AU2015413796B2 - Electric Vacuum cleaner - Google Patents

Abstract

Provided is a vacuum cleaner, wherein a secondary battery (204) in a cleaner main body (200) is charged during storage, and when in use, power from the secondary battery (204) causes an electric blower (212) for sucking dust to rotate. When a power failure is detected, an illumination unit (250) is turned on with power from the secondary battery (204). When the cleaner main body (200) is connected to an external power source (420) and no power is supplied to the cleaner main body (200) from the external power source (420), it is determined that a power failure of the external power source (420) has occurred. The illumination unit is automatically turned on when a power failure occurs, thereby allowing a user to immediately understand the situation. Additionally, the presence of the illumination unit in the vacuum cleaner eliminates the need of another plug or another secondary battery.

Description

ELECTRIC VACUUM CLEANER

TECHNICAL FIELD [0001]

The present invention relates to an electric vacuum cleaner. In particular, the present invention relates to a rechargeable electric vacuum cleaner provided with an illuminating unit which serves as an emergency light automatically turning on at the time of a power outage.

BACKGROUND ART [0002]

An example of an electric vacuum cleaner provided with an illuminating unit is disclosed in Patent reference 1. The electric vacuum cleaner disclosed in Patent reference 1 is provided with an LED illuminating unit and a fluorescent-lamp illuminating unit, which can be selectively turned on or off by operation input. For instance, the LED illuminating unit is used to direct light into a narrow area like a spotlight, while the fluorescent-lamp illuminating unit is used to illuminate a wide area.

PRIOR ART REFERENCE

PATENT REFERENCE [0003]

Patent reference 1: Japanese Patent Application

Publication No. 2011-206339

SUMMARY OF THE INVENTION

PROBLEMS TO BE SOLVED BY THE INVENTION [0004] However, electric vacuum operation by an conventional on responsive to does not turn on the above-described cleaner turns operator, and automatically upon occurrence of a power outage.

Also known is an illuminating appliance which

-1 2

2015413796 05 Feb 2019 automatically turns on upon occurrence of a power outage. However, it requires a dedicated outlet, and also requires a separate secondary battery for lighting at the time of a power outage.

[0005]

Furthermore, special attention needs to be paid for keeping the illuminating appliance connected to the external power source in preparation for power outages which do not occur frequently. This is burdensome to the user.

[0006]

It would be desirable to provide an electric vacuum cleaner having an illuminating unit which turns on automatically upon occurrence of a power outage. It is an object of the present invention to substantially overcome or at least ameliorate one or more of the above disadvantages.

MEANS FOR SOLVING THE PROBLEM [0007]

An electric vacuum cleaner according to the present invention comprises a cleaner main body provided with:

a secondary battery accommodating section for accommodating a secondary battery; a charge controller for charging the secondary battery using electric power from an external power source; and an electric fan driven by electric power from the secondary battery; the electric vacuum cleaner further comprising:

an illuminating unit for illuminating a neighborhood of the cleaner main body; an illumination controller for turning on the illuminating unit when it detects a power outage of the external power source, and a connection detector for detecting connection of the cleaner main body to the external power source; and a power input detector for detecting supply of electric power from the external power source to the cleaner main body; wherein

AH26(22091737J ):TCW

2015413796 05 Feb 2019 the illumination controller detects a power outage of the external power source based on a result of the detection by the connection detector and a result of the detection by the power input detector.

EFFECTS OF THE INVENTION [0008]

According to embodiments of the present invention, when a power outage occurs, the illuminating unit automatically turns on, so that the situation can be perceived promptly. Moreover, since the illuminating unit is provided on the electric vacuum cleaner, no separate outlet or secondary battery is required.

Furthermore, since the electric vacuum cleaner is used relatively frequently for cleaning, it is often the case that the user has the cleaner connected to the power source for the purpose of charging, so that without paying special attention in preparation for power outages, lighting for emergency can be secured.

BRIEF DESCRIPTION OF THE DRAWINGS [0009]

Preferred embodiments of the present invention will now be described, by way of examples only, with reference to the accompanying drawings, wherein:

Fig. 1 is an external view showing an electric vacuum cleaner of a first embodiment of the present invention in a stored state.

