JP5695993B2 - Electric vacuum cleaner - Google Patents

Description

  The present invention relates to an electric vacuum cleaner including a suction tool having a rotary cleaning body, and more particularly to a technique for controlling driving of the rotary cleaning body at the time of starting.

  A conventional general vacuum cleaner includes a vacuum cleaner body having a dust collecting part, a suction tool having a suction port communicated with the dust collection part, and an electric motor that is provided in the vacuum cleaner body and generates a negative pressure at the suction port. And a blower.

  What has a rotary cleaning body is known as a suction tool. The rotary cleaning body is rotatably provided with respect to the suction tool, and rotates so as to scrape dust scattered on the surface to be cleaned. The rotary cleaning body is connected to a rotary cleaning body electric motor for driving the rotary cleaning body.

As a vacuum cleaner including a suction tool having a rotary cleaning body, Patent Document 1 discloses a vacuum cleaner that starts an electric blower and a rotary cleaning body motor with a common start switch while soft-starting the electric blower. ing.
In the electric vacuum cleaner according to Patent Document 1, the amount of air blown by the electric blower is gradually increased (soft start) after the start switch is turned on and until a predetermined time elapses. Further, after the start switch is turned on and the standby time has elapsed, the rotary cleaning body electric motor is started or the rotational speed of the rotary cleaning body electric motor is gradually increased.

  According to the technique according to Patent Document 1, it is possible to suppress a change in wind noise caused by the rotary cleaning body at the start-up so that the user does not feel uncomfortable.

Japanese Patent Laid-Open No. 10-211144

However, in the technique according to Patent Document 1, after the start switch is turned on and the standby time has elapsed, the rotating cleaning body motor is started or the rotational speed of the rotating cleaning body motor is gradually increased. In the initial stage after the start switch is turned on, the electric power supplied to the rotary cleaning body electric motor is zero or small. For this reason, the driving torque of the rotary cleaning body is also small.
In such a case, for example, when the surface to be cleaned is a carpet, the outer peripheral portion of the rotary cleaning body is entangled with the bristles of the carpet. As a result, in the initial stage after the start switch is turned on, there is a possibility that the rotary cleaning body cannot be driven to rotate well.

  The present invention has been made to solve the above-described problems of the prior art, and an object of the present invention is to make it possible to achieve both noise reduction at startup and smooth driving of the rotary cleaning body.

The vacuum cleaner according to the present invention includes a vacuum cleaner body having a dust collecting portion, a suction tool having a suction port communicated with the dust collection portion, and a negative pressure applied to the suction port provided in the vacuum cleaner body. An electric blower to be generated, a rotary cleaning body provided rotatably with respect to the suction tool, an electric motor for rotary cleaning that rotates the rotary cleaning body, and a start instruction relating to the electric blower and the electric motor for rotary cleaning body When the start instruction is input via the operation input unit and the operation input unit, a predetermined time elapses from each start of the electric blower and the rotary cleaning body motor. Drive control for performing drive control of the electric blower and the rotary cleaning body motor by giving each of them a target control amount characteristic that becomes a steady state while gradually increasing the respective target control amounts. And parts, and a current detector for detecting a current flowing to the rotary cleaning-body motor, the current flowing to the rotary cleaning-body motor detected by the current detector, the magnitude of the predetermined current value A current comparison determination unit for comparison determination .
The drive control unit, the given target control quantity characteristics become non-linear as a whole increased proportion of the target control amount is within the predetermined time, have row driving control of the rotary cleaning-body motor, said predetermined time, It consists of the previous period connected to the start of the electric motor for the rotary cleaning body and the latter period connected to the previous period, and the increase rate of the target control amount in the previous period is sharper than the increase rate of the target control amount in the latter period. The length of the previous period is set until the current comparison / determination unit determines that the current value flowing through the rotary cleaning body electric motor exceeds the predetermined current value within the predetermined time. The main feature is that the time length starting from the start of the rotary cleaning body electric motor is variably set .

  According to the present invention, it is possible to achieve both noise reduction during start-up and smooth driving of the rotary cleaning body.

It is an external view showing the whole vacuum cleaner structure concerning the embodiment of the present invention. It is the perspective view which looked at the 1st suction tool with which the rotary cleaner provided in the vacuum cleaner which concerns on embodiment of this invention was removed from the downward direction. It is a functional block diagram around the control part of the vacuum cleaner concerning the embodiment of the present invention. It is a flowchart figure with which it uses for operation | movement description of the vacuum cleaner which concerns on embodiment of this invention. It is explanatory drawing showing an example of the target control amount characteristic table which divided | segmented the target control amount characteristic corresponding to each of several operation modes for every division of the elapsed time from starting. It is a figure where it uses for operation | movement description of the vacuum cleaner which concerns on embodiment of this invention. Fig.5 (a)-FIG.5 (d) are time chart figures with which it uses for operation | movement description of the vacuum cleaner which concerns on embodiment of this invention. 6A (a) and 6A (b) are diagrams comparing the vacuum cleaner according to the comparative example and the vacuum cleaner according to the example from the viewpoint of the noise level on the main body side. FIG. 6B (a) and FIG. 6B (b) are diagrams comparing the vacuum cleaner according to the comparative example and the vacuum cleaner according to the example from the viewpoint of the noise level on the inlet side. FIG. 6C (a) and FIG. 6C (b) are diagrams comparing the vacuum cleaner according to the comparative example and the vacuum cleaner according to the example from the viewpoint of the noise level as a product.

