JP2011024611A - Electric vacuum cleaner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electric vacuum cleaner which can purify air in a whole room during cleaning of a surface to be cleaned. <P>SOLUTION: Air which passes through specific filters and is purified is discharged from an exhaust port 13 in the back of a cleaner body 2. On the other hand, an ejection port 20 which is arranged below the exhaust port 13 separates a part of the air passing through the filters and blows it out upward. In this manner, the current of air outflowing from the exhaust port 13 backward is directed upward by allowing the air blown out upward from the ejection port 20 to collide with the air discharged from the exhaust port 13 from beneath. A main suction port 32 of a suction device 6 facing the floor surface X sucks dust on the floor surface X and surrounding air. On the other hand, a sub suction port 34 facing the surface opposite to the floor surface X sucks the air which is discharged from the back of the cleaner body 2 upward and circulates in the room. In this manner, the air which passes through the filters and is purified can be spread everywhere in the room with dust Y floating in the room along with dust on the floor surface X being caught. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a vacuum cleaner.

There is known an electric vacuum cleaner capable of sucking not only dust present on a surface to be cleaned but also dust floating around (refer to Patent Document 1).
In the electric vacuum cleaner described in Patent Document 1, an electric blower is built in the main body of the vacuum cleaner, and an intake passage through which dust and air sucked by the suction force of the electric blower passes is configured in the main body of the vacuum cleaner. . The intake passage is provided with a dust collection part. Of the dust and air passing through the intake passage, dust is collected in the dust collection part, and the air is an exhaust port provided in the cleaner body. Discharged from the machine.

  The vacuum cleaner body of the electric vacuum cleaner described in Patent Document 1 is provided with a second intake passage different from the above-described intake passage (referred to as “first intake passage”). The second intake passage connects the outside of the machine and the first intake passage and is opened and closed by the shutter portion. The vacuum cleaner main body is provided with dust detection means. When the dust detection means detects dust floating in the vicinity of the cleaner body, the shutter portion opens the second intake passage, and dust floating in the vicinity of the cleaner body enters the second intake passage by the suction force of the electric blower. The air is sucked and collected by a dust collection filter provided in the second intake passage.

  Therefore, in the electric vacuum cleaner described in Patent Document 1, not only dust on the surface to be cleaned but also dust floating in the vicinity of the main body of the cleaner are collected together, so that the vicinity of the main body of the cleaner is simultaneously cleaned with the surface to be cleaned. The air can also be cleaned.

JP 2007-68676 A

In the electric vacuum cleaner described in Patent Document 1, the air in the vicinity of the cleaner body can be cleaned during cleaning of the surface to be cleaned, but not only the air in the vicinity of the cleaner body but also the air in the entire room is cleaned. It is preferable that
The present invention has been made under such a background, and a main object of the present invention is to provide a vacuum cleaner that can clean the air in the entire room during cleaning of the surface to be cleaned.

Another object of the present invention is to provide a vacuum cleaner that can reliably clean the air in the entire room.
Another object of the present invention is to provide a vacuum cleaner that can prevent a failure of the configuration for purifying air.

  According to the first aspect of the present invention, the main body of the vacuum cleaner that sucks air and dust from the intake port, captures the dust, purifies the air through a predetermined filter, and exhausts the air from the rear exhaust port, and the rear from the exhaust port. A jet outlet provided below the exhaust port for diverting a part of the air that has passed through the predetermined filter and jetting it upward so as to direct the flow of the outflowing air upward; Connected to the air inlet through a pipe or hose, in addition to the first air inlet facing the surface to be cleaned, facing the surface opposite to the surface to be cleaned, exhausted upward from the rear of the cleaner body and circulated in the room A vacuum cleaner comprising: a suction tool having a second suction port for sucking air to be performed.

The invention according to claim 2 is provided with a cord outlet provided in the vacuum cleaner main body above the jetting outlet for drawing out an electric cord from the vacuum cleaner main body. It is a vacuum cleaner of description.
A third aspect of the present invention is the electric vacuum cleaner according to the first or second aspect, further comprising a shutter disposed within the outline of the vacuum cleaner body and opening and closing the jet outlet within the outline. .

  The invention according to claim 4 is the electric vacuum cleaner according to claim 3, characterized in that the jet nozzle is formed in the contour.

  According to the first aspect of the present invention, in the vacuum cleaner main body of the electric vacuum cleaner, the air purified through the predetermined filter is exhausted from the rear exhaust port. On the other hand, a jet outlet provided below the exhaust port diverts a part of the air that has passed through a predetermined filter and jets it upward. As a result, the air ejected upward from the ejection port collides with the air exhausted from the exhaust port from below, so that the flow of air flowing out from the exhaust port can be directed upward.

And the suction tool connected to the inlet of the cleaner body via a pipe or hose has a first inlet facing the surface to be cleaned and a second inlet facing the surface opposite to the surface to be cleaned. Yes. While the first suction port sucks dust on the surface to be cleaned and the surrounding air, the second suction port sucks air that is exhausted upward from the back of the cleaner body and circulates in the room as described above. .
Thereby, in the vacuum cleaner, the air purified through the predetermined filter can be distributed in the room (indoor) while capturing the dust drifting in the room together with the dust on the surface to be cleaned. The air in the whole room can be cleaned during cleaning.

According to the second aspect of the present invention, the cleaner body is provided with the cord outlet for drawing out the electric cord from the cleaner body. Therefore, the air purified through a predetermined filter is exhausted from the cord outlet after the electric cord is cooled.
Here, since the cord outlet is provided above the jet outlet, the air jetted upward from the jet outlet collides with the air exhausted from the cord outlet from below and flows out from the cord outlet. The air flow can be directed upward in the same manner as the air flow exhausted from the exhaust port.

