Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings.
1 is a perspective view showing the internal configuration of the cleaner body according to the first embodiment, Figure 2 is a cross-sectional perspective view showing the internal configuration of the cleaner body according to the first embodiment. 1 illustrates a state in which a case forming the outer shape of the cleaner body is removed.
1 and 2, the vacuum cleaner of the present embodiment includes a main body provided with a suction motor assembly 30 for generating suction force. In this embodiment, since there is a major interest in the internal configuration of the main body, detailed illustration and description of the external appearance and other configuration of the main body will be omitted.
The main body is detachably mounted with a dust separator 10 for separating dust in the air and storing the separated dust. The main body includes a mounting part 5 on which the dust separation device 10 is mounted.
In addition, the main body includes a guide tube 60 for guiding the air containing dust to move to the dust separation device 10, and a purification device 20 for filtering the air discharged from the dust separation device 10. Is provided.
The purification device 20 is located between the dust separation device 10 and the suction motor assembly 30 based on the flow of air. Therefore, the air containing the dust flows to the suction motor assembly 30 through the guide tube 60, the dust separation device 10, the purifying device 20.
In the description of this embodiment, it is noted that "dust" includes other foreign matter in addition to the dictionary meaning.
First, the dust separation apparatus 10 will be briefly described.
The dust separation device 10, a dust separation unit 110 for separating the dust in the air by a cyclone method, a dust collecting container 120 to store the dust separated in the dust separation unit 110, A cover member 130 covering the dust separator 110 is included.
An inside of the dust collecting container 120 is provided with a suction pipe 122 to allow the air of the guide tube 60 to be moved to the dust separation unit 110. The suction pipe 122 may be integrally formed with the dust collecting container 120 or may be coupled to the dust collecting container 120 and extend in the vertical direction.
The dust separation unit 110 is detachably coupled to the upper side of the dust collecting container 120, the dust separation unit 110, in the state coupled to the dust collecting container 120, the suction pipe 122 and A suction port 112 is formed in communication.
In addition, the dust separation unit 110 includes a dust discharge unit 115 through which dust separated from air is discharged, and an air discharge port 114 through which air is discharged. In addition, a filter member 116 for filtering the air discharged to the air outlet 114 is coupled to the dust separation unit 110.
On the other hand, the purification device 20, a filter mounting unit 210, a filter unit 240 for filtering the air discharged from the dust separation device 10 accommodated in the filter mounting unit 210, and the filter unit A discharge duct 215 through which the dust removed at 240 flows and a manipulation unit 280 for rotating the filter unit 240 by a user's manipulation are included.
The discharge duct 215 is in selective communication with the guide tube 60. That is, the dust removed from the filter unit 240 flows through the discharge duct 215 to the guide tube 60 and then to the dust separation device 10.
In addition, the discharge duct 215 is opened and closed by the opening and closing device 50. In another aspect, the discharge duct 215 is selectively communicated with the guide tube 60 by the opening and closing device 50. The opening and closing device 50 includes an opening and closing member 510 provided in the guide tube 60. The opening and closing member 510 is rotatably coupled to the guide tube 60, it is rotated by an opening and closing motor to be described later.
The suction motor assembly 30 includes a suction motor (not shown) and a motor housing 310 in which the suction motor is accommodated. The motor housing 310 is formed with an inlet 312 through which air discharged from the purifying device 20 is introduced.
3 is a perspective view showing a configuration of an opening and closing device according to the first embodiment.
Referring to FIG. 3, the opening and closing device 50 includes an opening and closing member 510 for selectively communicating the discharge duct 215 and the guide tube 60, and opening and closing for operating the opening and closing member 510. A motor 520 and a detector 530 for detecting a rotation position of the opening and closing member 510 are included.
On the other hand, the guide tube 60 is formed with an inlet 610 through which the dust discharged from the discharge duct 215 is introduced.
The rotating shaft 512 of the opening and closing member 510 is installed at the inlet 610. In addition, the pressing unit 514 for selectively pressing the sensing unit 530 is coupled to the rotation shaft 512 on the outside of the inlet 610. The open / close motor 520 is coupled to the pressing unit 514. For example, the sensing unit 530 may be applied with a micro switch.
Accordingly, the pressing unit 514 is rotated together with the opening and closing member 510, and the pressing unit 514 is the detection unit 530 while the opening and closing member 510 closes the discharge duct 215. ) Will be pressed. Then, the stop signal of the open / close motor 520 is transmitted from the detection unit 530 to the controller to be described later, and the operation of the open / close motor 520 is stopped by the control unit.
The switch motor is a motor capable of bidirectional rotation, for example, a synchronous motor (synchronous motor) may be used.
The synchronized motor is configured to be capable of forward and reverse rotation by the motor itself. When the force applied to the motor is greater than or equal to a predetermined value when the motor rotates in one direction, the rotation of the motor is converted to the other direction.
At this time, the force applied to the motor is a resistance force (torque: torque) generated as the opening and closing member 510 is interfered with the inner circumferential surface of the guide tube 60 in the process of opening the discharge duct 510. When the resistance reaches a set value, the rotation of the motor is configured to change direction. When the resistive force is applied to the motor, the current applied to the motor is momentarily increased, so that the controller stops the operation of the motor when the current of the motor is momentarily increased.