  Hereinafter, a vacuum cleaner according to an embodiment of the present invention will be described in detail with reference to the drawings as appropriate.

(Whole structure of the electric vacuum cleaner 1 according to the embodiment of the present invention)
First, the whole structure of the vacuum cleaner 1 which concerns on embodiment of this invention is demonstrated with reference to FIG. 1A. FIG. 1A is an external view showing the overall structure of a vacuum cleaner according to an embodiment of the present invention.
As shown in FIG. 1A, the vacuum cleaner 1 according to the embodiment of the present invention includes a vacuum cleaner body 2, a hose portion 3, an operation tube 4, a telescopic extension tube 5, and a second A suction tool 6 and a first suction tool (corresponding to the “suction tool” of the present invention, hereinafter referred to as “suction tool”) 7 are provided. Among these, in this embodiment, the extension pipe 5 is composed of an outer pipe 10 and an inner pipe 20.
In addition, when expressing the direction of each part in the following description, the side of the cleaner body 2 is defined as one end (one end side) along an unillustrated ventilation path communicating between the cleaner body 2 and the suction tool 7. The side of the suction tool 7 opposite to this will be described as the other end (the other end side).

As shown in FIG. 1A, the outer casing of the vacuum cleaner main body 2 is composed of an upper case and a lower case that are substantially hemispherical. The upper case is positioned above the approximate center in the vertical direction, and the lower case is positioned below the approximate center in the vertical direction. Inside the vacuum cleaner main body 2, there are provided an electric blower 2b that generates a negative suction pressure at a suction port 41, which will be described later, a dust collection portion 2c that accommodates dust collected by the negative suction pressure of the electric blower 2b, and the like. ing.
The electric blower 2b includes a dust collection motor 81 to be described later.

  The dust collection part 2c is located in the front side (side in which the connection port 2a is formed) of the cleaner body 2 as shown in FIG. 1A. A lid (not shown) that can be opened and closed is provided on the front side of the upper case. By opening this lid, it is possible to access the dust collecting part 2c accommodated in the cleaner body 2. One end of the hose part 3 is connected to the connection port 2a of the cleaner body 2 so as to communicate with the dust collecting part 2c of the cleaner body 2.

  As shown in FIG. 1A, the operation tube 4 is formed in a substantially cylindrical shape from the other end connected to the extension tube 5 to one end connected to the hose portion 3. A grip portion 4 a is formed on the operation tube 4. The grip portion 4a is provided with a hand operation switch (corresponding to the “operation input portion” of the present invention) SW. An electrical component for the hand operation switch SW is provided in the grip portion 4a.

  By operating the hand operation switch SW, the user operates the operation mode of the electric blower 2b (for example, strong / medium / weak three-step suction force switching) or the power described later provided in the suction tool 7 It is possible to set a brush operation mode (for example, strong / medium / weak three-level rotation speed switching).

  As shown in FIG. 1A, the second suction tool 6 is detachably connected to the other end 20 a of the inner pipe 20 of the extension pipe 5. The 2nd suction tool 6 can function as a suction tool which sucks dust independently by removing suction tool 7 from other end 6a. The second suction tool 6 may be detachably connected between the outer tube 10 of the extension tube 5 and the other end 4 b of the operation tube 4. However, the 2nd suction tool 6 is not an essential structure.

  The suction tool 7 is connected to the other end 6a of the second suction tool 6 as shown in FIG. 1A. As shown in FIG. 1A, the suction tool 7 can be used by being connected to the other end 20 a of the inner tube 20 of the extension tube 5 and the other end 4 b of the operation tube 4. Details of the configuration of the suction tool 7 will be described later.

  In addition, in the vacuum cleaner 1 which concerns on this embodiment, the vacuum cleaner main body 2, the hose part 3, the operation pipe | tube 4, and extension are supplied with the electric power to the motor 83 (refer FIG. 2) for the rotary cleaning body which the suction tool 7 mentions later. This is performed through a power supply line (not shown) provided in each of the pipe 5 and the second suction tool 6.

(Structure of the suction tool 7 with which the vacuum cleaner 1 which concerns on embodiment of this invention is equipped)
Next, the detail of the structure of the suction tool 7 with which the vacuum cleaner 1 which concerns on embodiment of this invention is equipped is demonstrated with reference to FIG. 1B. FIG. 1B is a perspective view of the suction tool 7 with the rotary brush 30 removed, as viewed from below, provided in the electric vacuum cleaner 1 according to the embodiment of the present invention.

  A suction chamber 40 is formed on the lower surface of the suction tool 7 (the surface facing the surface to be cleaned) as shown in FIG. 1B. In the suction chamber 40, a rotating brush (corresponding to the “rotary cleaning body” of the present invention) 30 constituting a power brush is detachably incorporated. The power brush includes a rotary brush 30 and a rotary brush motor 83 (see FIG. 2) which drives the rotary brush 30 to be described later. The rotating brush 30 rotates so as to scrape dust scattered on the surface to be cleaned.

