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EP 0 683 639 B1 |
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EUROPEAN PATENT SPECIFICATION |
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Mention of the grant of the patent: |
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31.05.2000 Bulletin 2000/22 |
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Date of filing: 08.02.1994 |
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International Patent Classification (IPC)7: A47L 9/00 |
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International application number: |
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PCT/US9401/190 |
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International publication number: |
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WO 9417/719 (18.08.1994 Gazette 1994/19) |
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ULTRA QUIET VACUUM CLEANER
ULTRA-LÄRMARMER STAUBSAUGER
ASPIRATEUR ULTRA SILENCIEUX
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Designated Contracting States: |
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DE FR GB IT SE |
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Priority: |
09.02.1993 US 15100
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Date of publication of application: |
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29.11.1995 Bulletin 1995/48 |
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Proprietor: NCT Group, Inc. |
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Linthicum, MD 21090-1206 (US) |
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Inventors: |
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- SMITH, Dexter, G.
Columbia, MD 21044 (US)
- NOWICKI, Christopher, P.
Bowie, MD 21042 (US)
- ARNOLD, Michael, F.
Westminster, MD 21158 (US)
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Representative: Nash, Keith Wilfrid et al |
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KEITH W. NASH & Co.,
90-92 Regent Street Cambridge CB2 1DP Cambridge CB2 1DP (GB) |
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References cited: :
JP-A- 4 187 131 JP-A- 5 003 843 US-A- 4 878 188 US-A- 5 105 377
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JP-A- 5 003 841 JP-A- 5 007 536 US-A- 5 091 953
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| Note: Within nine months from the publication of the mention of the grant of the European
patent, any person may give notice to the European Patent Office of opposition to
the European patent
granted. Notice of opposition shall be filed in a written reasoned statement. It shall
not be deemed to
have been filed until the opposition fee has been paid. (Art. 99(1) European Patent
Convention).
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[0001] The term vacuum cleaner can encompass a wide variety of appliances that use negative
pressure to collect various solids and even liquids into a collection area for disposal.
This invention relates to vacuum cleaners of all sizes that need to reduce broad band
noise, with or without tonal components present.
[0002] The heart of any vacuum cleaner is the motor/blower unit. This is typically a universal
motor with one or more stages of fan blades attached. A typical household unit might
be a two horsepower motor with a two stage backward curved fan system. One fan might
have 6 blades and the other 7.
[0003] On the inlet side of the motor/blower is the bag cavity area. Here, the negative
pressure developed by the motor/blower is transferred to the hose and nozzle by the
bag volume. There may be one or more filters in addition to the bag to keep dust and
large particles from damaging the motor/blower.
[0004] The outlet of the motor/blower is exhausted to the environment usually through some
type of dust filter.
[0005] Previous vacuum designs had size, weight, and performance, but seldom noise, as the
primary concerns. Designing a vacuum cleaner solely from a noise point of view clearly
separates the noise sources. These sources can be attacked with the most cost effective
means, either using active, passive or a combination of the two.
[0006] The following patents describe the active noise control system used: U.S. Patent
No. 5,091,953 to Tretter, U.S. Patent No. 5,105,377 to Ziegler and U.S. Patent No.
4,878,188 to Zeigler. This invention incorporates several of the techniques and apparatus
described to actively cancel noise produced by the vacuum.
[0007] Also known from the prior art are vacuum cleaners having active noise compensation
in accordance with Japanese Patent Specifications No. 5-3841, 5-3843 and 5-7536, which
form the basis of the preamble of claim 1. All these vacuum cleaners have an exhaust
passage from the motor/blower which has a wrapped configuration.
[0008] In summary, the vacuum cleaner designed following the teachings of the present invention,
using passive and active noise control methods, has resulted in a vacuum cleaner with
superior acoustic performance and comparable hydraulic performance to similar units.
Random broad band noise and tonal noise can be reduced depending on the exact configuration
of the vacuum cleaner.
[0009] The noise sources in the vacuum cleaner are as follows:
1. Nozzle
2. Hose
3. Bag Cavity
4. Coupling
5. Motor/Blower
6. Exhaust Area
[0010] The nozzle and hose will not be addressed in the present invention. After the other
noise sources are reduced, the nozzle and hose are the major noise sources in the
vacuum. Further reductions in noise level will result by redesigning these two components.