In the present exemplary embodiment, the operation of the open / close motor 520 is controlled by the operation of the sensing unit 530 and the resistive force applied to the open / close motor 520, but the rotation speed of the open / close motor 520 is different. In advance, the opening and closing motor may be configured to rotate only as much as the set number of rotations.
Hereinafter, the purification apparatus will be described in detail.
4 is a perspective view of a purification apparatus according to the first embodiment, FIG. 5 is a cross-sectional perspective view of the purification apparatus according to the first embodiment, FIG. 6 is an exploded perspective view of the filter unit according to the first embodiment, and FIG. A front view of the purification device according to the first embodiment.
4 to 7, the purifier 20 includes a filter unit 240, a housing 230 protecting the filter unit 240, and a filter mounting unit in which the housing 230 is accommodated. 210, a cover 250 rotatably coupled to an upper side of the filter mounting unit 210 to selectively open and close the filter mounting unit 210, and an operation unit 280 to move the filter unit 240. ) Is included.
In detail, the filter mounting unit 210 is formed with an inlet 211 through which the air discharged from the dust separation device 10 is introduced, and an outlet 212 through which the air passing through the filter unit 240 is discharged. .
In addition, partition ribs 213 and 213a for vertically partitioning the inner space of the filter mounting unit 210 are formed in the horizontal direction on the inner surface of the filter mounting unit 210 while the housing 230 is accommodated therein. A discharge duct 215 is formed at an outer lower side of the filter mounting unit 210 based on the partition ribs 213 and 213a. The discharge passage 216 through which dust flows is formed in the discharge duct 215.
In addition, the filter mounting unit 210 is provided with a filter detecting unit 270 for detecting the mounting of the filter unit 240. For example, a switch may be used as the filter detector 270 or may be a hall sensor that detects a magnetic member provided in the housing 230. In the present embodiment, the type of the filter detector 270 is not limited.
The filter unit 240 is rotated relative to the housing by the operation unit 280 in a state accommodated in the housing 230.
The filter unit 240 includes a filter housing 241 and a filter 246 seated on the filter housing 241.
The filter housing 241 is formed with a hole 243 through which air passes. A plurality of gear teeth 242 (also referred to as a connecting portion) for engaging the gear 420 is formed around the filter housing 241.
For example, a pleats filter that is bent a plurality of times may be used as the filter 246. The filter 246 includes a first filter 246a positioned above and a second filter 246b positioned below the partition ribs 213 and 213a. That is, a part of the filter 246 positioned above the division ribs 213 and 213a is called a first filter 246a, and a part of the filter 246 positioned below the division ribs 213 and 213a. Is referred to as a second filter 246b.
In the housing 230, a first housing 231 on which the filter unit 240 is seated, and the first housing 231 in a state where the filter unit 240 is seated on the first housing 231. A second housing 237 coupled to is included.
The second housing 237 is formed in a ring shape and includes a first opening 238 through which air flows. In addition, the gear tooth 242 of the filter unit 240 passes through the first opening 238 while the second housing 237 is coupled to the first housing 231. Protrudes outward.
A second opening 232 is formed in the first housing 231 for the air passing through the filter unit 240 to flow.
In the state where the filter unit 240 is accommodated in the housing 230, the housing 230 is selectively accommodated in the filter mounting unit 210.
In addition, the first housing 231 is formed with a handle 234 for the user to easily grip.
At this time, in order to prevent the shaking of the housing 230 in the state in which the housing 230 is accommodated in the filter mounting unit 210, a first guide part 217 is formed in the filter mounting unit 210. The first housing 231 is formed with a second guide portion 236 for insertion into the first guide portion 217.
Meanwhile, referring to FIG. 5, the inner space of the filter mounting unit 210 is divided up and down based on the partition ribs 213 and 213a. A portion (first filter) of the filter 246 is located in the upper space 214a, and another portion (second filter) of the filter 246 is located in the lower space 214b. Then, the air discharged from the dust separation device 10 is introduced into the upper space 214a through the inlet 211 of the filter mounting unit 210 to pass through only the first filter 246a.
That is, when the filter 246 is based on the entire air, the air introduced into the purification device 20 passes through a portion of the filter 246.
At this time, unless the discharge duct 215 and the guide tube 60 communicate with each other, since the suction force of the suction motor hardly acts on the lower space 214b, air flows in the lower space 214b. This practically does not occur.
Here, the upper space 214a serves to connect the inlet 211 and the outlet 212 of the filter mounting unit 210, so that the upper space 214a may be referred to as a connection flow path.
Meanwhile, a plurality of vibration damping members 218 are formed on the surface 210a on which the inlet 211 of the filter mounting portion 210 is formed. The vibration damping member 218 protrudes from the surface 210a toward the filter unit 240 and is in contact with the filter 246. Therefore, dust of the filter 246 is removed by friction between the filter 246 and the vibration damping member 218 while the filter unit 240 is rotated by the operation unit. The dust removed from the filter 246 is stored in the lower space 214b.