  As shown in FIG. 1B, the suction tool 7 includes a suction body 50 and a suction joint 55. The mouthpiece body 50 includes a lower cover 51 that forms a lower portion so as to cover the rotating brush 30, and an upper cover 52 that is attached to the upper portion of the lower cover 51.

  The mouthpiece main body 50 is provided with a bumper 53 between the lower cover 51 and the upper cover 52 from the front to the left and right sides. The bumper 53 is made of an elastic material such as rubber or elastomer, and maintains the airtightness in the mouthpiece main body 50 during use, and the mouthpiece main body 50 collides with furniture or the like when the electric vacuum cleaner 1 (see FIG. 1) is used. When it does, it plays the role of the shock absorbing material which absorbs the damage | damage to the said furniture etc. and the impact to the suction inlet main body 50. FIG.

  The suction joint 55 attached to the rear side of the suction body 50 is rotatably connected to the suction body 50 with the other end sandwiched between the lower cover 51 and the upper cover 52 as shown in FIG. 1B. ing. The suction joint 55 is rotatable in the left-right direction with respect to the first connection pipe 55 a that can be rotated (vertically) from a substantially horizontal state to a substantially vertical state with respect to the surface to be cleaned. A second connecting pipe 55b. The inlet joint 55 is formed with an air flow passage R1 inside along the longitudinal direction.

  The extension pipe 5 and the second suction tool 6 are connected to one end of the second connection pipe 55b. The inlet joint 55 has a function of allowing the extension pipe 5 to be tilted in the left-right direction of the inlet body 50 in a state where the extension pipe 5 is substantially perpendicular to the surface to be cleaned, for example. Thus, by twisting the operation tube 4 in either the left or right direction, the suction body 50 can be rotated approximately 90 degrees in the left or right direction, and cleaning can be performed with the left and right direction of the suction body 50 set as the moving direction. . Therefore, it can be cleaned by moving the suction tool 7 along the wall or inserting the suction tool 7 into a narrow gap.

  The suction chamber 40 opened to the lower surface of the lower cover 51 has a substantially curved concave shape in cross section. A suction port 41 is formed behind the suction chamber 40. The suction port 41 communicates with the passage R1 of the suction joint 55.

Ribs 43 are formed on the inner surface of the suction chamber 40. Four ribs 43 are formed on each side, four on each side and eight on each side. Each rib 43 is in a state in which a portion 43a on the downstream side in the rotation direction of the rotary brush 30 (see arrow X1 in FIG. 1B) is inclined toward the suction port 41 side than a portion 43b on the upstream side in the rotation direction. Protrusions are formed.
In a state where the rotary brush 30 is attached to the suction chamber 40, the rib 43 comes into contact with the tip of the brush 33 of the rotary brush 30.

  Bearings 44 and 45 that support the shafts at both ends of the rotary brush 30 are formed at both ends of the suction chamber 40. Bearing covers 44a and 45a are attached to the bearings 44 and 45 so that both ends of the rotating brush 30 are supported.

  As shown in FIG. 1B, a pair of rotating body joint portions 36 a are attached to both ends of the core 31. One of the pair of rotating body joint portions 36a is provided with a support shaft portion 37a supported by the bearing 45 of the lower cover 51. In addition, a connecting portion 37b that is connected to a driving portion (not shown) provided in the bearing 44 of the lower cover 51 is provided on the other side of the pair of rotating body joint portions 36a.

  When the vacuum cleaner 1 is operated, the rotating brush 30 rotates in the direction indicated by the arrow X1 in FIG. 1B. Here, the rotation in the direction indicated by the arrow X1 is applied to the suction tool 7 as a force that moves the suction tool 7 forward relative to the surface to be cleaned. Therefore, when the rotary brush 30 is rotated, the forward movement of the suction tool 7 can be assisted.

  On the other hand, when the rotating brush 30 rotates in the direction indicated by the arrow X1, the tip of the brush 33 is positioned so as to contact the rib 43. Therefore, dust, lint, etc. sucked from the lower surface opening of the lower cover 51 Then, it is conveyed in the direction of the arrow X1 along the rotation direction of the rotary brush 30. In this state, the sucked dust, lint, and the like hit the side surface of the rib 43 before being wound around the rotary brush 30, and are conveyed toward the suction port 41 along the inclination of the rib 43. And it is conveyed from the suction inlet 41 to the cleaner main body 2 side through the passage R1 of the suction joint 55, and is conveyed to the dust collecting part 2c of the cleaner main body 2.

(Configuration around the controller 61 of the vacuum cleaner 1 according to the embodiment of the present invention)
Next, the configuration around the control device 61 of the vacuum cleaner 1 according to the embodiment of the present invention will be described with reference to FIG. FIG. 2 is a functional block diagram around the control device 61 of the vacuum cleaner 1 according to the embodiment of the present invention.

  As shown in FIG. 2, the control device 61 of the vacuum cleaner 1 according to the embodiment of the present invention includes a microcomputer (hereinafter referred to as “microcomputer”) 63 that performs various controls, an operation input circuit 64, Power supply circuit 65, Hz signal generation circuit 67, AD conversion circuit 69, dust collection motor drive circuit 71, rotary brush motor drive circuit 73, current sensor 75, first triac 76, second And the triac 77. The control device 61 is actually a control board mounted on the electric vacuum cleaner 1.

