JP5313067B2 - Electric vacuum cleaner - Google Patents

Description

  The present invention relates to a vacuum cleaner.

  Conventionally, a vacuum cleaner generates air intake by an electric blower and sucks dust on the surface of an object to be cleaned into the vacuum cleaner together with surrounding air. The dust sucked into the electric vacuum cleaner is removed from the intake air by a filter in the dust collection chamber, or is separated from the intake air by turning the intake air.

  In a vacuum cleaner, members constituting an intake passage through which intake air passes are charged by friction with intake air. Further, the dust is charged by the friction between the intake air and the dust. In particular, in a vacuum cleaner that swirls the intake air to separate the intake air and dust, the intake air swirls along the inner peripheral wall surface of the dust collection chamber, so that the dust collection chamber is easily charged. In addition, since the dust charged by friction with the intake air also rotates in the dust collection chamber together with the intake air, the dust collection chamber is also charged when the charged dust contacts.

  When the dust collection chamber or dust inside the dust collection chamber is charged, the following problems may occur. That is, when the vacuum cleaner user discards the dust accumulated in the dust collection chamber, the dust adheres to the dust collection chamber and is not easily disposed of, or the dust jumps out of the dust collection chamber. May scatter around.

  In order to prevent the dust and the dust collection chamber from being charged, for example, it is conceivable to supply ions to the intake air. The following vacuum cleaners have been proposed as vacuum cleaners that supply ions to the intake air.

  Japanese Patent Laying-Open No. 2004-194977 (Patent Document 1) describes a vacuum cleaner including an adapter that is attached to a suction port of a vacuum cleaner main body instead of a dust suction hose when cleaning is not performed. This adapter incorporates a negative ion generator. When the electric blower of the cleaner is driven in a state where the adapter is attached to the suction port of the cleaner body, negative ions are supplied into the cleaner body together with the airflow passing through the adapter. In addition, the air path of the adapter is restricted by the air path restriction, and the speed of the airflow passing through the adapter can be made higher than the speed of the airflow during normal cleaning. With this air flow, the dust film attached to the filter is peeled off. Moreover, since negative ions are supplied together with this air flow, the charging of the filter is neutralized to facilitate the removal of dust.

  Japanese Patent Laying-Open No. 2003-153831 (Patent Document 2) describes a vacuum cleaner including an ion generator capable of generating positive ions or negative ions. In this electric vacuum cleaner, the ion generator is installed in the middle of the intake passage upstream of the dust collector. In this vacuum cleaner, an ion generator is connected to the ceiling surface of the dust cup for swirling air. The ion outlet of the ion generator communicates with an opening formed in the ceiling surface of the dust cup.

  Japanese Patent Laying-Open No. 2007-159654 (Patent Document 3) describes a vacuum cleaner provided with an ion generation chamber provided with a discharge means for generating ions. In this vacuum cleaner, the intake air in the intake path is introduced into the ion generation chamber, and the ions generated by the discharge means in the ion generation chamber are led to the intake passage together with the intake air.

Japanese Patent Laid-Open No. 2004-194777 JP 2003-153831 A JP 2007-159654 A

  However, in the electric vacuum cleaner described in Japanese Patent Application Laid-Open No. 2004-194977 (Patent Document 1), it is necessary to replace the dust suction hose and adapter for cleaning. The air path of the adapter is throttled by the air path restriction, and the speed of the airflow passing through the adapter is faster than the airflow during cleaning. When the speed of the airflow increases, the friction between the intake air and the members constituting the dust, the adapter, and the vacuum cleaner increases. When friction increases, dust and each member are more easily charged. As a result, it is difficult to neutralize dust and each member effectively by negative ions supplied from the adapter.