The cover 250 is rotatably coupled to the filter mounting unit 210.
The operation unit 280 is coupled to the upper side of the cover 250. The operation unit 280 includes an operation member 281, a first transmission part 282 coupled to the operation member 281, and an operation force of the operation member 281 from the first transmission part 282. A second delivery unit 283 receiving the transmission, and a case 290 covering the first transmission unit 282 and the second transmission unit 283 is included.
In detail, the case 290 is detachably coupled to the cover 250. The operation member 281 penetrates one surface of the case 290, and a guide hole 292 is formed to guide the movement of the operation member 281. The manipulation member 281 is connected to the first transfer part 282 through the guide hole 292. The guide hole 292 is formed long in the left and right directions.
For example, a rack gear may be used as the first transfer part 282. In the present embodiment, the first transfer part 282 may be formed of a bendable material.
The second transmission part 283 is formed integrally with the first gear 284 and the first gear 284 connected to the first transmission part 282, and has a diameter of the first gear 284. The second gear 285 is formed larger than the diameter of). The second gear 285 passes through the hole 252 formed in the cover.
In addition, while the cover 250 is rotated to shield the filter mounting unit 210, the second gear 285 is located in an inner space of the filter mounting unit 210 and the gear of the filter housing 241. Meshes with tooth 242.
Therefore, the filter unit 240 is rotated while the user moves the operation member 281 to the left or right, and dust of the filter 246 is rotated by the rotation of the filter unit 240. 218 may be removed.
At this time, when the operation member 281 is moved from one end of the guide hole 292 to the other end, the filter unit 240 is rotated 180 degrees.
8 is a vertical sectional view showing a state in which the dust collecting container according to the first embodiment is mounted on the mounting portion, and FIG. 9 is a horizontal sectional view of the dust collecting container according to the first embodiment.
8 and 9, the dust collecting container 120 defines a dust storage unit 121 in which dust is stored. In addition, the dust storage unit 121 is provided with a pressing member 150 for compressing the stored dust to be movable.
The pressure member 150 includes a pressure plate 152 for compressing dust and a rotation shaft 154 integrally formed with the pressure plate 152. The rotating shaft 154 is coupled to the fixed shaft 124 protruding upward from the bottom surface of the dust collecting container 120.
The pressing member 150 is driven by the driving device 160. In detail, the driving device 160 includes a compression motor 161 provided in the mounting unit 5 and a power transmission unit for transmitting the power of the compression motor 161 to the pressure member 150.
The power transmission unit is connected to the shaft of the compression motor 161, the drive gear 162 (also referred to as a first power transmission unit), and is connected to the pressing member 150 is driven from the drive gear 162 It includes a driven gear (164: also referred to as the second power transmission portion) that receives the.
The shaft 166 of the driven gear 164 penetrates through the dust collecting container 120 at the lower side of the dust collecting container 120 and is connected to the rotating shaft 154 of the pressing member 150. Therefore, the driven gear 164 is exposed to the outside of the dust collecting container 120.
The drive gear 162 is exposed to the outside of the mounting portion 5 in a state coupled to the compression motor 161. The mounting portion 5 is formed with an opening 6 through which the drive gear 162 passes.
Since the driving gear 162 is exposed to the outside of the mounting portion 5 as described above, when the dust collecting container 120 is mounted to the mounting portion 5, the driven gear 164 and the driving gear 162. Is engaged so that the pressing member 150 is rotatable.
On the other hand, the driven gear 164 is provided with a magnetic member 165. For example, the magnetic member 165 may be integrally formed by inserting injection into the driven gear 164.
The inside of the mounting portion 5 is provided with a plurality of detectors for detecting the magnetic force generated by the magnetic member 165. In detail, the detection unit includes a mounting detection unit 174 for detecting the mounting of the dust collecting container 120 and a motion detection unit 176 for detecting the movement of the driven gear 164. Hall sensors may be applied to the sensing units 174 and 176.
In this embodiment, since the pressing member 150 moves together with the driven gear 164, detecting the movement of the driven gear 164 may be described as detecting the movement of the pressing member 150. .
In addition, the mount detecting unit 174 is positioned below the center vertically of the driven gear 164 in order to detect the magnetization of the portion A of the magnetic member 165.
The motion detector 176 is spaced apart from the mounting detector 174, and detects the magnetism of part B of the magnetic member 165.
At this time, in order to effectively detect the magnetism generated from the magnetic member 165 by the motion detector 176, the motion detector 176, the dust collecting container 120 is mounted to the mounting portion (5) When the driven gear 164 is rotated, it is preferable that the magnetic member 165 is located vertically below the trajectory that is drawn.
Therefore, in the state in which the dust collecting container 120 is mounted on the mounting portion 5, the magnetism is always sensed by the mounting detection unit 174.
On the other hand, in the process in which the driven gear 164 is rotated, only when the magnetic member 165 is located above the motion detecting unit 176, the magnetic member 165 in the motion detecting unit 176 The magnetism of the is detected, and thus the movement of the driven gear 164 or the pressing member 150 can be confirmed. Detailed description thereof will be described below.
