JP2007203101A - Vacuum cleaner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vacuum cleaner which is reduced in size and made lighter in weight. <P>SOLUTION: The vacuum cleaner is provided with a voltage conversion means 42 which can change the boosting rate of the output voltage of a secondary battery 11 and supplies power to a motor-driven blower 6, and a voltage conversion control means 47 for changing the boost rate of the output voltage of the secondary battery 11 by the voltage conversion means 42 according to the driving time of the motor-driven blower 6. Since the temperature rise of the motor-driven blower 6, voltage conversion means 42 and secondary battery 11 can be suppressed, respectively, the driving time of the motor-driven blower 6 by the secondary battery 11 is secured. Since the motor-driven blower 6 is efficiently driven by the secondary battery 11 of a low output voltage, miniaturization and weight reduction can be achieved. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a vacuum cleaner provided with an electric blower to which electric power is supplied from battery means.

  Conventionally, this type of vacuum cleaner has an electric blower. A converter circuit that controls the input voltage to the electric blower is connected to the electric blower. This converter circuit is connected to battery means for supplying electric power to the electric blower, and boosts the output voltage output from the battery means.

  The converter circuit includes a transformer having one coil, and an input terminal is connected to the midpoint of the coil of the transformer. One end of the coil of the transformer is connected to the anode of the first diode, and the other end of the coil of the transformer is connected to the anode of the second diode.

  Further, the cathode of the second diode is connected to the cathode of the first diode to serve as an output terminal. One end of the first switching element is connected between the midpoint of the coil and the connection point of the second diode. One end of the second switching element is connected between the middle point of the coil and the connection point of the first diode. The other end of the first switching element and the other end of the second switching element are connected in common.

The converter circuit includes a control circuit. The control circuit alternately turns on the first switching element and the second switching element, and uses the voltage applied between the input terminal and the common terminal as an input voltage between the output terminal and the common terminal. Output voltage. As a result, this control circuit boosts the output voltage of the battery means with the transformer by the on / off operation of the first switching element and the second switching element (see, for example, Patent Document 1).
JP 2001-16845 A

  However, in the above vacuum cleaner, in order to reduce the size of the battery means, the output voltage of the battery means is boosted by the on / off operation of the first switching element and the second switching element. For this reason, when the output voltage of the battery means passes through the first switching element or the second switching element, the voltage is lowered by the first switching element and the second switching element. As a result, it is difficult to efficiently boost the output voltage of the battery means.

  Further, a transformer is used to efficiently boost the output voltage of the battery means by the on / off operation of the first switching element and the second switching element. Generally, the transformer has other parts in weight and volume. For example, it is larger than a capacitor or a resistor. For this reason, the weight and volume of the entire converter circuit are increased, and there is a problem that it is difficult to efficiently reduce the size and weight.

  This invention is made | formed in view of such a point, and it aims at providing the vacuum cleaner which can be reduced more in size and weight.

  The present invention relates to an electric blower, a voltage conversion means for supplying power to the electric blower that can change the step-up rate of the output voltage of the battery means, and the battery means by the voltage conversion means according to the drive time of the electric blower. And a control means for changing the step-up rate of the output voltage.

  In addition, the present invention provides an electric blower, voltage conversion means for supplying power to the electric blower, the voltage boosting rate of the output voltage of the battery means being changeable, and the battery by the voltage conversion means according to the temperature of the electric blower Control means for changing the step-up rate of the output voltage of the means.

  According to the present invention, since the control means changes the step-up rate of the output voltage of the battery means by the voltage conversion means according to the driving time of the electric blower, the temperature rise of each of the electric blower, voltage conversion means and battery means is increased. Since it can suppress, the drive time of the electric blower by this battery means can be ensured more, and since an electric blower can be efficiently driven with the battery means with a low output voltage, it can reduce in size and weight.

  Further, according to the present invention, since the control means changes the boosting rate of the output voltage of the battery means by the voltage conversion means according to the temperature of the electric blower, the temperature rise of each of the electric blower, the voltage conversion means and the battery means is increased. Since it can suppress, the drive time of the electric blower by this battery means can be ensured more, and since an electric blower can be efficiently driven with the battery means with a low output voltage, it can reduce in size and weight.

