00 rim of the pre-filter shown in Figures 5 to 9 and its associated seal element.
Figure 11 shows a side perspective view of a portion of the upper surface Sof a rim of an embodiment of a pre-filter similar to that shown in Figures 5 to SFigure 12 shows a longitudinal cross-section of a portion the nose cone of the vacuum cleaner shown in Figure1 and an embodiment of a seal element for the rim of the pre-filter shown in Figures 5 to 11.
C 10 Figure 13 shows a longitudinal cross-section of a portion the nose cone of the vacuum cleaner similar to that shown in Figure 1 and an embodiment of a seal element for the rim of the pre-filter shown in Figures 5 to 11.
The battery powered hand held vacuum cleaner shown in Figure 1 comprises a main housing portion and a nose cone and can be releasably mounted on a charging unit in a known manner. The charging unit can optionally be mounted on a wall for storage and re-charging of the vacuum cleaner.
I
9 SThe main housing portion comprises a handle and houses a motor (10) which is Spowered by a re-chargeable battery unit (12) also housed within the main housing O portion. When the vacuum cleaner is mounted on the charging unit the battery 00 N unit (12) is electrically connected to the charging unit to charge the battery unit. For this purpose the charging unit can be connected to a mains electricity supply via an electrical cable The motor (10) is switched on and off by movement of an actuator (16) which is slideably mounted on the main housing portion The actuator (16) operates a switch unit (18) which switches the motor (10) on and off.
O
10 The motor (10) rotatingly drives a fan When the fan (20) is rotated by the motor it draws air into it axially from the front of the fan through an inlet (84) provided in the front of the main housing portion as indicated by arrows The fan expels air radially, as indicated by arrows The air expelled by the fan (20) exits the main housing portion via vents (not shown) provided in said housing portion.
A dual filter system (34) which comprises a pre-filler (36) and a primary filter (38) is releasably latched onto the front of the main housing portion in front of the inlet (84) to the fan (20) by a pair of pegs (40) which extend from the front of the main housing portion. The pegs (40) have enlarged heads and can be releasable latched within a corresponding pair of keyhole shaped apertures provided in the pre-filter (36) and in the primary filter (38) in a manner described in more detail below.
The nose cone can be releasably fitted onto the main housing portion by the engagement of detent members (22,24) provided on the main housing portion with cooperating recesses (26,28) provided in the nose cone. Detent member (24) can bc retracted from recess (28) by depressing a release lever (30) against the force of a biasing spring (32) in order to remove the nose cone from the main housing portion The nose cone comprises an inlet tube (42) for the ingress of dust and debris to be collected by the vacuum cleaner. At the rear end of the inlet tube (42) is provided a deflector (44) for deflecting dust and debris downwardly into a collecting chamber (46) provided in the nose cone
O
O In use when the vacuum cleaner is detached from the charging unit and the motor is switched on, the impeller (12) rotates to draw an airflow into the front end (48) O of the inlet tube along the inlet tube (42) through the dual filter system (34) and 00 I axially into the fan The front end (48) of the inlet tube is directed by a user towards a surface from which dust and/or other debris is to be collected. The airflow cI generated by the fan (20) entrains dust and debris within it and so this dust and debris is pulled up the inlet tube (42) and a proportion of is deflected downwardly with the airflow by the deflector (36) towards collecting chamber In this way some of the dust and debris entrained in the airflow will be removed from the airflow and collected within the collecting chamber The remainder of the dust and debris entrained within the airflow will be separated from the airflow by the dual filter system The proportion of dust and debris separated from the airflow by the prefilter (36) will drop downwardly, due to gravity, and will be collected in the collccting chamber The remaining, relatively small, proportion of the dust and debris separated from the airflow by the primary filter (38) will be collected in the space between the pre-filter (36) and the primary filter (38).
When a user has collected a pre-determined amount of dust and debris or has completed a debris collecting task, the motor (10) will be switched off and the nose cone removed from the main housing portion by depressing the release lever The dust and debris contained in the collecting chamber (46) can then be disposed of. Also the dual filter system (36) can be removed as required by the operator from the main housing portion and any dust or debris collected on or between the pre-filter (36) and the primary filter (38) can be removed. The dual filter system (34) and nose cone can then be re-fitted onto the main housing portion (2) and the vacuum cleaner is ready for further use or can be stored away for subsequent use.