On the other hand, the connecting portion 126 is formed between the fixed shaft 124 and the suction pipe 122. The connection part 126 is integrally formed with the fixed shaft 124 and the suction pipe 122. The connection part 126 prevents dust from passing between the fixed shaft 124 and the suction pipe 122 in the process of compressing the dust by the pressing member 150.
10 is a block diagram showing a configuration of a vacuum cleaner according to a first embodiment.
Referring to FIG. 10, the vacuum cleaner may include an operation signal input unit 70 for selecting a power (eg, strong, medium, or weak mode) of the suction motor, and a mode selection unit for selecting an operation mode of the vacuum cleaner ( 72, the controller 80 controlling the operation of the suction motor 320 and the open / close motor 520 according to the signal input from the mode selector 72, and the pressing member 150 to rotate. Compression motor 161, a mounting detection unit 174 for detecting the mounting of the dust collecting container 120, a motion detection unit 176 for detecting the movement of the pressing member 150, and the filter unit ( Filter detection unit 270 for detecting the mounting of 240, a signal generator 180 for generating a signal to the outside of the cleaner, and a dust amount display unit 190 for displaying the amount of dust stored in the dust collecting container 120 .
In detail, the operation mode includes a general cleaning mode and a dust discharge mode.
The general cleaning mode is a mode for cleaning the floor or the indoor space. In this general cleaning mode, the discharge duct 215 is closed by the opening / closing member 510.
The dust discharging mode is a mode for discharging the dust accumulated in the lower space 214b of the filter mounting part from the filter mounting part 210 by the filter mounting part 210, and the opening / closing member 510 under the dust discharge mode. The discharge duct 215 is opened by the.
In addition, the suction motor 320 is operated under the general cleaning mode and the dust discharge mode.
The compression motor 161 is preferably a motor capable of forward rotation and reverse rotation. That is, the compression motor 161 may be a motor capable of bidirectional rotation.
Accordingly, the pressing member 150 may perform forward rotation (clockwise rotation) and reverse rotation (counterclockwise rotation), and both sides of the suction pipe 122 may be rotated as the pressing member 150 rotates forward and reverse. Dust can be compressed.
As such, in order to enable forward and reverse rotation of the compression motor, a synchronous motor may be used as the compression motor. The synchro-motor is configured to be capable of forward and reverse rotation by the motor itself, and when the force applied to the motor is greater than or equal to a predetermined value when the motor rotates in one direction, the rotation of the motor is converted to the other direction. .
At this time, the force applied to the motor is a resistance force (torque: torque) generated when the pressure member 150 presses dust, and when the resistance force reaches a set value, the direction of rotation of the motor is changed. It is composed.
Since the synchronized motor is generally known in the motor art, a detailed description thereof will be omitted. However, it is one of the technical ideas of the present invention to enable the reverse rotation of the compression motor by the synchronized motor.
In addition, even when the pressing member 150 is rotated to reach a peak that can no longer rotate while compressing the dust, the pressing member 150 may be configured to continuously press the dust for a predetermined time. Here, the peak that the pressing member 150 cannot rotate refers to when the resistance reaches a set value.
When the resistance reaches a set value, the current applied to the motor is suddenly increased. When the current detection unit (not shown) detects a change in current and transmits the change to the controller 80, the controller 80 blocks the current applied to the motor for a predetermined time.
Therefore, the pressing member 150 is maintained in a state in which dust is compressed. Then, when a predetermined time passes while the compression motor 161 is stopped, power is again applied to the compression motor 161 so that the pressing member 150 may be rotated.
At this time, since the resistance time when the power applied to the compression motor 161 reaches the set value, when the compression motor 161 is driven again, the rotation direction of the compression motor 161 is the power source. It will be in the opposite direction as before.
In addition, the compression motor 161 preferably continuously rotates the pressing member 150 forward / reverse at the same angular speed so that dust can be easily compressed.
On the other hand, when the dust collecting container 120 is not mounted to the mounting portion 5, the magnetism of the magnetic member 165 is not detected by the mounting detection unit 174.
In this state, when the operation signal of the suction motor 320 is input from the operation signal input unit 70, the control unit 80 causes the signal generation unit 180 to generate a dust collecting container-free signal.
In addition, when the filter unit 240 is not mounted to the filter mounting unit 210, the controller 80 controls the signal generator 180 to generate a non-connected tube signal.
On the other hand, when the magnetism of the magnetic member 165 is sensed by the mounting detector 174 and the mounting of the filter unit 240 is detected by the filter detector 270, the controller 80 The amount of dust stored in the dust collecting container 120 is determined using the motion information of the pressing member 150 detected by the motion detecting unit 176. Then, the amount of dust stored in the dust container 120 is displayed on the dust amount display unit 190. In addition, when the controller 80 determines that more than a reference amount of dust is stored, the signal generator 180 causes the dust emptying signal to be generated.
In this case, the signal generated by the signal generator 180 may be an audio signal or a visual signal, or may be a vibration transmitted directly to the user. As the signal generator 180, a speaker, an LED, a vibration motor, and the like may be used.