Currently, this vacuum design is 10 dBA quieter than similar production vacuums on
the market today (Figure 1a). Figure 1b is the active reduction of 8 dBA.
[0011] An object of the present invention is to provide acoustic design and isolation techniques
on the bag cavity, motor/blower area and coupling on a vacuum cleaner to produce cost
effective active noise control thereto.
[0012] According to the invention, there is provided a vacuum cleaner system adapted for
quiet operation, said system comprising
an inlet means adapted to allow for the intake of solids and liquids, and including
a cavity area (20) which is acoustically designed to produce the lowest pressure drop,
the cross-sectional area of the inlet means being adapted to impede the transfer of
acoustic energy to the cavity,
a motor/blower means (21) associated with said inlet means and adapted to provide
negative pressure at said inlet means to facilitate the intake of said solids and
liquids,
collection means associated with said inlet means so as to collect solids and liquids
that are drawn into said inlet means by said negative pressure,
exhaust duct means (25) which conducts cooling air used to cool said motor/blower
means (21) out of said system, and
active noise control means associated with said system to measure the noise generated
by said system and to produce an equal counter noise so as to reduce the system generated
noise.
[0013] These and other objects of the invention will become apparent when reference is had
to the accompanying drawings in which:
Figures 1a and 1b are graphs showing the noise reduction the invention provides, passive
and active respectively, versus a standard vacuum cleaner.
Figure 2 is an elevation view of a vacuum cleaner showing major active noise control
components.
Figure 3 is a plan view of the vacuum cleaner of Figure 2, and
Figure 4 is a schematic view of the active noise cancellation system of this invention.
[0014] Referring to Figures 2 and 3 the bag cavity 20 area is essentially an acoustically
designed muffler. A muffler can be described as a section of duct or pipe shaped to
reduce the transmission of sound while allowing the free flow of air. The vacuum inlet
muffler must meet acoustical, aerodynamic, geometrical and mechanical criteria. The
acoustic criteria specifies the amount of noise reduction required from the muffler
as a function of frequency. Aerodynamically, the muffler should produce the minimum
pressure drop so that the smallest rated motor/blower unit can be used. As will be
mentioned later, using a smaller rated motor/blower unit 21 will result in quieter
noise levels.
[0015] The muffler should also possess the smallest practical dimensions. Since muffler
acoustic characteristics are highly dependent on geometry, there will be a tradeoff
between muffler performance and geometry. The muffler must be mechanically sound as
well, meaning that it must have enough structural rigidity so the wall will not collapse
due to the negative pressure in the bag cavity area. In addition, acoustic foam used
to line the surface of the muffler must have a cleanable, puncture resistant surface
in case the bag breaks.
[0016] The muffler is basically a combination reactive/dissipative type muffler. The geometry
of the muffler determines the acoustical performance of the reactive portion of the
muffler. In principle, the acoustic energy travelling through the pipe is reflected
back towards the source because of the impedance mismatch created by a change in cross-sectional
area. The acoustic performance of the dissipative portion of the muffler is determined
by the absorption properties of the acoustic material used to line the inside of the
muffler.
[0017] The coupling 22 between the bag cavity 20 and motor chamber 23 is a flexible rubber
tube. This tube helps quiet the vacuum in two ways. First, the tube provides a smooth
flow path for the air that minimises the noise produced by turbulence and separation.
It is important that air flow coming into the entrance of the blower (fan) be as uniform
as possible in order to keep fan noise to a minimum and fan efficiency at a maximum.
Secondly, the flexible coupling 22 reduces the transmission of structural vibrations
from the motor chamber to the bag cavity (muffler) walls. This is achieved through
the large impedance difference between the motor chamber structure and the flexible
coupling 22. Because the coupling is lower in impedance, it reflects the structural
vibration wave back towards the source. Obviously, the greater the impedance mismatch,
the greater the attenuation of structure borne noise will be. However, the hose must
be rigid enough to withstand the negative pressure created by the vacuum motor 21.