Fig. 2 is an external view showing the electric vacuum cleaner of the first embodiment in a use state.

Fig. 3 is a block diagram showing an electrical system of the electric vacuum cleaner of the first embodiment.

AH26(22091737J ):TCW

3a

2015413796 05 Feb 2019

Fig. 4 is a schematic diagram showing a plug having a contact sensor of a connection detector of the electric vacuum cleaner of the first embodiment.

Fig. 5 is a flowchart showing the operation of the electric vacuum cleaner of the first embodiment, at the time of occurrence of a power outage, and at the time of restoration from a power outage.

Fig. 6 is an external view showing an electric vacuum cleaner of a second embodiment of the present invention in a stored state.

AH26(22091737J ):TCW

643853WO01T

Fig. 7 is a schematic diagram showing a contact sensor provided on the electric vacuum cleaner of the second embodiment, and used to sense connection between power supplying terminals and power receiving terminals

Fig. 8 configuration functions of electric vacuum embodiment.

is a block diagram showing the of a computer for implementing the the illumination controller of the cleaner of the first or second

MODE FOR CARRYING OUT THE INVENTION [0010]

First Embodiment

Fig. 1 and Fig. 2 show external views of an electric vacuum cleaner of a first embodiment of the present invention.

As shown in Fig. 1 and Fig. 2, the electric vacuum cleaner 100 has a cleaner main body 200, a plug 310, a power cord 320, a handle 330, a suction intake member 340, a connecting tube 342, and an operation input section 350.

[0011]

Fig. 1 shows a state in which the electric vacuum cleaner 100 is supported by a storage mechanism which is an attachment of the electric vacuum cleaner 100. Fig. 2 shows a state in which the electric vacuum cleaner 100 is being used for cleaning.

[0012]

The storage mechanism 400 shown in Fig. 1 is placed near an outlet 410. The outlet 410 is connected to an external power source 420. For example, the external power source 420 is a commercial power source.

[0013]

At the time of storage, the cleaner main body 200 is supported by the storage mechanism 400, as shown in

-4643853WO01T

Fig. 1, and the plug 310 is inserted in the outlet 410 for charging. .

[0014]

At the time of use, the operator 450 typically holds the handle 330 as shown in Fig. 2, and applies the suction intake, member 340 to the object to be cleaned, such as the floor surface, causing dust to be sucked .

[0015]

Fig. 3 is a block diagram showing an electrical system of the electric vacuum cleaner of Fig. 1 and Fig. 2. Fig. 3 also shows flow of dust and air.

[0016]

As shown in Fig. 3, the cleaner main body 200 has a battery accommodating section 202, a charge controller 206, an electric fan 210, a motor controller 216, a power input section 220, a posture detector 230, an illuminance detector 235, a connection detecting circuit 241, a power input detector 245, an illuminating unit 250, an illumination controller 260, and a dust separating/collecting section 344.

The electric fan 210 has a fan 212 and a fan motor 214.

[0017]

A secondary battery 204 is removably inserted in the battery accommodating section 202. When inserted in the battery accommodating section 202, the secondary battery 204 is electrically connected to the charge controller 206.

[0018]

The power input section 220 supplies the power input from the external power source 420, via the outlet 410, the plug 310, and the power cord 320, to the charge controller 206.

-5 643853WO01T

The charge controller 206 charges the secondary battery 204 using the power from the power input section 220.

[0019]

The operation input section 350 is provided, for instance, on the handle 330, and is operated when the operator 450 uses the electric vacuum cleaner for cleaning .

[0020]

The motor controller 216 performs control over starting, stopping, the rotary speed, and the like of the fan motor 214 responsive to operation input by means of the operation input section 350. The motor controller 216 operates on the power from the secondary battery 204, and drives the fan motor 214 using the power from the secondary battery 204.

[0021]

When the fan motor 214 rotates, the fan 212 rotates, and a negative pressure is created in the suction intake member 340 and the connecting tube 342. As indicated by dotted lines in Fig. 3, air containing dust is sucked by the suction intake member 340, and is sent via the connecting tube 342 to the dust separating/collecting section 344, where the dust is collected. The air having passed the dust separating/collecting section 344 is exhausted to the outside of the cleaner main body 200.