  Moreover, when installing an ion generator in the middle of an intake passage in the upstream of a dust collector like the vacuum cleaner of Unexamined-Japanese-Patent No. 2003-153831 (patent document 2), inside an intake passage In addition, it is possible to neutralize dust and members that form the intake passage. However, even if the dust in the air intake passage and the dust in the air intake passage are neutralized, the dust is rubbed against the air intake and the air intake passage before it flows into the dust collecting chamber and is charged again. In addition, the intake air containing dust is swirled inside the dust collection chamber, and the intake air, the dust, and the dust collection chamber are charged. On the other hand, when the ion outlet of the ion generator communicates with an opening formed on the ceiling surface of the dust cup, ions can be supplied directly into the dust collection chamber. However, since an exhaust pipe is formed at the top of the dust cup, ions that have flowed into the dust cup from the ceiling surface of the dust cup are removed from the exhaust pipe along with the airflow before sufficiently turning inside the dust cup. It will leak.

  In the electric vacuum cleaner described in Japanese Patent Application Laid-Open No. 2007-159654 (Patent Document 3), the charged dust is collected by the collecting means without rotating the intake air. In this electric vacuum cleaner, ions are supplied to the intake air in order to charge the dust, so the dust and the collecting means are not neutralized.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a vacuum cleaner that can effectively neutralize a dust collection chamber.

The vacuum cleaner according to one aspect of the present invention includes a suction port body, an electric blower, an intake passage, a dust collection chamber, and an ion generator. The suction port body has a suction port. The electric blower generates intake air. The intake passage guides intake air from the suction port body to the electric blower. The dust collection chamber is disposed in the intake passage, and rotates the intake air to separate the dust. In the dust collection chamber, an inflow port through which intake air in the intake passage flows into the dust collection chamber is formed .

An opening for supplying ions generated by the ion generation unit to the dust collection chamber is formed on the peripheral wall surface of the dust collection chamber. The opening is formed in the vicinity of the inflow port, and a valve configured to open or close the opening based on the pressure in the dust collection chamber is disposed in the opening. Yes.

A vacuum cleaner according to another aspect of the present invention includes a suction port body, an electric blower, an intake passage, a dust collection chamber, and an ion generator. The suction port body has a suction port. The electric blower generates intake air. The intake passage guides intake air from the suction port body to the electric blower. The dust collection chamber is disposed in the intake passage, and rotates the intake air to separate the dust. In the dust collection chamber, an inflow port through which intake air in the intake passage flows into the dust collection chamber is formed.

An opening for supplying ions generated by the ion generation unit to the dust collection chamber is formed on the peripheral wall surface of the dust collection chamber. The opening is arranged along the swirling direction of the intake air flowing in from the inlet, and the opening is configured to be able to open or close the opening based on the pressure in the dust collecting chamber. The arranged valve is arranged.

Ions generated by the ion generator are supplied from the opening into the dust collection chamber. The opening is formed in the vicinity of the inlet through which the intake air in the intake passage flows into the dust collection chamber. Therefore, the ions supplied from the opening into the dust collection chamber flow into the dust collection chamber together with the intake air flowing into the dust collection chamber from the inflow port. Or the opening part is arrange | positioned along the turning direction of the intake air which flows in from an inflow port.

Intake is swirled in the dust collection chamber. The dust contained in the intake air is swirled together with the intake air and separated from the intake air. Also, ions that flow into the dust collection chamber along with the intake air swirl with the intake air in the dust collection chamber. In this way, by rotating the ions together with the intake air in the dust collection chamber, the ions and the dust come into contact with each other in the intake air, and the dust in the intake air can be discharged. Further, in the dust collection chamber, the dust collection chamber can be neutralized by bringing ions into contact with the portion of the intake air that is in contact with the swirling dust contained in the intake air.

A dust collection chamber, separate from the inlet to the intake containing dust flows, open mouth for supplying ions are formed. Therefore, as compared with the conventional vacuum cleaner open mouth in the dust collecting chamber is not formed, the suction force output of the electric blower even the same may decrease. This decrease in suction force is not a problem during normal use. However, when the pressure of the dust accumulated dust collecting chamber dust collection chamber rises above a certain extent, by the open mouth to the dust collection chamber is formed, the suction force than a conventional vacuum cleaner May be lower.

