KR20010059857A - recirculating type vacuum cleaner - Google Patents

Abstract

PURPOSE: A ventilation reflux type vacuum cleaner is provided to lengthen the life of a motor and to prevent the motor from being deteriorated by more efficiently radiating heat from the motor. CONSTITUTION: A body(310) of a ventilation reflux type vacuum cleaner contains a motor(312) in which a fan(311) is combined with a shaft(312a), a dust collecting bag(313) and a dividing part(314) between the fan and motor to prevent the flow of air. The motor is a biaxial motor and the other shaft(312b) of the motor is combined with a belt(315) to rotate a rotating brush(323) of a suction body(320). A first space(316) divided by the dividing part has a reflux passage(340) to guide air to the suction body without passing through the motor and a second space(317) has a cooling passage(350) to be communicated with indoor air. The cooling passage contains a passage guide(353) to form a suction cooling passage(351) and a discharge cooling passage(352). A blower fan(360) of the vacuum cleaner body is combined with a shaft(312b). An injection port(324) is connected to the reflux passage at the bottom of the suction body. A suction port(321) is connected to one end of a suction passage(322) and the dust collecting bag is connected to the other end of the suction passage.

Description

Recirculating type vacuum cleaner

The present invention relates to a vacuum cleaner, and more particularly, to a reflux reflux vacuum cleaner that can prevent indoor pollution by reusing air discharged by dust collection in a vacuum cleaner.

In general, vacuum cleaners can be roughly classified into canister type vacuum cleaners and up-right type vacuum cleaners.

Unlike the canister type cleaner, the upright cleaner is a vacuum cleaner mainly used in a wide area such as a living room, especially a place where a carpet is laid, and the overall structure thereof will be described later.

1 and 2a and 2b illustrate a general upright type vacuum cleaner as described above, and a main body 10 which is built up vertically and coupled to a lower portion of the main body to suck various foreign substances such as dust and the like. It consists of a suction port body 20, the suction port 21 is formed, and the handle portion 30 is connected to the upper end of the main body.

At this time, the fan 12 is axially coupled to the lower part of the main body is provided to rotate the fan 11 to generate a vacuum force, the upper in the main body inlet 20 A dust collecting bag 13 is provided to collect the air sucked through and various foreign matters, and in front of the main body, the air sucked into the main body 10 and passed through the dust collecting bag 13 is discharged to the outside of the main body. The discharge hole 14 is formed to be.

In addition, a suction passage 22 is formed inside the suction port 20 to guide the flow of various dust and air sucked through the suction port 21, and one end of the suction passage has a dust collecting bag in the main body 10. It is connected to the suction hose 15 in communication with (13).

At the position where the suction port 21 of the suction port 20 is formed, a rotating brush 23 partially exposed through the bottom surface thereof is rotatably installed, and the rotating brush includes a motor 12 provided in the main body 10. It is connected to the shaft (12b) of the belt 16 as a drive force is transmitted.

At this time, the motor can transmit the driving force to the fan 11 and the belt 16 provided in the main body 10, respectively, as the shaft 12a, 12b is composed of a biaxial motor protruding to both sides thereof. It is understandable.

The operation of the upright type vacuum cleaner configured as described above will be described below in more detail.

First, if you want to perform the cleaning of the carpet according to the user's needs, using the handle 30 to place the main body 10 in the cleaning performing place.

Thereafter, the user drives the motor 12 in the main body 10 by turning on a switch (not shown) provided on the side of the main body.

Accordingly, the fan 11 coupled to the motor and the shaft 12a receives the driving force of the motor and rotates to generate suction force, and the suction force passes through the dust collecting bag 13 in the main body 10 and the suction hose. Is passed to (15).

As a result, the suction force transmitted through the suction hose is transferred to the ground through the suction port 21 formed in the suction port 20 to perform the cleaning of various foreign substances on the ground.

In addition, at this time, the rotary brush 23 installed at the suction port is also connected to the motor 12 and the belt 16 provided in the main body 10 so as to receive and rotate the driving force of the motor.

