DE102019103002A1 - Hand-held cyclone vacuum cleaner - Google Patents

Abstract

The invention relates to a hand-held cyclone vacuum cleaner, having a suction material container (1) for receiving suction material, a device body (2) which can be detachably connected to the suction material container (1) and has a drive unit which is designed to generate a suction air flow, wherein an air channel (10) located in the suction material container (1) and a suction channel (8) located in the housing body (2) have an air path for the suction air flow during operation when the suction material container (1) and the housing body (2) are connected, which is aligned along a flow axis which is parallel to an axis of movement when connecting the suction material container (1) and the device body (2).

Description

The invention relates to a hand-held cyclone vacuum cleaner which, for the sake of simplicity, is referred to below as a vacuum cleaner. In particular, the invention relates to a vacuum cleaner which has a suction material container for receiving suction material and a device body which can be detachably connected to the suction material container and which has a drive unit which is designed to generate a suction air flow.

In the case of a cyclone vacuum cleaner, it is necessary that it has a removable suction material container so that the suction material can be removed from the suction material container. When attaching and detaching the suction material container from the device body, at least one sealing point must be contacted or released. This at least one sealing point relates in particular to the intake and exhaust air suction stream of the separation system, which is connected upstream of the suction material container. In addition, however, it is necessary for this at least one sealing point to be optimally pressed during operation, so that losses due to secondary air in addition to the suction air flow are minimized.

The invention thus poses the problem of providing a vacuum cleaner which has an optimized sealing effect between the suction material container and the device body.

According to the invention, this problem is solved by a vacuum cleaner having the features of claim 1. Advantageous refinements and developments of the invention emerge from the following subclaims.

The advantages that can be achieved with the invention are, in addition to an optimized sealing effect, that a user of the vacuum cleaner is enabled to apply this sealing effect with a relatively low expenditure of force and also to release it again easily. In addition, a simple, non-destructive overcoming of the mechanism e.g. possible for assembly purposes. A pressing force is provided by means of the concept described. During operation, sealing areas pull towards the sealing point. This results in an improved seal when the vacuum cleaner is in operation. This optimizes the sealing effect between the suction material container and the device body.

The invention relates to a hand-held cyclone vacuum cleaner, comprising a suction material container for receiving suction material and a device body which can be detachably connected to the suction material container and has a drive unit which is designed to generate a suction air flow, with an air duct located in the suction material container and a suction channel located in the housing body when the suction material container is connected and the housing body has an air path for the suction air flow during operation that is aligned along a flow axis that is parallel to an axis of movement when connecting the suction material container and the device body.

The expression “hand-held” means that the vacuum cleaner is operated by the user by hand. For this purpose, the vacuum cleaner preferably also has a handle which can be connected to the suction material container and which is connected to it during operation.

Furthermore, the vacuum cleaner can have a suction tube which can be connected to the suction material container and / or the device body and, during operation, is connected to one of them if necessary. Optionally, the suction tube can still be connected to the handle; this embodiment is advantageous if the suction pipe is connected to the suction material container during operation. The suction pipe can also be connected to a floor nozzle; this embodiment is advantageous if the suction tube is connected to the device body during operation and the suction material container is connected to the handle.

The term "cyclone vacuum cleaner" is to be understood as meaning a vacuum cleaner that is bagless and in which eddies and possible turbulences are generated in an air stream entering the vacuum cleaner, whereby the suction material such as e.g. Dust particles are pushed and deposited in a predetermined direction due to centrifugal force. The expression "bagless" means that the suction material in the vacuum cleaner is collected directly in the suction material container without a bag or similar replaceable filter medium for receiving suction material being arranged in it, so that the user has to empty the suction material from the suction material container does not remove a bag or the like from the suction material container. The vacuum cleaner can, however, have one or more filter media which prevent sucked-up material from reaching the drive unit arranged in the device body. Both the suction material container and the device body are preferably made of plastic.

The vacuum cleaner is preferably a cordless vacuum cleaner. That is, the vacuum cleaner has an accumulator and is designed to be operated by means of the accumulator as a power source. The accumulator can be connected to the suction material container and / or the device body, preferably the device body.

In an operational working position, the suction material container is on a rear side or at the rear end of the vacuum cleaner, which means that it is closer to the user's hand and further away from the surface to be vacuumed than the device body. The suction channel located in the device body changes into the air channel located in the suction material container during operation, ie the suction air flow flows first through the suction channel and then through the air channel during operation.