Therefore, by placing the valve in an open mouth, for example, when the pressure of the dust collection chamber is lower than a predetermined pressure by opening valve, ions are supplied to the dust collecting chamber from the open mouth Like that. Further, by closing the valve when the pressure in the dust collecting chamber is higher than the predetermined pressure, without supplying ions to the dust collection chamber from the open mouth, to favor keeping the suction power To do.

Thus, based on the pressure of the dust collection chamber, with the structure described it is possible to open or close the open mouth by the valve, while maintaining the suction force of the vacuum cleaner, the dust capturing It is possible to neutralize the collection chamber.

By doing in this way, the vacuum cleaner which can discharge static electricity effectively in a dust collection chamber can be provided.

Vacuum cleaner according to the present invention comprises a filter disposed on the downstream side of the electric blower, the air that has passed through the filter, may comprise a return passage for returning the dust collection chamber through the open mouth preferable.

Fine dust is removed from the intake air that has passed through the filter disposed on the downstream side of the electric blower by the filter. The thus intake air is cleaned by return to the dust collection chamber through the open mouth by a return channel, it is possible to reuse the air intake. Further, it is possible to increase the amount of ions supplied from the open mouth to the dust collection chamber. By increasing the amount of ions supplied to the dust collection chamber, the ion concentration in the dust collection chamber can be increased, and the charge in the dust collection chamber can be effectively neutralized.

  As described above, according to the present invention, it is possible to provide an electric vacuum cleaner that can effectively neutralize the dust collection chamber.

1 is a perspective view showing an entire vacuum cleaner as a first embodiment of the present invention; FIG. It is sectional drawing when the vacuum cleaner of 1st Embodiment is seen from the top. It is a figure when the vacuum cleaner of 1st Embodiment is seen from the direction of the III-III line shown in FIG. It is a figure which shows the whole dust collection chamber with which the vacuum cleaner of 1st Embodiment is provided. It is sectional drawing when the vacuum cleaner of 2nd Embodiment is seen from the top. It is a figure when the vacuum cleaner of 2nd Embodiment is seen from the direction of the VI-VI line shown in FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
As shown in FIG. 1, the vacuum cleaner 1 includes a suction port body 101 having a suction port, an electric blower (suction motor) that generates intake air, a main body 100 that houses a dust collection chamber, and a suction port body 101. An extension pipe 102, a connection pipe 103, a suction hose 104, and a connection pipe 105 that connect the main body 100 are provided. The extension pipe 102, the connection pipe 103, the suction hose 104, and the connection pipe 105 form an intake passage.

  An extension pipe 102, a connection pipe 103 having a handle, a suction hose 104, and a connection pipe 105 are sequentially connected to the suction port body 101. The suction hose 104 is connected to the main body 100 via a connecting pipe 105. The handle of the connection pipe 103 is provided with an operation unit (not shown) for the user to switch between driving and stopping the electric blower.

  The extension tube 102 may be divided in the middle or made into a double-structured telescopic type so that the user can adjust the length according to the application. The suction hose 104 is configured to bend flexibly.

  The main body 100 is provided with wheels 106 that support the main body 100 so as to be movable on the floor surface. Further, a handle (not shown) for the user to lift the main body 100 is usually disposed on the main body 100, but the handle may not be disposed on the main body 100.

  As shown in FIGS. 2 and 3, the main body 100 of the vacuum cleaner 1 (FIG. 1) mainly includes an electric blower 110, a dust collection chamber 120, a first ion generation chamber 130, A second ion generation chamber 140, a filter 150, and an exhaust path 107 are disposed. On the outer peripheral surface of the main body 100, an exhaust port 108 connected to the exhaust path 107 is formed between the two wheels 106.

