KR102180432B1 - Nozzle for a vacuum cleaner and vacuum cleaner - Google Patents

Abstract

The present invention provides a nozzle 1 for a vacuum cleaner 100, comprising a housing 2 with a suction channel 3, a lighting device 4 configured to illuminate an adjacent area to be cleaned, and the lighting device 4 And a switching means (6) for actuating, the nozzle (1) comprising a sensing means (5) configured to determine a measured value at the nozzle (1), coupled to the sensing means (5) Said switching means 6 are adapted to automatically activate said lighting device 4 when said measured value exceeds a predetermined threshold value.

Description

Nozzle for vacuum cleaner and vacuum cleaner {NOZZLE FOR A VACUUM CLEANER AND VACUUM CLEANER}

The present invention relates generally to the field of vacuum cleaners. More specifically, the present invention relates to a vacuum cleaner nozzle having a lighting device.

A vacuum cleaner is a device that uses the suction power generated by a fan unit to create a partial vacuum to suck objects such as dust, particles, fibers, hair, etc., usually from the floor and carpet. Typically this is done by means of a vacuum cleaner nozzle which is connected via a nozzle outlet to an extension tube and/or via a suction hose to a dust compartment in the body of the vacuum cleaner. The suction hose usually engages with a removable dust bag placed within the dust compartment to collect dust and debris sucked through the vacuum cleaner nozzle when the vacuum cleaner is in the operating mode. Therefore, the air stream containing dust sends the removed object to the body of the vacuum cleaner through the hose, and the removed object is separated from the air stream in the dust bag. Alternatively, a cyclone or other suitable dust separation unit can be used to separate the dust from the dust-containing air stream.

US 2006/0096057 A1 discloses a lighting accessory assembly for a vacuum cleaner comprising a transparent extension having a first end having a distal vacuum cavity suction end and releasably connectable to the vacuum cleaner hose. The LED is positioned so that the LED light traverses the transparent extension medium and exits the wall and the distal end of the transparent extension. The LED lighting provides a clear line of sight to the operator around and illuminated through the transparent extension of the area to be cleaned, and illuminates the contents in the initial vacuum cavity of the transparent extension to improve operator cleaning efficiency.

The disadvantage of known vacuum cleaners including lighting devices is that the lighting devices must be manually operated and shut down, which obviously worsens the usefulness of the vacuum cleaner. Accordingly, there is a need for improvement of an existing vacuum cleaner including a lighting device in order to increase the usefulness of the vacuum cleaner.

An object of an embodiment of the present invention is to provide an improved nozzle and a vacuum cleaner for a vacuum cleaner with improved usability. This object is solved by the features of the independent claims. Preferred embodiments are defined in the dependent claims. Unless expressly indicated otherwise, embodiments of the present invention may be freely combined with each other.

The invention is intended for battery powered vacuum cleaners as well as power powered vacuum cleaners. The present invention can be used in a canister vacuum cleaner, an upright vacuum cleaner, or a stick vacuum cleaner. It could also be used for robotic vacuum cleaners.

According to a first aspect of the present invention, the present invention is a nozzle for a vacuum cleaner, comprising a housing having a suction channel, a lighting device configured to illuminate an adjacent area to be cleaned, and a switching means for operating the lighting device, the nozzle And a sensing means configured to determine a measurement value at the silver nozzle, and the switching means coupled to the sensing means relates to a nozzle configured to automatically activate the lighting device when the measured value exceeds a predetermined threshold value. will be.

Accordingly, the nozzle is configured to automatically operate the lighting device based on the detected measured value.

According to a preferred embodiment, the nozzle and the vacuum cleaner body are electrically separated. In other words, the nozzle does not include means for electrically coupling the lighting device to the vacuum cleaner body, ie there is no wired or wireless electrical connection between the nozzle and the vacuum cleaner body. Accordingly, the vacuum cleaner body is simplified by the technical configuration of the vacuum cleaner nozzle and the interface between the vacuum cleaner nozzle and the hose, respectively. Each of the vacuum cleaner nozzles is configured to perform switching and operation of the lighting device automatically, ie without any operative connection to the vacuum cleaner body. Accordingly, it is also possible to upgrade the vacuum cleaner having the nozzle according to the present invention.

According to a preferred embodiment, the switching means is configured to operate the lighting device when the vacuum cleaner is turned on and to deactivate the lighting device when the vacuum cleaner is turned off. Accordingly, since the lighting device is automatically turned off when the vacuum cleaner is turned off, effective switching of the lighting device is achieved, and power can be saved.