According to the third aspect of the present invention, since the shutter for opening and closing the ejection port is provided, when there is no need to eject air from the ejection port, the shutter closes the ejection port, so that external dust can be removed from the ejection port. Intrusion into the cleaner body can be prevented.
And since a shutter is arrange | positioned in the outline of a cleaner body, and opens and closes a jet nozzle in this outline, even if an external force is added to a cleaner body, an external force does not act on a shutter, but a shutter (air It is possible to prevent a failure of the cleaning configuration.

Further, since the jet port is located below the exhaust port, the shutter that opens and closes the jet port is also located below the exhaust port. Therefore, since the shutter is disposed away from the exhaust port, the shutter is difficult to be exposed to the air exhausted from the exhaust port, and can be smoothly opened and closed without being affected by the air exhausted from the exhaust port.
According to the fourth aspect of the present invention, since the spout is formed within the outline of the cleaner body, the spout is not blocked even if something contacts the cleaner body. Therefore, since air can be reliably ejected upward from the ejection port, the air can be circulated in the room, and the air in the entire room can be reliably cleaned.

It is a right view of the vacuum cleaner 1 which concerns on one Embodiment of this invention. It is right side sectional drawing of the cleaner body 2. FIG. It is the perspective view which looked at the vacuum cleaner main body 2 from the back side. It is right side sectional drawing of the rear side part of the cleaner body 2. FIG. It is the perspective view which looked at the suction tool 6 and its periphery in the vacuum cleaner 1 from the front side. It is the figure which applied the modification in FIG. It is an AA arrow sectional view in Drawing 6, and (a) shows the 1st example and (b) shows the 2nd example. It is BB arrow sectional drawing in FIG. 3 is a perspective view of a first filter 8. FIG. 3 is a plan sectional view of the first filter 8. FIG. It is right side sectional drawing of the cleaner body 2. FIG. 3 is a right side cross-sectional view of the first filter 8 placed on the floor surface X. FIG. (A) is a principal part right sectional drawing of the cleaner body 2 of the vacuum cleaner 1 which concerns on a modification, (b)-(d) is the principal part enlarged view of (a).

Embodiments of the present invention will be specifically described below with reference to the drawings.
FIG. 1 is a right side view of a vacuum cleaner 1 according to an embodiment of the present invention. FIG. 2 is a right side sectional view of the cleaner body 2. FIG. 3 is a perspective view of the cleaner body 2 as seen from the back side. FIG. 4 is a right sectional view of the rear portion of the cleaner body 2. FIG. 5 is a perspective view of the suction tool 6 and its periphery in the electric vacuum cleaner 1 as seen from the front side. In the following, regarding the description of the vacuum cleaner 1 and its components, for the sake of convenience, the left side in FIG. 1 will be described as the front side, the right side as the rear side, the near side as the right side, and the back side as the left side, unless otherwise specified. The left-right direction and the width direction are the same.

As shown in FIG. 1, the electric vacuum cleaner 1 includes a cleaner main body 2, a hose 3, an operation unit 4, a pipe 5, and a suction tool 6.
The vacuum cleaner main body 2 has a box shape that is slightly longitudinally rounded in the front-rear direction. The vacuum cleaner main body 2 mainly includes a casing 7 that is a hollow body that forms an outer shell thereof, and a first filter 8 and an electric blower 9 (see FIG. 2) housed in the casing 7.

  In the housing 7, an air inlet 11 is formed on the front surface 10, an exhaust port 13 is formed on the rear surface 12, and an air flow path 14 (see FIG. 7) communicates with the air inlet 11 and the air outlet 13 inside the housing 7. 2 is also defined. The first filter 8 and the electric blower 9 described above are disposed in the air flow path 14 (see FIG. 2). The first filter 8 is located on the front side of the electric blower 9, and is located on the upstream side of the electric blower 9 when viewed in the air flow direction in the air flow path 14.

Further, wheels 16 are attached to the rear portions of the left and right side surfaces 15 of the housing 7, and casters 18 are attached to the bottom surface 17 of the housing 7. The cleaner body 2 can smoothly move on the floor surface X by rotating the wheels 16 and the casters 18 on the floor surface X (surface to be cleaned).
Here, as shown in FIG. 1, the wheel 16 and the casters 18 are in contact with the floor surface X while the cleaner body 2 is in a normal posture and the bottom surface 17 of the housing 7 faces the floor surface X from above. In this state, the rear surface 12 is substantially flat along the vertical direction. On the rear surface 12, the above-described exhaust port 13 and the cord outlet 19 (see FIG. 3) are formed in the upper portion, and the jet port 20 (see FIGS. 2 and 3) is formed in the lower portion. Yes. That is, the jet nozzle 20 is provided below the exhaust port 13 and the cord outlet 19.

As shown in FIG. 3, the exhaust port 13 has a slit shape elongated in the width direction, and a plurality of the exhaust ports 13 are formed so as to be aligned vertically.
The cord outlet 19 is for drawing out an electric cord (not shown) for supplying electric power to the electric blower 9 from the inside of the housing 7 (the vacuum cleaner body 2). Here, a concave portion 12A that is recessed forward is formed at the upper right end portion of the rear surface 12 in a rear view, and the cord outlet 19 is formed in the rear surface 12 at the back of the concave portion 12A. An electric cord (not shown) passes through the cord outlet 19 when drawn out from the housing 7 or stored in the housing 7. The cord outlet 19 communicates with the air flow path 14 (see FIGS. 1 and 2). A button 35 is provided on the top surface 21 of the housing 7, and when the button 35 is pressed, an electrical cord (not shown) drawn from the housing 7 can be pulled back into the housing 7. it can.