  In the first ion generation chamber 130, a first ion generation unit 131 is disposed. The first ion generator 131 generates positive ions. A second ion generation unit 141 is disposed in the second ion generation chamber 140. The second ion generation unit 141 generates negative ions. The first ion generation unit 131 may generate negative ions, the second ion generation unit 141 may generate positive ions, or the first ion generation unit 131 and the second ion generation unit 141 may Both may generate the same type of ions. Both the first ion generation unit 131 and the second ion generation unit 141 may generate both positive and negative ions. The first ion generation part 131 and the second ion generation part 141 constitute an ion generation part.

  An inlet 121 and an outlet 124 are formed in the dust collection chamber 120. The dust collection chamber 120 is connected to the connecting pipe 105 (FIG. 1) of the electric vacuum cleaner 1 through the inflow port 121. In addition, the dust collection chamber 120 is connected to the electric blower 110 through the air outlet 124. An exhaust passage 107 is connected to the electric blower 110. A filter 150 is disposed at the inlet of the exhaust path 107, that is, at the end of the exhaust path 107 on the electric blower 110 side.

  The dust collection chamber 120 is further formed with a first opening 133 and a second opening 143 in addition to the inlet 121 and the outlet 124. The first opening 133 allows the inside of the first ion generation chamber 130 and the inside of the dust collection chamber 120 to communicate with each other. An intake port 132 is formed in the first ion generation chamber 130. The inside of the first ion generation chamber 130 communicates with the outside of the main body 100 through the air inlet 132. Through the second opening 143, the inside of the second ion generation chamber 140 and the inside of the dust collection chamber 120 are communicated. An intake port 142 is formed in the second ion generation chamber 140. The inside of the second ion generation chamber 140 communicates with the outside of the main body 100 through the air inlet 142.

  The first opening 133 and the second opening 143 are arranged along the swirl direction of the intake air flowing from the inflow port 121.

  The height position of the first opening 133 in the dust collection chamber 120 is preferably substantially the same as the height position of the inlet 121 or lower than the inlet 121. The height position of the second opening 143 is preferably substantially the same as the height position of the first opening 133 or lower than the first opening 133.

  The first opening 133 and the second opening 143 are formed at positions facing each other across the center of the dust collection chamber 120.

  With the above configuration, ions supplied from the first opening 133 and the second opening 143 are sucked into the cylinder 123 shown in FIG. The inside of the dust collecting chamber 120 can be swung on the board.

  As shown in FIG. 4, the dust collection chamber 120 includes a dust cup 122 in which an inlet 121 is formed, a cylinder 123 that is disposed inside the dust cup 122 and through which intake air flows, and a blower that is connected to the cylinder 123. And an outlet 124. On the outer peripheral surface of the dust collection chamber 120, a first ion generation chamber 130 in which the first ion generation unit 131 is disposed and a second ion generation chamber 140 in which the second ion generation unit 141 is disposed. And are formed.

  The operation of the dust collecting chamber 120 configured as described above will be described. An arrow indicated by a two-dot chain line in FIGS. 2 to 4 indicates a direction in which intake air flows.

  When the user operates the operation unit to start the operation of the vacuum cleaner 1, the first ion generation unit 131, the second ion generation unit 141, and the electric blower 110 are driven. When the first ion generation unit 131 and the second ion generation unit 141 are driven, ions are generated in each of the first ion generation unit 131 and the second ion generation unit 141.

  When the electric blower 110 is driven, intake air is generated. The intake air is sucked into the suction port body 101 from the suction port. The intake air sucked into the suction port body 101 passes through the extension pipe 102, the connection pipe 103, the suction hose 104, and the connection pipe 105 in this order, and is sucked into the main body 100 of the electric vacuum cleaner 1. In the main body 100, the intake air flows from the connecting pipe 105 through the inflow port 121 into the dust collection chamber 120.

  When the electric blower 110 is driven, intake air sucked into the main body 100 from the intake port 132 of the first ion generation chamber 130 and the intake port 142 of the second ion generation chamber 140 is also generated. The intake air flowing from the intake port 132 flows into the dust cup 122 of the dust collection chamber 120 from the first opening 133 through the first ion generation unit 131. The intake air that flows in from the intake port 142 flows into the dust cup 122 of the dust collection chamber 120 from the second opening 143 through the second ion generation unit 141.