One of the benefits of the arrangement utilising a dual filter attached to the main housing portion is that this design provides for relative ease of emptying and cleaning the vacuum cleaner. In particular, the user may hold the housing unit in one hand whilst removing the collecting chamber (26) with an opposed hand, the dust and O debris being primarily retained within the collecting chamber (46) and thus can be emptied at the operator's convenience. No additional step is required to remove die 0 pre- or primary filters from the main housing and any debris collected between the 00 primary filter and the pre-filter can simply be removed by vibrating or shaking the housing unit with the filters attached thereto. This enables a continuous operation to Cl empty the vacuum cleaner.
The dual filter system (36) will now be described in more detail, with reference to r figures 1 to 13.
0 The primary filter (38) of the dual filter system (34) shown in Figure 1 comprises a moulded plastic frame within which is supported a concertina of woven polyester filter material The moulded plastic frame comprises a rim (52) from which extend two opposing side support frames (54, 56). Each side support frame (54, 56) comprises an outer frame (60a, 60b, 60c) within which are formed an array of lower forked support arms (58a) and an array of upper forked support arms (5 Rb) which cooperate in a zig-7ag formation. The concertina of fdter material (50) is supported between the zig-zag formation of opposing support arms (58a, 58b) and by the end support arms (60a, 60c) of the outer frame. In addition triangular shaped sections of 2 0 woven polyester filter material (62) are supported between adjacent support arms (58a), adjacent support arms (58b), adjacent support arms (60a, 58a) and adjacent support arms (60c, 58a). The triangular sections of filter material (62) provide a side filter surface across the area contained within the outer frame (60a,60b,60c) of each support frame (54, 56).
The primary fidter (38) is manufactured by folding a concertina of filter material within and locating triangular sections of filter material (62) appropriately within a moulding die and then injecting plastics material into the moulding die to form the moulded plastics frame comprising rim (52) and opposing support frames (54,56).
The opposing support frames will thus support the woven filter material (50, 62) securely in position. The folding of the filter material (50) in the concertina 0 arrangement and the additional triangular sections of filter material (62) provides a primary filter (38) with a relatively large cross-sectional area.
0 The rim (52) of the primary filter (38) has formed within it on opposing sides keyhole shaped apertures (64,66), which are used to releasably latch the primary filter (38) to N co-operating pegs (40) provided on the front of the main housing portion of the S vacuum cleaner of Figure 1.
As shown in Figure 1, in use the primary filter (38) will be surrounded by a pre-tilter S 10 (36) shown in Figures 5 to 9. The pre-filter (36) comprises a moulded plastic open box-shaped casing having front surface (66) and four side surfaces (68a to 68d) and a rim A resilient seal element (72) extends around the periphery of the rim The front surface (66) and the four side surfaces each. have formed through them an array (74) of circular filter holes, for example the array of filter holes (74a) formed in the front surface (66) as shown in Figure 7 and the array of filter holes (74b) formed in the side surface (68b) as shown in Figure 9. Each of the holes in the arrays of holes (74) has a diameter of approximately Imm although the size may vary, if required between 0.75mm and 1.75mm. The arrays of holes in the pre-filter (36) provide a first coarse filtering stage in front of the primary filter which provides a second fine 2 filtering stage.
To aid in the injection moulding of the pre-filter (36) the front face (66) of the prefilter comprises a solid circular region (76) from which extend radially outwardly six solid arms The solid circular region (76) and arms (78) assist in the flow of molten plastics material during the injection moulding process, which flow would otherwisc be impaired by narrow channels between the holes forming the arrays of holes The solid circular region (76) also provides a region of the pre-filter (36) that can prominently display information such as trade marks.
It has been found in practice that the 1mn diameter size of the holes in the pre-filter (36) is generally greater than the majority of the particles of dust and debris entering the nose cone in use of the vacuum cleaner shown in Figure 1. However, the pre- Sfilter (36) still deflects the majority of particles of dust and debris, irrespective of their size, out of the airflow drawn through the pre-filter (36) by the fan These O deflected particles of dust and debris are collected in the collecting chamber (46) of 0 0 the nose cone Up to 90% of particles of debris and dust normally p;icked up during household vacuuming and entrained in the airflow in front of the pre-filter (36) (C1 can be removed from that airflow by the pre-filter. However, the amount of Sparticulane removed from the airflow is dependent on the size of that particulate.