[0022]

When the electric vacuum cleaner 100 is not being used for cleaning, it is desirably stored in a state in which the cleaner main body 200 is standing upright. This is to reduce the area of the floor required for storage. It is also desirable that the secondary battery 204 be charged during storage.

-6643853WO01T [0023]

As an example, as shown in Fig. 1, the electric vacuum cleaner 100 is supported by the storage mechanism 400 in an upright posture with respect to the floor surface, is stored in this state, and the plug 310 is inserted in the outlet 410.

[0024]

When the plug 310 is inserted in the outlet 410, the power from the external power source 420 is supplied via the plug 310 and the power cord 320 to the cleaner main body 200, and is supplied via the power input section 220 and the charge controller 206 to the secondary battery 204, whereby the secondary battery 204 is charged. The control of the charging is performed by the charge controller 206.

[0025]

When cleaning is carried out, the electric vacuum cleaner 100 is typically used in a state in which the plug 310 is removed from the outlet 410. However, in the range in which cleaning is possible with the plug 310 being inserted in the outlet 410, the plug 310 may be kept inserted in the outlet 410.

[0026]

At the time of cleaning, the motor controller 216 responds to operation input by means of the operation input section 350 to cause rotation of the fan motor 214. using power from the secondary battery 204, and the fan 212 driven by the fan motor 214 causes dust on the floor surface or the like to be sent from the suction intake member 340, via the connecting tube 342, to the dust separating/collection section 344.

[0027]

As described above, at the time of storage, the electric vacuum cleaner 100 is supported by the storage

-7643853WO01T mechanism 400, in an upright state. In the present embodiment, the storage mechanism 400 is a mechanism for causing the electric vacuum cleaner 100 to stand upright, and is a stand against which the electric vacuum cleaner 100 may be leaned.

[0028]

Here, it is assumed that the electric vacuum cleaner 100 is of a generally elongated shape, and an upright state means a state in which the handle 330 of the electric vacuum cleaner 100 is above the suction intake member 340, and the longitudinal direction of the elongated electric vacuum cleaner 100 is in a direction close to the vertical direction. The direction close to the vertical direction is a direction which differs from the vertical direction by, for example, 30 degrees or less.

[0029]

In the example shown in Fig. 1, the storage mechanism 400 is a structure for supporting the electric vacuum cleaner 100, and with the connecting tube 342 and the suction intake member 340 being fixed to the cleaner main body 200, the suction intake member 340 is made to abut the floor surface, and the cleaner main body 200 is inclined, so that a side surface 208 of a casing 207 (the surface of the side wall part of the casing) is rested against and supported by a supporting surface 402 of the storage mechanism 400.

[0030]

The posture detector 230 detects a posture of the electric vacuum cleaner 100, and outputs the result of the detection to the illumination controller 260. For example, the posture detector 230 detects the posture of the electric vacuum cleaner 100 as a whole, by detecting the posture of the cleaner main body 200.

-8643853WO01T

For example, the posture detector 230 is formed of a sensor (acceleration sensor, or the like) for detecting the posture. For example, the inclination with respect to the vertical direction is detected as the posture.

[0031]

The illuminance detector 235 detects illuminance in the neighborhood of the cleaner main body 200, and outputs the result of the detection to the illumination controller 260. For example, the illuminance detector 235 comprises a sensor (illuminance sensor) capable of measuring illuminance on the surface of the casing 207 of the cleaner main body 200.

[0032]

The connection detection circuit 241 forms a part of the connection detector 240. The connection detector 240 detects connection of the power input section 220 to the external power source 420 (hence connection of the cleaner main body 200 to the external power source 420), and outputs the result of the detection to the illumination controller 260. For example, the connection detector 240 determines whether the plug 310 is connected to the outlet 410.

In addition to the connection detection circuit 241, the connection detector 240 is provided with a contact sensor, for example.

[0033]

An example of the contact sensor is shown in Fig.

4. In the illustrated example, a contactor 242 is provided at a part of the plug 310. When the plug 310 is inserted in the outlet 410, the contactor 242 senses the insertion by abutment with the surface of the outlet 410. A signal indicating the result of the detection is transmitted via a signal line 243 to the connection detection circuit 241. The signal is then

-9643853WO01T transmitted from the connection detection circuit 241 to the illumination controller 260.