  The intake air flowing into the dust cup 122 from the inflow port 121 swirls inside the dust cup 122 as indicated by a two-dot chain line arrow in the drawing. The intake air passes through the first opening 133 and the second opening 143 while turning. When the intake air passes through the first opening 133, the ions generated by the first ion generation unit 131 are supplied to the intake air. When the intake air passes through the second opening 143, the ions generated by the second ion generation unit 141 are supplied to the intake air.

  The ions supplied to the intake air from the first opening 133 and the second opening 143 rotate in the dust cup 122 together with the intake air. At this time, ions in the intake air collide with dust in the intake air. Further, the ions in the intake air collide with the inner wall surface of the dust cup 122.

  The dust in the intake air is often charged due to friction with the intake air or contact between the dust. Further, the inner wall surface of the dust cup 122 is often charged by friction with the intake air or contact with dust. When the ions supplied from the first opening 133 and the second opening 143 collide with the dust and the inner wall surface of the dust cup 122 thus charged, the dust and the dust cup 122 are neutralized. The

  The intake air is separated from the dust by swirling in the dust cup 122. The intake air separated from the dust in the dust cup 122 flows out through the cylinder 123 to the air outlet 124 and flows through the air outlet 124 toward the electric blower 110. A filter 150 is installed on the downstream side of the electric blower 110. The intake air passes through the filter 150, is purified, passes through the exhaust path 107, and is discharged from the exhaust port 108 to the outside of the main body 100.

  When the cleaning using the electric vacuum cleaner 1 is completed, the user operates the operation unit to stop the driving of the electric blower 110 and the driving of the first ion generating unit 131 and the second ion generating unit 141. After the driving of the electric blower 110, the first ion generation unit 131, and the second ion generation unit 141 was completely stopped, the user removed the dust cup 122 from the main body 100 and was stored in the dust cup 122. Discard the dust.

  The dust and the dust cup 122 are neutralized while the electric blower 110, the first ion generator 131, and the second ion generator 141 are being driven. Therefore, when the dust is discarded from the dust cup 122, it is less likely that the dust is scattered by static electricity or remains attached to the dust cup 122. The dust cup 122 from which the dust has been removed is mounted on the main body 100 of the vacuum cleaner 1 again.

  As described above, the vacuum cleaner 1 of the first embodiment includes the suction port body 101, the electric blower 110, the intake passage, the dust collection chamber 120, and the first ion generation unit 131. The suction port body 101 has a suction port. The electric blower 110 generates intake air. The intake passage guides intake air from the suction port body 101 to the electric blower 110. The dust collection chamber 120 is disposed in the intake passage and separates dust by turning the intake air.

  The dust collection chamber 120 is formed with an inlet 121 through which intake air in the intake passage flows into the dust collection chamber 120. A first opening 133 for supplying the ions generated by the first ion generator 131 into the dust collection chamber 120 is formed on the peripheral wall surface of the dust collection chamber 120. The first opening 133 is formed in the vicinity of the inflow port 121.

  Ions generated by the first ion generation unit 131 are supplied into the dust collection chamber 120 from the first opening 133. The first opening 133 is formed in the vicinity of the inlet 121 through which the intake air in the intake passage flows into the dust collection chamber 120. Therefore, the ions supplied from the first opening 133 into the dust collection chamber 120 flow into the dust collection chamber 120 together with the intake air flowing into the dust collection chamber 120 from the inlet 121.

  In the dust collection chamber 120, the intake air is swirled. The dust contained in the intake air is swirled together with the intake air and separated from the intake air. Further, the ions that flow into the dust collection chamber 120 together with the intake air also rotate along with the intake air in the dust collection chamber 120. Thus, by rotating the ions in the dust collection chamber 120 together with the intake air, the ions and the dust come into contact with each other in the intake air, and the dust in the intake air can be neutralized. Further, in the dust collection chamber 120, the dust collection chamber 120 can be neutralized by bringing ions into contact with intake air or a portion where the swirling dust contained in the intake air contacts.