  Hereinafter, the structure of the 1st prerequisite technique of the vacuum cleaner of this invention is demonstrated with reference to FIG.

  1 to 3, reference numeral 1 denotes a vacuum cleaner body. The vacuum cleaner body 1 is attached to a case body 2 and a rear portion connected to the upper portion of the case body 2 so that the upper portion can be opened by rotation. A body case 4 having a lid 3 is provided. In addition, as shown in FIG. 2, an electric blower chamber 7 that houses an electric blower 6 as a commutator motor that is driven by rotation of a commutator (not shown) is defined in the case body 2. The temperature of the electric blower 6 increases according to the driving time. A motor silencer cylinder 8 that silences the drive sound emitted from the electric blower 6 accommodated in the electric blower chamber 7 is partitioned and formed above the electric blower chamber 7.

  In the main body case 4 on the front side of the electric blower chamber 7, a battery as a power source as a battery means, that is, a power source chamber 12 for accommodating the secondary battery 11 is defined. The secondary battery 11 supplies electric power to the electric blower 6 and is heavier than the electric blower 6. In addition, an opening 13 for opening the secondary battery 11 in the power supply chamber 12 so as to be detachable is opened below the power supply chamber 12. A battery housing cover 14 that closes the opening 13 is detachably attached to the opening 13 in a state where the secondary battery 11 is housed in the power supply chamber 12 from the opening 13. Furthermore, a charging terminal (not shown) for supplying power to the secondary battery 11 to charge the secondary battery 11 is attached to the center of the rear surface of the case body 2 of the main body case 4.

  Further, a pair of side plate portions 16 are disposed on both sides of the case body 2 so as to protrude upward. The pair of side plate portions 16 are curved inward so that the facing distance on the front side of the substantially intermediate portion in the vertical direction is gradually narrowed. A plurality of exhaust ports 17 communicating with the electric blower chamber 7 and opening toward the substantially front side are formed in the curved front side portion of each of the pair of side plate portions 16.

  Further, traveling wheels 18 as wheels are rotatably supported on both sides below the rear portion of the case body 2. In addition, a turning wheel 19 is attached to the center of the lower portion of the front part of the case body 2 so as to be rotatable, that is, turnable. As a result, the turning wheel 19 can travel on the floor surface by the traveling wheel 18.

  A suction pipe 22 is attached to the front lower surface of the lid 3 of the main body case 4 and is bent in a substantially L shape with the main body suction port 21 opened forward and the lower end opened downward. A handle 23 as a handle means is provided on the upper surface of the lid 3. The handle 23 is formed in a substantially Y shape in plan view.

  A dust cup 25 as a bottomed cylindrical dust collection cup is detachably attached to the front side of the case body 2 of the main body case 4. A pre-filter 26 formed of a mesh member having a bottomed cylindrical shape with a bottom closed in an arc shape and having air permeability is detachably attached to the dust cup 25.

  Furthermore, as shown in FIG. 3, the base end of the flexible hose body 28 is connected to the main body inlet 21 of the cleaner body 1 so as to be detachable. At the tip of the hose body 28, a hand operating portion 29 is provided as operating means that is bent in a substantially square shape. A stop setting button 31, a standard setting button 32, and a strong setting button 33 for setting the driving state of the electric blower 6 and the like are spaced apart from a portion facing the base end side of the bent portion in the hand operating portion 29. Are arranged in parallel.

  Further, a suction port body 36 that is a nozzle body is detachably connected to and connected to the distal end of the hand operation portion 29 of the hose body 28 via an extension pipe 35 that can be expanded and contracted. The extension pipe 35 is attached with an accessory hook 37 to which an accessory such as a gap nozzle (not shown) is detachably attached.

  On the other hand, as shown in FIG. 2, the electric blower 6 is driven in the main body case 4 above the power supply chamber 12 of the vacuum cleaner main body 1 and in front of the electric blower chamber 7 of the vacuum cleaner main body 1. A circuit device 41 for controlling the above is attached. The circuit device 41 is provided with voltage conversion means 42 for boosting the output voltage of the secondary battery 11. Further, as shown in FIG. 1, the circuit device 41 is provided with a blower control means 43 that is connected to the electric blower 6 and controls an input voltage to the electric blower 6.