  The jet nozzle 20 is long in the width direction and communicates with the air flow path 14 (see FIGS. 1 and 2). As shown in FIG. 2, a recess 22 that is recessed toward the front side is formed in the portion of the rear surface 12 of the housing 7 where the jet port 20 is formed in relation to the jet port 20. The recess 22 has a substantially triangular shape that narrows toward the front side when viewed from the width direction, and is elongated in the width direction (see also FIG. 3). The rear surface 12 includes an inclined surface 23 that extends to the front lower side and forms a front upper portion of the recess 22. The spout 20 forms a front lower portion of the recess 22, is exposed from the recess 22 to the rear surface 12, and faces the rear upper side.

  The jet nozzle 20 is provided with a shutter 24 that has a plate shape elongated in the width direction. The shutter 24 can be opened and closed by rotating about a shaft 25 extending in the width direction. In FIG. 1, the shutter 24 is closed so as to extend to the rear lower side, and closes the ejection port 20 from the inside of the housing 7. On the other hand, when the shutter 24 is rotated by a predetermined amount in the counterclockwise direction when viewed from the right side from the closed state, the shutter 24 opens on the inclined surface 23 so as to extend from the bottom to the front upper side and opens the ejection port 20 (FIG. 4). (Refer to the shutter 24 indicated by a broken line in FIG. 2). The shutter 24 is closed except during cleaning.

A hose 3 shown in FIG. 1 is a flexible bellows-like hose, and one end 3 </ b> A of the hose 3 is connected to the air inlet 11 so that the inside of the hose 3 and the air flow path 14 communicate with each other. .
The operation unit 4 is connected to the other end 3B of the hose 3. The operation unit 4 includes a cylindrical tube portion 26 that is directly connected to the other end 3 </ b> B of the hose 3, and a main grip 27 and a sub grip 28 that are integrally provided on the outer peripheral surface of the tube portion 26. The inside of the tube portion 26 and the inside of the hose 3 are in communication with each other. The main grip 27 and the sub grip 28 are located on the outer peripheral surface of the cylindrical portion 26 so as to be shifted from each other by about 180 ° in the circumferential direction of the outer peripheral surface, and project outward in the radial direction of the cylindrical portion 26. In FIG. 1, the main grip 27 protrudes upward, and the sub grip 28 protrudes downward. By appropriately grasping the main grip 27 and the sub grip 28, the vacuum cleaner 1 can be moved in a desired direction.

  The pipe 5 connects the operation unit 4 and the suction tool 6. The pipe 5 can be divided into an operation unit side pipe 29 and a suction tool side pipe 30 in the longitudinal direction. One end portion (rear end portion in FIG. 1) of the suction tool side pipe 30 is inserted into the operation portion side pipe 29, and one of the operation portion side pipe 29 and the suction tool side pipe 30 is connected to the other. The total length of the pipe 5 can be changed to an arbitrary length by sliding it. The inside of the pipe 5 and the inside of the cylinder portion 26 of the operation unit 4 are in communication with each other.

The suction tool 6 has a hollow box shape that is long in the width direction and slightly thin in the vertical direction. The inside of the suction tool 6 and the inside of the pipe 5 communicate with each other. Thereby, the suction tool 6 is connected to the inlet 11 of the cleaner body 2 through the pipe 5, the operation part 4, and the hose 3 (which may be either the hose 3 or the pipe 5).
In the suction tool 6, a main suction port 32 (first suction port) is formed on the bottom surface 31, and a sub suction port 34 (second suction port) is formed on the top surface 33. Both the main suction port 32 and the sub suction port 34 communicate with the inside of the suction tool 6, the main suction port 32 faces the floor surface X from above, and the sub suction port 34 extends upward (with the floor surface X). Facing the other side (see also FIG. 5).

  In such a vacuum cleaner 1, at the time of cleaning, the electric blower 9 (see FIG. 2) receives power and is driven to generate a suction force. This suction force mainly acts on the main suction port 32 in the suction tool 6. Therefore, the dust on the floor surface X (labeled Y in FIG. 5) is sucked into the suction tool 6 from the main suction port 32 by this suction force, and the suction tool 6, the pipe 5, and the operation unit. After passing through the cylindrical portion 26 and the hose 3 in this order, the air is sucked from the intake port 11 to the air flow path 14 of the cleaner body 2. Further, the air around the suction tool 6 is sucked up to the air flow path 14 together with the dust on the floor surface X.

  The air and dust sucked up to the air flow path 14 are received by the first filter 8 as indicated by thick solid arrows in FIG. At that time, dust is captured by the first filter 8, whereby air and dust are separated, and only air passes through the first filter 8 and continues to flow through the air flow path 14. The air that has passed through the first filter 8 is discharged by the electric blower 9 to the downstream side of the electric blower 9 in the air flow direction described above in the air flow path 14.

  Here, in the air flow path 14, a second filter 36 (a portion filled with dots) as a predetermined filter is provided on the downstream side of the electric blower 9 and discharged to the downstream side of the electric blower 9. The air passes through the second filter 36. The second filter 36 has a high dust capturing performance belonging to the class of so-called ULPA filters (Ultra Low Penetration Air Filter), and can capture finer dust than the first filter 8. Therefore, when air passes through the second filter 36, fine dust that could not be captured by the first filter 8 in this air is captured by the second filter 36. Thus, the air is completely cleaned by passing through the second filter 36.