  By doing in this way, the vacuum cleaner 1 which can neutralize the dust collection chamber 120 effectively can be provided.

  Moreover, in the vacuum cleaner 1 of 1st Embodiment, the ion for supplying the ion produced | generated by the 2nd ion generation part 141 in the dust collection chamber 120 on the surrounding wall surface of the dust collection chamber 120 is provided. Two openings 143 are formed. The first ion generation unit 131 generates ions supplied into the dust collection chamber 120 from the first opening 133, and the second ion generation unit 141 collects the dust from the second opening 143. Ions supplied into the chamber 120 are generated.

  By supplying ions into the dust collection chamber 120 from the first opening 133 and the second opening 143, the ion concentration can be made uniform in the dust collection chamber 120.

  Moreover, in the vacuum cleaner 1 of 1st Embodiment, the 1st opening part 133 and the 2nd opening part 143 are arrange | positioned so that it may mutually oppose.

  By disposing the first opening 133 and the second opening 143 so as to face each other, the ion concentration can be made more uniform in the dust collection chamber 120.

  Moreover, in the vacuum cleaner 1 of 1st Embodiment, the 1st ion generating part 131 generate | occur | produces any one ion of a positive ion or a negative ion, and the 2nd ion generating part 141 is a positive ion or It is preferable to generate the other negative ion.

  The first ion generating unit 131 generates either positive ions or negative ions, and the second ion generating unit 141 generates the other positive ions or negative ions, thereby collecting the dust. The inside of 120 can be discharged more effectively.

(Second Embodiment)
As shown in FIGS. 5 and 6, the main body 200 of the vacuum cleaner according to the second embodiment is different from the main body 100 (FIG. 2) of the vacuum cleaner according to the first embodiment in addition to the configuration of the main body 100. The first valve 234 for opening or closing the first opening 133 and the second valve 244 for opening or closing the second opening 143 are provided.

  Further, in the main body 100 of the vacuum cleaner of the first embodiment, the first ion generation chamber 130 is formed with an intake port 132 (FIG. 2), and the second ion generation chamber 140 is formed with an intake port 142 (FIG. 2). However, these air inlets 132 and 142 are not formed in the main body 200 of the vacuum cleaner of the second embodiment.

  The first valve 234 always maintains an open posture by a biasing means such as a spring, but closes the first opening 133 when the pressure in the dust collection chamber 120 becomes higher than a predetermined pressure. Is configured to do. The second valve 244 always maintains an open posture by a biasing means such as a spring, but closes the second opening 143 when the pressure in the dust collection chamber 120 becomes higher than a predetermined pressure. Is configured to do. The first valve 234 and the second valve 244 open the first opening 133 and the second opening 143, respectively, when a normal vacuum cleaner is used.

  The first valve 234 and the second valve 244 when the first opening 133 and the second opening 143 are opened are shown by solid lines in FIGS. 5 and 6. The first valve 234 and the second valve 244 when the first opening 133 and the second opening 143 are closed are indicated by two-dot chain lines in FIGS. 5 and 6.

  Furthermore, the main body 200 of the vacuum cleaner of the second embodiment is different from the main body 100 (FIG. 2) of the vacuum cleaner of the first embodiment in that a return port 263 is formed in the exhaust path 107. A first return reflux path 261 is formed between the return port 263 and the first opening 133. A second return path 262 is formed between the return port 263 and the second opening 143.

  When the electric blower 110 of the vacuum cleaner of the second embodiment is driven, intake air is generated and air containing dust is sucked from the suction port of the suction port body 101 as in the case of the vacuum cleaner of the first embodiment. In the dust collection chamber 120, the intake air is swirled and separated from the dust.