[0034]

The power input detector 245 detects the supply of power from the external power source 420 to the power input section 220 (hence the supply of power from the external power source 420 to the cleaner main body 200), and outputs the result of the detection to the illumination controller 260. The power input detector 245 may, for example, include a sensor which can determine whether the power is input by sensing the current flowing from the power cord 320 to the power input section 220. The sensor is formed, for example, of a current sensor.

[0035]

The posture detector 230, the illuminance detector 235, the connection detector 240, and the power input detector 245 operate on the power from the secondary battery 204.

[0036]

The illumination controller 260 controls turn-on and turn-off of the illuminating unit 250, responsive to the results of the detection by the posture detector 230, the illuminance detector 235, the connection detector 240, and the power input detector 245. The illumination controller 260 causes the illuminating unit 250 to be powered by the secondary battery 204 when it is turned on.

[0037]

The illuminating unit 250 is provided to illuminate upward when it is turned on, in a state in which the electric vacuum cleaner 100 is standing upright. For example, it is desirable that the illuminating unit 250 be so provided as to be

-10643853WO01T positioned on the upper side of the electric vacuum cleaner 100, e.g., on the upper side of the cleaner main body 200, and is so configured as to illuminate a wide area of the ceiling situated above, in a state in which the electric vacuum cleaner 100 is standing upright. This is because such an arrangement is advantageous in that the surrounding situation can be observed at the time of occurrence of a power outage.

[0038]

When the electric vacuum cleaner 100 is in a use state, the illuminating unit 250 is kept in a turn-off state .

When the electric vacuum cleaner 100 is in a nonuse state, operation in a power outage monitoring mode is started. In this power outage monitoring mode, the illumination controller 260 performs detection of occurrence of a power outage, and control over turn-on and turn-off of the illuminating unit 250.

Whether the electric vacuum cleaner 100 is in a non-use state is determined based, for example, on the operation by means of the operation input section 350. For example, it is determined that the non-use state has begun when a predetermined time has elapsed after the fan 212 is turned off by the operation input section 350, and it is determined that the non-use state has ended at the moment when the fan 212 is turned on by the operation input section 350.

[0039]

In the power outage monitoring mode, the illumination controller 260 monitors the outputs of (indicating the results of the detection by) the posture detector 230, the illuminance detector 235, the connection detector 240, and the power input detector 245, and performs control over turn-on and turn-off of

-11 643853W001T the illuminating unit 250 based on these outputs. The process for this control is explained with reference to Fig . 5. .

[0040] ’

The process of Fig. 5 is initiated at a predetermined time interval.

At first, in step STll, whether the cleaner main body 200 is connected to the external power source 420 is determined based on the output of the connection detector 240. When it is connected, the process proceeds to step ST12.

[0041]

In step ST12, whether the power is supplied from the external power source 420 to the cleaner main body 200 is determined based on the output of the power input detector 245.

If it is determined that the power is not supplied (NO in step ST12), the process proceeds to step ST13.

[0042]

In step ST13, whether the illuminance in the neighborhood of the cleaner main body 200 is equal to or more than a threshold value is determined based on the output of the illuminance detector 235.

If it is less than the threshold value (NO in the ST13), the process proceeds to step ST14.

[0043]

In step ST14, it is determined whether the electric vacuum cleaner 100 is in the upright state based on the output of the posture detector 230.

If it is in the upright state (YES in step ST14), the process proceeds to step ST15.

[0044]

In step ST15, the illuminating unit 250 is turned

- 12643853WO01T on. That is, if it has been in the on-state, the onstate is continued. If it has been in the off-state, it is changed to the on-state.

[0045]

In the case of NO in step ST11 (it is not connected to the power source), YES in step ST12 (the power is supplied) , YES in step ST13 (the illuminance is equal to or more than the threshold value), or NO in step ST14 (it is not in the upright state), the process proceeds to step ST16.

In step ST16, the illuminating unit 250 is turned off. That is, if it has been in the off-state, the off-state is continued. If it has been in the on-state, it is changed to the off-state.

[0046]

By following the process shown in Fig. 5, the illumination controller 260 exercises the following control.

That is, the illumination controller 260 turns on the illuminating unit 250 when all of the four conditions (a) to (d) noted below are satisfied.

