EP2926706A1 - Device for vacuum cleaning - Google Patents

Abstract

The invention relates to a device for vacuuming with a vacuum cleaner, a vacuum hose connected to the housing of the vacuum cleaner and a filter bag, the boiler vacuum cleaner having a motor-blower unit which is designed such that its average electrical power consumption is between 1000 W and 200 W, and at a mean electrical input power between 1000 W and 800 W, a negative pressure in the measuring chamber at orifice 6 of greater than 12.5 kPa and a negative pressure in the measuring chamber at orifice 8 of greater than 4.0 kPa results, 799 W and 600 W. a negative pressure in the measuring chamber at orifice 6 of greater than 10.0 kPa and a negative pressure in the measuring chamber at orifice 8 greater than 3.4 kPa results, 599 W and 400 W, a negative pressure in the measuring chamber at orifice 6 of greater than 7 , 0 kPa and a negative pressure in the measuring chamber at aperture 8 of greater than 2.5 kPa results, 399 W and 200 W, a negative pressure in the measuring chamber at aperture 6 of gr SSER than 4.0 kPa and a negative pressure in the measuring chamber with diaphragm 8 resulting from greater than 1.4 kPa, and wherein the suction tube has an average cross-sectional area of at least 9.5 cm ^2, in particular at least 11 cm ² or 13 cm ^2, , and the filter bag is made of nonwoven fabric.

Description

FIELD OF THE INVENTION

The invention relates to a device for vacuuming comprising a vacuum cleaner with a suction hose connected to the housing of the vacuum cleaner, and comprising a filter bag, in particular a disposable filter bag made of nonwoven fabric.

DEFINITIONS

• VO 666/2013: VERORDNUNG (EU) Nr. 666/2013 DER KOMMISSION vom 8. Juli 2013 zur Durchführung der Richtlinie 2009/125/EG des Europäischen Parlaments und des Rates im Hinblick auf die Festlegung von Anforderungen an die umweltgerechte Gestaltung von Staubsaugern.
• VO 665/2013: DELEGIERTE VERORDNUNG (EU) Nr. 665/2013 DER KOMMISSION vom 3. Mai 2013 zur Ergänzung der Richtlinie 2010/30/EU des Europäischen Parlaments und des Rates im Hinblick auf die Energieverbrauchskennzeichnung von Staubsaugern.
• Nennleistungsaufnahme: Die Nennleistungsaufnahme in W bezeichnet die vom Hersteller angegebene elektrische Aufnahmeleistung, wobei bei Geräten, die neben der Staubsaugerfunktion auch andere Funktionen aufweisen, nur die elektrische Leistungsaufnahme bei Nutzung als Staubsauger relevant ist (VO 666/2013, Anhang II, Abs. 2, lit. k).
• EN 60312: EN 60312 bezeichnet - soweit nicht ausdrücklich anders angegeben - die Norm DIN EN 60312-1 (VDE 0705-312-1) in der Ausgabe von Januar 2014: Staubsauger für den Hausgebrauch - Teil 1: Trockensauger - Prüfverfahren zur Bestimmung der Gebrauchseigenschaften (IEC 60312-1: 2010, modifiziert + A1:2011, modifiziert); Deutsche Fassung EN 60312-1:2013.
• Bestimmung der Luftdaten: Die Luftdaten eines Staubsaugers werden gemäß EN 60312 Abschnitt 5.8 bestimmt. Dabei wird die Messeinrichtung B gemäß Abschnitt 7.3.7.3 verwendet. Falls Motor-Gebläseeinheiten solo, also ohne Staubsaugergehäuse, gemessen werden, wird ebenfalls die Messeinrichtung B verwendet. Für gegebenenfalls notwendige Zwischenstücke zum Anschluss an die Messkammer gelten die Ausführungen in Kapitel 7.3.7.1.
• Leistungsaufnahme eines Staubsaugers: Die Leistungsaufnahme P₁ eines Staubsaugers bei einer vorgegebenen Blende wird gemäß EN 60312 Abschnitt 5.8 bestimmt. Dabei wird die Messeinrichtung B gemäß Abschnitt 7.3.7.3 verwendet. Für gegebenenfalls notwendige Zwischenstücke zum Anschluss an die Messkammer gelten die Ausführungen in Kapitel 7.3.7.1.
• Leistungsaufnahme einer Motor-Gebläseeinheit: Die Leistungsaufnahme P₁ einer Motor-Gebläseeinheit bei einer vorgegebenen Blende wird ebenfalls gemäß EN 60312 Abschnitt 5.8 bestimmt. Dabei wird die Messeinrichtung B gemäß Abschnitt 7.3.7.3 verwendet. Für gegebenenfalls notwendige Zwischenstücke zum Anschluss an die Messkammer gelten die Ausführungen in Kapitel 7.3.7.1.
• Mittlere elektrische Aufnahmeleistung eines Staubsaugers: Die mittlere Aufnahmeleistung eines Staubsaugers wird mit dem Versuchsaufbau zur Bestimmung der Luftdaten gemäß EN 60312 Kapitel 5.8 durchgeführt. Es wird die Messkammer Ausführung B verwendet. Für gegebenenfalls notwendige Zwischenstücke zum Anschluss an die Messkammer gelten die Ausführungen in Kapitel 7.3.7.1. Die mittlere Aufnahmeleistung wird definiert als $$\mathrm{P}=\mathrm{0},\mathrm{5}\left({\mathrm{P}}_{\mathrm{f}}+{\mathrm{P}}_{\mathrm{i}}\right)$$
  
