DE10056933A1 - Cooling system for vacuum cleaner includes a cooling chamber housing a cooling fan driven by the main motor, the fan is sucking in external air, which is then discharged in the outlet path via the outlet passage - Google Patents

Abstract

The vacuum cleaner uses a sucking rotor (130) placed close to the motor (140) and driven by that motor. The air enters via the brush intake (151) and progresses along the intake path (101). The exhaust path (102) leads to the brush outlet (152). The cooling chamber (210) is housing a cooling fan (230) driven by the motor (140). The fan is sucking in external air, which is discharged in the outlet path (102) via the outlet passage (214).

Description

The present invention relates to a vacuum cleaner and in particular an exhaust air backflow vacuum cleaner, which in the Is able to use an impeller motor used in it Use of outside air by a cooling fan is sucked in to cool.

In general, a vacuum cleaner collects foreign matter, such as z. B. dust, etc. by sucking in ambient air Cleaning surface and exhaust of the sucked-in air, while removing foreign matter with a dust bag and filters an exhaust air filter. Because such Vacuum cleaner lets out exhaust air with bad smell, there was a problem in that a user entered a feels uncomfortable when using the vacuum cleaner. To fix such a problem of a vacuum cleaner, was a so-called backflow vacuum cleaner proposed. The The purpose of the backflow vacuum cleaner is to basically to prevent the spread of bad smell by sucking in the air coming out of the Vacuum cleaner body flows out, d. H. by circulating the Air.  

Fig. 1 shows an example of such a conventional backflow vacuum cleaner comprising a body 10 having a suction passage 11 and an exhaust passage 12, a dust collecting chamber 13, which is located in the suction passage 11, and an impeller 14 which is rotated by a motor 15, a connecting pipe 20 having a suction pipe 21 and an outlet pipe 22 connected to the suction and outlet passages 11 and 12 , respectively, and a brush 23 formed at one end of the connecting pipe 20 .

In the conventional reverse flow vacuum cleaner constructed as above, ambient air in the area of the cleaning surface is sucked in by the rotation of the motor 15 and the impeller 14 through the brush 23 . After it has been sucked in, the air is passed through the suction pipe 21 of the connecting pipe 20 and the dust collection bag 13 , while the foreign substances, such as. B. dust or dirt, collected by the dust collection bag 13 and filtered.

After the foreign matters have been filtered out by the dust collecting bag 13 , the air is discharged through the outlet passage 12 , the outlet pipe 22 and the brush 23 . The exhausted air is then sucked in again by the brush 23 together with the surrounding dust or dirt around the brush 23 .

However, the conventional reverse flow vacuum cleaner has a structure in which the air sucked in by the brush cools the motor 15 during its circulation. Here, when the air is exposed to the heat of the drive motor 15 , the air is heated. And when the heated air is sucked back into the vacuum cleaner, the cooling efficiency deteriorates more and more. If the vacuum cleaner is operated for a long period of time, the operational efficiency of the vacuum cleaner deteriorates more severely due to the heated motor 15 . As a result, the suction of the brush also deteriorates, which worsens the performance and effectiveness of the vacuum cleaner.

It is therefore an object of the present invention to Backflow vacuum cleaner with an improved Cleaning performance and effectiveness through an improved Cooling efficiency of an engine due to an improved Circulation path of the air caused by the torque of the Motors is sucked into and out of the vacuum cleaner emanates to provide.

The above object is achieved by an inventive Reverse flow vacuum cleaner solved, which an impeller, which in a vacuum cleaner body is built in so that it can be Engine is turned; one suction passage and one Outlet passage connected to the vacuum cleaner body are to determine a circulation path of air, the is sucked in by a rotational force of the impeller; on Connecting pipe with a suction pipe and one Exhaust pipe, which with the suction or Outlet passage are connected; a suction brush that with the connecting pipe is connected; and a cooling section that is provided between the suction and outlet passages, for cooling the engine.