  Of the air that has passed through the second filter 36, most of the air moves upward along the periphery of the electric blower 9 in the air flow path 14, toward the rear surface 12 side of the housing 7, and toward the rear from the exhaust port 13. Although it is discharged (exhaust) to the outside of the machine (see thick solid arrow), a part is exposed to an electric cord (not shown) in the casing 7 and then from the cord outlet 19 (see FIG. 3). It is discharged outside the machine. Since an electric cord (not shown) generates heat in response to supplying electric power to the electric blower 9, it is cooled by being exposed to air as described above.

  Furthermore, some of the air that has passed through the second filter 36 is diverted to the shutter 24 in the air flow path 14 without going to either the exhaust port 13 or the cord outlet 19. As a result, the shutter 24 that has been in the closed position so far is pushed open by the wind pressure of a part of the air that has passed through the second filter 36 and has reached the shutter 24 (see the thick broken line arrow), and tilts upward to the rear side. (See the shutter 24 shown by the broken line in FIG. 4). As a result, the jet outlet 20 is opened to the rear upper side, and the air that has reached the shutter 24 is jetted from the jet outlet 20 upward (in detail, rear upper side) to the outside as shown by the thick broken arrow. .

  Thus, the air discharged from the jet port 20 toward the rear upper side (see the thick broken line arrow) is discharged from the exhaust port 13 and the cord outlet 19 (see FIG. 3) to the outside of the machine (thick). Collision from the front lower side against the solid arrow). As a result, the air exhausted from the exhaust port 13 and the cord outlet 19 and flowing backward is corrected so that the flow direction is upward and flows upward as shown by a thick white arrow in FIG. Become. This exhaust of air so that it flows upward is referred to as upward exhaust. Moreover, the air (refer to the thick broken line arrow of FIG. 2) discharged | emitted from the jet nozzle 20 toward the back upper side is called an air curtain.

Here, referring to FIG. 5, the suction force generated by electric blower 9 (see FIG. 2) acts not only on main suction port 32 but also on sub suction port 34 in suction tool 6. In FIG. 5, an image of the suction force acting on the main suction port 32 is indicated by a thick black arrow, and an image of the suction force acting on the sub suction port 34 is indicated by a thick white arrow.
With the suction force acting on the sub suction port 34, referring to FIG. 1, as described above, the air exhausted upward from the exhaust port 13 and the cord outlet 19 (rear of the cleaner body 2) toward the outside of the machine. The flow direction of the air (including the air discharged from the jet outlet 20) is corrected to the forward direction, and this air flows upward in the room as indicated by the thick white arrow, and then flows from the sub suction port 34. It is sucked into the suction tool 6.

  That is, the room (room) in which the vacuum cleaner 1 is disposed by the air exhausted upward (exhaust upward) from the exhaust port 13 and the cord outlet 19 to the outside and the suction force acting on the sub suction port 34. ), An air flow Z (thick white arrow) from the exhaust port 13, the cord outlet 19 and the jet port 20 toward the sub suction port 34 is generated above the vacuum cleaner 1. As a result, the dust Y drifting in the room rides on the air flow Z and is forcibly sucked into the suction tool 6 from the sub suction port 34, so that the dust Y is filtered through the first filter 8 in the air flow path 14 of the cleaner body 2. And can be efficiently captured by the second filter 36 (see FIG. 2).

And when the dust Y drifting indoors is sucked from the sub suction port 34, the dust on the floor surface X is continuously sucked from the main suction port 32. Can inhale both dust.
Further, the air purified by the first filter 8 and the second filter 36 (see FIG. 2) after being sucked into the suction tool 6 is exhausted upward from the exhaust port 13, the cord outlet 19, and the jet port 20 to enter the room. Since it spreads, the indoor air circulates while forming the above-described flow Z, and is sucked into the sub suction port 34 of the suction tool 6 on the way, and is cleaned by the electric vacuum cleaner 1.

As described above, in the electric vacuum cleaner 1, the air purified through the first filter 8 and the second filter 36 can be distributed throughout the room while capturing the dust Y floating in the room together with the dust on the floor surface X. Therefore, the air in the entire room can be cleaned while the floor surface X is being cleaned.
In addition, since the air discharged | emitted from the inside of the air flow path 14 to the exterior is exhausted upward, it can prevent that the dust on the floor surface X soars when this air is bathed on the floor surface X.

  Referring to FIG. 2, when driving of the electric blower 9 is stopped, the electric blower 9 does not generate a suction force, so that air does not flow in the air flow path 14, so there is no air that pushes the shutter 24 open. (The wind pressure becomes weaker), and the shutter 24 closes by its own weight and closes the ejection port 20 again (see also the shutter 24 shown by a solid line in FIG. 4). Thereby, when it is not necessary to blow out air from the jet nozzle 20, it is possible to prevent external dust from entering the casing 7 from the jet nozzle 20. Moreover, in this state, since the structure in the housing | casing 7 is not exposed from the jet nozzle 20, it looks good.

Here, referring to FIG. 4, the shutter 24 that opens and closes the spout 20 will be described in detail. The shutter 24 opens and closes around the shaft 25 described above so that the rear portion rotates more than the front portion. .
The shutter 24 always rotates in the recess 22 described above when viewed from the width direction. Therefore, the rotation trajectory 37 of the shutter 24 (see the enlarged view in FIG. 4) between when it is open (see the shutter 24 shown by a broken line) and when it is closed (see the shutter 24 shown by a solid line). ) Is in the recess 22. In other words, the rotation locus 37 is on the inner side of the outer contour 38 on the rear surface 12 of the housing 7 (the vacuum cleaner body 2) in which the recess 22 is formed.