[0018] The motor chamber 23 is the most important part of the vacuum acoustic design because
it houses the primary noise source of the vacuum, the motor/blower unit 21. This motor
chamber isolates the motor from the rest of the vacuum both acoustically and structurally
by incorporating a sealed chamber design. It is important that all transmission paths
be treated with some noise reduction method or else a sound "short" will exist allowing
the acoustic or vibration energy to escape to the surrounding medium. The only openings
are for the flow of air at the inlet coupling and the exhaust duct. In essence, these
represent acoustic sound shorts but they have been minimised by this design. On the
inlet side, the use of a flexible coupling and cross-sectional area change impede
the transfer of the acoustic energy to the bag cavity 20. In the exhaust duct, the
use of passive materials and active noise cancellation reduce motor noise significantly.
[0019] Motor/blower noise is comprised of both discrete frequency and broad band noise.
Discrete frequency signals are produced by the electrical line frequency and its harmonics,
the fundamental shaft frequency and harmonics, and the blade passing frequency of
the fan(s) and harmonics. Broad band noise is produced by turbulent air flow over
the motor cage and other surrounding discontinuities. The nature of the noise will
dictate the noise control method to be used for the motor/blower chamber. High frequency
noise, typically above 2000 Hz, can be attenuated using simplistic passive noise control
methods. Acoustic foam is used to absorb the acoustic energy and convert into mechanical
energy (i.e. heat) for the high frequency noise attenuation. This method is effective
because the wavelengths of the sound are short in this frequency region allowing them
to penetrate the material. However, low frequency noise must be attenuated using a
more complex method because the longer wavelengths tend to pass through the material.
The use of massive and/or thick material will stop the transmission of the longer
wavelengths. Thus, the material chosen for the motor chamber is a decoupled absorber/barrier.
The barrier is massive enough to reduce low frequency noise while the absorber reduces
the high frequency.
[0020] Air used to cool the motor is vented through a substantially straight exhaust duct
25. The exhaust is vented out the back away from the operator to minimise the noise
the operator hears. The duct 25 is attached to the motor chamber 23 and extends beyond
it to the back of the cleaner. It therefore has a length relatively short when compared
to the overall length of the system, and as compared to a wrapped duct. This design
purposely forces motor noise into the duct because this vacuum, unlike any existing
vacuum design, utilises active noise cancellation to cancel the low frequency noise
that is not addressed by passive noise control measures. The duct 25 is a primary
source of noise because of the turbulent flow in the duct and discrete frequency motor
noise. As previously discussed in the design of the motor chamber, passive noise control
works for the high frequency. In this case, acoustic foam lines the ductwork to attenuate
the high frequency. For low frequency control, active noise cancellation is employed
for the first time on a vacuum. Active noise control is necessary for the low frequency
because passive noise control methods would require very thick and massive materials
that would cause the vacuum to be bigger and heavier than necessary.
[0021] Microphones 28, 29 are placed along the straight exhaust duct and act as an upstream
noise and a downstream residual error sensor, respectively, to sense noise to be cancelled
and to provide feedback. The active cancelling noise is introduced via speaker 27
to counter the existing noise in the duct and is run by controller 26. Take up reel
24 is located between the speaker and the motor chamber. Controller 26 houses the
power supply and processor having the cancellation algorithm.
1. A vacuum cleaner system adapted for quiet operation, said system comprising
an inlet means adapted to allow for the intake of solids and liquids, and including
a cavity area (20) which is acoustically designed to produce the lowest pressure drop,
the cross-sectional area of the inlet means being adapted to impede the transfer of
the acoustic energy to the cavity,
a motor/blower means (21) associated with said inlet means and adapted to provide
negative pressure at said inlet means to facilitate the intake of said solids and
liquids,
collection means associated with said inlet means so as to collect solids and liquids
that are drawn into said inlet means by said negative pressure,
exhaust duct means (25) which conducts cooling air used to cool said motor/blower
means (21) out of said system, and
active noise control means associated with said system to measure the noise generated
by said system and to produce an equal counter noise so as to reduce the system generated
noise.
2. A vacuum cleaner system according to claim 1, characterised in that the active noise
control means includes sensing means (28, 29) in the path of air passing through said
exhaust duct means (25) to sense the noise.
3. A vacuum cleaner system according to claim 2, characterised in that the microphone
means comprise an upstream noise sensor (28) and a downstream residual error sensor
(29) in a straight region of the exhaust means.