The signal generated by the signal generator 180 may be set differently from a signal of dust emptying, a signal of not collecting a dust container, and a signal of not mounting a filter unit.
In addition, the signal generator 180 includes a first signal generator for generating a signal without a dust collection container, a second signal generator for generating a dust empty signal, and a third signal generator for generating a signal without a filter unit; Can be.
11 is a view illustrating a process in which dust is compressed inside the dust collecting container.
Referring to FIG. 11, the pressing member 150 is bidirectionally rotated inside the dust collecting container 120. When the pressing member 150 is positioned at a point that is 1/2 of the maximum rotation angle of the pressing member 150 in the dust collecting container 120, the magnetic member 165 is provided in the motion detecting unit 176. Your magnetism is detected.
Here, the position of the pressing member 165 when the motion detecting unit 176 detects the magnetism of the magnetic member 165 is referred to as a “reference position” for convenience of description.
In addition, in the controller 80, a time (TD1: first reciprocating time) required for the pressing member 150 to return to the reference position after rotating the clockwise direction from the reference position, for example, and the pressing member 150. The time (TD2: second round trip time) required for returning from the reference position to the reference position after the counterclockwise rotation, for example, is sensed.
As the amount of dust compressed by the pressing member 150 increases, the first round trip time TD1 and the second round trip time TD2 are gradually shortened. In the present exemplary embodiment, when any one of the first round trip time TD1 and the second round trip time TD2 reaches a predetermined reference time, it is determined that sufficient dust is accumulated in the dust collecting container 120, and thus the dust emptying signal To be generated.
Hereinafter, the operation of the vacuum cleaner according to the present embodiment will be described.
12 is a view showing the air flow in the vacuum cleaner under the normal cleaning mode, Figure 13 is a view showing the air flow in the vacuum cleaner under the dust discharge mode, Figure 14 is a control method of the vacuum cleaner according to the embodiment It is a flowchart explaining.
12 and 13, solid lines represent air and dotted lines represent dust.
12 and 14, the general cleaning mode is selected by the mode selection unit 72. Then, it is determined whether the suction motor operation signal is input through the operation signal input unit 70 (S10). When it is determined that the suction motor operation signal is input, it is determined whether the dust collecting container 120 is mounted (S11).
When the dust collecting container 120 is not mounted to the mounting unit 5, the magnetism of the magnetic member 165 is not detected by the mounting detecting unit 174. In this case, the controller 80 controls the signal generator 180 to generate an unmounted signal of the dust collecting container 120 (S12). In addition, the suction motor 320 maintains a stopped state.
When the suction motor operation signal is input in the state in which the dust collecting container 120 is not mounted as described above, the user can easily confirm that the dust collecting container is not mounted by informing the outside. In addition, since the operation of the suction motor is stopped while the dust collecting container 120 is not mounted, unnecessary operation of the suction motor can be prevented.
On the other hand, when the magnetism is sensed by the mounting detecting unit 174 and determines that the dust collecting container 120 is mounted, it is determined whether the filter unit 240 is mounted on the filter mounting unit 210 (S13). .
When the mounting signal of the filter unit 240 is not transmitted from the filter detector 270 to the controller 80 (or the non-connector signal is transmitted from the filter detector 270 to the controller 80). In this case, the controller 80 controls the signal generator 180 to generate a filter unit-free signal (S14).
On the other hand, when the mounting of the dust collecting container 120 and the mounting of the filter unit 240 is detected, the controller 80 causes the suction motor 320 to be turned on according to the suction power selected by the user (S15). ).
When the suction motor 320 is turned on, air containing dust is sucked into the guide tube 60 by the suction force. The air containing the dust sucked into the guide tube 60 is sucked into the dust separating unit 110 through the suction pipe 122 and the suction port 112.
At this time, in the general cleaning mode as described above, the discharge duct 115 is kept closed.
The air sucked into the dust separator 110 is separated from the dust during the spiral flow along the inner circumferential surface of the dust separator 110. Then, the separated dust is moved to the dust collecting container 120 through the dust discharge unit 115. On the other hand, the air is discharged to the outside of the dust separation unit 110 through the air outlet 114 after passing through the filter member 116. In addition, the air discharged to the outside of the dust separation unit 110 is introduced into the purification apparatus 20 through the inlet 211 of the purification apparatus 20. The air introduced into the purification device 20 passes through a part of the filter 246 (first filter 246a) located in the upper space 214a of the filter mounting unit 210. The air passing through the first filter 246a is discharged to the outside of the purification apparatus 20 through the outlet 212 of the filter mounting unit 210. Air discharged to the outside of the purifying device 20 is introduced into the motor housing 310 through the inlet 312 of the motor housing 310, and after passing through the suction motor 320, It is discharged to the outside.
As the dust in the air is separated as described above and the dust is stored in the dust collecting container 120, the pressing member 150 compresses the dust stored in the dust collecting container 120.
That is, the controller 80 drives the compression motor 161 to compress the dust stored in the dust collecting container 120 after the suction motor 320 is operated (S16).