Therefore, something hits the rear surface 12 of the housing 7, the vacuum cleaner body 2 falls from the rear surface 12 side to the floor surface X (see FIG. 1), or the user steps on the vicinity of the shutter 24 on the rear surface 12. However, since the rear surface 12 receives an external force instead of the shutter 24, the shutter 24 is not damaged.
As described above, the shutter 24 is opened by wind pressure and closed by its own weight, and thus has a light thin plate shape and has a relatively low strength. Moreover, since it is not urged | biased by the spring etc. in the opening direction or the closing direction, when the attitude | position of the cleaner body 2 is changed, it may open and close arbitrarily. Therefore, if something hits the shutter 24, the shutter 24 may be damaged. However, as described above, the shutter 24 and the rotation trajectory 37 thereof are arranged in the recess 22 (that is, inside the contour 38 of the cleaner body 2), so that the shutter 24 does not hit the object. It is possible to prevent the shutter 24 from being damaged and realize a configuration in which the shutter 24 is opened and closed by wind pressure and its own weight.

Moreover, since the shutter 24 is not protruded from the rear surface 12 by disposing the shutter 24 in the recess 22, the vacuum cleaner body 2 can be downsized.
And since the jet nozzle 20 opened and closed by the shutter 24 forms the front lower side portion of the recess 22 as described above, it is recessed in the recess 22 (from the rear surface 12 of the housing 7 into the housing 7). The rear surface 12 is located below the exhaust port 13 and the cord outlet 19 (see also FIG. 3). That is, the jet port 20 and the shutter 24 are located at positions away from the exhaust port 13 and the cord outlet 19.

  Therefore, the air discharged from the exhaust port 13 and the cord outlet 19 (see the thick solid line arrow in FIG. 2) is exposed to the shutter 24 so that the rotation of the shutter 24 is not hindered. The air can be smoothly opened at a position away from the air exhausted from the exhaust port 13 and the cord outlet 19 to the outside of the machine. Thereby, since the jet nozzle 20 is open | released reliably, the upper exhaust_gas | exhaustion mentioned above can be implement | achieved reliably.

Moreover, since the jet nozzle 20 is formed inside the above-mentioned outline 38, even if something contacts the cleaner body 2, the jet nozzle 20 is not blocked. Therefore, since air can be reliably ejected upward from the ejection port 20, the air can be circulated in the room as described above, and the air in the entire room can be reliably cleaned.
FIG. 6 is a diagram in which a modification example in FIG. 4 is applied. 7 is a cross-sectional view taken along the line AA in FIG. 6, where (a) shows a first example and (b) shows a second example. 8 is a cross-sectional view taken along the line BB in FIG.

  In any of the above-described embodiments and modifications described below, a rib 39 is provided at a position on the front side of the ejection port 20 in the air flow path 14. As shown in FIG. 7, the rib 39 is thin in the front-rear direction and has a plurality of first ribs 39 </ b> A (see also FIG. 6) that are long in the width direction and extending in the vertical direction below the spout 20. And a plurality of second ribs 39 </ b> B that are long in the front-rear direction and extend vertically below the spout 20. Then, the plurality of first ribs 39A are arranged in the front-rear direction, the plurality of second ribs 39B are arranged in the width direction, and the first ribs 39A and the second ribs 39B intersect, It has a lattice shape in plan view.

  Here, referring to FIG. 8, the air discharged from the jet nozzle 20 to the outside is affected by the rotation direction of the motor included in the electric blower 9 (see FIG. 2), and is directly above in the rear view. Without being discharged, it is going to be discharged while shifting in the width direction (here, the right side in the rear view) (see thick broken line arrow). Further, in the vacuum cleaner body 2, the above-described electric cord (not shown) and a cord reel (not shown) for winding the electric cord are arranged on the left side (right side in the rear view) of the electric blower 9. Therefore, the electric blower 9 is shifted from the center in the width direction of the cleaner body 2 to the left side in the rear view. For this reason, the air discharged from the jet port 20 to the outside of the machine tends to be discharged while shifting further to the right in the rear view (see thick broken line arrows).

In this case, the air discharged from the jet port 20 to the outside of the machine is discharged while being shifted to the right side, so that the air discharged from the exhaust port 13 and the cord outlet 19 to the outside of the machine (see thick solid arrows in FIG. 2). ) Cannot effectively collide with each other, and the above-described ascending exhaust may be difficult.
However, the ribs 39, particularly the plurality of second ribs 39B arranged in the width direction, direct the air flow toward the jet outlet 20 in the air flow path 14 directly above the jet outlet 20 in the rear view. To arrange. As a result, the air discharged from the jet nozzle 20 to the outside of the machine is discharged almost directly in the rear view without being displaced while shifting in the width direction (see thick solid arrows). As a result, the air discharged from the jet port 20 to the outside of the machine can effectively collide with the air discharged from the exhaust port 13 and the cord outlet 19 to the outside of the machine, so that the above-described ascending exhaust can be realized reliably. Can do.

As shown in FIG. 6, a filter 40 is disposed on the front side of the ejection port 20 in the air flow path 14. The filter 40 is formed of a sponge or the like, and has a strip shape that is substantially the same in the width direction as the ejection port 20 and is long in the width direction (see also FIG. 7). The filter 40 is positioned by being placed on the rib 39.
The filter 40 has a role of capturing external dust that tries to enter the air flow path 14 from the spout 20 opened by the shutter 24 and jets the structure in the air flow path 14 (that is, the cleaner body 2). It also has a role of hiding so as not to be exposed to the outside from the outlet 20.