SThe 1mm diameter circular hole size used in the pre-filter would be expected not to O 10 deflect the generally much smaller sized particles of dust and debris entrained in an airflow through it. However, when the particles of dust and debris entrained within the airflow hit the front surface of the pre-filter (36) the momentum of the particles is reduced or eliminated. The airflow into the pre-filter (36) is often insufficient to then recapture such particles and these particles fall into the collecting chamber This significantly reduces the volume of particles of dust and debris which reach the primary filter (38) and so there is a significant reduction in the amount of blocking of the pores of the filter material used therein hy conglomerations of such particles.
Furthermore, as the particles that reach the primary filter (38) will have passed through the Imm diameter holes in the pre-filter (36) they will be of more uniform diameter than if the pre-filter was not used. It has been found that this increased level of uniformity of diameter of particles incident on the filter material (50, 62) of the primary filler (36) is more resistant to binding and thus tends to reduce further the blocking up of the pores in the primary filter by conglomerations of particles. This is because particles of similar diameter are less likely to bind together to form a conglomerated mass that could block the filter material than particles of dissimilar diameters. The more uniform diameter particles that have passed through the pre-filter (36) tend not to bind and instead fall away from the filter material (50, 62) into the space between the pre-filter (36) and the primary filter This reduction of blocking of the pores of the primary filter improves the suction of the vacuum cleaner during use as the airflow to the fan (20) is not impeded by a blocked primary filter (38).
o In a similar way to the primary filter the rim (70) of the pre-filter (36) has formed within it on opposing sides keyhole shaped apertures (80, 82), which arc used o to releasably latch the pre-filter (38) to co-operating pegs (40) provided on the front of 00 C the main housing portion of the vacuum cleaner of Figure 1. When the primary filter (38) is received within the pre-filter the keyhole shaped apertures (64, C and (66, 82) line up so that the dual Jilter system (34) comprising the pre-filter (36) and the primary filter (38) can be releasably latched to the main housing portion as Su single assembly.
o 10 To fit the dual filter system (34) to the main housing portion the widened portions of the keyhole shaped apertures (64, 80) and (66, 82) are fitted over the enlarged head of a corresponding one of the pair of pegs The dual filter system (34) is then rotated slightly to slide the stem of the pegs (40) into the narrow portion of the respective keyhole shaped apertures (64, 80) and (66, 82) in order to securely latch the dual filter system (34) to the main housing portion over the inlet (84) to the fan One of the pegs (40) comprising an enlarged head (86) and a stem (88) is shown clearly in dotted lines in Figure Figure 10 shows in more detail the resilient seal element (72) which surrounds the rim (70) of the pre-filter The seal element (72) is made of a resilient material such as rubber, silicone, neoprene or other suitable clastomers and is intended to form an air tight seal between the pre-filter (36) and the primary filter between the dual filter system (34) and the nose cone and between the dual filter system and the main housing portion The rim (70) has a stepped portion (90) which extends around its periphery and the resilient seal element (72) is moulded over this stepped portion. The seal element (72) comprises a radially outwardly extending portion which as seen in Figure 1 engages the inner surface ufthe wall of the nose cone when the nose cone is fitted to the main housing portion to form an airtight seal between the dual filter system (34) and the nose cone. The seal element also comprises a first axially rearwardly extending portion (94) (Figure 10) which extends around the periphery of the rim (52) Sof the primary filter (38) to engage a forward surface of the main housing portion (2) Sto form an airtight seal between the dual filter system (34) and the main housing 0 portion, and as a consequence an airtight seal is also formed between the pre-filter (36) and the primary filter The seal element (72) further comprises a second axially rearwardly extending portion (96) against which the rim (52) of the primary N' filter (38) abuts when the pre-filter (36) and primary filter (38) are together fined onto the main housing portion. This provides further air tight sealing between tle pre-filtcr (36) and primary filter This sealing is further enhanced by extending the seal element (72) at the keyhole shaped apertures (80,82) so that an extensioa (98) (See also Figure 6) of the seal element extends around each keyhole shaped aperture 82) partly within a recess (100) formed in the lower side of the rim (70) around said apertures.