(a) It is determined from the result of the detection by the connection detector 240 that the cleaner main body 200 is connected to the external power source 420.

(b) It is determined from the result of the detection by the power input detector 245 that no power is supplied from the external power source 420 to the cleaner main body 200.

(c) It is determined from the result of the detection by the illuminance detector 235 that the illuminance in the neighborhood of the cleaner main body 200 is less than the threshold value.

(d) It is determined from the result of the detection by the posture detector 230 that the electric vacuum

-13 643853WO01T cleaner 100 is in the upright state.

[0047]

When, on the other hand, any of the four conditions (a), (b) , (c) and (d) noted above is not satisfied, the illuminating unit 250 is turned off.

[0048]

The conditions (a) and (b) noted above are satisfied when a power outage occurs. It is so arranged that the illumination controller 260 turns on the illuminating unit 250 only in such a situation.

Even if the above condition (b) is satisfied, the illuminating unit 250 is not turned on when the above condition (a) is not satisfied. This is because it is possible that the power is not supplied from the external power source 420 due to non-insertion of the plug 310 in the outlet 410, rather than a power outage.

[0049]

Also, even if the above conditions (a) and (b) are satisfied, the illumination controller 260 does not turn on the illuminating unit 250 when the above condition (c) is not satisfied. This is because in such a case it can be determined that the ambient light is bright (when sunlight is received, or some other illuminating light is on) , and in such a case, it is not necessary to turn on the illuminating unit 250 because it is bright in the neighborhood even if a power outage occurs.

[0050]

Furthermore, even if the above conditions (a), (b) and (c) are satisfied, the illumination controller 260 does not turn off the illuminating unit 250 when the above condition (d) is not satisfied. This is to prevent the illuminating light of the illuminating unit 250 from directly entering the eyes of people, even in

- 14643853WO01T the event of a power outage.

[0051]

Variation 1.

In the embodiment described above, the illuminating unit 250 is turned on when all of the above conditions (a), (b) , (c) and (d) are satisfied.

Alternatively, it may be so arranged ( a ) that the illuminating unit 250 is turned on when the conditions (a) and (b) are satisfied (even if the conditions (c) and (d) are not satisfied);

( β ) that the illuminating unit 250 is turned on when the conditions (a), (b) and (c) are satisfied (even if the condition (d) is not satisfied); or ( γ ) that the illuminating unit 250 is turned on when the conditions (a), (b) and (d) are satisfied (even if the condition (c) is not satisfied).

[0052]

Variation 2.

In the embodiment described above, the power input detector 245 is a sensor capable of sensing a current flowing from the power cord 320 to the power input section 220, and is formed, for example, of a current sensor, and the sensor operates on the power from the secondary battery 204.

However, the present invention is not limited to such a configuration. ‘

For example, the configuration may be such that when a current from the external power source 420 flows a signal due to this current indicating the input of power is output, and otherwise the signal is not output [0053]

Variation 3.

In the first embodiment described above, the storage mechanism 400 is provided as an attachment to

-15 643853WO01T the electric vacuum cleaner 100. However, an existing structure which can serve as a supporting member, for example a wall of the room for storing the electric vacuum cleaner, may be used as the storage mechanism 400.

[0054]

Also, the electric vacuum cleaner 100 may be so configured as to be capable of standing by itself.

[0055]

Variation 4 .

In the first embodiment, it is assumed that the electric vacuum cleaner is of a stick-type. However, the present invention is also applicable where the electric vacuum cleaner is of a handy-type. The present invention is also applicable where the electric vacuum cleaner is of a canister type. The present invention is also applicable where the electric vacuum cleaner is an electric vacuum cleaner which autonomously performs cleaning (robot-type electric vacuum cleaner).

[0056]

Variation 5.

In connection with the first embodiment, it is explained that the illuminating unit 250 is provided to illuminate upward when the electric vacuum cleaner 100 is in an upright state.

Such a configuration is advantageous because when the electric vacuum cleaner 100 is elongated as shown in Fig. 1, and if the upper end of the electric vacuum cleaner 100 in its stored state, where the illuminating unit 250 is positioned, is above the eyes of an average person, then the illuminating light from the illuminating unit 250 is prevented from directly entering the eyes of the person.