4. A vacuum cleaner system as claimed in claim 1 or claim 2 or claim 3, characterised
in that said motor/blower means is housed in a sealed chamber means (23) which is
adapted to isolate the motor from the remainder of the vacuum system both acoustically
and structurally.
5. A vacuum cleaner system as claimed in claim 4, characterised in that said chamber
means (23) has an air inlet and an exhaust outlet, and in that said chamber air inlet
is connected to said cavity means by a flexible tube coupling (22) to provide for
a smooth flow to minimise noise produced by turbulence and separation and to reduce
structural vibrations.
6. A vacuum cleaner system as claimed in claim 5, characterised in that the relative
cross sections of said chamber means (23) and said flexible coupling (22) create a
substantial acoustic impedance difference.
7. A vacuum cleaner system as claimed in claim 5 or claim 6, characterised in that said
chamber means (23) is constructed as a decoupled absorber/barrier which allows for
reduction of low frequency noise while absorbing high frequency noise.
8. A vacuum cleaner system according to any of claims 1 to 7, characterised in that the
loudspeaker (27) producing the counter noise is located in the exhaust means (25).
9. A vacuum cleaner system according to claim 8, characterised in that the loudspeaker
(27) is positioned adjacent the exit of the exhaust means (25).
1. Staubsaugersystem für geräuscharmen Betrieb, gekennzeichnet durch
eine Einlass-Vorrichtung, die das Aufnehmen von Feststoffen und Flüssigkeiten ermöglicht
und einen Hohlraumbereich (20) aufweist, der akustisch so konstruiert ist, dass er
einen möglichst geringen Druckabfall ergibt, wobei die Querschnittsfläche der Einlass-Vorrichtung
in der Lage ist, die Übertragung der akustischen Energie in den Hohlraum zu unterdrücken,
eine Motor-Gebläsevorrichtung (21), die der Einlass-Vorrichtung zugeordnet und in
der Lage ist, einen negativen Druck an der Einlass-Vorrichtung zu erzeugen, um das
Einbringen der Feststoffe und Flüssigkeiten zu erleichtern,
eine Sammelvorrichtung, die der Einlass-Vorrichtung so zugeordnet ist, dass sie Feststoffe
und Flüssigkeiten sammelt, die in die Einlass-Vorrichtung durch den negativen Druck
eingesaugt werden,
eine Auslaßleitung (25), die Kühlluft führt, welche zum Kühlen der Motor/Gebläse-Vorrichtung
(21) aus dem System dient, und
eine aktive Geräusch-Steuervorrichtung, die dem System zugeordnet ist, um das Geräusch
zu messen, das von dem System erzeugt wird, und um ein gleichgroßes Gegengeräusch
zu erzeugen, damit das vom System erzeugte Geräusch reduziert wird.
2. Staubsaugersystem nach Anspruch 1, dadurch gekennzeichnet, dass die aktive Geräusch-Steuervorrichtung
eine Abfühlvorrichtung (28, 29) im durch die Auslass-Leitung (25) strömenden Luftpfad
zum Feststellen des Geräusches aufweist.
3. Staubsauger nach Anspruch 2, dadurch gekennzeichnet, dass die Mikrophon-Vorrichtung
einen Sensor (28) für das stromaufwärts auftretende Geräusch und einen Sensor (29)
für den stromabwärts auftretenden Restfehler in einem geradlinigen Bereich der Auslass-Vorrichtung
aufweist.
4. Staubsaugersystem nach Anspruch 1, 2 oder 3, dadurch gekennzeichnet, dass die Kombination
aus Motor und Gebläse in einer abgedichteten Kammer (23) aufgenommen ist, die den
Motor gegenüber dem übrigen Teil des Vakuumsystems sowohl akustisch als auch baulich
isoliert.
5. Staubsaugersystem nach Anspruch 4, dadurch gekennzeichnet, dass die Kammer (23) einen
Lufteinlass und einen Abluft-Auslass aufweist und dass der Kammer-Lufteinlass mit
der Hohlraumvorrichtung durch eine flexible Rohrkupplung (22) verbunden ist, um einen
ungestörten Fluss zu erzielen, damit das durch Turbulenzen und Ablösen erzeugte Geräusch
ein Minimum wird und bauliche Vibrationen reduziert werden.