Thus, when the dual filter arrangement (34) is assembled and fitted onto the main housing portion the primary filter (38) is inserted into the pre-filter (38) such that the concertina of filter material (50) is received within the box-shaped cavity of the pre-filter, the keyhole shaped apertures (64, 80) and (66, 82) are aligned, the second axially extending portion (96) of the seal (72) abuts the rim (52) of the primary filter (38) and the first axially extending portion (94) of the seal (72) extends around the periphery of the rim (52) of the primary'filter The dual filter arrangement is then latched onto the studs (40) provided on the main housing portion This latching of the dual filter system (34) to the pegs (40) presses the rims (52, 70) of the filters together and so reinforces the seal between the pre-filter (36) and primary filter (38) provided by the portion (96) of the seal element It also presses the rim (70) of the pre-filter (36) towards the front surface of the main housing portion and so reinforces the seal between the pre-filter and the main housing portion provided by the portion (94) of the seal element (72).
An altcmative design of pre-filter (38) which provides an improved releasable latch 3 0 connection between the dual filter system (34) and the main housing unit of the vacuum cleaner of Figure I is shown in Figure 11. In the arrangement of Figure 11, a raised cam surface (102) is provided on the upper surface of the rim (70) of the prer Sfilter (38) bordering the narrow portion and part of the widened portion of each keyhole shaped aperture (80, 82). Each cam surface (102) comprises a pair of ramps O (104) facing towards the widened end of the aperture it borders and an opposing pair 00 of ramps (106) facing towards the narrow end of the aperture it borders. Each cam surface (102) co-operates with the underside of the enlarged head portion (86) of a N respective peg When the dual filter system (34) is fitted over the pair of pegs provided on the main housing portion the enlarged head portion (86) passes l through the widened portion of the respective key shaped apertures (64, 80) and (66, 82). Then the dual filter system (34) is rotated by a small amount so that the neck 3 0 portion of each peg (40) slides into the narrow portion of the respective apertures and the enlarged head portion (86) of each peg latches the dual filter system into the main housing portion.
With the improved arrangement shown in Figure 11, rotation of the dual filter system (34) in this way, causes the underside of the enlarged head (86) of each peg to ride up the pair of ramps (104) on the respective cam surface (102). This urges the rim of the pre-filter (36) towards the main housing portion and thus towards the rim (52) of the primary filter (38) against the biasing force of the axially extending portions (94, 96) of the seal element Further rotation of the dual filter system causes the underside of the enlarged head (84) of each peg to move down the opposing ramps (106) and come to rest in its final latched position against the flat raised portion of the cam surface (102) surrounding the narrowed portion of each aperture (80, 82). This slightly releases the compression of the axially extending portions (94, 96) of the seal element However, with the dual filter system in its 2 5 latched position, the rim (70) of the pre-filter system is urged sufficiently towards the main housing portion and towards the rim (52) of the primary filter (36) for the axially extending portions (94, 96) to form an air tight seal against the main housing portion and the rim (52) respectively. This ensures that in use of the vacuum cleaner all airflow to the fan (20) passes through the pre-filler (36) and through the primary filter Furthermore, the two ridges (108) on each cam surface (102) between the opposing ramps (104, 106) serve as a retaining means to retain the pegs (40) in their latched position against the resilience of the axially extending portions (94, 96) of the 0 sealing clement In this way the dual filter system can only be unlatched from P the pegs (40) by rotation in a direction opposite to that required to latch the dual filter 0 system to the pegs, which rotation can only occur if a force is applied which is 0 0 sufficient to compress the axially extending portions (94, 96) so that the underside of the enlarged heads (86) of the pegs (40) can ride over the ridges (108) in the cam N' surfaces (102).
(tN C Alternatively, or in conjunction with the use of the cam surfaces (102), internal ribs may be provided around the interior surface of the collecting chamber (46) so as the collecting chamber (46) is moved into engagement with the main housing portion these ribs engage with the rim (70) of the pre-filter system so as to serve to compress the axially extending portions (94, 96) of the sealed element (72) into respective engagement with the housing portion and primary filter (36) accordingly. The use of ribs in this manner will provide a uniformly distributed compression force about the entire periphery of the seal of the pre-filter.