  The blower control means 43 is connected to the stop setting button 31, the standard setting button 32, and the strong setting button 33 of the hand control unit 29, and the stop setting button 31, the standard setting button 32, and the strong setting button 33 are connected. The driving state of the electric blower 6 is controlled by operating the setting button 33. Further, the blower control means 43 includes a switch 44 as a switching means for switching one of the output voltage of the voltage conversion means 42 and the output voltage of the secondary battery 11 by a switching operation and inputting it to the electric blower 6. . The switch 44 causes the output voltage switched by the switch 44 to be input to the blower control means 43, and the electric blower control means 43 controls the electric blower 6.

  The voltage conversion means 42 includes a frequency setting means 45 for setting an operation of the transistor TR1 for boosting the output voltage of the secondary battery 11, that is, an on / off frequency. The frequency setting means 45 is connected to a frequency control means 46 that varies the output voltage of the voltage converting means 42 in accordance with the frequency setting by the frequency setting means 45. The frequency control means 46 is connected to a voltage conversion control means 47 as a control means for controlling the frequency control means 46. The voltage conversion control means 47 is connected to the frequency setting means 45, and this frequency setting means 45 is controlled by the frequency control means 46. The voltage conversion control means 47 is connected to the blower control means 43 and controlled by the blower control means 43.

  A series circuit of a resistor R1 and a resistor R2 is connected between both ends of the secondary battery 11. The voltage conversion control means 47 is connected between the resistors R1 and R2, and the voltage divided by the resistors R1 and R2 is applied to the voltage conversion control means 47.

  Further, a capacitor C1 is connected in parallel with the series circuit of the resistors R1 and R2. One end of this capacitor C1 is connected to one end of a coil L1 as a voltage conversion coil, and the other end of this coil L1 is connected to the collector of an NPN transistor TR1 as a switching element as switching means. Yes. The emitter of the transistor TR1 is grounded, and the base of the transistor TR1 is connected to the frequency setting means 45.

  The collector of the transistor TR1 is connected to the anode of the diode D1. The cathode of the diode D1 is connected to one end of a capacitor C2, which is a capacitive impedance element, and the other end of the capacitor C2 is grounded. A series circuit of a resistor R3 and a resistor R4 is connected in parallel to the capacitor C2.

  A voltage conversion control unit 47 is connected between the other end of the resistor R3 and one end of the resistor R4, and a current passing through the resistor R3 is input to the voltage conversion control unit 47. Furthermore, the other end of the resistor R3 is connected to one of the switching terminals 48 of the switch 44, and the other of the switching terminals 49 of the switch 44 is connected to the other end of the secondary battery 11.

  Next, the operation of the first prerequisite technology will be described.

  First, the output from one end of the secondary battery 11 is charged to the capacitor C2 through the diode D1 while being switched by the transistor TR1, and the output voltage output from the capacitor C2 to the switch 44 is one end of the secondary battery 11. It is boosted from the output voltage from.

  Further, the output supplied to the transistor TR1 is also supplied to the frequency setting means 45, and the frequency setting means 45 is controlled by the frequency control means 46 by the voltage conversion control means 47 when the electric blower 6 is started or when necessary. Let

  Further, the input voltage divided by the resistor R1 and the resistor R2 and the output voltage divided by the resistor R3 and the resistor R4 are detected by the voltage conversion control means 47. From the voltage conversion control means 47, the electric blower The constant voltage output to 6 is held at a desired value.

  Further, based on the operation of the hand operation unit 29, the blower control means 43 controls the frequency control means 46 via the voltage conversion control means 47 in order to control the input voltage to the electric blower 6.

  At this time, when there is no need to increase the input voltage to the electric blower 6, the voltage conversion means 42 is bypassed and output from the secondary battery 11 by direct output of the secondary battery 11 by the switch 44. Output voltage is passed to the blower control means 43.

  Further, the blower control means 43 controls the frequency control means 46 via the voltage conversion control means 47 and the frequency setting means 45 sets the frequency of the output of the voltage conversion means 42 to control the energy of the coil L1 and the capacitor. Control the voltage of C2.