- 16643853WO01T [0057]

However, this is not indispensable, and the illuminating unit may be provided to illuminate in a predetermined direction other than the upward direction [0058]

Variation 6.

In connection with the first embodiment, it is explained that upright means that the longitudinal direction of the elongated electric vacuum cleaner 100 is in a direction close to the vertical direction. However, the present invention is not limited to the cases where the electric vacuum cleaner 100 is elongated. What is essential is that, at the time of storage, the electric vacuum cleaner 100 is placed in a state of a predetermined posture, i.e., a state in which it is oriented in a predetermined direction, and that, in such a state, the illuminating unit 250 illuminates in a predetermined direction e.g., the upward direction.

In such a case, in place of the above-mentioned condition (d) , the following condition (d' ) which is a generalization of the condition (d) is used.

(d' ) It is determined that from the result of the detection by the posture detector 230, the electric vacuum cleaner 100 is in a state in which it is oriented in a predetermined direction.

[0059]

For instance, if the illuminating unit 250 is positioned below the eyes of people, the illuminating unit 250 may be provided to illuminate downward, thereby to prevent direct entry of the illuminating light into the eyes of people.

[0060]

Variation 7.

-17643853WO01T

The present invention is also applicable where the cleaner main body 200 is separable from at least one of the suction intake member 340, the connecting tube 342 and the handle 330. In such a case, the arrangement will be such that the posture detector 230 detects the posture of the cleaner main body 200, and the illumination controller 260 determines, from the result of the detection by the posture detector 230, whether the cleaner main body 200 is in a state in which it is oriented in a predetermined direction.

[0061]

In this case, the cleaner main body 200 may be configured to maintain a predetermined posture even if it is not supported by the storage mechanism 400, that is, it may be configured to stand by itself. For instance, the cleaner main body 200 may be provided, at its bottom, with a protruding structure which abuts the floor surface and forms a three-point support for the cleaner main body 200.

[0062]

Second Embodiment

In the first embodiment described above, the storage mechanism 400 functions only as a support of the electric vacuum cleaner 100. The storage mechanism 400 may also serve as a charging table or charging stand, as shown in Fig. 6.

[0063]

In this case, it is configured so that in a state in which the cleaner main body 200 is supported by the storage mechanism 400, power supplying terminals 404, 405 of the storage mechanism 400 and power receiving terminals 224, 225 of the cleaner main body 200 are electrically in contact with each other. The storage mechanism 400 has the power cord 320 and the plug 310,

- 18643853WO01T and the plug 310 is inserted in the outlet 410.

[0064]

Also, as the connection detector 240, one which senses connection between the outlet 410 and the plug 310, and also senses connection between the power supplying terminals 404, 405 and the power receiving terminals 224, 225 is used.

And, if the connection is sensed for both, it is determined that the cleaner main body 200 is connected to the external power source.

[0065]

For the sensing of the connection between the outlet 410 and the plug 310, the contact sensor described with reference to Fig. 4 in connection with the first embodiment can be used.

[0066]

Fig. 7 shows a contact sensor which can be used to sense the connection between the power supplying terminals 404, 405 and the power receiving terminals 224, 225.

In the example shown in Fig. 7, a contactor 221 is provided adjacent to the power receiving terminals 224, 225, so as to protrude from the side surface 208 of the casing 207 (the surface of the side wall part of the casing) of the cleaner main body 200. When the power receiving terminals 224, 225 are pressed against the power supplying terminals 404, 405, the contactor 221 abuts the supporting surface 402 of the storage mechanism 400, thereby sensing the electrical connection between the power receiving terminals 224, 225 and the power supplying terminals 404, 405.

A signal indicating the result of the sensing is transmitted via a signal line 223 to the connection detection circuit 241.

- 19643853WO01T [0067]

From the result of the detection communicated via the signal line 243, and the result of the detection communicated via the signal line 223, the connection detection circuit 241 determines that the cleaner main body 200 is connected to the external power source 420 when (al) it is determined that the plug 310 is connected to the outlet 410, and (a2) it is determined that the power receiving terminals 224, 225 are connected to the power supplying terminals 404, 405.