The suction material container is separated from the device body for emptying. During operation, the suction material container is connected to the device body. For this purpose, it is placed on the device body and a suction air flow is generated by the drive unit, which flows through the suction channel of the device body and then through the air channel of the suction material container. A prevailing negative pressure pulls the device body and the suction material container towards one another, since the air path of the suction air flow is aligned during operation along the flow axis which is parallel to an axis of movement when connecting the suction material container and the device body. This achieves a high sealing effect between the two components. In the case of the air path, the generated eddies and any eddies in the suction air flow are not taken into account, rather the path of the main flow direction of the suction air flow is meant.

In a preferred embodiment, the device body has a base plate and a nozzle extending away from the base plate and the suction material container has a housing part and a prefilter with a sleeve-like part which is arranged in the housing part, one end of the housing part and an edge of the Device body have a complementary contour and the sleeve-like part can be placed on the socket. During operation, the suction air flow also flows through the pre-filter and the nozzle, so that the suction air flow first flows through the suction channel, then the air channel, and then through a channel formed by the pre-filter and the nozzle. The flow axis of the suction channel and the air channel is preferably parallel to the flow axis of the channel formed by the prefilter and the nozzle. This further improves the sealing effect between the suction material container and the device body.

The air duct and the duct formed by the connector and the pre-filter are preferably connected by a connecting duct. The flow axes of the suction channel and the air channel are parallel to the flow axis of the channel formed by the connector and the pre-filter, but the main flow direction of the suction air flow flowing through the suction channel and the air channel is opposite to the main flow direction of the channel formed by the connector and the pre-filter, whereby the main flow direction is to be understood as a flow direction in which the eddies and any eddies are disregarded. Due to the negative pressure prevailing at the connection during operation, the suction material container is additionally drawn towards the device body, which results in an optimized sealing effect at this point. The connector is preferably arranged in the direction of flow of the suction flow in front of the drive unit, for example in the form of a fan. The sleeve-like part of the prefilter preferably engages over the nozzle when the suction material container is placed on the device body.

The socket preferably has several locking cams and the pre-filter has several locking geometries, each of which is designed and designed to receive a locking cam, each locking geometry having a slot which is open in the direction of the base plate when the suction material container is placed on the device body each has a locking part extending away from the respective slot, which is closed in the direction of the base plate and extends at an angle away from the respective slot in the direction opposite to the base plate. Each slot of each locking geometry is preferably designed to allow a latching cam of the connector to be at least partially inserted into the sleeve-like part of the prefilter when the suction material container is placed on the device body. This allows the suction material container to be placed on the device body without any additional force being applied. The way for placing is limited by a stop on the respective slot. Each locking geometry preferably has a geometry such that the suction material container can be placed in a predetermined position. The system is thereby coded.

Each locking geometry has the one slot and the one locking part extending away from the respective slot. The locking parts are closed in the direction of the base plate and extend at an angle from the respective slot in the direction opposite to the base plate. They therefore have a slope with respect to the respective slot.

In a preferred embodiment, the slots of the locking geometries are each designed in such a way that the locking cams are guided in the slots when the prefilter is placed on the socket. This placement is done by the user without any effort. From this position, the sleeve-like part of the prefilter can be rotated in such a way that the locking cams can be inserted into the respective locking part. The sleeve-like part of the prefilter and the connector are preferably designed in such a way that the suction material container extends into the respective locking part when the locking cams are turned the slope of the locking part located in the pre-filter pulls over the locking cams onto the socket. A stroke resulting therefrom is preferably in the range of 2 to 4 mm. Due to this thread-like construction, a high sealing force can be applied with comparatively little manual force.

The connection piece and the prefilter are preferably each at least partially conical. The connecting piece is preferably equipped with a conical geometry which is designed to come into contact with the prefilter via a sealing area during the stroke when the suction material container is connected to the device body. The prefilter is preferably also conical in the sealing area, i.e. the sleeve-like part is preferably at least partially conical. By placing the suction material container on the device body, a seal is also provided between the suction channel and the air channel. The conical geometry of the connector is preferably also designed in such a way that when the suction material container is released from the device body, the slope of the locking part causes the connector and the pre-filter to be easily separated from one another. A surface seal is provided by means of the conical configuration.

The locking cams are preferably distributed at a uniform angle over the circumference of the connecting piece and the locking geometries are distributed uniformly over the circumference of the pre-filter. This results in a uniform distribution of a force when locking the suction material container on the device body. For example, the connector has three locking cams and the prefilter has three locking geometries.