The cooling part comprises a cooling chamber with a partition, an interior of the same in a first room and divided a second space so that the impeller in first room is arranged and the engine in the second room is arranged; a cooling fan located in the second room located, facing the impeller and the motor is connected to outside air towards the engine and the Suck in the impeller; a grid that on Vacuum cleaner body arranged according to the cooling fan with a plurality of holes in the grid are trained; and a first outlet pipe and a second  Outlet pipe, which are located in the first or second room, to deflate the air caused by the impeller and the Cooling fan is sucked in.

An embodiment of the invention is shown below explained in more detail with reference to the drawing. Show it:

Fig. 1 is a schematic view of a conventional reverse flow vacuum cleaner;

Fig. 2 is a schematic view of a backflow vacuum cleaner according to the invention; and

Fig. 3 is a schematic sectional view of the main part of the present invention, a drive motor cooling member that is, from FIG. 2.

As shown in Figs. 2 and 3, a backflow vacuum cleaner according to the present invention includes a body 100 having a suction passage 101 and an outlet passage 102 , a dust collecting chamber 120 located in the suction passage 101 , and an impeller 130 rotated by a motor 140 , a connecting pipe 160 connected to the body 100 and having a suction pipe 161 and an outlet pipe 162 connected to the suction and outlet passages 101 and 102 , a brush 150 formed at one end of the connecting pipe 160 , and a cooling part 200 which is provided between the suction and outlet passages 101 and 102 to cool down the temperature of the engine 140 .

Fig. 3 shows the cooling part 200, which is the unique feature of the present invention, with a cooling chamber 210 formed between the suction and the exhaust passage 101 and 102, while accommodating the impeller 130 and the motor 140, a cooling fan 230 which is arranged in the cooling chamber 210 to be rotated by the motor 140 , and a grill 250 which is arranged on a vacuum cleaner body 100 corresponding to the cooling fan 230 and in which a plurality of holes 251 are formed. Here, reference numeral 121 refers to a dust collection bag, which the foreign matter such. B. dust or dirt from the sucked air.

According to the present invention, the cooling chamber 210 comprises a partition wall 201 which divides the interior spaces of the cooling chamber 210 into a first and a second space 211 and 212 . The impeller 130 and the motor 140 are supported on the partition 201 in such a way that the impeller 130 is arranged in the first space 211 , whereas the motor 140 is arranged in the second space 212 . Furthermore, the cooling fan 230 is located in the second space 212 to be rotated by the motor 140 and to suck in the outside air through the holes 251 of the grille 250 .

Meanwhile, the first and second spaces 211 and 212 are connected to the outlet passage 102 through the first and second outlet pipes 213 and 214 , respectively. Since the first exhaust pipe 213 passes through the second exhaust pipe 214 here, the air from the first and second exhaust pipes 213 and 214 unites in the exhaust passage 102 .

According to the present invention, it is preferable that the second outlet pipe 214 has a larger diameter than that of the first outlet pipe 213 .

When the vacuum cleaner is operated, in the reverse flow vacuum cleaner according to the invention constructed as above, ambient air in the area of the cleaning surface is sucked in through a suction passage 151 of the brush 150 with a high suction force, which is generated by the rotation of the motor 140 and the impeller 130 . After it is sucked in, the air flows through the suction pipe 161 of the connecting pipe 160 and to the dust collection bag 121 , where the foreign matter, such as e.g. B. dust or dirt, the air can be collected and filtered.

After the foreign matters are filtered out by the dust collecting bag 121 , the clean air flows out of the vacuum cleaner via the first space 211 and the first outlet pipe 213 of the cooling chamber 210 , the outlet passage 102 , the outlet pipe 162 of the connecting pipe 160 and the outlet passage 152 of the brush 150 . When the air once discharged is sucked in again, the air together with foreign matter near the brush 150 is sucked in through the suction passage 151 of the brush 150 and circulates in the above-mentioned way.