  • P_f = Leistungsaufnahme in Watt nach 3 Minuten Betrieb auf der Messkammer bei Blende 9 (Nenndurchmesser d₀ = 50 mm)
  • P_i = Leistungsaufnahme in Watt nach weiteren 20s Betrieb auf der Messkammer bei Blende 0 (Nenndurchmesser d₀ = 0 mm).

The following standards, definitions and measuring methods are used to describe the state of the art and the invention:

• Regulation 666/2013: Commission Regulation (EU) No 666/2013 of 8 July 2013 implementing Directive 2009/125 / EC of the European Parliament and of the Council with regard to ecodesign requirements for vacuum cleaners.
• Regulation 665/2013: Commission Delegated Regulation (EU) No 665/2013 of 3 May 2013 supplementing Directive 2010/30 / EU of the European Parliament and of the Council with regard to energy labeling of vacuum cleaners.
• Nominal power consumption: The rated power consumption in W denotes the electrical input power specified by the manufacturer, with devices having other functions in addition to the vacuum cleaner function, only the electrical power consumption when used as a vacuum cleaner is relevant (VO 666/2013, Annex II, para. 2, letter k).
• EN 60312: EN 60312 designates - unless otherwise stated - the standard DIN EN 60312-1 (VDE 0705-312-1) in the January 2014 edition: Domestic vacuum cleaners - Part 1: Dry vacuum cleaners - Test method for determining the performance characteristics (IEC 60312-1: 2010, modified + A1: 2011, modified); German version EN 60312-1: 2013.
• Determination of the air data: The air data of a vacuum cleaner are determined in accordance with EN 60312 section 5.8. The measuring device B is used in accordance with section 7.3.7.3. If motor-blower units are measured solo, ie without a vacuum cleaner housing, the measuring device B is also used. For any necessary intermediate pieces for connection to the measuring chamber, the explanations in chapter 7.3.7.1 apply.
• Power consumption of a vacuum cleaner: The power consumption P _{1 of} a vacuum cleaner at a given orifice is determined in accordance with EN 60312 section 5.8. The measuring device B is used in accordance with section 7.3.7.3. For any necessary intermediate pieces for connection to the measuring chamber, the explanations in chapter 7.3.7.1 apply.
• Power consumption of a motor-blower unit: The power consumption P _{1 of} a motor-blower unit at a given orifice is also determined in accordance with EN 60312 section 5.8. The measuring device B is used in accordance with section 7.3.7.3. For any necessary intermediate pieces for connection to the measuring chamber, the explanations in chapter 7.3.7.1 apply.
• Average electrical power consumption of a vacuum cleaner: The average power consumption of a vacuum cleaner is determined using the experimental setup for determining the air data in accordance with EN 60312, Chapter 5.8. The measuring chamber version B is used. For any necessary intermediate pieces for connection to the measuring chamber, the explanations in chapter 7.3.7.1 apply. The average recording power is defined as $$\mathrm{P}=\mathrm{0}.\mathrm{5}\left({\mathrm{P}}_{\mathrm{f}}+{\mathrm{P}}_{\mathrm{i}}\right)$$
  
  • P _f = power consumption in watts after 3 minutes of operation on the measuring chamber at aperture 9 (nominal diameter d ₀ = 50 mm)
  • P _i = power consumption in watts after another 20s operation on the measuring chamber at aperture 0 (nominal diameter d ₀ = 0 mm).

• P_f = Leistungsaufnahme in Watt nach 3 Minuten Betrieb auf der Messkammer bei Blende 9 (Nenndurchmesser d₀ = 50 mm)
• P_i = Leistungsaufnahme in Watt nach weiteren 20 s Betrieb auf der Messkammer bei Blende 0 (Nenndurchmesser d₀ = 0 mm).