  Around the control device 61, an AC power source 79 such as a commercial power source, a dust collecting motor (corresponding to the “electric blower” of the present invention) 81, and a rotary brush motor (for the “rotary cleaning body” of the present invention). Corresponds to the “motor”.) 83. These are connected to each part of the control device 61. Although it does not specifically limit as the motor 81 for dust collection or the motor 83 for rotary brushes, For example, an alternating current commutator motor can be used suitably.

The microcomputer 63 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. The microcomputer 63 reads and executes a program stored in the ROM, and sets the target control amount characteristics corresponding to each of the plurality of operation modes in a table by dividing the elapsed time from the start into a table. A function for storing the table 85 (see FIG. 3B), a corresponding characteristic is read out from the target control amount characteristic table 85, a drive control signal according to the characteristic is generated, and the generated drive control signal is transmitted to the rotary brush motor drive circuit 73. It works to control execution such as sending functions.
The microcomputer 63 corresponds to the “drive control unit” and the “current comparison determination unit” of the present invention.

  The operation input circuit 64 to which the hand operation switch SW is connected is connected to the microcomputer 63. The operation input circuit 64 is operated by the user, and the operation mode of the electric blower 2b (for example, strong / medium / weak three-level suction force switching) and the power brush operation mode (for example, strong / medium / low). Information on the three-level rotation speed of medium / weak is supplied to the microcomputer 63. The hand operation switch SW and the operation input circuit 64 correspond to the “operation input unit” of the present invention.

  A power supply circuit 65 connected to the AC power supply 79 is connected to the microcomputer 63. The power supply circuit 65 has a function of converting AC power input via the first and second power supply terminals P <b> 1 and P <b> 2 of the AC power supply 79 into DC power and supplying, for example, a DC voltage of 5 V to the microcomputer 63.

  The Hz signal generation circuit 67 connected to the AC power source 79 is connected to the microcomputer 63. The Hz signal generation circuit 67 has a function of generating, for example, a 50/60 Hz cycle signal provided by a commercial power supply (see the Hz signal in FIG. 5B) and supplying the generated Hz signal to the microcomputer 63.

AD conversion circuit 69 has a function of supplying to the microcomputer 63 converts the motor current I _B rotary brush flowing through the rotary brush motor 83 detected by the current sensor 75, into digital values. The AD conversion circuit 69 and the current sensor 75 correspond to the “current detection unit” of the present invention.

  The dust collection motor drive circuit 71 gives a drive control signal for driving the dust collection motor 81 to the first triac 76.

  The rotary brush motor drive circuit 73 gives the second triac 77 a drive control signal (see the pulse signal shown in FIG. 5C) for driving the rotary brush motor 83.

  A series circuit of a first triac 76 and a dust collecting motor 81 is connected between the first and second power supply terminals P1 and P2 of the AC power source 79. As a result, the dust collection motor 81 has an output signal (for example, FIG. 5) obtained by cutting out a part of the input signal (for example, see FIG. 5A) of the AC power supply 79 by the phase control action exhibited by the first triac 76. 5 (d)) is supplied.

  A series circuit of a second triac 77 and a rotary brush motor 83 is connected between the first and second power supply terminals P 1 and P 2 of the AC power source 79. As a result, an output signal (for example, FIG. 5) obtained by cutting a part of the input signal (for example, see FIG. 5A) of the AC power source 79 by the phase control action exerted by the second triac 76 to the rotary brush motor 83. 5 (d)) is supplied.

(Operation of the vacuum cleaner 1 according to the embodiment of the present invention)
Next, operation | movement of the vacuum cleaner 1 which concerns on embodiment of this invention is demonstrated with reference to FIG. 3A, FIG. 3B, FIG. 4, and FIG. FIG. 3A is a flowchart for explaining the operation of the electric vacuum cleaner according to the embodiment of the present invention. FIG. 3B is an explanatory diagram illustrating an example of the target control amount characteristic table 85 in which the target control amount characteristics for each operation mode are stored separately for each elapsed time segment from the start. FIG. 4 is an explanatory diagram showing a comparison of target control amount characteristics from the start of the dust collection motor 81 and the rotary brush motor 83 to the steady state in the vacuum cleaner 1 according to the embodiment of the present invention. Fig.5 (a)-FIG.5 (d) are time chart figures with which it uses for operation | movement description of the vacuum cleaner 1 which concerns on embodiment of this invention.

  The processing flow shown in FIG. 3A is started when the user inserts a power plug (not shown) of the vacuum cleaner 1 into an outlet and performs a starting operation using the hand operation switch SW, for example.

  In step S11, the microcomputer 63 constantly monitors the operation input related to the start instruction. If a start instruction accompanied with the setting of the operation mode is input during the monitoring, the microcomputer 63 advances the process flow to step S12.

In step S12, the microcomputer 63 acquires the operation mode.
In the following description, it is assumed that “strong” having the largest driving torque is set as the operation mode among strong / medium / weak.