However, when the filter 40 is placed on the rib 39 so as to block the entire cross section of the air flow path 14, the filter 40 becomes resistant to the air going from the air flow path 14 to the ejection port 20. Since the momentum (ie, the above-described wind pressure) of the air going to the jet outlet 20 is weakened, the shutter 24 does not open smoothly, and the above-described ascending exhaust may be difficult.
Therefore, the filter 40 is disposed only in the front region 14A that enters the user's field of view 41 from the rear in the air flow path 14 near the ejection port 20, while the rear region 14B is not blocked by the filter 40. . Specifically, a portion of the filter 40 that matches the rear region 14B is cut away.

  Therefore, even if the air going from the air flow path 14 to the jet port 20 reaches the filter 40, it can flow smoothly from the rear region 14B not covered by the filter 40 to the jet port 20, The above-described decrease in wind pressure can be suppressed. Thereby, since the shutter 24 opens smoothly, ascending exhaust can be realized with certainty. Further, when the air flows through the rear region 14B, the rear portion 24A that rotates the most in the shutter 24 (the furthest from the rotation shaft 25) is positioned at the tip of the air, so the rear region 14B Since the air that has flowed directly hits the rear portion 24A of the shutter 24, the shutter 24 can be efficiently rotated and smoothly opened.

In this way, while the exhaust can be reliably realized, the filter 40 is located at a position that enters the user's field of view 41. Therefore, the structure in the air flow path 14 (the vacuum cleaner body 2) is the user's field of view. It does not enter 41 and looks good.
As an aspect in which the filter 40 does not block the rear region 14B of the air flow path 14, as shown in FIG. 7A, the filter 40 may not be disposed at all in the rear region 14B. As shown in (b), the filter 40 may not partially block the rear region 14B. When the filter 40 is not disposed in the rear region 14B at all (see FIG. 7A), air can flow more smoothly in the rear region 14B, while the filter 40 partially moves the rear region 14B. When there is no blockage (see FIG. 7B), since the filter 40 is also present in the rear region 14B, it is possible to reliably prevent dust from entering the air flow path 14.

FIG. 9 is a perspective view of the first filter 8. FIG. 10 is a plan sectional view of the first filter 8. FIG. 11 is a right side sectional view of the cleaner body 2. FIG. 12 is a right side sectional view of the first filter 8 placed on the floor surface X. FIG.
Next, the first filter 8 will be described in detail.
Regarding the first filter 8, the interior of the housing 7 of the cleaner body 2 includes a first chamber 43 on the front side in which the first filter 8 is accommodated by the partition wall 42, and the electric blower 9, as shown in FIG. 2. It is partitioned into a rear second chamber 44 to be accommodated. A communication port 45 is formed in the middle of the partition wall 42 in the vertical direction, and the first chamber 43 and the second chamber 44 communicate with each other through the communication port 45.

  Further, a portion of the top surface 21 of the housing 7 that coincides with the first chamber 43 in the front-rear direction forms a cover 46 that can be opened and closed. When the cover 46 is closed as shown in FIG. When the first chamber 43 is blocked from the outside and the cover 46 is open (not shown), the first chamber 43 is exposed upward. Therefore, the first filter 8 can be attached to and detached from the cleaner body 2 from above by opening the cover 46.

And the 1st filter 8 has comprised the substantially rectangular parallelepiped shape which becomes thin gradually toward the front side (refer also FIG. 9). The first filter 8 mainly includes a casing 51, a mesh filter 52, and a pleat filter 53 that form the outline of the first filter 8.
The casing 51 has a box shape that gradually narrows toward the front side, and an inlet 54 is formed in the approximate center of the front surface, and an outlet 55 is formed in almost the entire rear surface (see also FIG. 9). Both the inlet 54 and the outlet 55 communicate with the inside of the casing 51. Further, in a state where the first filter 8 is attached to the cleaner body 2, the inlet 54 communicates with the inside of the hose 3 (see FIG. 1) via the air inlet 11 of the housing 7, and the outlet 55 is It communicates with the second chamber 44 through the communication port 45 of the partition wall 42 described above. Therefore, in the first chamber 43 in which the first filter 8 is accommodated in the cleaner body 2, the inside of the casing 51 forms the air flow path 14.

Moreover, packing 61 is attached to the outer peripheral edge part (the part which borders the exit 55) of the rear surface of the casing 51 (refer also FIG. 9). Since the packing 61 is in close contact with the partition wall 42 so as to surround the communication port 45 from the front side, the sealing degree of the air flow path 14 between the first filter 8 and the partition wall 42 is increased. .
The mesh filter 52 is formed of a fine air-permeable mesh, and divides the inside of the casing 51 into a front swirl chamber 56 and a rear storage chamber 57.

  The swirl chamber 56 is formed with a swirl passage that swirls around a central axis extending in the front-rear direction, and the air that has flowed into the swirl chamber 56 from the inlet 54 in the air passage 14 is swirled in this swirl passage. The At this time, since centrifugal force is applied to the dust contained in the air, the dust is effectively separated from the air, captured by the mesh filter 52 and stored in the swirl chamber 56. The air from which the dust collection has been removed through the mesh filter 52 flows into the storage chamber 57.