Average electrical power consumption of the motor-blower unit: The average electrical power consumption of a motor-blower unit is carried out with the test set-up for determining the air data in accordance with EN 60312 chapter 5.8. For this, the motor-blower unit is connected directly to the measuring chamber (version B). For any necessary intermediate pieces for connection to the measuring chamber, the explanations in chapter 7.3.7.1 apply. The average recording power is defined as $${\mathrm{P}}_{\mathrm{m}}=\mathrm{0}.\mathrm{5}\left({\mathrm{P}}_{\mathrm{f}}+{\mathrm{P}}_{\mathrm{i}}\right)$$

• P _f = power consumption in watts after 3 minutes of operation on the measuring chamber at aperture 9 (nominal diameter d ₀ = 50 mm)
• P _i = power consumption in watts after another 20 s operation on the measuring chamber at aperture 0 (nominal diameter d ₀ = 0 mm).

Average power consumption when determining the functional properties of a filled dust container: The average power consumption for determining the functional properties of a filled dust container is determined on the basis of EN 60312. Deviating from this standard, the measurement is carried out with the measuring chamber B at aperture 8. The average power consumption in the determination of the functional properties with a filled filter bag is defined as the mean value of the power consumption when the filter bag is empty and the power consumption when the filter bag is filled. For the suction of the test dust and the maximum amount to be absorbed (filled filter bag), the conditions of chapter 5.9.2., Especially the conditions of 5.9.2.3 apply.

Air flow: The air flow is determined according to EN 60312 with the measuring chamber according to version B. The air flow can be determined at different apertures. In accordance with EN 60312, measurements are made with a 30 mm diameter orifice. If this is measured differently for another aperture, this is stated. In the prior art, this air flow is often referred to as volume flow or suction air flow.

Airflow drop : The airflow drop is determined according to EN 60312 chapter 5.9 with the measuring chamber according to design B. Notwithstanding this standard, the measuring chamber is equipped with a 40 mm perforated plate (according to standard 30 mm). The vacuum values h _f in the measuring chamber are converted into an air flow according to chapter 7.3.7. The difference between the air flow when the filter bag is empty and the air flow when the filter bag is loaded is called airflow waste.

Disposable filter bag : A disposable filter bag or disposable bag in the sense of the present invention is understood to mean a disposable filter bag.

Flat bags: Under a flat bag filter bags are understood, the filter bag wall of two individual layers of filter material with the same surface is formed such that the two Individual layers are connected to each other only at their peripheral edges (of course the term same area does not exclude that the two individual layers differ from each other in that one of the layers has an inlet opening).

The connection of the individual layers can be realized by one or more (for example four) welding or adhesive seams along the entire circumference of the two individual layers.

Alternatively, the filter bag can be formed by a single layer of filter material, in that it is folded around one of its symmetry axes and the remaining open peripheral edges of the resulting two partial layers are welded or glued (so-called tubular bag). In such a production therefore one circumferential or more (for example three) welding or gluing seams are necessary. Two of these seams then form the filter bag edge, the third seam can also form a filter bag edge or lie on the filter bag surface.

Each of the aforementioned single layers of filter material may comprise multiple layers of nonwoven fabric, as is common for nonwoven filter bags today.

The welded or adhesive seams can also be designed as a spiral fold.

Flat bags may also have so-called gussets. These gussets can be completely unfoldable. A flat bag with such gussets is for example in the DE 20 2005 000 917 U1 shown (see there Fig. 1 with folded gussets and Fig. 3 with unfolded gussets). Alternatively, the gussets may be welded to portions of the peripheral edge. Such a flat bag is in the DE 10 2008 006 769 A1 shown (see there in particular FIG. 1 ).

Filter bag with surface folds: EP 2 366 320 A1 and EP 2 366 321 A1 disclose filter bag with surface wrinkles in the context of the present application.

Suction power: Suction power is the product of negative pressure [kPa] and air flow [l / s] and is designated P ₂ according to EN 60312.

Efficiency: The efficiency of the motor-blower unit or a vacuum cleaner is calculated from the suction power P ₂ and the power consumption P ₁ according to EN 60312 chapter 5.8 (see in particular chapter 5.8.4., Paragraph 4). For this purpose, the motor-blower unit or the vacuum cleaner is connected to the measuring chamber (version B). For any necessary intermediate pieces for connection to the measuring chamber, the explanations in chapter 7.3.7.1 apply. The nominal diameters d _{0 of} the diaphragms used can be found in the table in Section 7.3.7.3. The efficiency for a given aperture is calculated according to $$\mathrm{\eta }\left[\%\right]=\left({\mathrm{<figure-callout\; id="2"\; label="P"\; filenames="imgf0001.png,imgf0012.png"\; state="\{\{state\}\}">P</figure-callout>}}_{\mathrm{2}}/{\mathrm{<figure-callout\; id="1"\; label="P"\; filenames="imgf0001.png,imgf0012.png"\; state="\{\{state\}\}">P</figure-callout>}}_{\mathrm{1}}\right)*\mathrm{100}$$

Here, P _{1 is} the power consumption of the vacuum cleaner (for a given aperture) and P _{2 is} the air power (for a given aperture), ie the product of airflow (see above) and negative pressure (see below).