Accordingly, the rotary brush 23 positioned in front of the suction port 20 sweeps the ground (carpet surface) while rotating to float various foreign matters attached to the ground, and the various foreign matters suspended in this way are sucked in the suction port. After being introduced into the suction passage 22 through the passage 21, the suction hose 15 passes through the suction hose 15 and is introduced into the dust collecting bag 13 together with the air.

In addition, various foreign matters having relatively large particles among the air and various foreign matters introduced into the dust collecting bag 13 as described above are collected in the dust collecting bag, and only the air whose particles are considerably small is the dust collecting bag 13. After passing through the discharge through the discharge hole 14 formed in the main body 10 to the outside.

As a result, the cleaning as described above is carried out continuously and repeatedly.

However, according to the conventional general upright type vacuum cleaner as described above, since the air used for cleaning passes through the dust collecting bag 13 and is discharged back into the room, the smell and various kinds of dust generated from the various dust collected in the dust collecting bag. The bacteria also had to be discharged into the room through the dust collecting bag 13 together with the air.

As a result, the indoor air may be contaminated, which may cause a user's hygiene problem, resulting in a decrease in reliability of the user's product.

3 is a schematic internal configuration of an upright cleaner showing a state in which an exhaust reflux method is adopted to solve the problem.

That is, the reflux passage 40 is formed so as to close the discharge hole formed in the main body, and the air that radiates the motor 12 to the inlet body 20 again.

Accordingly, the exhaust air containing various odors and bacteria while passing through the dust collecting bag 13 is sequentially passed through the motor 12 and the reflux flow passage 40 to be discharged to the bottom surface of the suction port 20, and thus discharged. The exhaust air is again sucked by the suction force transmitted through the suction port 21 of the suction port 20 to continue the circulation.

However, the vacuum cleaner using this type of exhaust reflux method has a structure in which the cooling of the motor 12 is performed by using the exhaust air continuously refluxed, but in general, the temperature of the air passing through the motor 12 is increased. In view of the fact that the exhaust gas is gradually cooled due to the continuous reflux, the motor 12 can no longer be cooled for some time and eventually the winding 12c of the motor 12 has to be overheated.

This causes a drastic deterioration of the motor performance, which in turn causes a problem that the cleaning efficiency of the vacuum cleaner also deteriorates.

4 is a canister type vacuum cleaner to which the exhaust reflux method is applied, and 20% of the exhaust air that is refluxed is configured to prevent hygienic problems and motor overheating as described above. It is discharged into the room, and the structure is configured to allow the reflux by suctioning the amount of the discharged air again.

That is, the dust collecting bag 113 and the motor 112 in the main body 110, respectively, and the air passing through the motor to be injected toward the inlet port 121 formed on the bottom surface of the suction port 120 again. 140 is formed, and the exhaust port 118 is formed on the rear surface of the main body which is the rear side of the motor.

At this time, by forming the injection port 124 to correspond to the suction port 121 on the front side of the bottom of the suction port body, air flowing through the reflux flow path 140 can be injected to the bottom surface of the suction port body 120 through the injection port. Yes it is possible.

By such a structure, air and various odor components or bacteria (hereinafter, referred to as “exhaust air”) passing through the dust collecting bag 113 in the main body 110 are not directly discharged to the outside of the cleaner first, the main body 110. The inner side of the motor 112 is provided to cool the motor 112, and subsequently the air cooled by the motor flows under the guidance of the reflux flow path 140, the injection hole 124 formed in the inlet body 120 Inject through the suction inlet 120 bottom surface front.

Thereafter, the exhaust air injected to the bottom surface of the inlet port 120 as described above receives the suction force generated continuously through the inlet port 121 of the inlet port, is sucked into the inlet port, and continues to be reintroduced into the main body 110. The reflux of the air is made to achieve the effect that the indoor discharge of odors and bacteria generated from various pollutants can be prevented.