In step S <b> 13, the microcomputer 63 has an elapsed time tp from the start being equal to or shorter than a first predetermined time t <b> 1 (for example, a time length that can be appropriately changed such as “0.5 to 1.0 seconds”). It is determined whether or not. The first predetermined time t1 corresponds to the “first period” of the present invention.
In the vacuum cleaner 1 according to the present embodiment, the classification of the category to which the elapsed time tp from the start belongs (within the first predetermined time t1 / exceeds the first predetermined time t1 and the second predetermined time t2 The target control amount characteristics for controlling the driving of the rotary brush motor 83 are greatly different depending on the following three types (internal / exceeding the first predetermined time t1). Therefore, in step S13, it is assigned to which section of the target control amount characteristic table 85 shown in FIG. 3B the elapsed time tp from the current start belongs.
The second predetermined time t2 is set to the same time length as that of the soft start of the dust collection motor 81 (the air flow rate from the start to the steady state is gradually increased).

  Here, in the target control amount characteristic table 85 shown in FIG. 3B, the relationship between the target control amount characteristic according to each section and the target control amount characteristic from the start of the rotary brush motor 83 shown in FIG. 4 to the steady state. Will be described.

In the target control amount characteristic table 85 shown in FIG. 3B, the section related to (tp ≦ t1) is steeper than that of the section related to (t1 <tp ≦ t2) regardless of the type of operation mode. The common target control amount characteristic “H0” (see the characteristic “H0” from the characteristic point P _t0 to the characteristic point P _t1 in FIG. 4) is set side by side.
As a method for setting the common target control amount characteristic “H0” for the operation modes belonging to the category related to (tp ≦ t1), for example, the target described later in association with the elapsed time tp from the start is used. A table lookup method in which the control amount (phase time width) is stored, or a sequential operation method using an arithmetic expression in which the elapsed time tp from the start is input and the target control amount (phase time width) is output are appropriately adopted. That's fine.

  In short, immediately after the start of the rotary brush motor 83, instead of using a different target control amount characteristic for each operation mode, a common target control amount characteristic “H0” that is relatively steep is employed, so that The driving torque of the motor 83 is strengthened, and this solves the problem that the rotating brush 30 cannot be driven and rotated immediately after starting.

Further, in the target control amount characteristic table 85 shown in FIG. 3B, in the section relating to (t1 <tp ≦ t2), the operation mode “as shown in FIG. 3B and FIG. The target control amount characteristic “L1” for “weak”, the target control amount characteristic “M1” for operation mode “medium”, and the target control amount characteristic “H1” for operation mode “strong”. Each individual target control amount characteristic exhibiting a slope is set.
Note that the method for setting appropriate target control amount characteristics for each operation mode belonging to the section relating to (t1 <tp ≦ t2) is the same as the above example (table lookup method, sequential calculation method, etc.). It is the same.

  In short, after a certain time has elapsed since the start of the rotary brush motor 83, instead of using the common target control amount characteristic, it is set more gently than the common target control amount characteristic “H0”, and By adopting the target control amount characteristics “L1”, “M1”, and “H1” having different inclinations for each operation mode, noise reduction at the time of starting the rotary brush motor 83 is achieved.

Then, in the target control amount characteristic table 85 shown in FIG. 3B, in the category related to (tp> t2), the operation mode “weak” is shown in FIG. 3B and FIG. 4 according to the difference in the type of operation mode. The target control amount characteristic “L2”, the operation mode “medium” is the target control amount characteristic “M2”, the operation mode “strong” is the target control amount characteristic “H2”, and so on. Each of the individual target control amount characteristics exhibiting a flatness (slope is flat) is set. These are the same as the existing technology.
Note that the method for setting appropriate target control amount characteristics for each operation mode belonging to the category (tp> t2) is the same as the above example (table lookup method, sequential calculation method, etc.). is there.

  Returning to FIG. 3A, the description will be continued. As a result of the determination in step S13, if it is determined that the elapsed time tp from the start is equal to or shorter than the first predetermined time t1 (tp ≦ t1; “Yes” in step S13), in step S14, the microcomputer 63 reads out the corresponding characteristic from the target control amount characteristic table 85 shown in FIG. 3B and generates a drive control signal according to the characteristic. Thereafter, the microcomputer 63 returns the process flow to step S13, and causes the determination in step S13 to be performed again.

  In this example of the operation description, “strong” is set as the operation mode, and the elapsed time tp from the start is equal to or shorter than the first predetermined time t1, therefore, from the target control amount characteristic table 85 shown in FIG. 3B. “H0” is read out as the corresponding target control amount characteristic. Then, a drive control signal according to the characteristic H0 is generated.

  The drive control signal according to the characteristic H0 generated in this way is sent to the rotary brush motor drive circuit 73. The rotary brush motor drive circuit 73 performs predetermined waveform shaping on the drive control signal. The pulse signal waveform thus shaped (see FIG. 5C) is applied to the second triac 77. As a result, an output signal (FIG. 5 (FIG. 5)) is obtained by rotating a part of the input signal (see FIG. 5A) of the AC power supply 79 to the rotary brush motor 83 by the phase control action exerted by the second triac 76. d)) is supplied.

  Here, the waveform of the output signal shown in FIG. 5D is the rising edge of the pulse signal waveform shown in FIG. 5C (FIG. 5C) among the waveforms of the input signals shown in FIG. From the time tup1), the falling time of the Hz signal waveform shown in FIG. 5B (see tdown in FIG. 5B), or the time rising of the Hz signal waveform shown in FIG. 5B (FIG. 5B). ) (See tup2)) is generated by cutting out portions corresponding to time widths (which correspond to “target control amount (phase time width)”). The procedure for generating such a signal waveform is the same in the following.