Negative pressure in the measuring chamber at a given orifice: The negative pressure in the measuring chamber at a given orifice is in accordance with EN 60312, Chapter 5.8. For this, the motor-blower unit is connected directly to the measuring chamber (version B). For any necessary intermediate pieces for connection to the measuring chamber, the explanations in chapter 7.3.7.1 apply. The nominal diameters d _{0 of} the diaphragms used are given in section 7.3.7.3.

Average cross-sectional area of a suction hose: To determine the average cross-sectional area of a suction hose, the cross-section of the suction hose is measured at 10 points evenly distributed over the suction hose length and the mean of these measurements is determined. The first measurement is performed at one end of the tube and the tenth measurement at the other end of the tube. The measurement of the cross-section is determined by internal gauge gauges corresponding to the shape of the cross-sectional area to be measured. For hoses that change their cross-sectional area, the limit gauge is inserted into the suction hose in the direction of the increasing cross-sectional area. Apart from irregular cross-sectional areas, the cross-sectional areas of spiral-wound or helically wound or differently structured suction hoses can also be determined. This method can be used in particular in conical suction hoses.

Pouch area of a filter bag: The bag area of a bag designates the area that lies between the marginal welds that define the outer shape of the filter bag. Gussets and surface wrinkles must be taken into account for the calculation. The area of the filling opening including a surrounding this opening Weld is removed from the surface. It only means the theoretically usable area. Differences in the flow through the bag or due to incomplete unfolding of the filter bag are not taken into account. For filter bags that are not flat bags, of course, all additional areas (eg block bottom bag with side surfaces and face) are used to determine the bag area.

Volume Filter bag holding space : The volume can be determined from the 3D drawing data of the vacuum cleaner or determined by pouring water or granules.

Deflection device: deflection devices for deflecting air in the sense of the application are, for example, in WO 2007 059936 A1 . WO 2007 059937 A1 . WO 2007 059938 A1 and WO 2007 059939 A1 disclosed.

Spacer Device : By spacer device is meant a device which ensures that there is a gap between the filter bag and the wall of the filter bag receiving space. In particular, the spacer means may consist of a bottom and / or at least one side wall and / or a lid, so the filter bag so partially or completely surrounded. It is important to ensure that the contact surface between the filter bag and spacer device is minimized. The spacer device may be made of any materials and be removable or permanently installed. If filter bags with surface folds are used, then a spacer device can be used that is specially adapted to these surface folds. How such a spacer device is designed, the WO 2012 126612 (especially Figures 3 and 4 ).

Efficient vacuum cleaner: An efficient vacuum cleaner has an energy efficiency class of B or better (according to VO 665/2013, ANNEX I) and at the same time a cleaning class of C or better (according to VO 665/2013, APPENDIX I).

STATE OF THE ART

The demands placed on devices for vacuuming have undergone a significant change in recent years.

The VO 666/2013 requires the nominal power consumption of vacuum cleaners from 2017 to be limited to below 900 W. The VO 665/2013 means that in the longer term the annual energy consumption of a vacuum cleaner should be less than 10 kWh. This results in a rated power consumption of a vacuum cleaner of less than 300 W. The users of devices for vacuuming, however, expect that the cleaning performance compared to devices for vacuuming, as they are realized today with much higher recording power, not deteriorate. This is also taken into account by Regulation 665/2013, for example by Sets the requirement for an A rating (carpet cleaning class) for the dust absorption of carpet to ≥ 91%.

For example, the vacuum cleaner Miele S 8340, one of the vacuum cleaners that is considered to be particularly energy-efficient in the prior art, achieves air data (according to EN 60312 chapter 5.8.4) at aperture 8 (40 mm) and power consumption P ₁ of 1310 W (power level on the vacuum cleaner symbol "hard floor, heavily soiled carpets and carpets" in the following "max") a resulting suction air flow of 38.5 l / s. The resulting air flow at a power consumption P ₁ of 704 W (power level on the device symbol "high-quality velor carpets, bridges and runners", hereinafter referred to as "carpet") is insufficient for a satisfactory dust absorption. Thus, with a power consumption of 704 W (at aperture 8) only an air flow of 30.0 l / s is achieved.

The situation with respect to the air flow still deteriorates during the filling of the filter bag during use of the vacuum cleaner. FIG. 1a respectively. Figure 1 b show exemplarily the original accessories (suction hose and suction pipe) supplied by Miele for this vacuum cleaner and the original filter bags supplied by Miele at an average power consumption when determining the service characteristics when the dust container is filled with 698 W (carpet) or 1286 W (max) achieved air flow (flow rate in l / s) depending on the filling with up to a maximum of 400 g DMT dust type 8 according to EN 60312.

To ensure efficient suction, air flows of at least 33 l / s are desirable.

In the Miele S 8340, a motor-blower unit is used whose characteristics, ie their air data in FIG. 2a (Carpet) and FIG. 2b (max) are shown.