Here, although the compression motor 161 is described as being operated after the suction motor 320 is operated in this embodiment, the suction motor 320 and the compression motor 161 may be operated simultaneously.
In step S16, when the compression motor 161 is driven, the driving gear 162 coupled with the compression motor 161 is rotated. When the driving gear 162 is rotated, the driven gear 164 meshed with the driving gear 162 is rotated. As the driven gear 164 is rotated, the pressing member 150 rotates to compress dust.
At this time, the controller 80 checks whether the pressing member 150 is located at a reference position (S17).
Since the present exemplary embodiment measures the first reciprocating time and the second reciprocating time (or the moving range of the urging member) of the urging member 150 based on the reference position of the urging member 150, the urging member ( In the initial operation of 150, it is necessary to confirm that the pressing member 150 is in the reference position.
The time when the pressing member 150 is positioned at the reference position for the first time is a time when the motion detecting unit 176 detects the magnetism of the magnetic member 165 for the first time during the initial operation of the compression motor 161. .
Accordingly, the controller 80 may determine whether the movement detector 176 first detects the magnetism of the magnetic member 165 for the first round trip time TD1 or the second of the pressing member 150. The round trip time TD2 is measured (S18). For example, the controller 80 includes a counter unit for measuring the round trip time.
Here, as the amount of dust compressed in the dust collecting container 120 by the pressing member 150 increases, the left and right reciprocating rotation time of the pressing member 150 is shortened.
The controller 80 determines the first round trip time TD1 and the second round trip time TD2 of the pressing member 150 through the motion detector 176, and determines the first round trip time TD1 or It is determined whether the second round trip time TD2 has reached a predetermined reference time (S19). Here, the predetermined reference time is a time set by the designer in the controller 80 itself, which is a basis for determining that a predetermined amount or more of dust has accumulated in the dust collecting container 120. The reference time is obtained by a designer repeating the test several times and depends on the capacity of the vacuum cleaner.
In the present embodiment, when either the first round trip time TD1 or the second round trip time TD2 reaches the reference time (when the reference time is less than or equal to), the amount of dust is required (dust emptying is required). Amount of money). However, when the first round trip time TD1 and the second round trip time TD2 both reach a predetermined reference time, it may be determined that the amount of dust has reached a predetermined amount (a quantity required for dust emptying). .
As a result of the determination in step S19, when any one of the first round trip time TD1 and the second round trip time TD2 is longer than the reference time, the process returns to step S16 to perform the previous process. On the other hand, when the first round trip time TD1 or the second round trip time TD2 reaches the reference time, the controller 80 controls the signal generator 180 to generate a dust empty signal (S20). .
In addition, the control unit 80 turns off the suction motor 320 so that dust is no longer sucked (S21). Here, if the suction of dust continues in a state in which the amount of dust accumulated in the dust collecting container 120 exceeds a predetermined amount, the suction efficiency of the dust may be reduced and the suction motor 320 may be overloaded, so that the suction module The rotor 320 is to be stopped.
In addition, the control unit 80 causes the compression motor 161 to be turned off (S22).
On the other hand, while the suction motor 320 is operating or the suction motor 320 is stopped, the user can operate the operation member 281 to rotate the filter unit 240. When the operation member 281 moves from one end of the guide hole 292 to the other end, the filter unit 240 is rotated 180 degrees.
In detail, when the manipulation member 281 is operated, the first transfer part 282 connected to the manipulation member 281 is moved. When the first transfer unit 282 moves, the second transfer unit 283 connected to the first transfer unit 282 rotates, and the filter unit (B) is rotated by the rotation of the second transfer unit 283. 240 is rotated.
When the filter unit 240 is rotated 180 degrees, the first filter 246a located in the upper space 214a moves to the lower space 214b, and the second filter located in the lower space 214b. 246b moves to the upper space 214a. Here, since the lower space 214b is a space in which the filter is damped by the vibration damping member, the lower space 214b may be referred to as a cleaning space.
In the process of moving the first filter 246a to the lower space 214b, the dust of the first filter 246a is removed by the damping member 218. In addition, the dust removed from the first filter 246a falls downward.
Meanwhile, the dust discharge mode will be described with reference to FIG. 12.
The dust discharge mode is selected in the first case in which the dust discharge mode is selected during the normal cleaning mode, and in the second case in which the dust discharge mode is selected while the suction motor 320 is stopped after the normal cleaning mode is completed. In this case, the dust discharge mode may be selected before the user selects the general cleaning mode.
In the first case, since the suction motor 320 is operating, the suction motor 320 is stopped and the suction motor 320 is restarted after the opening of the discharge duct 215 is completed. At this time, when the suction motor 320 is stopped, the compression motor 161 is stopped together, and when the suction motor 320 is restarted, the compression motor 161 is also restarted together.
Alternatively, in the first case, the discharge duct 215 may be opened while the suction motor 320 is operating. At this time, the compression motor 161 is also maintained in an operating state. When the discharge duct 215 is opened and a predetermined time elapses, the discharge duct 215 is closed.