In this case, as the exhaust port 118 is formed in the space in which the motor 112 of the main body 110 is located, approximately 20% of exhaust air, which is a part of the exhaust air passing through the motor 112, is exhausted. The new air is discharged to the outside of the cleaner through the exhaust port 118, and the new air is discharged through the suction port 121 formed in the suction port 120 to reduce the temperature of the refluxed air.

Accordingly, it can be understood that the heat dissipation effect of the motor can be better.

However, such a structure also has to re-induce indoor pollution, which is an inherent problem, as it is discharged together with various smells and bacteria in the exhaust air.

In addition, the above-described structure, that is, the structure of heat dissipating the motor by the inflow of indoor air due to 20% exhaust air discharge, considering the current trend of increasing the capacity, the larger the size of the motor, the effect will only be limited to a slight degree, after all, In order to selectively drive or stop the motor 112, a structure in which a thermostat (not shown) was mounted around the motor had to be added.

However, such a structure also prevents overheating of the motor winding 112c to some extent, but since the cleaning is not performed when the cleaning of the batch is performed, that is, when the driving of the motor is stopped, the inconvenience of the user may increase. There are only a number of problems.

The vacuum cleaner shown in Fig. 5, which is the invention described in US Pat. No. 5,574,48, adopts the exhaust reflux method as described above, wherein 20% of the refluxed air is configured to be replaced with new air and the suction efficiency The structure is improved.

That is, a separate bypass valve 241 is provided on the reflux flow path 240 so that the opening and closing degree is appropriately adjusted according to the suction efficiency, and the position of the injection hole 224 connected to the reflux flow path is the suction port 220. Protrudes through the suction port 221 so as to be positioned in the area S where suction is to be made.

Therefore, when the air and various dusts are introduced by the operation of the first cleaner, the bypass valve 241 formed on the reflux flow path 240 is in a closed state so that the reflux of the exhaust air is 100%.

In addition, when the pressure of the inlet 221 is increased in the process of repeating the above process, the bypass valve is opened so that some of the exhaust air is discharged into the room through the open exhaust port 218. The amount of the discharged air is newly introduced through the inlet 221 formed in the inlet body 220.

Due to this, not only the heat dissipation effect of the motor 212 can be maintained, but also the indoor pollution due to the discharged air can be prevented to the maximum.

However, this type is also weak, but the contamination of the room is made continuously, causing consumer dissatisfaction. Especially, the motor overheating occurs again when the cleaner is used for a long time because the motor heat dissipation effect is not excellent. There was no choice but to.

In addition, when using a large-capacity motor, as described above, the newly introduced air alone is inadequate enough to prevent overheating of the motor, thereby causing a limitation in an application field in which only a small-capacity motor must be used. Was done.

However, even if applied only to a small capacity motor, the overheating problem of the motor cannot be completely solved.

The present invention has been made to solve the conventional problems as described above, so that the heat dissipation of the motor constituting the exhaust reflux vacuum cleaner can be made more smoothly to prevent the extension of the life of the motor and deterioration of performance in advance. The purpose is.

1 is a perspective view showing a general upright cleaner

FIG. 2A is a cross-sectional view illustrating the line II of FIG. 1. FIG.

2B is a cross-sectional view of the II-II line of FIG. 1.

3 is a schematic view showing an exhaust reflux method of a general vacuum cleaner

Figure 4 is a perspective view schematically showing a canister cleaner to which a conventional exhaust reflux method is applied

5 is a cross-sectional view showing another type of cleaner to which the conventional exhaust reflux method is applied.

6 is a schematic view showing an exhaust reflux method of a vacuum cleaner according to the present invention;

Figure 7 is a longitudinal cross-sectional view showing a state in which the exhaust reflux method according to the invention applied to the upright vacuum cleaner

FIG. 8 is a cross-sectional view illustrating a line III-III of FIG. 7.