In a preferred embodiment, the vacuum cleaner has an operating element which is connected to the suction material container in such a way that the suction material container is arranged between the operating element and the device body and that the operating element is designed to be rotatable from an open position to a closed position and vice versa. The operating element is preferably designed to lock or release the suction material container on the device body. When the control element is arranged in the open position, the suction material container is detached from the device body or detachably connected (i.e. the suction material container can be detached from the device body by pulling it largely without force). When the control element is arranged in the closed position, the suction material container is connected to the device body, i. it cannot be detached from it by pulling it from it. Rather, the operating element must be rotated from the closed position to the open position so that the suction material container can be detached from the device body by means of pulling.

The locking geometries are preferably designed in such a way that, in the connected state of the suction material container and the housing body, the latching cams are inserted into the respective locking part when the operating element is in the closed position and, when the operating element is in the open position, in are inserted into the respective slot. The vacuum cleaner is designed in such a way that when the control element is turned into the closed position, the suction material container moves over the slope in the pre-filter in the locking geometry, i.e. the locking part, pulls the locking cams onto the socket. The stroke resulting therefrom is preferably in the range from 2 to 4 mm.

In a preferred embodiment, the vacuum cleaner has inlet bevels which are each arranged on the pre-filter adjacent to one of the locking parts and adjacent to the slot assigned to the respective locking part, the locking cams each having a bevel on their bevel when the suction material container is placed on the device body Side. When the prefilter is placed on the nozzle, it springs open through contact between the locking cams and the inlet bevels and the locking cams jump into the locking parts of the locking geometries in an end position. This allows the pre-filter to be placed on the nozzle without the locking cams having to be guided in the slots. This prevents the components from being destroyed if the user makes a mistake when placing the suction material container on the device body. In addition, during assembly in the production of the vacuum cleaner, the suction material container does not have to be rotated in order to connect it to the device body. As a result, the suction material container can be connected to the device body, even when the control element is in the closed position.

• 1 eine perspektivische Ansicht des erfindungsgemäßen Staubsaugers,
• 2 eine weitere perspektivische Teil-Ansicht des in 1 gezeigten Staubsaugers,
• 3 eine Teil-Querschnittsansicht des in 2 gezeigten Staubsaugers,
• 4 eine weitere perspektivische Teil-Ansicht des in 1 gezeigten Staubsaugers,
• 5 eine weitere Teil-Querschnittsansicht des in 4 gezeigten Staubsaugers,
• 6 eine vergrößerte Teil-Querschnittsansicht des in 3 gezeigten Staubsaugers,
• 7 eine vergrößerte Teil-Querschnittsansicht des in 5 gezeigten Staubsaugers,
• 8 eine perspektivische Teil-Ansicht des in 1 gezeigten Gerätekorpus,
• 9 eine perspektivische Teil-Ansicht des in 1 gezeigten Sauggutbehälters.

An embodiment of the invention is shown purely schematically in the drawings and is described in more detail below. It shows schematically and not to scale

• 1 a perspective view of the vacuum cleaner according to the invention,
• 2 a further perspective partial view of the in 1 shown vacuum cleaner,
• 3 a partial cross-sectional view of the in 2 shown vacuum cleaner,
• 4th a further perspective partial view of the in 1 shown vacuum cleaner,
• 5 a further partial cross-sectional view of the in 4th shown vacuum cleaner,
• 6 an enlarged partial cross-sectional view of the FIG 3 shown vacuum cleaner,
• 7th an enlarged partial cross-sectional view of the FIG 5 shown vacuum cleaner,
• 8th a perspective partial view of the in 1 device body shown,
• 9 a perspective partial view of the in 1 suction material container shown.

1 shows a perspective view of the vacuum cleaner according to the invention. The in 1 The vacuum cleaner shown has a suction material container 1 for taking up suction material with a housing 12th on. The vacuum cleaner also has a device body 2 on, the detachable with the suction material container 1 is connectable. The device body 2 has a base plate 13th one up from the base plate 13th away extending nozzle 5 and one up from the base plate 13th housing part extending away 15th on. The stub 5 is inside the housing part 15th arranged in the same direction as the nozzle 5 from the base plate 13th extends away. One end of the case 12th and end of the housing part 15th have a complementary contour that can be attached when the suction material container 1 to the device body 2 is arranged. Furthermore, the device body 2 two more sockets 14th which can be connected to a suction tube (not shown) and / or a handle (not shown). The device body 2 has a drive unit (not shown) that is designed to generate a suction air flow during operation, which flows through a in the device body 2 trained suction channel 8th flows. The vacuum cleaner also has an operating element 3 on, the one with the suction material container 1 is connected in such a way that the suction material container 1 between the control element 3 and the device body 2 is arranged. The control element 3 is designed to be rotatable from an open position to a closed position and vice versa. The device body is in the open position 2 from the suction material container 1 solvable, as in 1 is shown. The suction material container is in the closed position 1 with the device body 2 connected in such a way that it is not in this position from the device body 2 can be released by pulling.