The mean electrical input power of the vacuum cleaner must be clearly differentiated from the mean electrical input power of the motor-blower unit, since the total mean electrical input power of the motor-blower unit is substantially converted into the air flow to be achieved, whereas the average electrical input power of the vacuum cleaner for compensation the flow losses that result from the flow paths in the vacuum cleaner (from the floor nozzle to the air outlet from the device - without motor-blower unit) is spent.

The average electrical input power of the motor-blower unit of the Miele S 8340 is 1121 W (max) or 622 W (carpet). With this average recording power, aperture 8 (this aperture corresponds approximately to the conditions that are present on hard floor) Air flow of about 55.5 l / s (max) and about 43.7 l / s (carpet), which when using this motor-blower unit in Miele S 8340 finally to the above already for aperture 8 specified air flows (then actually also available for vacuuming) of 38.5 l / s (max) and 29.9 l / s (carpet).

The suction hose of the Miele S 8340 has an average cross-sectional area of about 9.1 cm ² .

DESCRIPTION OF THE INVENTION

In view of the aforementioned disadvantages of the prior art, it is an object of the invention to provide a filter bag vacuuming apparatus which improves the efficiency of the prior art apparatus and in determining the air data according to EN 60312 (Chapter 5.8 .4) at aperture 8 (40 mm) a suction air flow of more than 33 l / s is achieved, so that a cleaning class of C according to VO 665/2013 or better can be achieved, and wherein the average electrical power consumption of the vacuum cleaner is as low as possible, so that an energy efficiency class of B according to VO 665/2013 or better is achieved, so an efficient vacuum cleaner in the sense of the present invention is realized.

This object is achieved by a device for vacuuming according to claim 1.

This comprises a vacuum cleaner with a suction hose connected to the housing of the vacuum cleaner and a filter bag, in particular a non-woven fabric disposable filter bag, the vacuum cleaner having a motor-blower unit with a mean electrical input power between 1000 W and 200 W. Here is the motor-blower unit designed such that at a mean electrical power input between 1000 W and 800 W, a negative pressure in the measuring chamber at aperture 6 (23 mm) greater than 12.5 kPa and a negative pressure in the measuring chamber at aperture 8 (40 mm) of greater than 4.0 kPa; between 799 W and 600 W a negative pressure in the measuring chamber at orifice 6 of greater than 10.0 kPa and a negative pressure in the measuring chamber at orifice 8 of greater than 3.4 kPa sets; between 599 W and 400 W, a negative pressure in the measuring chamber at orifice 6 of greater than 7.0 kPa and a negative pressure in the measuring chamber at orifice 8 of greater than 2.5 kPa; and between 399 W and 200 W, a negative pressure in the measuring chamber at orifice 6 of greater than 4.0 kPa and a negative pressure in the measuring chamber at orifice 8 of greater than 1.4 kPa sets.

This particular characteristic of the motor-blower unit differs from the characteristic usually in devices for vacuuming inserted motor-blower units.

The differences in the air data between the present invention and the prior art are disclosed in Figure 2a and 2b that show the state of the art, as well as in Figure 3a and 3b , which show an embodiment of the invention, illustrates. With the same recording power, the motor-blower unit with the characteristic according to the invention provides a significantly higher airflow at the diaphragms (D6 and D8) which are essential for the cleaning effect. D6 roughly corresponds to the situation when vacuuming carpets, D8 corresponds approximately to the situation when sucking on hard floor.

Surprisingly, it has been found that a motor-blower unit as specified above in combination with a suction hose with an average cross-sectional area of at least 9.5 cm ² can be used to increase efficiency for vacuum cleaners and together with the disposable filter bags made of nonwoven fabric in their cleaning effect with devices for Vacuuming are comparable, as they are available today only with much higher recording power.

Accordingly, the suction hose must have an average cross-sectional area of at least 9.5 cm ² , in particular at least 11 cm ² or most especially at least 13 cm ² . This cross-sectional area should not be significantly undercut for the pipe section, which establishes the connection between the suction hose and filter bag in the vacuum cleaner.

Experiments have shown that the combination of said motor-blower unit and said suction hose with an average power consumption in the determination of the performance characteristics with filled dust container of about 670 W, fully meet the future energy policy requirements, for the generation of an air flow of more than 41 l / s (with empty filter bag) and thus sufficient to achieve a more than satisfactory suction result.

The filter bag may preferably have a bag area of between 1000 cm ² and 4000 cm ² .

The suction hose may be at least partially tapered and have a larger cross-sectional area at an end proximate to the motor / blower unit than at an end remote from the motor / blower unit. In this case, the suction hose may have a minimum and a maximum cross-sectional area and the minimum diameter of the suction hose may be reduced by at least 5%, in particular at least by 20%, from the maximum diameter. For example, the smallest diameter of the conical suction hose may be 35 mm at the near end and 47 mm at the far end. Alternatively, the suction hose may have a cylindrical shape throughout. In addition to good handling, a conical shape of the suction hose can also increase the efficiency of the vacuum cleaner.