Explanation of symbols for main parts of the drawings

311.Fan 312.Motor

313. Dust collection bag 314. Compartment

316. First space 317. Second space

320. Inlet port 321. Inlet port

322. Suction channel 324. Injection port

340. Reflux flow path 350. Cooling flow path

353.Euro Guide 360.Blowing Fan

According to an aspect of the present invention for achieving the above object is to install a motor axially coupled to the fan in each of the main body, the partition between the fan and the motor so as not to make the air flow between each other, the motor is located A cooling passage is formed in the space portion of the side to communicate with the room, and a reflux passage is formed in the space portion of the side where the fan is located to guide the flow of air to the suction inlet. A suction port is formed to be connected to the suction channel so that indoor air and various foreign substances are sucked together, and the other end of the suction channel is connected to the air inlet side of the dust collecting bag, and the air exhausted through the dust collecting bag is sucked in. By reflowing through the exhaust reflux vacuum cleaner, characterized in that the continuous reflux can be made Is provided.

6 is a schematic view showing the exhaust reflux method of the vacuum cleaner according to the present invention, Figure 7 is a longitudinal cross-sectional view showing a state in which the exhaust reflux method according to the present invention is applied to the upright vacuum cleaner, Figure 8 7 is a cross-sectional view illustrating the III-III line of FIG. 7.

Referring to this in more detail the structure according to an embodiment of the present invention.

First, the present invention seats the motor 312 and the dust collecting bag 313, the fan 311 is coupled to the shaft 312a in the main body 310, respectively, so that the air flow between the fan and the motor is not made to each other The partition 314 is provided.

At this time, the motor is a biaxial motor, the shaft 312a protruding to one side thereof is coupled with the fan 311 as described above, and the shaft 312b protruding to the other side rotates provided in the suction port 320. It is coupled with the belt 315 to rotate the brush 323.

In addition, in each of the space portions 316 and 317 partitioned by the partition portion 314, the first space portion 316 on the side where the fan 311 is located does not directly pass through the motor 311, but directly intakes 320 A reflux flow path 340 is formed to guide the flow of air to the air), and a cooling flow path 350 is formed in the second space part 317 on the side where the motor is located so as to communicate with the room.

In the above, the cooling passage 350 is divided into a suction cooling passage 351 in which indoor air is sucked to the side where the motor 312 is located, and an exhaust cooling passage 352 in which the indoor air cooled by the motor 312 is discharged. The flow path guide 353 is formed to be formed in a state.

In addition, a blowing fan 360 is provided on the second space part 317 in the main body 310 in which the motor is located.

At this time, the blowing fan is preferably coupled to the shaft 312b to which the belt 315 is connected among the shafts 312a and 312b provided in the motor 312.

The blower fan may be separately provided to receive the driving force by other driving means without being axially coupled to the motor 312 as described above. Due to the simpler structure is to ensure that the effect can be sufficiently obtained.

In addition, the bottom surface of the inlet port 320 is formed with an injection port 324 connected to the reflux flow channel 340 and the inlet port 321 connected to one end of the suction channel 322 to suck the indoor air and various foreign matters. , The other end of the suction passage is connected to the air inlet side of the dust collecting bag (313).

Such a configuration of the present invention is to separate the reflux air flow path that repeats the intake, exhaust, and reflux with the cooling air flow path that simply cools only the motor. Applied.

Hereinafter, the operation according to the embodiment of the present invention configured as described above will be described in detail.

First, when power is supplied to the cleaner according to the user's needs, the motor 312 is driven.

Accordingly, the fan 311 provided on one side of the motor rotates to generate suction force, and the suction force is connected to the suction passage 320 through the dust collecting bag 313 and the suction passage 322. By being delivered to the suction port 321, the foreign matter and air, such as various dust in the room, are sucked through the suction port.

Various foreign matters and indoor air sucked into the main body 310 through the suction port 320 by the above process are introduced into the dust collecting bag 313 provided in the main body, and then various foreign matters are collected by the dust collecting bag. At the same time as the dust is collected, the indoor air receives a continuous suction force generated from the fan 311, and passes through the inner space of the main body in which the dust collecting bag and the dust collecting bag are seated, in the first space 316 in which the fan 311 is located. Will flow toward.