6. Staubsaugersystem nach Anspruch 5, dadurch gekennzeichnet, dass die relativen Querschnitte
der Kammer (23) und der flexiblen Rohrkupplung (22) eine erhebliche akustische Impedanz-Differenz
erzeugen.
7. Staubsaugersystem nach Anspruch 5 oder 6, dadurch gekennzeichnet, dass die Kammer
(23) als eine entkoppelte Absorber/Barriere-Vorrichtung konstruiert ist, die eine
Reduzierung von Geräusch niedriger Frequenz ermöglicht, während Geräusch hoher Frequenz
absorbiert wird.
8. Staubsaugersystem nach einem der Ansprüche 1 - 7, dadurch gekennzeichnet, dass der
das Gegengeräusch erzeugende Lautsprecher in der Auslass-Vorrichtung (25) angeordnet
ist.
9. Staubsaugersystem nach Anspruch 8, dadurch gekennzeichnet, dass der Lautsprecher (27)
in der Nähe des Ausgangs der Auslass-Vorrichtung (25) angeordnet ist.
1. Système d'aspirateur apte à fonctionner silencieusement, ledit système comprenant
un moyen d'entrée apte à permettre l'aspiration de solides et de liquides, et comportant
une zone de cavité (20) conçue, d'un point de vue acoustique, pour produire une perte
de charge minimale, la section transversale du moyen d'entrée étant apte à empêcher
le transfert de l'énergie acoustique vers la cavité,
un moyen formant moteur/ventilateur (21) associé audit moyen d'entrée et apte à créer
une pression négative au niveau dudit moyen d'entrée pour permettre l'aspiration desdits
solides et liquides,
un moyen de collectage associé audit moyen d'entrée afin de collecter des solides
et des liquides qui sont entraînés jusque dans ledit moyen d'entrée par ladite pression
négative,
un moyen formant conduit d'échappement (25) qui conduit de l'air de refroidissement
servant à refroidir ledit moyen formant moteur/ventilateur (21) à l'extérieur dudit
système, et
un moyen d'insonorisation active associé audit système pour mesurer le bruit généré
par ledit système et pour produire un bruit antagoniste égal afin de réduire le bruit
généré par le système.
2. Système d'aspirateur selon la revendication 1, caractérisé en ce que le moyen d'insonorisation
active comporte un moyen de détection (28, 29) sur le trajet de l'air passant par
ledit moyen formant conduit d'échappement (25) afin de détecter le bruit.
3. Système d'aspirateur selon la revendication 2, caractérisé en ce que des moyens formant
microphones comprennent un détecteur amont (28) de bruit et un détecteur aval (29)
d'erreur résiduelle dans une région rectiligne du moyen d'échappement.
4. Système d'aspirateur selon la revendication 1 ou la revendication 2 ou la revendication
3, caractérisé en ce que ledit moyen formant moteur/ventilateur est logé dans un moyen
formant chambre hermétique (23) apte à isoler le moteur du reste du système d'aspirateur
du point de vue de l'acoustique et de la structure.
5. Système d'aspirateur selon la revendication 4, caractérisé en ce que ledit moyen formant
chambre (23) a une entrée d'air et une sortie d'échappement, et en ce que ladite entrée
d'air de la chambre est reliée audit moyen formant cavité par un raccord tubulaire
flexible (22) pour assurer un écoulement régulier afin de limiter le bruit produit
par turbulence et séparation et de réduire les vibrations de la structure.
6. Système d'aspirateur selon la revendication 5, caractérisé en ce que les sections
transversales relatives dudit moyen formant chambre (23) et dudit raccord flexible
(22) créent une différence notable d'impédance acoustique.
7. Système d'aspirateur selon la revendication 5 ou la revendication 6, caractérisé en
ce que ledit moyen formant chambre (23) est construit sous la forme d'un absorbeur/écran
découplé qui permet de réduire le bruit à fréquence basse tout en absorbant le bruit
à fréquence élevée.
8. Système d'aspirateur selon l'une quelconque des revendications 1 à 7, caractérisé
en ce que le haut-parleur (27) produisant le bruit antagoniste se trouve dans le moyen
d'échappement (25).
9. Système d'aspirateur selon la revendication 8, caractérisé en ce que le hautparleur
(27) est placé au voisinage de la sortie du moyen d'échappement (25).