  At this time, an accurate frequency in terms of functions of main electrical components such as the switching frequency of the coil L1, the loss of the transistor TR1, and the ripple current of the capacitors C1 and C2 so that the input voltage to the electric blower 6 becomes a desired value. That is, by driving the transistor TR1 with a duty, the conversion efficiency in the output voltage of the secondary battery 11 is improved.

  Further, as the electric power input to the electric blower 6 increases, the ripple current of the capacitors C1 and C2 increases and exceeds the tolerance of the capacitors C1 and C2. Therefore, if the frequency set by the frequency setting means 45 is increased by the frequency control means 46 to reduce the ripple current to the capacitors C1 and C2, it is not necessary to increase the electric capacities of these capacitors C1 and C2.

  As described above, according to the first premise technique, in order to improve the cleaning efficiency by the electric blower 6, the input current and the input voltage to the electric blower 6 may be increased. When 6 is a commutator motor, it is technically difficult to increase the current input to the commutator of this electric blower 6 to a predetermined value, for example, 10 A or more, and the carbon of the brush portion that contacts this commutator However, due to wear and sparks generated by the commutator, the phenomenon that the motor cannot be driven occurs and it is difficult to ensure the reliability of the electric blower 6.

  Therefore, in order to increase the input voltage to the commutator and increase the input power without increasing the input current to the commutator of the electric blower 6, a secondary battery 11 in which a plurality of battery bodies are connected in series is provided. However, in order to increase the battery voltage output from the secondary battery 11, the number of the battery bodies of the secondary battery 11 increases, and the weight of the secondary battery 11 increases. The manufacturing cost of the secondary battery 11 is increased.

  Therefore, the output voltage of the secondary battery 11 may be boosted only when necessary, and the output voltage of the secondary battery 11 may be decreased when necessary to ensure the capacity of the secondary battery 11. For this reason, by the switching operation using the switch 44 by the blower control means 43, the electric blower 6 is directly driven by the blower control means 43 with the output voltage of the secondary battery 11, or the blower control means 43 is passed through the voltage conversion means 42. To drive. Further, without increasing the output current from the secondary battery 11, the output voltage of the secondary battery 11 is boosted by the voltage conversion means 42 to increase the input voltage to the electric blower 6.

  Therefore, when the power supplied to the electric blower 6 is small without requiring a strong suction force, that is, when there is no need to increase the output voltage of the secondary battery 11, the secondary battery is not passed through the voltage conversion means 42. 11 output voltages can be directly input to the blower control means 43. As a result, the power consumption in the voltage conversion means 42 can be suppressed, and the loss of the output voltage of the secondary battery 11 is reduced. Therefore, the output voltage can be reduced without reducing the driving efficiency of the electric blower 6 by the secondary battery 11. Low secondary battery 11 can be made.

  Further, when the input voltage to the electric blower 6 is increased, the output voltage of the secondary battery 11 is boosted and the input current flowing to the commutator of the electric blower 6 is not increased to 10 A or more.

  Here, since it is a short time that the electric blower 6 needs to be driven by increasing the input voltage to the electric blower 6, without using the secondary battery 11 having a high output battery voltage, Since the output voltage output from the secondary battery 11 can be boosted to a desired value by the similar secondary battery 11, the driving efficiency of the electric blower 6 by the secondary battery 11 is ensured while the electric blower 6 The electric blower 6 can be driven without increasing the value of the current flowing to the commutator.

  In addition, since the secondary battery 11 having a high battery voltage or a light lithium (Li) battery is expensive, the weight of the circuit device 41 is lighter and cheaper than the secondary battery 11 having a high battery voltage. By using the secondary battery 11 and the circuit device 41 having a low battery voltage, the manufacturing cost of the secondary battery 11 can be reduced, and the vacuum cleaner body 1 can be reduced in weight and size.

  Further, when the output voltage of the secondary battery 11 is boosted by the voltage conversion means 42, the frequency of the output of the voltage conversion means 42 is controlled by the frequency control means 46 and set by the frequency setting means 45. Since the output voltage of the secondary battery 11 can be boosted by increasing the output frequency of the voltage conversion means 42 by the frequency setting means 45 using the control means 46, the driving efficiency of the electric blower 6 by the secondary battery 11 is lowered. The secondary battery 11 with a lower output voltage can be obtained without any problem.