Figure 13 shows a cross-section of the seal element (72) shown in Figure 10, with like parts identified by like numerals. Figure 13 also shows a modified portion of the outer wall of the nose cone adjacent the seal element (72) from that shown in Figure 1. In the Figure 13 embodiment an internal raised wall (110) extends around the portion of the internal surface of the nose cone which surrounds the seal element This creates an improved air tight seal between the dual filter system (34) and the inner surface of the nose-cone The radially extending portion (92) of the resilient seal element (72) abuts the rear surface of the wall (110). In use of the vacuum cleaner the underpressure created in the forward part (112) of the nose cone relative to the ambient air pressure in the region (114) in front of the main housing portion reinforces a sealing engagement between the portion (92) of the sealing element (72) and the wall (110). The pressure differential urges the front surface of the resilient radially extending portion (92) of the seal. element (72) into sealing engagement with the rear surface of the wall (110). Again this ensures that all the airflow through the nose cone passes through the dual filter arrangement (34) into the fan 4 1 6 18 Figure 12 shows an alternative embodiment to that shown in Figure 13, with like parts identified by like numerals, in which the wall (110) is not required on the internal 0 surface of the nose cone and the radially extending portion (92) of the seal element N, (72) is bent rearwardly to form and third axially rearwardly extending portion (116).
In Figure 12 the radially extending portion (92) is bent rearwardly through approximately 90°. Thus, as shown in solid lines in Figure 12, when the nose cone (4) O is fined on the main housing unit with the vacuum cleaner switched off, there is no N sealing engagement between the seal element (72) and the nose cone However, when the vacuum cleaner is switched on the pressure differential between the underpressure created in the region (112) of the nose cone and the ambient pressure in the region (114) causes the third resilient axialiy extending portion (116) to move outwardly into the position showed in Figure 12 in dotted lines and into a sealing engagement with the internal surface of the wall of the nose cone Thus, when the vacuum is in use a seal is provided between the dual filter system (34) and the nose cone to ensure that all the airflow through the nose cone passes through the dual filter system. However, when the vacuum cleaner is not in use the lack of engagement between the seal element (72) and the nose cone can help to prevent wear of the portion (116) of the seal element due to the repeated removal and replacement of the nose cone during the lifetime of the vacuum cleaner.
Throughout this specification and the claims which follow, unless the context requires otherwise, the word "comprise", and variations such as "comprises" and "comprising", will be understood to imply the inclusion of a stated integer or step or group of integers or steps but not the exclusion of any other integer or step or group of integers or steps.
The reference to any prior art in this specification is not, and should not be taken as, an acknowledgment or any form of suggestion that that prior art forms part of the common general knowledge in Australia.

Claims (21)

1. A filter arrangement for a vacuum cleaner for filtering particles of dust and debris from an airflow passing through the vacuum cleaner in which the filter arrangement has a first, coarse, filter to pre-filter the air flow and a second, fine, filter, a peripheral rim via which it is fitted to a first housing part of a vacuum cleaner, and an annular seal element made of a resilient material surrounding said rim, the seal element including a portion for forming a seal with the first housing part and a portion for forming a seal between the coarse and fine filters.
2. A filter arrangement according to claim 1, wherein the portion of the seal element for forming a seal with the first housing part is a first rearwardly extending resilient portion which extends around the periphery of the rim towards the first housing part to form a seal therewith when the filter arrangement is fitted to the vacuum cleaner.
3. A filter arrangement according to claim 1 or 2, wherein the seal element includes a substantially radially outwardly extending resilient portion which extends around the periphery of the rim to engage a second housing part of the vacuum cleaner to form a seal therewith when the filter arrangement is fitted to the vacuum cleaner.
4. A filter arrangement according to claim 3, wherein a radially inwardly extending wall is provided on the second housing part of the vacuum cleaner and a front facing surface of the radially outwardly extending resilient portion engages a rearwardly facing surface of said wall to form a seal therebetween.
A filter arrangement according to claim 4, wherein in use of the vacuum cleaner the seal between the radially outwardly extending resilient portion and the radially inwardly extending wall is reinforced by a pressure differential generated by an underpressure located in front of the filter arrangement.
6. A filter arrangement according to claim 1 or 2, wherein the seal element includes a P\OPER\RSHI12529380- Ipa do-O 1V06A Ssubstantially radially outwardly extending resilient portion which extends around the periphery of the rim for co-operation with a second housing part of the vacuum cleaner, wherein the periphery of the radially outwardly extending resilient portion is arranged such N, that it does not engage the second housing part of the vacuum cleaner when the vacuum C* 5 cleaner is not in use but when the vacuum cleaner is in use a pressure differential generated by an underpressure located in front of the filter arrangement urges the periphery of the radially outwardly extending resilient portion into engagement with the second housing Spart to form a seal therebetween.