According to a preferred embodiment, the sensing means consist of a pressure sensor configured to measure the vacuum in the suction channel of the nozzle. In the operating mode of the vacuum cleaner, a vacuum is generated in the suction channel of the vacuum cleaner nozzle. Accordingly, by detecting the vacuum level of the suction channel, the operating state of the vacuum cleaner may be determined. When the vacuum level in the suction channel exceeds a predetermined threshold value, the lighting device can be turned on.

According to a preferred embodiment, the sensing means consists of an air flow sensor configured to measure the air flow in the suction channel of the nozzle. In the operating mode of the vacuum cleaner, airflow is generated in the suction channel of the vacuum cleaner nozzle. Accordingly, by sensing the airflow level in the suction channel, the operating state of the vacuum cleaner can be determined. When the airflow level in the suction channel exceeds a predetermined threshold value, the lighting device can be turned on.

According to a preferred embodiment, the sensing means and switching means consist of a single sensing and switching element. Preferably, the sensing means comprise a movable element configured to be moved according to the value to be measured. This movement can be used to switch electrical contacts at the same time. Accordingly, the movable element of the sensing means also constitutes a switching element of the switching means. Accordingly, the technical configuration of the vacuum cleaner nozzle can be simplified.

According to a preferred embodiment, the lighting device is electrically coupled with an electrical circuit configured to suppress flicker of the lighting device due to fluctuations in the vacuum and/or airflow in the suction channel of the nozzle. The electrical circuit may be a filter and delay circuit having at least one capacitor for providing power to the lighting device irrespective of the short time discontinuities of the power supply due to undesirable switching characteristics.

According to a preferred embodiment, the lighting device consists of at least one light emitting diode (LED). Advantageously, the light emitting diode comprises a long lifetime and is extremely energy efficient. Accordingly, even when the lighting device is a battery driven type, the life of the battery is extremely long.

According to a preferred embodiment, the lighting device is integrated into the housing of the nozzle. When the lighting device is battery powered, the housing of the vacuum cleaner nozzle includes a battery compartment accommodating the battery.

According to a second aspect, the present invention relates to a vacuum cleaner including the nozzle according to any one of the above-described embodiments.

According to a third aspect, the present invention is a method of operating a lighting device of a vacuum cleaner nozzle, the nozzle comprising a housing having a suction channel and a switching means for actuating the lighting device, the lighting device forming an adjacent area to be cleaned. It is configured to illuminate, the measured value is determined by the sensing means at the nozzle, and the lighting device relates to a method of being operated by the switching means when the measured value exceeds a predetermined threshold value.

According to a preferred embodiment, the lighting device is automatically operated when the vacuum cleaner is turned on, and automatically shuts down when the vacuum cleaner is turned off.

Preferably, the vacuum in the suction channel of the nozzle is measured by means of sensing.

The term "essentially" or "approximately" as used herein means a deviation from the exact value by +/-10%, preferably by +/-5%, and / Or a variation in the form of minor changes in function.

Various aspects of the invention, including certain features and advantages of the invention, will be readily understood from the following detailed description and accompanying drawings.
1 shows a cross-sectional view of a vacuum cleaner nozzle according to the present invention.
2 shows a canister type vacuum cleaner.
3 shows a perspective view of a vacuum cleaner nozzle according to the present invention.
4 is a cross-sectional view of a pressure switch used to operate a lighting device of a vacuum cleaner nozzle.

The invention is now more fully described with reference to the accompanying drawings in which an embodiment is shown. However, the present invention should not be construed as being limited to the examples presented herein. Throughout the description that follows, like reference numerals have been used to indicate like elements, parts, items, or features, where applicable.

FIG. 1 shows a vacuum cleaner nozzle 1 for a vacuum cleaner 100 suitable for a canister-type vacuum cleaner 100, specifically. The vacuum cleaner nozzle 1 is configured to be connected to the vacuum cleaner 100 to vacuum debris (eg, by suction) from areas, surfaces and/or objects. For example, the vacuum cleaner nozzle 1 may include a vacuum inlet 1.1 configured to receive debris. Further, the vacuum cleaner nozzle 1 may include a vacuum outlet 1.2 in fluid communication with the vacuum inlet 1.1 through the suction channel 3. The vacuum outlet 1.2 is removably connected to the hose 120 of the vacuum cleaner 100 (refer to FIG. 2) to remove debris from a storage unit (for example, a vacuum cleaner) in the vacuum cleaner body 110 of the vacuum cleaner 100. It may be configured to deliver to a bag or canister, not shown). The vacuum outlet 1.2 can be connected to the hose 120 in any way that provides fluid communication between the vacuum cleaner nozzle 1 and the vacuum cleaner 100. It will be appreciated that the vacuum cleaner 100 can be of any type, such as, for example, upright, canister, central vacuum or stick. The vacuum cleaner 100 may be a battery driven type or a power driven type. It could also be used for robotic vacuum cleaners. The vacuum cleaner 100 may be configured to contain any type of gas, liquid and/or solid, such as, for example, air, debris and/or water.