  The intake air flowing from the dust collection chamber 120 to the electric blower 110 through the air outlet 124 then passes through the filter 150 disposed on the downstream side of the electric blower 110. When the intake air passes through the filter 150, fine dust mixed when the intake air passes through the electric blower 110 is removed. The intake air that has passed through the filter 150 and has been purified flows into the exhaust path 107.

  When the amount of dust stored in the dust collection chamber 120 is not so large, the first valve 234 and the second valve 244 are respectively the first opening 133 and the second opening. 143 is opened. When the first opening 133 and the second opening 143 are opened, a part of the intake air that has flowed into the exhaust passage 107 passes through the return port 263 and the first return reflux passage 261 and the second return passage 261. It flows into the return reflux path 262. The remaining part of the intake air is discharged from the exhaust port 108 to the outside of the main body 200.

  The intake air that has flowed into the first return flow path 261 from the return port 263 flows again into the dust collection chamber 120 through the first opening 133. At this time, the ions generated by the first ion generator 131 are supplied into the dust collection chamber 120 together with the intake air. The intake air that has flowed into the second return flow path 262 from the return port 263 flows again into the dust collection chamber 120 through the second opening 143. The ions generated by the second ion generator 141 are also supplied into the dust collection chamber 120 together with the intake air.

  The intake air flowing through the first return path 261 and the second return path 261 passes through the filter 150 and is purified. Therefore, even if the intake air is reused in this way, the first ion generator 131 and the second ion generator 141 are not easily contaminated. Further, since the intake air is supplied into the dust collection chamber 120 through the first opening 133 and the second opening 143, the intake air is generated in the first ion generation unit 131 and the second ion generation unit 141. The ions are supplied into the dust collection chamber 120 together with the intake air. In this way, it is possible to increase the amount of ions supplied into the dust collection chamber 120 and enhance the charge removal effect.

  On the other hand, when the amount of dust stored in the dust collection chamber 120 increases, the pressure in the dust collection chamber 120 increases when the electric blower 110 is driven. When the pressure in the dust collection chamber 120 becomes higher than a predetermined pressure, the first valve 234 closes the first opening 133 and the second valve 244 closes the second opening 143. When the first opening 133 and the second opening 143 are closed, ions are not supplied into the dust collection chamber 120.

  When the first opening 133 is closed by the first valve 234 and the second opening 143 is closed by the second valve 244, all the intake air in the exhaust passage 107 passes through the exhaust port 108. It is discharged outside the main body 200.

  As described above, in the vacuum cleaner of the second embodiment, the first valve 234 is disposed in the first opening 133. A second valve 244 is disposed in the second opening 143. The first valve 234 is configured to be able to open or close the first opening 133 based on the pressure in the dust collection chamber 120. The second valve 244 is configured to be able to open or close the second opening 143 based on the pressure in the dust collection chamber 120.

  In the dust collection chamber 120, a first opening 133 and a second opening 143 for supplying ions are formed separately from the inlet 121 through which intake air containing dust flows. Therefore, compared with a conventional vacuum cleaner in which the first opening 133 and the second opening 143 are not formed in the dust collection chamber 120, the suction force is low even if the output of the electric blower 110 is the same. Sometimes. This decrease in suction force is not a problem during normal use. However, when dust accumulates in the dust collecting chamber 120 and the pressure in the dust collecting chamber 120 rises to a certain level, the first opening 133 and the second opening 143 are formed in the dust collecting chamber 120. As a result, the suction force may be lower than that of a conventional electric vacuum cleaner.

  Therefore, the first valve 234 is disposed in the first opening 133. For example, when the pressure in the dust collection chamber 120 is lower than a predetermined pressure, the first valve 234 is opened, and the first valve 234 is opened. Ions are supplied into the dust collection chamber 120 from the opening 133. Further, the first valve 234 is closed when the pressure in the dust collection chamber 120 becomes higher than a predetermined pressure, so that ions are not supplied into the dust collection chamber 120 from the first opening 133. Give priority to keeping suction power.