[0068]

That is, the connection detection circuit 241 determines that the above condition (a) is satisfied when the condition (al) that the plug 310 is determined to be connected to the outlet 410, from the output of the contact sensor similar to that in Fig. 4, and the condition (a2) that the power receiving terminals 224, 225 are determined to be connected to the power supplying terminals 404, 405 from the output of the contact sensor in Fig. 7 are both satisfied.

When at least one of the above conditions (al) and (a2) is not satisfied, the connection detection circuit 241 determines that the above condition (a) is not satisfied.

[0069] .

The result of the determination by the connection detection circuit 241 is communicated, as the result of the detection by the connection detector 240, to the illumination controller 260.

[0070]

-20643853WO01T

The variations which are applicable to the first embodiment are also applicable to the second embodiment [0071]

According to the present invention, when a power outage occurs, the illuminating unit is automatically turned on, enabling the situation to be perceived promptly. Also, the illuminating unit is provided on the electric vacuum cleaner, so that no separate outlet or separate secondary battery is required.

[0072]

Furthermore, the electric vacuum cleaner is used relatively frequently for cleaning, and the user often has it connected to the power supply for charging, so that lighting for emergency can be secured without paying special attention in preparation for power outages .

[0073]

Also, if it is so arranged that the illuminating unit 250 is turned on when the above condition (c) is satisfied, it is possible to omit the turn-on when it is bright in the neighborhood of the cleaner main body 200, and waste of power can be avoided.

[0074] '

Also, if it is so arranged that the illuminating unit 250 is turned on when the above condition (d), or, more generally, the above condition (d') is satisfied, it is possible to prevent the illuminating light from the illuminating unit 250 from directly entering the eyes of people.

[0075]

In the above embodiments, at least part of the illumination controller 260, the posture detector 230, the illuminance detector 235, the connection detector 240 and the power input detector 245 may be in the form

-21 643853WO01T of a processing circuit. The processing circuit may be dedicated hardware, or a CPU which executes programs stored in a memory.

[0076]

When the processing circuit is a CPU, the functions of the illumination controller 260, the posture detector 230, the illuminance detector 235, the connection detector 240 and the power input detector 245 are implemented by software, firmware, or a combination of software and hardware. The software or the firmware is described as programs and stored in a memory. The processing circuit reads and executes the programs stored in the memory, to implement the functions of the illumination controller 260, the posture detector 230, the illuminance detector 235, the connection detector 240 and the power input detector 245. That is, the memory is provided to store the programs by which, when executed by the processing circuit, the functions of the illumination controller 260, the posture detector 230, the illuminance detector 235, the connection detector 240 and the power input detector 245 are implemented. These programs can be said to cause a computer to execute the processes, or their procedure, in the illumination control method performed by the illumination controller 260.

[0077]

Also, part of the functions of the illumination controller 260, the posture detector 230, the illuminance detector 235, the connection detector 240 and the power input detector 245 may be implemented by dedicated hardware, and part thereof may be implemented by software or firmware.

In this way, the processing circuit can implement the functions by hardware, software, firmware, or their

-2223

2015413796 28 Feb 2018 combination.

[0078] Fig. 8 shows an example of a configuration in which a computer (indicated by reference characters 500) including a single CPU constituting the above processing circuit implements the functions of the illumination controller 260.

The computer 500 shown in Fig. 8 is provided with a CPU 510, a memory 520, input interfaces 531 to 534, and an output interface 540, which are interconnected by a bus 550.

Input to the input interfaces 531 to 534, respectively, are signals (the results of the detection) from the posture detector 230, the illuminance detector 235, the connection detector 240, and the power input detector 245 in Fig. 3.

[0079] The CPU 510 operates according to programs stored in the memory 520, performs the determination of the illumination controller 260 described above, based on the signals (the results of the detection) input via the input interfaces 531 to 534, and performs control for turning on or off the illuminating unit 250 based on the result of the determination. That is, a control signal generated based on the result of the determination is supplied via the output interface 540 to the illuminating unit 250 for turning-on or turning-off the illuminating unit 250.

[0080] The content of the processes executed by the CPU 510 is similar to that described with reference to Fig. 5 in connection with the first embodiment. The data generated during the process execution is stored in the memory 520.