1 and 3, the vacuum cleaner nozzle 1 further includes a lighting device 4 that illuminates an adjacent area to be cleaned. The lighting device may include at least one light source configured to emit light when activated. Preferably, at least one light source is a light emitting diode (LED). The lighting device 4 may be an integral part of the housing 2 positioned above the vacuum cleaner nozzle 1. The lighting device 4 may be configured to illuminate the front area of the vacuum cleaner nozzle 1. Further, the lighting device 4 may be configured to at least partially illuminate the left and/or right side of the vacuum cleaner nozzle 1.

In order to operate the lighting device 4, switching means 6 are provided. The switching means 6 are configured to provide a switchable electrical coupling of the lighting device 4 to the power supply. The power supply unit may preferably be composed of at least one battery located in the battery compartment 8 of the vacuum cleaner nozzle 1.

In addition, the vacuum cleaner nozzle 1 includes a sensing means 5 for determining at least one measurement value in the vacuum cleaner nozzle 1. The sensing means 5 are coupled to the switching means 6 to activate or deactivate the lighting device 4 depending on the magnitude of the sensed measured value. Specifically, when the magnitude of the measured value exceeds a predetermined threshold value, the switching means 6 are configured to automatically activate the lighting device 4. Preferably, the size of the detected measured value is determined according to the switching state of the vacuum cleaner 100. For example, the measured value may be a pressure or airflow in the suction channel 3, a noise level around the vacuum cleaner nozzle 1, or a combination of these measured values. Accordingly, by determining at least one measurement value, the switching state of the vacuum cleaner 100 may be determined, and the lighting device 4 may be operated or stopped according to the switching state. Preferably, the interconnection of the switching means 6 and the sensing means 5 is configured so that the lighting device 4 is operated whenever the vacuum cleaner 100 is operated. By measuring at least one measurement value and determining based on this measurement value, when power is supplied to the vacuum cleaner 100, any kind between the vacuum cleaner nozzle 1 and the vacuum cleaner body 110 The coupling means can be avoided. Further, the lighting device 4 does not need to be operated by the user of the vacuum cleaner 100, which improves the usability of the vacuum cleaner 100.

4 shows a pressure switch 10 which will be used to automatically activate the lighting device 4. The pressure switch 10 combines the sensing means 5 and the switching means 6 into one integrated element. The pressure switch 10 comprises a housing 11 comprising at least a first chamber 12. The first chamber is defined at least in part by a reversibly deformable membrane 13. The first chamber 12 further comprises at least one opening 12. 1 to be coupled with the suction channel 3 to apply a vacuum to the first chamber 12. The vacuum inside the first chamber 12 is generated by the suction force in the suction channel 3.

Further, the membrane 13 is mechanically coupled with the electrically conductive element 14. According to this embodiment, the electrically conductive element 14 is located above the membrane 13. When applying a vacuum to the first chamber 12, the membrane 13 is deformed. The pressure switch 10 further comprises two electrical contacts 15a, 15b which are arranged at a distance from each other and thus do not have electrical contact with each other. If no vacuum is applied to the first chamber 12, the electrically conductive element 14 can be positioned at a distance to the electrical contacts 15a, 15b. There may be a spring 16 that holds the electrically conductive element 14 at a distance to the electrical contacts 15a, 15b. For example, the first free end of the spring 16 may be fixed to the housing 11 and the opposite second free end may be fixed to the electrically conductive element 14. When a vacuum is applied to the first chamber 12 and the vacuum value exceeds the threshold value (essentially determined by the spring force and the flexibility of the membrane 13), the electrically conductive element 14 is turned on to the electrical contacts 15a, 15b. ). Accordingly, the electrical contacts 15a and 15b are electrically conductively coupled.

When the vacuum in the first chamber 12 decreases and falls below the threshold value, the spring force and/or elastic restoring force of the membrane 13 is the force applied to the membrane 13 due to the vacuum inside the first chamber 12 High compared to Thus, the electrically conductive element 14 is spaced with respect to the electrical contacts 15a, 15b, so that an electrically conductive connection between the electrical contacts 15a, 15b no longer occurs. Thus, depending on the suction force in the suction channel 3 of the vacuum cleaner nozzle 1, the lighting device 4 is automatically operated or stopped.

The pressure switch 10 shown in FIG. 4 comprises a sensing means 5 as well as a switching means 6. The sensing means 5 consists of a first chamber 12 and an elastic membrane 13. The switching means 6 consists of an electrically conductive element 14 and electrical contacts 15a, 15b.