2 FIG. 11 shows a further perspective partial view of the FIG 1 shown vacuum cleaner. At the in 2 The partial view shown, the housing of the suction material container 1 is omitted for the sake of clarity. The suction material container 1 has a sleeve-like prefilter 4th in the housing (not shown) of the suction material container ( 1 ) is arranged and the on the nozzle 5 of the device body 2 is attachable. The sleeve-like pre-filter 4th is in 2 on the nozzle 5 attached, with the nozzle 5 and the pre-filter 4th are at least partially each conical. The stub 5 has several locking cams 6 on, one of which is in 2 is shown. The pre-filter 4th has multiple locking geometries 7th on, one of which is in 2 is visible. Any locking geometry 7th is designed and designed, each with a locking cam 6 record. Any locking geometry 7th has a slot 16 when the suction material container is put on 1 on the device body 2 in the direction of the base plate (not shown) open, as well as one each from the respective slot 16 away extending locking part 17th , which is closed in the direction of the base plate and is angled from the respective slot 16 extends away in the opposite direction to the base plate. In the 2 is the locking cam 6 in the slot 16 the locking geometry 7th introduced. The locking cam 6 is from this position in the locking part 17th insertable to the suction material container 1 with the device body 2 in this position the locking cam 6 to connect, or from the slot 16 pullable so that the suction material container 1 from the device body 2 is solvable.

3 FIG. 13 shows a partial cross-sectional view of the FIG 2 shown vacuum cleaner. One end of the case 12th of the suction material container 1 is on one end of the housing part 15th of the device body 2 put on. The suction channel 8th of the device body 2 and an air duct 10 of the suction material container 1 are about a seal 9 arranged adjacent to one another and arranged along a flow axis (not shown). This is generated in the housing body during operation 2 arranged drive unit (not shown) a suction air flow through the suction channel 8th , then the air duct 10 , the pre-filter 4th and the nozzle 5 flows.

4th FIG. 11 shows a further perspective partial view of the FIG 1 shown vacuum cleaner. The in 4th The vacuum cleaner shown corresponds to the one in 2 shown vacuum cleaner with the difference that the locking cam 6 in the locking part 17th is introduced. Because the locking part 17th is closed in the direction of the base plate (not shown), there is a locking of the suction material container in this position 1 with the device body 2 so that the locking cam 6 in this position not out of the locking geometry 7th can be pulled out. The suction material container 1 and the device body 2 are in this position of the locking cam 6 in the locking geometry 7th not detachable from each other by pulling.

5 FIG. 11 shows another partial cross-sectional view of the FIG 4th shown vacuum cleaner. The in 5 The vacuum cleaner shown corresponds to the one in 3 shown vacuum cleaner with the difference that locking cam 6 is inserted into the locking part (not shown) of the locking geometry (not shown) and compared to FIG 3 shown locking cam 6 is arranged higher because the locking part 17th has a slope (not shown).

6 FIG. 13 shows an enlarged partial cross-sectional view of the FIG 3 shown vacuum cleaner. The locking cam 6 is in the slot 16 introduced. The stub 5 has a sealing area 19th on, in which the nozzle is conical. Furthermore, the pre-filter 4th another sealing area 20th in which it is conical.

7th FIG. 13 shows an enlarged partial cross-sectional view of the FIG 5 shown vacuum cleaner. The in 7th The vacuum cleaner shown corresponds to the one in 6 shown vacuum cleaner with the difference that the locking cam 6 in the locking part 17th is introduced and that the conical sealing area 19th via the conical further sealing area 20th to the pre-filter 4th applies. The sealing areas 19th , 20th have therefore differed in comparison to their in 6 position shown.

8th FIG. 11 shows a further perspective partial view of the FIG 1 device body shown. The housing part 15th and the nozzle 5 extend in the same direction from the base plate 13th path. The stub 5 has several locking cams 6 on, which are arranged evenly distributed around its circumference. Purely by way of example, the connecting piece has three locking cams 6 on, of which in 8th two are visible. The locking cams 6 are on the nozzle 5 at an angle in relation to the base plate 13th arranged and designed such that they can be introduced into the locking part (not shown) of the suction material container (not shown) by a rotary movement. Each locking cam 6 each has a bevel 18th on.