Incidentally, other cross-sectional shapes of the suction hose (conically tapered or with a constant cross-section) are possible as long as the claimed cross-sectional areas are maintained.

The suction hose can have a length of 1 m to 3 m.

A suction pipe connected to the suction hose may have a diameter of more than 30 mm, preferably more than 33 mm and particularly preferably more than 36 mm.

The motor-blower unit may have an efficiency according to EN 60312 of at least 35%, preferably of at least 38% and particularly preferably of at least 40%, at aperture 7 (30 mm). This development of the invention leads to particularly efficient devices for vacuuming.

According to a development of the invention described above, including the said developments of the invention, the vacuum cleaner has a spacer device.

This may in this case have a bottom and / or at least one side wall and / or a lid. Thus, the spacer means may partially enclose the filter bag, at least on one side of the filter bag, or fully circumferentially. As a result, the filter bag is at least partially spaced from at least one inner housing wall of the device for vacuuming. If the spacer device is to completely surround the filter bag, then it will have a bottom, a lid and a number of side walls corresponding to the filter bag receiving space.

Preferably, the spacer means is formed such that between the bottom and / or the at least one side wall and / or the cover overflow paths, i. Fluid connections are provided. As a result, the entire surface of the filter bag can be utilized to suck the air from the filter bag into the motor-blower unit.

Furthermore, the spacer device may be formed integrally with the filter bag receiving space of the vacuum cleaner. Alternatively, it may also be provided as a separate unit that can be completely removed from the filter bag receiving space.

By the above measures, (completely or partially) a reduction of the filter performance by contacting the filter surface on an inner wall of the filter bag accommodating space can be avoided.

According to a development of the device described above, in this, contrary to the direction of air flow can be arranged in the following order: an air intake opening in the at least one side wall or in the bottom or in the cover, through which during operation of the vacuum cleaner air from the filter bag receiving space in the engine / Blower unit is sucked, a motor protection filter holder, and the spacer means, wherein the spacer means is spaced from the motor protection filter holder.

This ensures that there is always a clearance between the engine guard filter holder and the filter bag, and that the filter bag does not cover the engine guard filter holder, which requires would lead to the air from the filter bag is only sucked out of the area of the filter bag, which covers the motor protection filter.

The spacer device may in this case be in the form of a perforated plate and / or in the form of a grid and / or in the form of webs, web-shaped sections, brackets, bow-shaped sections, ribs, rib-shaped sections and / or pins.

The motor protection filter holder may be formed in these developments so that a motor protection filter in the motor protection filter holder z. B. is inserted. In this case, the material of the motor protection filter can have a sufficient intrinsic strength in order, for example, to be inserted, or it can be provided with a frame or stabilizing element (eg, network). This makes it possible to change the motor protection filter in a particularly simple manner.

According to a development of all the devices described above, a filter bag holding plate receptacle can be provided, which is arranged hinged relative to the device for vacuuming or can be removed completely from the vacuum cleaner. This measure allows a particularly simple change of the vacuumed vacuum cleaner bag.

In all the embodiments described above, the filter bag may be provided in the form of a flat bag. The flat bag form is the most common form for nonwoven bags since bags of this shape are very easy to manufacture. In contrast to the paper filter material used in filter bags made of paper, nonwoven filter material is very difficult to permanently fold due to the high resilience, so that the production of more complex bag shapes, such as block bottom bags or other bottom bag shapes, while possible, but very expensive and expensive.

The filter bag may in particular have surface folds.

In addition, the filter bag may be provided with at least one deflection device. Accordingly, the abovementioned spacer device can then be designed to accommodate filter bags with surface folds.

The various developments can be used individually as claimed or combined with each other.

BRIEF DESCRIPTION OF THE FIGURES

Figuren 1a und 1 b

die Abhängigkeit des erreichten Luftstroms von der Befüllung des Filterbeutels gemäß dem Stand der Technik;

Figuren 2a und 2b

Luftdaten für eine Motor-Gebläseeinheit, die gemäß dem Stand der Technik in Vorrichtungen zum Staubsaugen eingesetzt wird;

Figuren 3a und 3b

Luftdaten für eine Motor-Gebläseeinheit, die sich besonders zur Implementierung der vorliegenden Erfindung eignet;

Figur 4:

die Abhängigkeit des erreichten Luftstroms von der Befüllung des Filterbeutels für eine erfindungsgemäße Vorrichtung;

Figuren 5a bis 5p

verschiedene Ansichten einer Abstandshalteeinrichtung der erfindungsgemäßen Vorrichtung zum Staubsaugen; und

Figur 6

eine Darstellung eines Filterbeutels, der besonders für die vorliegende Erfindung geeignet ist.