7. A filter arrangement according to any one of claims 3 to 6, wherein said second housing part includes the wall of a removable nose cone of the vacuum cleaner through which dust and debris are sucked into the vacuum cleaner.
8. A filter arrangement according to any one of claims 1 to 7, wherein the seal element is made of rubber or an elastomer material and is moulded around the peripheral rim.
9. A filter arrangement according to any one of claims 1 to 8, wherein the peripheral rim is part of the coarse filter and the seal element is mounted on the peripheral rim.
A filter arrangement according to claim 9, wherein the fine filter also includes a peripheral rim via which it is fitted to the first housing part.
11. A filter arrangement according to claim 10, wherein the rim of the fine filter lies adjacent the rim of the coarse filter.
12. A filter arrangement according to claim 2 and claim 11, wherein the portion of the seal element for forming a seal between the coarse and fine filters is a second rearwardly extending resilient portion.
13. A filter arrangement according to claim 12, wherein the second rearwardly P OPERRS 2529380-1.p. doc-OlAY6A6 -21 extending resilient portion lies inwardly of the first rearwardly extending resilient portion with respect to the periphery of the rim.
14. A filter arrangement as claimed in any one of claims 1 to 13, wherein the filter can be releasably latched to a housing portion of a vacuum cleaner by a latching arrangement against a biasing force generated by the seal element.
A filter arrangement according to claim 14, wherein at least one cam surface is located between co-operating latching parts of the latching arrangement, such that the movement of at least one of the latching parts over the cam surface during the latching or unlatching movement causes the seal element to be compressed beyond the degree of compression of the seal element when the filter is latched to the first housing portion.
16. A filter arrangement according to claim 14 or claim 15, wherein at least one keyhole shaped aperture is provided in the filter through which can be releasably latched a co-operating latch element which extends from the first housing portion, said latch element including a peg with an enlarged head which can fit within the widened portion of the aperture and a stem which can fit within the narrow portion of the aperture.
17. A filter arrangement according to claim 16 when appended to claim 15, wherein the cam surface surrounds the aperture and includes at least one ridge over which the co- operating latch element must ride when moving into or out of the latched position.
18. A vacuum cleaner including a filter arrangement according to any one of the preceding claims.
19. A battery powered hand held vacuum cleaner according to claim 18 including a first housing portion which houses a battery pack, a motor and a fan and a second housing portion which includes a nose cone, wherein the battery pack powers the motor which rotatingly drives the fan to generate an airflow which enters the vacuum cleaner through the nose cone and passes through the dual filter arrangement into the fan.
P \OPERRSHM12529380 spa I doc I)6A6 -22- A filter arrangement, substantially as hereinbefore described with reference to the accompanying drawings.
21. A vacuum cleaner, substantially as hereinbefore described with reference to the accompanying drawings. DATED this 1st day of June 2006 Black Decker Incorporated by their Patent Attorneys DAVIES COLLISON CAVE
AU2004224922A 1999-07-17 2004-10-28 Improvements in vacuum cleaners Ceased AU2004224922B2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
AU2004224922A AU2004224922B2 (en) 1999-07-17 2004-10-28 Improvements in vacuum cleaners

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
GB9916759 1999-07-17
AU2003231582A AU2003231582B2 (en) 1999-07-17 2003-07-31 Improvements in vacuum cleaners
AU2004224922A AU2004224922B2 (en) 1999-07-17 2004-10-28 Improvements in vacuum cleaners

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AU2003231582A Division AU2003231582B2 (en) 1999-07-17 2003-07-31 Improvements in vacuum cleaners

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AU2004224922B2 true AU2004224922B2 (en) 2006-06-29

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Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4920608A (en) * 1988-08-08 1990-05-01 Emerson Electric Co. Portable hand held vacuum cleaner
US4928347A (en) * 1989-01-09 1990-05-29 Black & Decker Inc. Vacuum cleaner dust bowl latch and release system
US4967443A (en) * 1989-01-09 1990-11-06 Black & Decker, Inc. Filter assembly for a vacuum cleaner

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4920608A (en) * 1988-08-08 1990-05-01 Emerson Electric Co. Portable hand held vacuum cleaner
US4928347A (en) * 1989-01-09 1990-05-29 Black & Decker Inc. Vacuum cleaner dust bowl latch and release system
US4967443A (en) * 1989-01-09 1990-11-06 Black & Decker, Inc. Filter assembly for a vacuum cleaner

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