9 FIG. 11 shows a further perspective partial view of the FIG 1 suction material container shown. The suction material container 1 assigns the pre-filter 4th on, which has a sleeve-like part. The pre-filter 4th has - purely by way of example 3 - locking geometries 7th on each of the slot 16 and the locking part 17th have and around the circumference of the sleeve-like part of the pre-filter 4th are arranged evenly so that the in 8th locking cams shown can be introduced into them. Adjacent to each slot 16 and adjacent to each locking part 17th is an inlet slope 11 inside the pre-filter 4th educated. Every inlet slope 11 is designed such that one of the locking cams of the in 8th Device body shown (not shown) can run into them and into the locking part 17th is insertable. When putting on the pre-filter 4th on the in 8th It is spring-loaded by a contact between the locking cams and the inlet bevels 11 on, and the latching cams jump into the locking parts in an end position 17th the locking geometries 7th .

List of reference symbols

1

Suction material container

2

Device body

3

Control element

4th

Pre-filter

5

Support

6

Locking cams

7th

Locking

8th

Suction channel

9

poetry

10

Air duct

11

Inlet slope

12th

casing

13th

Base plate

14th

further nozzle

15th

Housing part

16

slot

17th

Locking part

18th

chamfer

19th

Sealing area

20th

Further sealing area

Claims (9)

Hand-held cyclone vacuum cleaner, having - a suction material container (1) for receiving suction material, - A device body (2) which can be detachably connected to the suction material container (1) and has a drive unit which is designed to generate a suction air flow, - An air channel (10) located in the suction material container (1) and a suction channel (8) located in the housing body (2) having an air path for the suction air flow during operation when the suction material container (1) and the housing body (2) are connected which is aligned along a flow axis which is parallel to an axis of movement when connecting the suction material container (1) and the device body (2). Vacuum cleaner after Claim 1 , characterized in that - the device body (2) has a base plate (13) and a nozzle (5) extending away from the base plate (13), and - the suction material container (1) has a housing (12) and a pre-filter (4 ) having a sleeve-like part which is arranged in the housing (12), one end of the housing (12) and one end of a housing part (15) of the device body (2) have a complementary contour and the sleeve-like part can be placed on the connecting piece (5). Vacuum cleaner after Claim 2 , characterized in that the connecting piece (5) has a plurality of locking cams (6) and the pre-filter (4) has a plurality of locking geometries (7) which are each designed and designed to receive a respective locking cam (6), each locking geometry (7) a slot (16) which is open in the direction of the base plate (13) when the suction material container (1) is placed on the device body (2) and has a locking part (17) extending away from the respective slot (16), which is closed in the direction of the base plate (13) and extends at an angle away from the respective slot (16) in the direction opposite to the base plate (13). Vacuum cleaner after Claim 3 , characterized in that the slots (16) of the locking geometries (7) are each designed in such a way that the locking cams (6) are guided in the slots (16) when the prefilter (4) is placed on the connector (5). Vacuum cleaner after Claim 3 or 4th , characterized in that the locking cams (6) are distributed at a uniform angle over the circumference of the connecting piece (5) and the locking geometries (7) are distributed uniformly over the circumference of the pre-filter (4). Vacuum cleaner after one of the Claims 2 to 5 , characterized in that the connector (5) and the pre-filter (4) are at least partially each conical. Vacuum cleaner according to one of the preceding claims, characterized by an operating element (3) which is connected to the suction material container (1) in such a way that the suction material container (1) is arranged between the operating element (3) and the device body (2), and that the Control element (3) is designed to be rotatable from an open position to a closed position and vice versa. Vacuum cleaner after Claim 7 , characterized in that the locking geometries (7) are designed in such a way that in the connected state of the suction material container (1) and the housing body (2), the locking cams (6) when the operating element (3) is in the closed position, in the respective locking part (17) are inserted, and, when the operating element (3) is arranged in the open position, are inserted into the respective slot (16). Vacuum cleaner according to one of the preceding Claims 3 to 8th , characterized by inlet bevels (11) which are each arranged on the prefilter (4) adjacent to one of the locking parts (17) and adjacent to the respective locking part (17) associated slot (16), the locking cams (6) each having a bevel (18) have on their side facing the inlet slope (11) when the suction material container (1) is placed on the device body (2).

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