Show it:

FIGS. 1a and 1b

the dependence of the achieved air flow from the filling of the filter bag according to the prior art;

FIGS. 2a and 2b

Air data for a motor-blower unit, which is used in accordance with the prior art in devices for vacuuming;

FIGS. 3a and 3b

Air data for an engine blower unit particularly suitable for implementing the present invention;

FIG. 4:

the dependence of the achieved air flow from the filling of the filter bag for a device according to the invention;

FIGS. 5a to 5p

different views of a spacer device of the device according to the invention for vacuuming; and

FIG. 6

a representation of a filter bag, which is particularly suitable for the present invention.

EMBODIMENTS OF THE INVENTION

In the vacuuming apparatus of the present invention, an engine-blower unit having a specific characteristic is used in combination with a relatively large-diameter suction hose. Surprisingly, this combination leads to efficient vacuum cleaners in the sense of the invention, ie a vacuum cleaner which is in an energy efficiency class of B or better (according to VO 665/2013, ANNEX I) and at the same time in a cleaning class of C or better (according to VO 665 / 2013, ANNEX I).

The motor-blower unit is characterized by a high volume flow, a high air flow and a high efficiency at aperture 7 (30 mm) and 8 (40 mm). The corresponding values are listed in Table 1.

In the FIGS. 3a and 3b Air data for an exemplary embodiment of the motor-blower unit, as used in the invention, shown here, an engine-blower unit the company Domel with the type designation 467.3.601-7. The abscissa shows the suction air flow in units of dm ³ / s or l / s. The ordinate shows values of the negative pressure (in kPa), the efficiency (in%), the power (in W) and the air power (in W). In FIG. 3a results for a mean electrical input of about 480 W, in FIG. 3b shown by about 976 W.

As already mentioned, the show FIGS. 2a and 2b for comparison, the air data for a motor-blower unit of the prior art. In FIG. 2a The air data for a mean electrical input of about 622 W and in FIG. 2b shown by about 1121 W.

Table 1 compares the relevant measurements for an exemplary embodiment of the engine blower unit of the present invention and a prior art motor blower unit. At lower mean electrical power input both the air flow at aperture 7 and aperture 8 and the air power at aperture 7 and aperture 8 and the efficiency at aperture 7 and aperture 8 for the exemplary embodiment are much higher than for the prior art. For example, at the aperture 8 and at a mean electrical input power of about 480 W, the air performance for the exemplary embodiment is about 70% higher than for the prior art with a mean electrical input of 622 W.

With comparable power consumption, the efficiency and air flow of the present embodiment are superior to the prior art motor-blower unit. In particular, with a relatively low mean electrical input power at the relevant panels, which correspond to the real situation on hard and carpeted floors, a very good air flow can be achieved with which a good cleaning efficiency class can be realized.

In FIG. 4 is shown for inventive devices for vacuuming the dependence of the achieved air flow of the filling amount of the filter bag. The results shown are similar to those of the prior art vacuuming apparatuses as shown in Figs FIGS. 1a and 1b shown is to compare.

FIG. 4 shows results for a mean power of about 670 W using a flat bag with gussets according to FIG. 6 and a conical tube with a minimum diameter of 42 mm and a maximum diameter of 47 mm using a spacer.

The spacer used is described in detail in FIGS FIGS. 5a to 5o shown. In FIG. 5p the spacer device is shown together with the motor protection filter holder. Like this one FIG. 5p can be seen, is ensured by the arrangement shown that between motor protection filter and filter bag is always a distance and the filter bag does not cover the motor protection filter holder, which would cause the air from the filter bag is sucked only from the area of the filter bag, the covered the motor protection filter. A 3D record of in FIG. 5 described apparatus for vacuuming can be obtained from Eurofilters NV, Lieven Gevaertlaan 21, 3900 Overpelt, Belgium. In particular, the spacer means for receiving a special filter bag, for example a filter bag according to FIG. 6 be trained.

For the average cross-sectional area of the embodiment according to the invention thus results in a value of 15.6 cm ² . The filter bag used has an area of about 1800 cm ² . The filter material used was the MTTS9 material supplied by Eurofilters NV, Lieven Gevaertlaan 21, 3900 Overpelt, Belgium. It is a multi-layer filter material with a dust storage layer and a meltblown fine filter layer. The filter bag has a deflecting device in the form of a slit nonwoven fabric of the material LF75, which can also be obtained from Eurofilters NV, Lieven Gevaertlaan 21, 3900 Overpelt, Belgium.

Incidentally, the embodiment of the invention corresponds to the prior art, as described above. Even with an average power consumption of only approx. 670 W, a volume flow of 41 l / s is achieved when the filter bag is empty; after filling with 400 g of DMT Type 8 and using a spacer, a flow rate of almost 37 l / s is achieved.

