KR20120048512A - Vacuum cleaner sucker with rotary fixed sole - Google Patents

Abstract

PURPOSE: A vacuum cleaner sucker with a rotary fixed sole is provided to offer optimum suction efficiency and user convenience even if the pressure-flux torque of a vacuum cleaner changes. CONSTITUTION: A vacuum cleaner sucker(100) comprises a sole(10) and a rotation control unit. The sole is connected to a rod(20) and cleans floor at two or more air pressure-flux torque. The rotation angle of the sole is proportional to the air pressure-flux torque.

Description

Vacuum cleaner inhaler with a fixedly fixed soul {VACUUM CLEANER SUCKER WITH ROTARY FIXED SOLE}

The present invention relates generally to an inhaler of a vacuum cleaner having a sole that is rotatably moving.

In the prior art, inhalers of vacuum cleaners with a rotating sole are known for adapting in the direction of movement for cleaning. In particular, EP 1 443 842 includes one suction tube bounded by two scraping edges and in accordance with the direction of movement one edge of which contacts the bottom, which is more important. To ensure that the vacuum cleaner inhaler has a sole that can turn at a limited angle about one axis. Scraping is the mechanical action of the soul over the fur of the fibrous floor to be cleaned. As a result, the scraping edge and the inside of the sole in contact with the floor act more strongly on the carpet hair and the remaining edges are lifted off the surface of the floor in a symmetrical manner. Instead, the system has the disadvantage of causing air leaks, especially on the opposite side of the depression, so that if the leak is too large, the flow rate may not be properly distributed depending on the vacuum-pressure torque of the vacuum cleaner over the entire length of the raised edge. It will not interfere with suction efficiency. On the other hand, if the vacuum-pressure torque of the vacuum cleaner causes a strong depressurization in the suction tube, the resulting adhesion will be large and will cause insufficient forward resistance to the user since the soul will move insufficiently to slide on the floor.

The object of the present invention is to counteract the above-mentioned disadvantages of the prior art and, in particular, comprises a solely pivoting sole, and even when the pressure-flow torque of the vacuum cleaner is changed, optimum suction efficiency and ease of use are provided. To propose a vacuum cleaner inhaler to provide.

To this end a first aspect of the invention relates to a vacuum cleaner inhaler having at least two values of pressure-flow torque and comprising a sole which is adapted to clean the floor and is rotatably connected to one rod. The cleaner inhaler comprises means for limiting the rotation of the sole relative to the rod to one rotation angle α, which rotation angle α depends on the pressure-flow torque of the air. Therefore, the present invention is that the scraping edge in contact with the floor will be moved up and down to allow sliding adapted to the adhesion while scraping the floor well, so that the air flow rate under the raised scraping edge is not too high. In addition, it is possible to adjust the pivoting angle or the rotation angle of the soul according to the pressure-flow torque of the vacuum cleaner in such a manner as to ensure that it is not too small and as well as the forward resistance. As a result, the vacuum cleaner inhaler according to the present invention may be used at various pressure-flow torques while maintaining optimum cleaning efficiency and may be adapted to the performance of the vacuum cleaner being kept easy to use.

In an advantageous manner, the angle of rotation α is proportional to the pressure-flow torque of the air. In that way, as the pressure flow torque is increased, on the one hand, the opposing edges are lifted further to allow air to pass downward, and on the other hand, as much as possible so as not to exert excessively increased resistance to movement. This moves up and down.

Advantageously, the means for limiting the rotation of the soul are braking means arranged at the top of the rod and at the top of the soul. The system is simplified because the system does not interfere with other parts of the inhaler.

A particularly advantageous embodiment is provided in which the soul is provided for use at the first air pressure-flow torque of the first vacuum cleaner or is used for use with the second air pressure-flow rate of the second vacuum cleaner, and which limits the rotation of the soul. The means limit the rotation of the sole about the rod to the first angle α1 in accordance with the first air pressure-flow torque or to the second angle α2 in accordance with the second air pressure-flow torque. It is composed. Such an inhaler is very simple for all types of vacuum cleaners with different performance levels and pressure-flow torques, ensuring that cleaning is optimal with the up and down movement of the sole adapted to the vacuum cleaner and its precise pressure-flow torque. To be mounted.

Advantageously, the braking means are the same on the rod or on the soul to limit the rotation of the soul to the first angle α1 or to the second angle α2. The embodiment makes it possible to minimize deformations on the inhaler and its components in order to simplify manufacturing and reduce production costs.

Advantageously, the braking means comprise one component having a length that is rigidly mounted on the rod or on the sole and which determines the value of the angle of rotation α. Such an implementation makes it simple to adjust the value of the angle of rotation of the soul.