On the other hand, in the second case and the third case, since the suction motor 320 is stopped, the suction motor 320 may be operated after the opening of the discharge duct 215 is completed.
Hereinafter, as an example, a case in which the dust discharge mode is selected while the suction motor 320 is stopped will be described.
When the dust discharge mode is selected by the mode selection unit 72 in the state in which the filter unit 240 is detected by the filter detection unit 270, the discharge duct may be rotated by the opening / closing member 510. 215 is opened. When the discharge duct 215 is opened, the discharge duct 215 and the guide tube 60 is in communication.
After the opening of the discharge duct 215 is completed, the suction motor 320 is operated to generate a suction force. At this time, the compression motor 161 operates in conjunction with the operation of the suction motor 320.
When the suction motor 320 is operated, since the lower space 214b of the filter mounting unit 210 communicates with the guide tube 60 by the discharge duct 215, the suction force of the suction motor 320 is increased. The lower space 214b of the filter mounting unit 210 acts.
Then, the dust in the lower space 214b is introduced into the guide tube 60 through the discharge duct 215 together with the air by the suction force. At this time, some dust not removed from the filter located in the lower space can be removed from the filter by the suction force.
The air introduced into the guide tube 60 flows through the dust separation device 10 and passes through the filter located in the upper space 214a and then flows into the motor housing 310. On the other hand, the dust introduced into the guide tube 60 is stored in the dust collecting container 120. In addition, the dust stored in the dust collecting container 120 is compressed by the pressing member 150.
At this time, the opening and closing member 510 blocks the flow path of the guide tube 60 as shown in FIG. 12, so that air outside the cleaner body is not introduced into the guide tube 60.
In addition, during the dust discharge mode, the controller 80 determines whether dust discharge in the lower space is completed. For example, when the operation time of the suction motor 320 reaches the reference time T1, it may be determined that the dust discharge mode is completed.
When it is determined that the dust discharge mode is completed, the operation of the suction motor 320 is stopped. In addition, the opening / closing member 510 is rotated by the opening / closing motor 520 to close the discharge duct 215. In addition, when the pressing unit 514 presses the micro switch 530 while the open / close motor 520 is rotated, the operation of the open / close motor 520 is stopped by the controller 80.
According to this embodiment, since the dust of the filter unit can be removed by the operation of the operation member, the user has to remove the filter unit 240 from the cleaner body to eliminate the need to clean the filter directly. .
In addition, since the dust removed from the filter is discharged from the filter mounting portion and stored in the dust collecting container, the accumulation of dust inside the purification device is prevented.
In addition, since the dust stored in the dust collecting container is automatically compressed by the pressing member, the dust collecting capacity of the dust collecting container can be maximized.
15 is a perspective view showing a purification apparatus according to the second embodiment, and FIG. 16 is a cross-sectional perspective view of the purification apparatus according to the second embodiment.
This embodiment is the same as the first embodiment in other parts, except that there is a difference in the structure of the purification device. Therefore, hereinafter, only characteristic parts of the present embodiment will be described.
15 and 16, the purification apparatus 700 of the present embodiment includes a filter unit 730, a housing 720 protecting the filter unit 730, and a filter in which the housing 720 is accommodated. A mounting portion 710, a cover 750 rotatably coupled to an upper side of the filter mounting portion 710 to selectively open and close the filter mounting portion 710, and a vibration suppression to remove dust from the filter unit 730. Apparatus 740 and an operation unit 280 for operating the vibration suppression apparatus by a user's operation are included.
In detail, the filter mounting part 710 is fixed to the cleaner body. The filter mounting part 710 is formed with an inlet 711 through which the air discharged from the dust separation device 10 flows, and an outlet 712 through which the air passing through the filter unit 730 is discharged.
In addition, a discharge duct 715 defining a discharge flow path 716 is formed at a surface where the inlet 711 of the filter mounting part 710 is formed. The discharge duct 715 is selectively communicated with the guide tube 60 by the opening and closing device 50 described in the first embodiment.
In addition, the filter mounting unit 710 is provided with a filter detecting unit 760 for detecting the mounting of the filter unit 730.
The housing 720 may include a first housing 721 in which the filter unit 730 is seated, and the first housing 721 in a state where the filter unit 730 is seated in the first housing 721. Included is a second housing 725 coupled to.
The second housing 725 is formed in a ring shape and includes a first opening 726 through which air flows. A second opening 722 is formed in the first housing 231 to allow air passing through the filter unit 730 to flow.
The filter unit 730 includes a filter housing 731 and a filter 734 seated on the filter housing 731.
The filter housing 731 is formed with a hole 732 through which air passes. As the filter 734, for example, a pleats filter formed by bending a plurality of times may be used.
The vibration damping device 740 is rotatably coupled to the filter mounting part 710. The filter mounting portion 710 is formed with a guide rib 714 for guiding the rotation of the vibration suppression device 740. In addition, the vibration suppression apparatus 740 is rotated by the operation unit 280.