Thus, the achievable volume flows are significantly higher than in the prior art, in which can be achieved with an average capacity of about 698 W only a flow of 30 l / s with empty filter bag. After loading with 400 g DMT8 dust, the volume flow is even lower than 27 l / s and is thus about 10 l / s lower than in the embodiment according to the invention.

The following table summarizes the air data for the Miele S 8340 (max and carpet) according to the prior art and for the embodiment of the vacuum cleaner according to the invention described above: Voltage [V] Average electrical power [W] Air flow aperture 7 [l / s] Air flow aperture 8 [l / s] Air output at aperture 7 [W] Air output at aperture 8 [W] Efficiency Aperture 7 [%] Efficiency aperture 8 [%] Motor blower unit Miele S 8340 Power level max 233 1121 47.6 55.5 378.0 185.0 27.8 13.3 Domel 467.3.601-7 220 976 52.0 66.3 496.3 319.0 41.5 26.3 Motor blower unit Miele S 8340 Performance level carpet 233 622 37.8 43.7 186.0 89.6 25.2 11.9 Domel 467.3.601-7 130 480 40.6 51.8 232.0 150.2 40.9 26.3

Claims (15)

Device for vacuuming comprising
a vacuum cleaner with a suction hose connected to the housing of the vacuum cleaner, and comprising
a filter bag, in particular a disposable filter bag, made of nonwoven fabric,
wherein the vacuum cleaner comprises a motor-blower unit, which is designed such that the average electrical power consumption is between 1000 W and 200 W, and at a mean electric power between • 1000 W and 800 W
a negative pressure in the measuring chamber at aperture 6 of> 12.5 kPa and
sets a negative pressure in the measuring chamber at aperture 8 of> 4.0 kPa, • 799 W and 600 W
a negative pressure in the measuring chamber at aperture 6 of> 10.0 kPa and
sets a negative pressure in the measuring chamber at aperture 8 of> 3.4 kPa, • 599 W and 400 W
a negative pressure in the measuring chamber at aperture 6 of> 7.0 kPa and
sets a negative pressure in the measuring chamber at aperture 8 of> 2.5 kPa, • 399 W and 200 W
a negative pressure in the measuring chamber at aperture 6 of> 4.0 kPa and
sets a negative pressure in the measuring chamber at aperture 8 of> 1.4 kPa, wherein the suction hose has an average cross-sectional area of at least 9.5 cm ² , in particular at least 11 cm ² or 13 cm ² . The device of claim 1, wherein the filter bag has a bag area of between 1000 cm ² and 4000 cm ² . The apparatus of claim 2, wherein the suction hose is at least partially tapered and has a larger cross-sectional area at an end proximate to the motor / blower unit than at an end remote from the motor / blower unit. Apparatus according to claim 3, wherein the suction hose has a minimum and a maximum cross-sectional area and the minimum diameter of the suction hose is reduced by at least 5%, in particular at least 20%, from the maximum cross-sectional area. Device according to one of the preceding claims, wherein the suction hose has a length of 1 m to 3 m. Device according to one of the preceding claims, wherein a suction tube connected to the suction hose has a diameter of more than 30 mm, preferably more than 33 mm and particularly preferably more than 36 mm. Device according to one of the preceding claims, in which the motor-blower unit at aperture 7 (30 mm) has an efficiency according to EN 60312 of at least 35%, preferably of at least 38% and particularly preferably of more than 40%. Device according to one of the preceding claims, in which the filter bag is designed as a flat bag and / or has surface folds and / or is provided with a deflection device. Device according to one of the preceding claims, wherein the vacuum cleaner comprises a spacer device having a bottom and / or at least one side wall and / or a lid for at least partially spacing a filter bag from at least one inner housing wall of the device for vacuuming. Apparatus according to claim 9, in which the spacer means is designed such that overflow paths are provided between the bottom and / or the at least one side wall and / or the lid. Apparatus according to claim 9 or 10, in which the spacer means is designed for a surface-bag filter bag. Device according to one of Claims 9 to 11, in which, in the device, the air flow direction is arranged in the following order: an air intake opening in the bottom or the at least one side wall or the cover through which air is sucked from the filter bag receiving space into the motor / blower unit during operation of the vacuum cleaner, a motor protection filter holder, and the spacer device, wherein the spacer means is spaced from the engine guard filter holder. Apparatus according to claim 12, in which the spacer means is in the form of a perforated plate and / or in the form of a grid and / or in the form of webs, web-shaped sections, brackets, bow-shaped sections, ribs, rib-shaped sections and / or pins. Device according to claim 12 or 13, in which the motor protection filter holder is designed so that a motor protection filter in the motor protection filter holder is retractable or foldable. Device according to one of the preceding claims, in which a filter bag holding plate receptacle is provided, which is arranged hinged relative to the device for vacuuming or can be removed completely from the device for vacuuming.

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