  In short, the target control amount (phase time width) is determined so that the rising timing of the pulse signal waveform (see FIG. 5C) output from the rotary brush motor drive circuit 73 corresponds to the Hz signal waveform shown in FIG. Of the half cycle, the closer to the first half, the longer. On the contrary, the target control amount (phase time width) is such that the rising timing of the pulse signal waveform (see FIG. 5C) is in the second half of the half cycle of the Hz signal waveform shown in FIG. The closer it is, the shorter it is.

  Therefore, by adjusting the rising timing of the pulse signal waveform (see FIG. 5C), the target control amount (phase time width) is changed, and with this, the output (drive torque) of the rotary brush motor 83 is controlled. can do. The control of the output by changing the target control amount (phase time width) is similarly applied when controlling the output (drive torque) of the dust collection motor 81.

Returning to FIG. 3A, the description will be continued. If it is determined in step S13 that the elapsed time tp from the start has exceeded the first predetermined time t1 (tp>t1; “No” in step S13), the microcomputer in step S15 63, the elapsed time tp from the start exceeds the first predetermined time t1, and the second predetermined time t2 (for example, “3 to 5 seconds”, for example, a predetermined length of time that can be appropriately changed ) Determine whether or not: The second predetermined time t2 corresponds to the “predetermined time” of the present invention. The time (t2-t1) corresponds to the “late period” of the present invention.
Step S15 is provided in the same manner as in step S13, in order to assign to which section of the target control amount characteristic table 85 shown in FIG. 3B the elapsed time tp from the current start belongs. .

  As a result of the determination in step S15, the elapsed time tp from the start exceeds the first predetermined time t1 and is equal to or shorter than the second predetermined time t2 (t1 <tp ≦ t2; “Yes in step S15” When the determination of “” is made, in step S16, the microcomputer 63 reads the corresponding characteristic from the target control amount characteristic table 85 shown in FIG. 3B and generates a drive control signal according to the characteristic. Thereafter, the microcomputer 63 returns the process flow to step S15, and causes the determination in step S15 to be performed again.

  In this example of the operation explanation, “strong” is set as the operation mode, and the elapsed time tp from the start exceeds the first predetermined time t1 and is equal to or less than the second predetermined time t2. Therefore, “H1” is read as the corresponding target control amount characteristic from the target control amount characteristic table 85 shown in FIG. 3B. Then, a drive control signal according to the characteristic H1 is generated.

  The drive control signal according to the characteristic H1 thus generated is sent to the rotary brush motor drive circuit 73. Thereafter, through the same processing as described above, a part of the input signal (see FIG. 5A) of the AC power supply 79 is cut off to the rotary brush motor 83 by the phase control action exhibited by the second triac 76. The output signal (see FIG. 5D) is supplied.

  Returning to FIG. 3A, the description will be continued. As a result of the determination in step S15, when it is determined that the elapsed time tp from the start exceeds the second predetermined time t2 (tp> t2; “No” in step S15), in step S17, The microcomputer 63 reads the corresponding characteristic from the target control amount characteristic table 85 shown in FIG. 3B and generates a drive control signal according to the characteristic. Thereafter, the microcomputer 63 ends a series of processing flow.

  In the example of this operation description, “strong” is set as the operation mode, and the elapsed time tp from the start exceeds the second predetermined time t2, so the target control amount characteristic table shown in FIG. 3B. From “85”, “H2” is read as the corresponding target control amount characteristic. Then, a drive control signal according to the characteristic H2 is generated.

  The drive control signal according to the characteristic H2 thus generated is sent to the rotary brush motor drive circuit 73. Thereafter, through the same processing as described above, a part of the input signal (see FIG. 5A) of the AC power supply 79 is cut off to the rotary brush motor 83 by the phase control action exhibited by the second triac 76. The output signal (see FIG. 5D) is supplied.

(Noise reduction effect produced by the vacuum cleaner 1 according to the embodiment)
Next, about the noise reduction effect which the vacuum cleaner 1 which concerns on an Example has, compared with the noise level of the vacuum cleaner which concerns on a comparative example, the noise level of a main body side, the noise level of a suction inlet side, and as a product The noise level will be described with reference to FIGS. 6A to 6C. The comparative example uses a vacuum cleaner that does not employ this embodiment.
In FIGS. 6A to 6C, the characteristic denoted by reference numeral 91 is the side noise characteristic when the noise level meter is set to the side of the noise source (main body / suction port / product), and numeral 93 is assigned. The above characteristics represent the upward noise characteristics when the noise level meter is set above the noise generation source (main body / suction port / product).

6A (a) and 6A (b) are diagrams comparing the vacuum cleaner according to the comparative example and the vacuum cleaner 1 according to the example from the viewpoint of the noise level on the main body side.
Comparing the comparative example shown in FIG. 6A (a) with the embodiment shown in FIG. 6A (b), the noise characteristics of both are substantially the same for both the side noise characteristic 91 and the upper noise characteristic 93. I understand.
Therefore, from the viewpoint of the noise level on the main body side, it can be said that the noise reduction effect exhibited by the vacuum cleaner 1 according to the embodiment does not reach.