As an alternative to that first embodiment, the soul is provided for use at a variable air pressure-flow rate of the vacuum cleaner, and means for limiting the rotation of the soul are defined by one variable angle in accordance with the variable pressure-flow torque of the air. α) limits the rotation of the soul. In that case, the present invention makes it possible to provide one vacuum cleaner inhaler which is automatically adapted to the vacuum cleaner's operating conditions and pressure-flow torque in order to ensure the optimum efficiency of cleaning. Such an implementation omits the manual adjustment or change of the inhaler in accordance with the pressure-flow torque.

Advantageously, the means for limiting the rotation of the soul comprise one elastic element, with the strength of the elastic element being limited to a certain angle α according to the variable air pressure-flow torque. One such elastic element makes it possible to adapt the angle of rotation of the soul with flow rate at very limited cost.

Advantageously, the angle α is variable within a preset range according to the variable air pressure-flow torque, and the means for limiting the rotation of the soul limit the rotation of the soul to one maximum rotation angle αm. Braking means. The embodiment makes it possible to ensure that the soul cannot pivot above one preset value according to the maximum pressure-flow torque of the vacuum cleaner.

A second aspect of the invention relates to a vacuum cleaner comprising one vacuum cleaner inhaler according to the first aspect.

Further features and advantages of the invention will become more apparent upon reading this specification in accordance with embodiments of the invention which are not at all limited and are presented by way of example illustrated by the accompanying drawings.

1 is a side view of a vacuum cleaner inhaler according to the invention pushed forward and used at a first pressure-flow torque;
Figure 2 shows the vacuum cleaner inhaler of Figure 1 in reverse operation.
FIG. 3 shows the vacuum cleaner inhaler of FIG. 1 used at a second pressure flow torque. FIG.

1 shows the side of a vacuum cleaner inhaler 100 pushed in a forward operating direction on a floor 200 to be cleaned. The vacuum cleaner inhaler 100 mainly includes one sole 10 connected to one rod 20 connected to the rest of the vacuum cleaner by one connecting portion 40 by one rotating shaft 22. . Meanwhile, the flow rate of the sucked air passes through one flexible pipe 30 disposed between the soul and the connecting portion 40. The sole 10 can rotate about the rod 20 around the shaft 21 and includes at least one roller 50 that bears against the floor. Rotate around the axis 23 to facilitate the use of. In the forward movement of the inhaler 100, the repulsive force of the user is separated into a vertical component facing downward and a horizontal component facing forward. The roller 50 takes the vertical component on the bottom and is therefore easy to move to the user, and only the horizontal component is transferred to the sole 10. The soul, on the other hand, comprises one suction tube 13 defined by one front scraping edge 11 and one rear scraping edge 12. The scraping edges are connected to a flat or sloped surface on the inner surface of the sole 10. In order to clean the floor 200, it is important to ensure optimal efficiency of suction. For that reason, the front edge 12 is in contact with the floor to ensure scraping, but to distribute the flow rate of air sucked into the suction pipe 13 along the entire length of the rear edge 12. ) Can be pivoted around the shaft 21 in such a way that it is isolated from the bottom by a value of (d1). In the direction of such movement, one brake 14 of the sole 10 comes into contact with one arm 24 of the rod to ensure a good value d1 according to the pressure-flow torque of the vacuum cleaner. Furthermore, the adhesion force exerted on the sole 10 due to the pressure-flow torque of the vacuum cleaner rubs the scraping edge 11 over the bottom 200 and consequently a friction force against movement. In order to limit such drag which is detrimental to use, the scraping edge 11 and a part of the inner surface of the sole 10 are in contact with the floor, while maintaining proper scraping of the floor 200 while In order to distribute the contact force in accordance with the pressure-flow torque of the vacuum cleaner, a vertical movement is provided. The soul 10 comprises another brake 15 which is not in contact with the arm 24 of the rod, and the angle α1 shown shows the maximum possible pivoting for the soul 10.

2 shows the inhaler 100 for a vacuum cleaner being pulled by the user and moving towards the rear. The user simply pulls the adjustment stick backwards at the set height from the bottom, which causes the roller 50 to be lifted off the floor. In order to reach the same advantages stated above, i.e. to optimize the efficiency of suction and to minimize friction while maintaining good scraping, the sole 10 is centered on the shaft 21 to be braked on the rod 20. To pivot. Its pivoting ensures that the front scraping edge 11 adapted to the air flow rate is isolated (d2) from the floor in order to distribute air over the entire length of the front scraping edge 11 and the rear screed It is possible to ensure that the rapping edge 12 and a portion of the inner surface of the sole 10 are in contact, thereby ensuring a weak friction and good scraping depending on the adhesion generated by the vacuum-pressure torque of the vacuum cleaner. .