Meanwhile, according to the present invention, when the cooling fan 230 is rotated together with the impeller 130 , the outside air is sucked in through the holes 251 of the grille 250 arranged on the vacuum cleaner body 100 . After being sucked in, the outside air flows into the second space 212 of the cooling chamber 210 , which cools the engine 140 . Then, the air flows through the second outlet pipe 214 into the outlet passage 102 and combines with the air flowing out of the first outlet pipe 213 . The combined air then flows through the outlet passage 102 and the outlet pipe 162 of the connecting pipe 160 and flows out through an outlet passage 152 of the brush 150 . The air flowing out of the body 100 is sucked back in together with the foreign matter through the suction passage 151 of the brush 150 and circulates in the above-mentioned way.

As described above, in the reverse flow vacuum cleaner with an air circulation according to the invention, the air circulation paths for the cleaning process and the engine cooling process are defined separately. As a result, the air drawn in by the brush 150 for the cleaning process cannot basically be exposed to the heated motor 140 during its circulation. Since the outside air is continuously supplied through the cooling fan 230 via a separate circulation path in order to cool the motor 140 , the heating of the motor is also fundamentally prevented.

In the reverse flow vacuum cleaner according to the invention separate determination of the air circulation paths for the Cleaning process and the engine cooling process, d. H. by separate circulation of those sucked in by the brush Air for the cleaning process and through the cooling fan sucked in air for the engine cooling process, the heating of the engine, and the cleaning performance and -effectiveness will be significantly improved.

As indicated above, it became a preferred one Embodiment of the present invention shown and described. Although the preferred embodiment of the present invention, it is of course, that the present invention is not based on this preferred embodiment may be limited should, but that various changes and Modifications within the spirit and scope the invention claimed below by a person skilled in the art can be made.

Claims (4)

1. Backflow vacuum cleaner which comprises:
an impeller ( 130 ) installed in a vacuum cleaner body ( 100 ) to be rotated by a motor ( 140 );
a suction passage ( 101 ) and an outlet passage ( 102 ) connected to the vacuum cleaner body ( 100 ) for setting a circulation path of air sucked in by the rotating force of the impeller ( 130 );
a connecting pipe ( 160 ) having a suction pipe ( 161 ) and an outlet pipe ( 162 ) connected to the suction and outlet passages, respectively;
a suction brush ( 150 ) connected to the connecting pipe ( 160 ); and
a coolant ( 200 ), which is provided between the suction and the outlet passage ( 101 , 102 ), for cooling the engine. 2. A vacuum cleaner according to claim 1, wherein the coolant ( 200 ) comprises:
a cooling chamber ( 210 ) with a partition ( 201 ) which divides an interior thereof into a first space ( 211 ) and a second space ( 212 ) such that the impeller ( 130 ) is arranged in the first space ( 211 ) and the motor ( 140 ) is arranged in the second room ( 212 );
a cooling fan ( 230 ) located in the second space ( 212 ) facing the impeller ( 130 ) and connected to the motor ( 140 ) for drawing in outside air toward the motor and the impeller;
a grille ( 250 ) disposed on the vacuum cleaner body ( 100 ) corresponding to the cooling fan ( 230 ), a plurality of holes ( 251 ) being formed in the grille; and
a first exhaust pipe ( 213 ) and a second exhaust pipe ( 214 ) located in the first and second spaces ( 211 , 212 ), respectively, for exhausting the air drawn in by the impeller ( 130 ) and the cooling fan ( 230 ). 3. A vacuum cleaner according to claim 2, wherein the air flows first through the second outlet pipe ( 214 ) such that the air discharged from the first and second outlet pipes combines into a common flow. 4. Vacuum cleaner according to either claim 2 or claim 3, wherein the second outlet pipe ( 214 ) has a larger diameter than that of the first outlet pipe ( 213 ).