FIG. 6B (a) and FIG. 6B (b) are diagrams comparing the vacuum cleaner according to the comparative example and the vacuum cleaner 1 according to the example from the viewpoint of the noise level on the suction port side.
Comparing the comparative example shown in FIG. 6B (a) with the example shown in FIG. 6B (b), the noise characteristics of both are greatly different from both the side noise characteristic 91 and the upper noise characteristic 93. I understand.

  In particular, in the upper noise characteristic 93 according to the comparative example shown in FIG. 6B (a), the noise level immediately after the start (until about 0.4 seconds have elapsed from the start) is from 35 decibels before start to about 55 decibels, It is growing rapidly. Further, in the side noise characteristic 91 according to the comparative example shown in FIG. 6B (a), the noise level immediately after start-up is not as high as the upper noise characteristic 93 from 35 decibels before start to about 45 decibels. It is growing rapidly.

On the other hand, in both the side noise characteristic 91 and the upper noise characteristic 93 according to the embodiment shown in FIG. 6B (b), the noise level until a predetermined time (4 seconds) elapses from the start is particularly It gently grows while drawing a gentle curve without causing a peak.
Therefore, from the viewpoint of the noise level on the suction port side, it can be said that the noise reduction effect exhibited by the vacuum cleaner 1 according to the example is extremely large as compared with the comparative example.

6C (a) and 6C (b) are diagrams comparing the vacuum cleaner according to the comparative example and the vacuum cleaner 1 according to the example from the viewpoint of the noise level as a product.
Comparing the comparative example shown in FIG. 6C (a) with the embodiment shown in FIG. 6C (b), the noise characteristics of both the side noise characteristic 91 and the upper noise characteristic 93 are the noise on the inlet side. As with the level, you can see that it is very different.

  In particular, in the upper noise characteristic 93 according to the comparative example shown in FIG. 6C (a), the noise level immediately after the start is sharply increased from 35 decibels before starting to about 55 decibels, similar to the noise level on the suction port side. It has become. Further, in the side noise characteristic 91 according to the comparative example shown in FIG. 6C (a), the noise level immediately after the start is from 35 decibels before start to about 46 decibels, similarly to the noise level on the suction port side. Although it is not as high as the upward noise characteristic 93, it is also rapidly increasing.

On the other hand, in both the side noise characteristic 91 and the upper noise characteristic 93 according to the embodiment shown in FIG. 6C (b), the noise level until the predetermined time (t2 = 4 seconds) elapses from the start. In particular, the curve gradually increases without creating a peak and drawing a gentle curve.
Therefore, from the viewpoint of the noise level as a product, it can be said that the noise reduction effect produced by the vacuum cleaner 1 according to the example is extremely large as compared with the comparative example.

(Operational effects produced by the vacuum cleaner 1 according to the present embodiment)
As described above, according to the vacuum cleaner 1 according to the present embodiment, the microcomputer 63 uses the target control in which the increase rate of the target control amount (phase time width) within the second predetermined time (t2) is nonlinear. Since it operates to perform drive control of the rotary brush motor 83 by giving a quantity characteristic (for example, the characteristic “H0” and the characteristic “H1” relating to the operation mode “strong” shown in FIG. 4), Noise reduction at the start of the motor 83 and smooth driving of the rotating brush 30 can be achieved at the same time.

Moreover, in the vacuum cleaner 1 which concerns on this embodiment, 2nd predetermined time (t2) consists of the first period (t1) which continues to start, and the second period (t2-t1) which continues to this first period (t1), The increase rate of the target control amount (phase time width) at (t1) is set steeper than the increase rate of the target control amount at the latter period (t2-t1).
Therefore, according to the vacuum cleaner 1 according to the present embodiment, in addition to the effect of achieving both noise reduction at the time of starting the rotary brush motor 83 and smooth driving of the rotary brush 30, in particular, the rotary brush motor 83 By enhancing the driving torque, it is possible to ensure smooth rotational driving of the rotating brush 30 immediately after starting.

In the vacuum cleaner 1 according to the present embodiment, the microcomputer 63 causes the target control in which the increase rate of the target control amount (phase time width) is linear in each period of the first period (t1) or the second period (t2-t1). A configuration is employed in which drive characteristics of the rotary brush motor 83 are controlled by giving respective quantity characteristics.
According to the vacuum cleaner 1 according to the present embodiment, by combining linear target control amount characteristics having different inclinations with each other, a non-linear target control amount characteristic is created as a whole. With the configuration, the initial purpose can be realized.

Further, as an embodiment of the electric vacuum cleaner 1 according to this embodiment, the current detecting section for detecting a current value I _B flowing through the rotary brush motor 83 and (AD conversion circuit 69 and the current sensor 75), the current detection unit 69, and the current value I _B flowing through the rotational brush motor 83 detected at 75, employs a predetermined current value I _R and for comparing the magnitude determines the current comparison section (the microcomputer 63), the further comprises configure Also good.
In such a configuration, the previous year (t1) the length of a predetermined time (t2) determined the current comparison section of the current I _B that flows through the rotating brush motor 83 that exceed a predetermined current value I _R in (microcomputer 63) is variably set to the length of time starting from the start up to the time point determined in step 63).