The vibration damping device 740 is formed in a disc shape, and a plurality of holes 742 are formed through which air passes. In addition, a plurality of gear teeth 746 (also referred to as a connection part) for connecting with the operation unit 280 is formed around the vibration damping device 740. In addition, a plurality of vibration damping members 744 are formed in the vibration damping apparatus 740 to remove dust from the filter 734. The plurality of vibration damping members 744 protrude toward the filter 734 from the vibration suppression apparatus 740 and contact the filter 734.
Therefore, when the vibration damping device 740 is rotated, the dust of the filter 734 is removed by the vibration damping member 744, and the removed dust is stored inside the filter mounting part 710.
In this embodiment, the configuration of the operation unit 280 is the same as in the first embodiment, the difference between the second transmission portion 283 is selectively connected to the gear teeth 746 of the vibration damping device 740. There is. Therefore, description of the configuration of the operation unit 280 will be omitted.
On the other hand, in the state in which the filter unit 730 is pulled out of the filter mounting unit 710, the internal space of the filter mounting unit 710 is partitioned up and down by the partition device 800.
The partition device 800 may include a driving motor 810 positioned outside the filter mounting unit 710 and a partition member 820 connected to the driving motor 810 and positioned inside the filter mounting unit 710. Included.
The partition member 820 includes a rotation shaft 821. The rotation shaft 821 is rotatably coupled to the filter mounting part 710, and a part of the rotation shaft 821 protrudes out of the filter mounting part 710 through the filter mounting part 710. In addition, the driving motor 810 is connected to the rotating shaft 821 protruding outside the filter mounting part 710.
In the state where the partition member 820 partitions the inner space of the filter mounting part 710, the discharge duct 715 and the guide tube 60 communicate with each other. Therefore, the suction force generated by the suction motor 320 acts on the lower space of the filter mounting part 710 so that the dust stored in the lower space of the filter mounting part 710 is discharged from the filter mounting part 710.
Hereinafter, the operation of the purification device will be described.
First, the general cleaning mode will be described.
In the general cleaning mode, the discharge duct 715 is maintained closed by the switchgear 50.
When the suction motor 320 is turned on while the dust collecting container is mounted to the mounting unit and the filter unit is mounted to the filter mounting unit, air containing dust is sucked into the guide tube 60 by suction force. The air containing the dust sucked into the guide tube 60 is sucked into the dust separating unit 110 through the suction pipe 122 and the suction port 112.
The air sucked into the dust separator 110 is separated from the dust during the spiral flow along the inner circumferential surface of the dust separator 110. The separated dust is moved to the dust collecting container 120 through the dust discharge unit 115. On the other hand, dust and air are discharged to the outside of the dust separation unit 110 through the air outlet 114. In addition, the air discharged to the outside of the dust separation unit 110 is introduced into the purification apparatus 700 through the inlet 711 of the purification apparatus 700. Air introduced into the purification apparatus 700 passes through the entire portion of the filter 734. And, the air passing through the filter 734 is discharged to the outside of the purifying device 700 through the outlet 712 of the filter mounting portion 710. Air discharged to the outside of the purification apparatus 700 is introduced into the motor housing 310 through the inlet 312 of the motor housing 310, and after passing through the suction motor 320, It is discharged to the outside.
On the other hand, while the suction motor 320 is operating or the suction motor 320 is stopped, the user can operate the operation member 281 to rotate the vibration damping device 740. When the vibration damping device 740 is rotated, dust of the filter 734 is removed by the vibration damping member 744, and the dust removed from the filter 734 is lower inside the filter mounting part 710. Are stored in.
Next, the dust discharge mode will be described.
Since the dust removed from the filter 734 is stored in the lower side of the filter mounting part 710, discharge of the stored dust is required. In this embodiment, the dust stored in the filter mounting unit 710 is automatically discharged.
In detail, when the filter unit 730 is detached from the filter mounting unit 710, the filter unit no signal is transmitted from the filter detection unit 760 to the controller 80.
In this state, when the dust discharge mode is selected, the controller 80 allows the driving motor 810 and the open / close motor 520 to operate. Then, the partition member 820 is rotated so that the inner space of the filter mounting part 710 is partitioned up and down. That is, the inner space of the filter mounting part 710 is partitioned into an upper space and a lower space by the partition member 820. At this time, the dust removed from the filter 734 is of course stored in the lower space.
The opening and closing member 510 opens the discharge duct 715 so that the discharge duct 715 and the guide tube 60 communicate with each other.
After the driving motor 810 and the opening / closing motor 520 are stopped, the controller 80 controls the suction motor 320 to be operated. In this case, the compression motor 161 may be operated together with the suction motor 320 or may be stopped.
When the suction motor 320 is operated, the suction force generated by the suction motor 320 acts as the lower space. Then, the dust in the lower space is discharged to the discharge duct 215 together with the air. Dust and air discharged to the discharge duct 215 is moved to the dust separation unit 110 along the guide tube 60. In addition, the air moved to the dust separator 110 moves to the suction motor 320 after flowing through the upper space. On the other hand, the dust moved to the dust separation unit 110 is stored in the dust collecting container 120.
When the suction motor 320 is turned on and a predetermined time elapses, the suction motor 320 is turned off, and the partition member 820 is rotated in the other direction by the driving motor 810.