FIG. 3 shows the inhaler 100 of FIG. 1 modified to be capable of operating forward and optimally used at the second pressure-flow torque. Under the assumption that the inhaler 100 should be used at lower pressure-flow torque, the lifting rear scraping edge on the one hand must distribute all the flow rate over the entire length of the rear edge and on the other hand the bottom The scraping edge in contact with it must then exert a mechanical action on the floor to ensure good scraping. For this purpose, the rod 20 is deformed by adding brakes 25, 26 which limit the rotation of the sole 10 around the axis 21 to obtain the above specified results. In fact, since the brake 14 comes into contact with the additional brake 25, the sole 10 pivots at an angle α2 less than the angle α1, and the rear edge 12 distributes less air flow rate. In order to lift it to a value d3 below (d1), the front scraping edge 11 is in contact with the bottom 200 but less inclined with respect to the bottom, with the result that the mechanical action is greater. The free space between the additional brake 26 and the brake 15 of the sole 10 represents the total rotational movement of the soul 10, ie an angle α2 less than the angle α1. The addition of additional brakes 25, 26 pivots the soul to optimize the efficiency of cleaning (distribution of flow rate along the entire length of the lifted edge and scraping the bottom) while ensuring the ease of use of the vacuum cleaner. Resulted in adapting to less pressure-flow torque. The inhaler 100 for the vacuum cleaner is operated in reverse and upon movement the soul 10 will pivot in the opposite direction, the additional brake 26 will come into contact with the brake 15 and in a similar manner thanks to limited pivoting. As such, the isolation from the bottom 200 of the front scraping edge 11 and the contact of the bottom 200 of the rear scraping edge 12 will be adapted to the new pressure-flow torque.

It is to be understood that many embodiments of the invention, as set forth herein, may be devised without departing from the scope of the invention as defined by the appended claims, and that many modifications and / or improvements will be apparent to those skilled in the art.

Claims (10)

A vacuum cleaner inhaler (100) comprising at least two solenoids (10) rotatably connected to one rod (20) for cleaning the floor at at least two air pressure-flow torques. The inhaler 100 comprises means for limiting the rotation of the sole 10 at one rotational angle α with respect to the rod, wherein the rotational angle α is dependent on the pressure-flow torque value of the air. Inhaler 100 for vacuum cleaner. The inhaler (100) of claim 1, wherein the rotation angle (α) is proportional to the pressure-flow torque of the air. The inhaler (100) of claim 1 or 2, wherein the means for limiting rotation of the soul are braking means disposed on the rod and the soul. 4. The sole according to claim 1, wherein the sole 10 is to be used at the first air pressure-flow torque of the first vacuum cleaner or at the second air pressure-flow torque of the second vacuum cleaner. Means for limiting the rotation of the sole are provided around the rod at a first angle α1 in accordance with a first air pressure-flow torque or at a second angle α2 in accordance with a second air pressure-flow torque. Vacuum cleaner inhaler, characterized in that to limit the rotation of one soul. 4. The braking means according to claim 3, characterized in that the braking means are on the rod or on the soul phase or the same to limit the rotation to the first angle α1 or the second angle α2. Inhaler 100 for vacuum cleaner. 6. A component as claimed in any one of claims 3 to 5, wherein the braking means are cylindrically securely mounted on the rod or on the sole and have a length that determines the value of the angle of rotation α. Inhaler 100 for a vacuum cleaner comprising a. The sole 10 is adapted for use in a variable air pressure-flow torque of a vacuum cleaner, and means for limiting the rotation of the soul are variable in accordance with the pressure-flow torque of the variable air. Vacuum cleaner inhaler 100, characterized in that to limit the rotation of the soul at an angle (α). 8. An elastic element according to claim 7, wherein the means for limiting the rotation of the sole is limited to the rotation of the soul at an angle [alpha] varying by the strength of the elastic element, in accordance with the pressure-flow torque of the variable air. Inhaler 100 for a vacuum cleaner comprising a. 9. The method according to claim 7 or 8, wherein the angle α varies within a preset range according to the pressure-flow torque of the variable air, and means for limiting the rotation of the soul are maximum rotation. Vacuum cleaner inhaler (100), characterized in that it comprises braking means for limiting the rotation of the soul at an angle (αm). A vacuum cleaner comprising an inhaler for a vacuum cleaner according to any one of claims 1 to 9.

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