The electric vacuum cleaner according to an embodiment of the present embodiment, the length of the previous period (t1), it was decided to variably set based on the magnitude of the current value I _B flowing through the rotary brush motor 83.
For example, a motor current value corresponding to a preferable value as the driving torque exhibited by the rotating brush 30 immediately after starting is obtained in advance. Then, thus the motor current value obtained is set as the current value I _B. If it does in this way, the vacuum cleaner which can implement | achieve a preferable characteristic as a drive torque which the rotating brush 30 exhibits immediately after a start can be obtained.

(About other embodiments)
The embodiment described above shows an example of realization according to the present invention. Therefore, the technical scope of the present invention should not be construed as being limited by the description of the present embodiment. This is because the present invention can be implemented in various forms without departing from the gist or main features thereof.

  In the description of the present embodiment, the microcomputer 63 has a target control amount characteristic in which the increase rate of the target control amount (phase time width) within the second predetermined time (t2) is non-linear. Although an example has been described in which each operation mode is given so as to perform drive control of the rotary brush motor 83, the present invention is not limited to this example. The number of operation modes may be singular. Moreover, it is sufficient to apply the present invention to at least one or more of the plurality of operation modes.

  In addition, in the description of the present embodiment, within the second predetermined time (t2), the target control amount characteristics that are adjacent to each other with the first predetermined time (t1) as a boundary and that have different inclinations are combined. However, the present invention is not limited to this example. However, the present invention is not limited to this example.

The “target control amount characteristic in which the rate of increase of the target control amount is non-linear” according to the present invention has a plurality of singular points (before and after the time at the boundary, within the second predetermined time (t2). The aspect which has the point from which the inclination of the target controlled variable characteristic which becomes linear may differ may be sufficient.
Further, the “target control amount characteristic in which the increase rate of the target control amount is nonlinear” according to the present invention is an aspect in which a target control amount characteristic that is nonlinear is formed at all time points within the second predetermined time (t2). (For example, a quadratic curve or a cubic curve) may be used.

Finally, in the description of the present embodiment, the phase time width is exemplified as the target control amount, but the present invention is not limited to this example.
As the “target control amount” according to the present invention, an appropriate variable can be adopted according to the drive control method of the rotary brush motor (rotary cleaning body motor) 83. Specifically, for example, when an inverter control system is employed as the drive control system of the rotary brush motor (rotary cleaning body motor) 83, a pulse width (duty ratio) may be employed as the “target control amount”. .

DESCRIPTION OF SYMBOLS 1 Electric vacuum cleaner 2 Vacuum cleaner main body 2b Electric blower 2c Dust collection part 7 1st suction tool (suction tool)
30 Rotating brush (Rotating cleaning body)
41 Suction port 63 Microcomputer ("drive control unit" and "current comparison determination unit")
64 Operation input circuit 69 AD conversion circuit (current detection unit)
71 Dust Collection Motor Drive Circuit 73 Rotary Brush Motor Drive Circuit 75 Current Sensor (Current Detection Unit)
76 First Triac 77 Second Triac 81 Dust Collection Motor (Electric Blower)
83 Motor for rotating brush (motor for rotating cleaning body)
85 Target control amount characteristics table SW Hand control switch

Claims (3)

A vacuum cleaner body having a dust collecting part;
A suction tool having a suction port communicated with the dust collecting portion;
An electric blower that is provided in the vacuum cleaner body and generates a negative pressure at the suction port;
A rotary cleaning body provided rotatably with respect to the suction tool;
An electric motor for a rotary cleaning body that rotationally drives the rotary cleaning body;
An operation input unit used when operating and inputting a start instruction for the electric blower and the rotary cleaning body electric motor;
When the start instruction is input through the operation input unit, the respective target control amounts gradually increase until a predetermined time elapses from the start of the electric blower and the rotary cleaning body electric motor. While providing a target control amount characteristic that is in a steady state, respectively, and a drive control unit that performs drive control of the electric blower and the rotary cleaning body electric motor,
A current detection unit for detecting a current value flowing through the electric motor for the rotary cleaning body;
A current comparison / determination unit that compares the current value detected by the current detection unit with the current value flowing through the rotary cleaning body motor and a predetermined current value ;
The drive control unit, the given target control quantity characteristics become non-linear as a whole increased proportion of the target control amount is within the predetermined time, have row driving control of the rotary cleaning-body motor,
The predetermined time is composed of a previous period connected to the start of the electric motor for the rotary cleaning body and a latter period connected to the previous period,
The increase rate of the target control amount in the previous period is set steeply compared with the increase rate of the target control amount in the latter period,
The length of the previous period is the time until the time when the determination that the current value flowing through the rotary cleaning body electric motor exceeds the predetermined current value within the predetermined time is made in the current comparison determination unit. Variably set to the length of time starting from the start of the electric motor for rotary cleaning body,
A vacuum cleaner characterized by that. The electric vacuum cleaner according to claim 1 ,
The drive control unit performs drive control of the electric motor for the rotary cleaning body by giving a target control amount characteristic in which an increase rate of the target control amount is linear in each period of the first period or the second period.
A vacuum cleaner characterized by that. A vacuum cleaner according to claim 1 or 2 ,
When the start instruction accompanied with the setting of the operation mode is input, the drive control unit gradually increases the respective target control amounts until the predetermined time elapses, and enters the set operation mode. Giving a target control amount characteristic to be a steady state based on each, and performing drive control of the electric blower and the electric motor for the rotary cleaning body,
A vacuum cleaner characterized by that.

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