At this time, the first space portion is partitioned from the second space portion 317 where the motor 312 is located by the partition portion 314, the first space portion injection port 321 of the suction port 320 Exhaust air introduced into the first space part 316 as one end of the reflux flow path 340 connected to the reflux flow path 340 does not pass through the second space part 317 in which the motor 312 is located. Straight through the outlet port 320 is discharged to the side where it is located.

This is not only to prevent the refluxed air from affecting the motor, but also to prevent the heat generated from the winding 312c of the motor 312 from being transferred to the refluxed air according to the driving of the motor.

As a result, the reflux air discharged to the suction port 320 is injected into the bottom surface of the suction port 320, that is, the ground through the injection hole 324 formed in the suction port, and the injected reflux air is suctioned. Through the suction port 321 formed on the bottom of the sphere receives the suction force generated continuously to be re-absorbed to achieve a continuous reflux.

On the other hand, in the above process, although the refluxed air does not pass through the motor 312, there is a concern that the performance of the motor 312 may be reduced due to the heat generated from the winding 312c of the motor, which is the motor 312 Can be solved by the configuration of the present invention configured to dissipate only the heat generated.

That is, since the second space part 317 where the motor is located is in communication with the room by the cooling flow path 350, the air in the room is introduced into the second space part 317 during the process of driving the motor 312. The heat is continuously radiated by the motor.

In addition, although not shown in FIG. 7, the shaft 312b of the motor 312 positioned in the second space part may be more smoothly discharged from the motor 312 using indoor air as shown in FIG. 6. As the blowing fan 360 is additionally installed, indoor air can be forcedly blown into the winding 312c inside the motor.

At this time, the flow path guide 353 is provided inside the motor to partition the suction cooling passage 351 through which the indoor air is sucked and the discharge cooling passage 352 through which the indoor air cooled by the winding of the motor 312c is discharged. As the indoor air forcedly blown by the blower fan 360 described above is configured to flow to the suction cooling flow path, the motor 312 may be cooled more smoothly.

As a result, according to the configuration of the present invention as described above and the action made due to the configuration of the present invention, the reflux air is continuously refluxed 100%, the motor is a smooth heat dissipation as a separate cooling air.

On the other hand, the present invention is not a technology that can be applied only to the upright cleaner described as an embodiment.

In other words, the canister cleaner can be applied sufficiently, and this can be said to be a useful invention that can be easily performed by anyone skilled in the art.

As described above, the present invention improves the structure of the exhaust reflux vacuum cleaner so that the refluxed exhaust air is continuously refluxed so that various odor components and bacteria flowing in the state contained in the exhaust air are discharged back into the room. It is possible to solve the problems caused by hygiene is effective.

In addition, the overheating of the motor generated during the above process also has a structure that allows only the motor to be cooled separately, there is an effect that can be solved at the same time the problem caused by the overheating of the motor.

The effects as described above not only enable the use of a large-capacity motor for each type of vacuum cleaner, but also allow the continuous cleaning to be carried out in a stable state, thereby achieving an effect of improving user reliability. .

Claims (1)

Each of the motors with a fan shaft coupled to the body, A partition is installed between the fan and the motor so as not to mutually flow air. In the space portion of the side where the motor is located to form a cooling flow path to communicate with the room, The cooling passage is provided with a blowing fan that rotates by receiving the driving force of the motor, In the space portion of the side where the fan is located to form a reflux flow path for guiding the flow of air to the inlet port, On the bottom surface of the inlet port to form a spray port connected to the reflux flow path and the suction port connected to the suction flow path to suck the indoor air and various foreign matters, The other end of the suction passage is connected to the air inlet side of the dust collecting bag exhaust reflux type vacuum cleaner, characterized in that the exhaust gas is passed through the dust collecting bag to be re-introduced through the inlet continuously.