AH26(14360776_2):JBL

643853WO01T [0081]

By the use of the programs causing a computer to execute the processes in the illumination control method performed by the illumination controller 260, it is possible to obtain effects similar to those described with reference to the illumination controller 260 .

[0082]

The same is true for the cases where the functions of the posture detector 230, the illuminance detector 235, the connection detector 240 and the power input detector 245 are implemented by the processing circuit.

REFERENCE CHARACTERS [0083]

100: electric vacuum cleaner; 200: cleaner main body; 202: battery accommodating section; 204: secondary battery; 206: charge controller; casing; 208: side surface; 210: electric fan; fan; 214: fan motor; 216: motor controller; power input section; 224, 225:

terminal; 230: posture detector; detector; 240: connection detector;

207 : 212 : 220 :

power receiving 235: illuminance

241: connection detection circuit; 242: contactor; 243: signal line; 245: power input detector; 250: illuminating unit; 260: illumination controller; 310: plug; 320:

power 342 :

cord; 330: handle; connecting tube;

340 : 344 suction intake member; dust separating/collecting section; 350: operation input section; 400: storage mechanism; 402: supporting surface; 404, 405: power supplying terminal; 410: outlet; 420 source; 500: computer; 510: CPU; 520 external power memory; 531 to

534: input interface; bus .

540: output interface; 550:

Claims (9)

1. An electric vacuum cleaner comprising a cleaner main body provided with:

a secondary battery accommodating section for accommodating a secondary battery; a charge controller for charging the secondary battery using electric power from an external power source; and an electric fan driven by electric power from the secondary battery; the electric vacuum cleaner further comprising:

an illuminating unit for illuminating a neighborhood of the cleaner main body; an illumination controller for turning on the illuminating unit when it detects a power outage of the external power source, and a connection detector for detecting connection of the cleaner main body to the external power source; and a power input detector for detecting supply of electric power from the external power source to the cleaner main body; wherein the illumination controller detects a power outage of the external power source based on a result of the detection by the connection detector and a result of the detection by the power input detector.

2. The electric vacuum cleaner as set forth in claim 1, wherein the illumination controller monitors the result of the detection by the connection detector, and the result of the detection by the power input detector; and turns on the illuminating unit when a condition (a) that the cleaner main body is determined to be connected to the external power source, from the result of the detection by the connection detector; and a condition (b) that no electric power is determined to be supplied from the external power source to the cleaner main body, from the result of the detection by the power input detector are both satisfied.

3. The electric vacuum cleaner as set forth in claim 2, wherein the illumination controller turns off the illuminating unit when at least one of the conditions (a) and (b) is not satisfied.

AH26(22091737J ):TCW

2015413796 05 Feb 2019

4. The electric vacuum cleaner as set forth in claim 2, further comprising:

an illuminance detector for detecting illuminance in a neighborhood of the cleaner main body; wherein the illumination controller monitors a result of the detection by the illuminance detector, and turns on the illuminating unit when, in addition to the conditions (a) and (b), a condition (c) that the illuminance in the neighborhood of the cleaner main body is determined to be less than the threshold value, from the result of the detection by the illuminance detector is satisfied.

5. The electric vacuum cleaner as set forth in claim 4, wherein the illumination controller turns off the illuminating unit when at least one of the conditions (a), (b) and (c) is not satisfied.

6. The electric vacuum cleaner as set forth in claim 2, further comprising:

a posture detector for detecting a posture of the electric vacuum cleaner; wherein the illumination controller monitors a result of the detection by the posture detector, and turns on the illuminating unit when, in addition to the conditions (a) and (b), a condition (d’) that the electric vacuum cleaner is determined to be in a state in which it is oriented in a predetermined direction, from the result of the detection by the posture detector is satisfied.

7. The electric vacuum cleaner as set forth in claim 6, wherein the illumination controller turns off the illuminating unit when at least one of the conditions (a), (b) and (d’) is not satisfied.

8. The electric vacuum cleaner as set forth in claim 6 or 7, wherein the electric vacuum cleaner is of an elongated shape, and the state in which the electric vacuum cleaner is oriented in a predetermined direction is an upright state.

AH26(22091737J ):TCW

9. The electric vacuum cleaner as set forth in claim 8, wherein the illuminating unit is provided to illuminate upward, when the electric vacuum cleaner is in the upright state.