  A pleated filter 53 is disposed in the storage chamber 57. The pleated filter 53 is a filter having a mountain-valley shape in which a cross-sectional shape viewed from above is alternately folded in the opposite direction and is continuous in the width direction (see FIG. 10). The pleated filter 53 allows the air that has flowed into the housing chamber 57 from the swirl chamber 56 to pass therethrough, while capturing fine dust that could not be captured by the mesh filter 52. The air that has passed through the pleated filter 53 flows into the second chamber 44 through the outlet 55 and the communication port 45 of the partition wall 42 described above, and then passes through the electric blower 9 in the second chamber 44 and then functions as described above. It is discharged outside.

As described above, in the first filter 8, relatively large dust is captured by the mesh filter 52, and relatively small dust is captured by the pleated filter 53, thereby reliably capturing the dust regardless of the size. can do.
In order to hold the pleat filter 53, the casing 51 is provided with a holder 58 as shown in FIG. The holder 58 has a bar shape that is long in the width direction and is exposed from the outlet 55 of the casing 51 and is opposed to the upper portion of the pleated filter 53 from the rear side (front side in FIG. 9).

  As shown in FIG. 10, the holder 58 has irregularities that match the ridge shape of the pleat filter 53 on the surface (front surface) facing the pleat filter 53, and has a valley shape that is recessed forward in the pleat filter 53. The pleat filter 53 is held by contacting only the deepest part (the front end part, the upper end part in FIG. 10) of each part. Thereby, since the rigidity of the pleat filter 53 is reinforced, deformation of the pleat filter 53 (particularly deformation in the width direction) is prevented. For this reason, when the air passes through the pleat filter 53, the adjacent ridges in the width direction of the pleat filter 53 are deformed and brought into close contact with each other, so that the air flow in the pleat filter 53 deteriorates or the pleat filter 53 Problems such as rapid clogging can be prevented.

  Here, referring to FIG. 2, the portion below the communication port 45 in the partition wall 42 described above of the cleaner body 2 is the lower side of the pleat filter 53 of the first filter 8 attached to the cleaner body 2. It faces the part from the rear side, and a dust removal lever 59 is attached to this part. The dust removal lever 59 can slide in the width direction by being driven by a motor or the like (not shown) built in the cleaner body 2. Further, the tip (front end) portion of the dust removal lever 59 protrudes forward to such an extent that it comes into contact with the fold peak (see FIG. 9) of the pleat filter 53. Then, when the dust removal lever 59 slides in the width direction at a predetermined timing, the tip of the dust removal lever 59 becomes a ridge of a fold of the pleat filter 53 (specifically, a resin-made material integrated with each of the ridges). Rib 60, see also FIG. Thereby, since the pleat filter 53 vibrates, the minute dust clogged in the pleat filter 53 can be peeled off from the pleat filter 53 to prevent the pleat filter 53 from being clogged.

  Here, the above-described holder 58 shown in FIG. 10 is in contact with only the deepest part (the front end part, which is the upper end part in FIG. 10) of each of the valley-shaped parts in the pleated filter 53, and therefore the pleated filter 53, the portion that is repelled by the dust removal lever 59 (the above-described portion on the rib 60 side and the rear end portion) is not held by the holder 58. Therefore, the pleat filter 53 can vibrate freely on the rib 60 side (see FIG. 9) when it is bounced by the dust removal lever 59 (see FIG. 2), so that the dust can be reliably peeled off from the pleat filter 53. it can.

  Here, referring to FIG. 9, the rib 60 integrated with each mountain of the pleated filter 53 is a plate shape that is thin in the width direction and long in the vertical direction, and a portion that is repelled by the dust removal lever 59 is a protruding portion. It becomes 60A and protrudes to the rear side. The ribs 60 are arranged in the width direction at the lower end of the outlet 55 of the casing 51 and are exposed to the outside. Therefore, when the fingertip of the user who has touched the first filter 8 reaches the lower end of the outlet 55, the rib 60 may be touched and the rib 60 may be broken at the moment. If the rib 60 is broken, the pleated filter 53 integrated with the rib 60 may be broken.

  Therefore, a protective cover 62 is attached to the casing 51. The protective cover 62 has a plate shape that is elongated in the width direction, and covers the lower portion of each rib 60 (the base portion 60B that is easily touched on the rib 60) from the outside (the front side in FIG. 9). Thereby, since each rib 60 becomes difficult to touch, it can prevent that the rib 60 breaks and the pleat filter 53 is torn. Further, even if the rib 60 is touched, the rib 60 is not easily broken compared to the case where the base portion 60B is touched because it is not the lower portion (base portion 60B) but the above-described upper protruding portion 60A.

  Further, in each rib 60, the above-described protruding portion 60 </ b> A protrudes outward (backward) from the packing 61 in the first filter 8 so as to be repelled by the dust removal lever 59 (see FIG. 2). Therefore, as shown in FIG. 12, when the first filter 8 is placed on the floor surface X so that the packing 61 side faces the floor surface X, the protrusions 60A of the ribs 60 may hit the floor surface X and be deformed. There is.

However, the protective cover 62 described above comes into contact with the floor surface X before the projecting portion 60A. Finally, in the first filter 8, only the protective cover 62 and the packing 61 are in contact with the floor surface X. Therefore, the rib 60 can be prevented from colliding with the floor surface X and being deformed.
2, when the first filter 8 is attached to and detached from the cleaner body 2 from above, the tip (front end) portion of the dust removal lever 59 is attached to the first filter 8 (particularly the packing 61) being attached / detached. A guide portion 63 shown in FIG. 11 is integrally provided on the partition wall 42 of the cleaner body 2 so as not to be caught. The guide portion 63 is substantially the same in the vertical direction as the dust removal lever 59 (see FIG. 2), and bulges forward from the partition wall 42 when viewed from the width direction. The front end of the guide part 63 is in front of the front end of the dust removal lever 59.