Notwithstanding the embodiment of the sensing and switching means 5, 6 described above with reference to FIG. 4, the sensing means is also an air flow sensor that detects airflow through the suction channel 3 or in the area of the vacuum cleaner nozzle 1. It may be composed of a noise sensor that detects the noise level. Combinations of the above-described sensing means 5 are also possible in order to improve the switching behavior of the lighting device 4.

In order to prevent any flickering of the lighting device 4 due to temporary fluctuations in the measured value, for example fluctuations in the vacuum or airflow in the suction channel, the lighting device 4 is provided with a short time fluctuation of the measured value and It can be electrically coupled with an electrical circuit 4.1 that is configured to provide a constant switching state regardless. Specifically, the electric circuit 4.1 may be a filter and a delay circuit providing at least one capacitor to compensate for short-time discontinuities of the power supply due to undesirable switching characteristics. Thus, a temporary failure of the lighting device 4 can be prevented.

An embodiment of a vacuum cleaner nozzle according to the present invention as defined above, as defined in the appended claims, has been described. This embodiment should be shown as a non-limiting example only. As those skilled in the art will appreciate, numerous modifications and alternative embodiments are possible within the scope of the present invention.

1: nozzle
1.1: vacuum inlet
1.2: vacuum outlet
2: housing
3: suction channel
4: lighting device
4.1: electrical circuit
5: detection means
6: switching means
8: battery compartment
10: pressure switch
11: housing
12: first chamber
12.1: opening
13: membrane
14: conductive element
15a: electrical contact
15b: electrical contact
16: spring
100: vacuum cleaner
110: vacuum cleaner body
120: hose

Claims (15)

As the nozzle 1 for the vacuum cleaner 100,
Housing (2) with suction channel (3),
A lighting device 4 configured to illuminate an adjacent area to be cleaned, and
Comprising switching means (6) for operating the lighting device (4),
The nozzle (1) comprises a sensing means (5) configured to determine a measured value at the nozzle (1), and the switching means (6) coupled to the sensing means (5) has the measured value It is configured to automatically operate the lighting device 4 when it exceeds a predetermined threshold value,
The nozzle 1 and the vacuum cleaner body 110 are electrically separated,
The switching means (6) is configured to operate the lighting device (4) when the vacuum cleaner (100) is turned on and to stop the lighting device (4) when the vacuum cleaner (100) is turned off. Composed,
The lighting device 4 has a constant switching regardless of the fluctuation of the measured value in order to suppress flicker of the lighting device 4 due to fluctuations in the vacuum or air flow in the suction channel 3 of the nozzle 1 A nozzle electrically coupled with an electrical circuit (4.1) configured to provide a state. delete delete The method of claim 1,
The sensing means (5) consists of a pressure sensor configured to measure the vacuum in the suction channel (3) of the nozzle (1). The method of claim 1,
The sensing means (5) consists of an air flow sensor configured to measure the air flow in the suction channel (3) of the nozzle (1). The method of claim 1,
Nozzle, wherein the sensing means (5) and the switching means (6) consist of a single sensing and switching element (7). delete The method of claim 1,
The nozzle, wherein the lighting device (4) consists of at least one light-emitting diode (LED). The method of claim 1,
The nozzle (4) is integrated into the housing (2) of the nozzle (1). The method of claim 1,
The lighting device 4 is a battery driven nozzle. The method of claim 10,
A nozzle comprising at least one battery compartment (8) accommodating the battery. A vacuum cleaner comprising a nozzle (1) according to claim 1. As a method of operating the lighting device 4 of the vacuum cleaner nozzle 1,
The nozzle 1,
A housing (2) with a suction channel (3), and
Comprising switching means (6) for operating the lighting device (4),
The lighting device 4 is configured to illuminate an adjacent area to be cleaned,
The measured value is determined at the nozzle 1 by means of detection means 5, the lighting device 4 being operated by means of the switching means 6 when the measured value exceeds a predetermined threshold value,
The nozzle 1 and the vacuum cleaner body 110 are electrically separated,
The lighting device 4 is automatically operated when the vacuum cleaner is turned on, and automatically stopped when the vacuum cleaner is turned off,
The lighting device 4 has a constant switching regardless of the fluctuation of the measured value in order to suppress flicker of the lighting device 4 due to fluctuations in the vacuum or air flow in the suction channel 3 of the nozzle 1 And electrically coupled with an electrical circuit (4.1) configured to provide a state. delete The method of claim 13,
The method, wherein the vacuum in the suction channel (3) of the nozzle (1) is measured by the sensing means (5).

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