  Similarly, the second valve 244 is disposed in the second opening 143. For example, when the pressure in the dust collection chamber 120 is lower than a predetermined pressure, the first valve 234 is opened, and the second valve 244 is opened. The ions are supplied into the dust collection chamber 120 from the opening 143 of the above. Further, the second valve 244 is closed when the pressure in the dust collection chamber 120 becomes higher than a predetermined pressure, and ions are not supplied into the dust collection chamber 120 from the second opening 143. Give priority to keeping suction power.

  In this way, the first opening 133 can be opened or closed by the first valve 234 based on the pressure in the dust collection chamber 120, and the second valve 244 can By configuring so that the two openings 143 can be opened or closed, the dust collection chamber 120 can be neutralized while maintaining the suction force of the vacuum cleaner.

  In addition, the vacuum cleaner of the second embodiment captures dust through the filter 150 disposed on the downstream side of the electric blower 110 and the intake air that has passed through the filter 150 through the first opening 133 or the second opening 143. A first return reflux path 261 and a second return reflux path 262 for returning to the collection chamber 120 are provided.

  Fine dust is removed from the intake air that has passed through the filter 150 disposed on the downstream side of the electric blower 110 by the filter 150. The intake air thus cleaned is returned to the dust collecting chamber 120 through the first opening 133 or the second opening 143 by the first return path 261 and the second return path 262. By this, the intake air can be reused. Further, the amount of ions supplied from the first opening 133 or the second opening 143 into the dust collection chamber 120 can be increased. By increasing the amount of ions supplied into the dust collection chamber 120, the ion concentration in the dust collection chamber 120 can be increased, and the inside of the dust collection chamber 120 can be effectively neutralized.

  Other configurations and effects of the vacuum cleaner of the second embodiment are the same as those of the vacuum cleaner of the first embodiment.

  The embodiment disclosed above should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above embodiments but by the scope of claims, and includes all modifications and variations within the meaning and scope equivalent to the scope of claims.

  DESCRIPTION OF SYMBOLS 1: Vacuum cleaner, 101: Suction port body, 110: Electric blower, 120: Dust collection chamber, 121: Inlet, 131: 1st ion generating part, 133: 1st opening part, 141: 2nd 143: second opening, 150: filter, 234: first valve, 244: second valve, 261: first return reflux path, 262: second return reflux path.

Claims (3)

A suction port body having a suction port;
An electric blower that generates intake air;
An intake passage for guiding intake air from the suction port body to the electric blower;
A dust collection chamber disposed in the intake passage and configured to rotate the intake air to separate the dust;
An ion generator,
In the dust collection chamber, an inflow port through which intake air in the intake passage flows into the dust collection chamber is formed,
The peripheral wall surface of the dust collection chamber, open mouth for supplying the ions generated by the ion generating unit in the dust collecting chamber is formed,
Before KiHiraki opening, the inlet of the formed near Rutotomoni, the opening is configured such that it can open or close the opening portion on the basis of the pressure in the dust collecting chamber A vacuum cleaner in which a valve is arranged . A suction port body having a suction port;
An electric blower that generates intake air;
An intake passage for guiding intake air from the suction port body to the electric blower;
A dust collection chamber disposed in the intake passage and configured to rotate the intake air to separate the dust;
An ion generator,
In the dust collection chamber, an inflow port through which intake air in the intake passage flows into the dust collection chamber is formed,
The peripheral wall surface of the dust collection chamber, open mouth for supplying the ions generated by the ion generating unit in the dust collecting chamber is formed,
Before KiHiraki opening, the flow is arranged along the turning direction of the intake air flowing from the inlet Rutotomoni, the opening may be open or to close the opening based on a pressure of the dust collecting chamber A vacuum cleaner, in which a valve configured to be possible is arranged . A filter disposed on the downstream side of the electric blower;
The intake air passing through the filter, and a front KiHiraki opening return passage for returning the dust collection chamber through an electric vacuum cleaner according to claim 1 or claim 2.

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