  Therefore, when the first filter 8 that moves substantially vertically downward to be attached to the cleaner body 2 approaches the dust removal lever 59 (see FIG. 2), the width direction of the protective cover 62 (see FIG. 9). By coming into contact with the guide portion 63 at both end portions, it shifts to the front side and avoids the dust removal lever 59 (see FIG. 2). And if the width direction both ends of the protective cover 62 get over the guide part 63, the 1st filter 8 will shift to the back side. As a result, the first filter 8 can be attached to the cleaner body 2 without being caught by the dust removal lever 59 (see FIG. 2). Since the first filter 8 is not caught by the dust removal lever 59 when being attached to the cleaner body 2, it is not caught by the dust removal lever 59 even when the first filter 8 is detached from the cleaner body 2.

  In addition, when the first filter 8 is attached to and detached from the cleaner body 2, the guide portion 63 is provided on both sides of the pleat filter 53 in the protective cover 62 described above and the casing 51 of the first filter 8 instead of the packing 61. It contacts the resin parts such as the frame 64 (see FIG. 9). Thereby, when attaching / detaching the 1st filter 8 with respect to the cleaner body 2, it can prevent that the packing 61 is damaged by the guide part 63 contacting the packing 61. FIG. Of course, as described above, when the first filter 8 is attached to and detached from the cleaner body 2, the first filter 8 is prevented from being caught by the dust removal lever 59 (see FIG. 2). It is possible to prevent the packing 61 from being damaged by coming into contact with the packing 61.

The present invention is not limited to the embodiment described above, and various modifications can be made within the scope of the claims.
Further, the modification shown in FIG. 13 can be applied to the shutter 24. In FIG. 13, (a) is a principal part right side sectional view of the vacuum cleaner main body 2 of the electric vacuum cleaner 1 according to a modification, and (b) to (d) are principal part enlarged views of (a). .

  Here, in FIG. 13, an auxiliary wing 47 that protrudes into the air flow path 14 is integrally formed at the front end portion of the lower surface 24 </ b> B facing the air flow path 14 in the shutter 24 when viewed from the width direction. Is provided. The auxiliary wing 47 has a thin plate shape elongated in the width direction. In FIG. 13A, the closed shutter 24 is inclined rearward and lower, while the auxiliary wing 47 extends forward and lower.

When such an auxiliary wing 47 is provided, the wind pressure described above changes with a change in the output of the electric blower 9 (see FIG. 2) (in other words, the wind speed of the exhaust) in a state where the shutter 24 is closed. Even so, the shutter 24 can always be opened to the maximum (maximum angle).
Specifically, when the air flowing through the air flow path 14 toward the shutter 24 as shown by a thick line arrow reaches the shutter 24 as shown in FIG. 13B, it hits the lower surface 24B of the shutter 24, as described above. Then, the shutter 24 is pushed open. At this time, if the force (air pressure described above) that pushes the shutter 24 open is strong, the shutter 24 opens quickly and reliably to the maximum (see FIG. 13D), but the wind pressure is weak. Is opened only halfway as shown in FIG. At this time, the shutter 24 is substantially parallel to the air flowing through the air flow path 14 (see the large thick arrow of the two thick arrows shown in FIG. 13C). The air (wind pressure) flowing through 14 does not effectively hit the shutter 24, and it is difficult to further open the shutter 24 from a state where it is halfway open.

  Here, a part of the air toward the shutter 24 is a wall surface 48 that defines the air flow path 14 in the cleaner body 2 as indicated by a small thick arrow of the two thick arrows shown in FIG. And flows around the front side of the shutter 24 and hits the auxiliary wing 47. At this time, since the auxiliary wing 47 is in such a posture as to resist the part of the air (not parallel to the part of the air flow), the shutter 24 is placed on the lower surface 24B. In addition, it is further pushed open by receiving the wind pressure with the auxiliary wing 47, and as a result, as shown in FIG.

DESCRIPTION OF SYMBOLS 1 Electric vacuum cleaner 2 Vacuum cleaner main body 3 Hose 5 Pipe 6 Suction tool 11 Intake port 13 Exhaust port 19 Cord outlet 20 Outlet 24 Shutter 32 Main suction port 34 Sub suction port 36 2nd filter 38 Outline X Floor surface

Claims (4)

A vacuum cleaner body that sucks air and dust from the air intake port, captures the dust, purifies the air through a predetermined filter, and exhausts it from the rear exhaust port,
Provided below the exhaust port so that the flow of air flowing backward from the exhaust port is directed upward, for diverting a part of the air that has passed through the predetermined filter and ejecting it upward. The spout of
Connected to the air inlet through a pipe or hose, in addition to the first air inlet facing the surface to be cleaned, facing the surface opposite to the surface to be cleaned, and exhausted upward from the back of the main body of the cleaner to exhaust the interior of the room A suction tool having a second suction port for sucking in circulating air;
A vacuum cleaner comprising:   2. The electric vacuum cleaner according to claim 1, further comprising a cord outlet that is provided above the jet nozzle in the main body of the vacuum cleaner and for drawing out an electric cord from the cleaner main body.   The vacuum cleaner according to claim 1, further comprising a shutter that is disposed within an outline of the vacuum cleaner body and that opens and closes the jet outlet within the outline.   The vacuum cleaner according to claim 3, wherein the jet nozzle is formed in the contour.

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