  Therefore, compared with the case where the output voltage of the secondary battery 11 is boosted by combining a converter circuit (not shown), the output voltage of the secondary battery 11 can be boosted with a simple configuration, so the circuit device 41 can be reduced in weight and size, Manufacturing cost can be reduced.

  Further, since the frequency setting means 45 increases the output frequency of the voltage conversion means 42 with the capacitor C2, the substantial electric capacity of the relatively heavy and large volume capacitor C2 of the circuit device 41 can be reduced. Therefore, the cleaner body 1 can be further reduced in size and weight.

  And when setting the input voltage to this electric blower 6 by the use at the time of cleaning by driving the electric blower 6, the driving time, and the suction force, the switching frequency and duty of the coil L1 are set to the loss of the transistor TR1, By controlling the ripple currents of the capacitors C1 and C2 in the optimum mode, the electric blower 6 can be accurately controlled and driven.

  Next, a second prerequisite technique of the present invention will be described with reference to FIG.

  The circuit device 41 shown in FIG. 4 is basically the same as the circuit device 41 shown in FIGS. 1 to 3, but causes the transistor TR1 to perform the switching operation by the switch of the blower control means 43.

  Therefore, in the circuit device 41 shown in FIG. 4, the electric blower 6 is directly driven by the blower control means 43 with the output voltage of the secondary battery 11 by the switching operation by the transistor TR1, or the blower control is performed through the voltage conversion means 42. Since it is driven by the means 43, it is possible to achieve the same effects as the circuit device 41 shown in FIGS.

  Further, when the operation of the transistor TR1 is stopped and turned off, the DC voltage output of the secondary battery 11 passes with almost no loss in the coil L1, so that it is almost equivalent to the operation when the voltage conversion means 42 is bypassed. become. Here, since the inductance of the coil L1 is generally about several tens of μH to several hundreds of μH, the impedance value of the coil L1 is almost zero, so that the output of the secondary battery 11 is hardly affected, and the transistor Equivalent operation is possible by switching TR1.

  Further, since a mechanical mechanism such as a switch for switching the output of the secondary battery 11 is not required, the configuration of the circuit device 41 can be simplified, and the circuit device 41 can be reduced in weight and size.

  Next, an embodiment of the present invention will be described with reference to FIG.

  The circuit device 41 shown in FIG. 5 is basically the same as the circuit device 41 shown in FIG. 4 except that a resistor R5 as an identification means for identifying the type of the secondary battery 11 is integrated with the secondary battery 11. The voltage value of the resistor R5 is detected by the voltage conversion control means 47 to identify the type of the secondary battery 11, such as battery voltage, electric capacity, battery characteristics, etc. The voltage conversion control means 47 changes the step-up rate of the output voltage of the secondary battery 11 by the voltage conversion means 42.

  Specifically, the voltage conversion control means 47 increases the step-up rate in the case of the high-performance secondary battery 11 from the duration, and boosts the voltage in the case of the inexpensive secondary battery 11 with inferior performance. Reduce the rate. As a result, even the secondary battery 11 having different performance is advantageous in terms of duration. Further, the voltage conversion control means 47 increases the step-up rate of the secondary battery 11 having a high output voltage and lowers the step-up rate of the secondary battery 11 having a low output voltage. As a result, similar performance can be obtained even with the secondary battery 11 having different output voltages.

  Further, the secondary battery 11 includes a series power supply unit 51 that outputs power to the outside, and a negative terminal 52 of the power supply unit 51 is grounded to the voltage conversion means 42. Further, the plus terminal 53 of the power supply unit 51 is connected to one end of the thermostat 54, and the other end of the thermostat 54 is connected to one end of the resistor R5. In addition, one end of the resistor R5 is connected to one end of the resistor R1 of the voltage conversion means 42 and is also connected to the blower control means 43. Further, the other end of the resistor R5 is connected to the voltage conversion control means 47.

  Further, a thermistor TH1 as temperature sensing means for sensing the temperature rise of the power supply unit 51 is disposed in the vicinity of the power supply unit 51 of the secondary battery 11. The resistance value of the thermistor TH1 changes as the temperature of the power supply unit 51 of the secondary battery 11 increases. Further, both ends of the thermistor TH1 are connected to the blower control means 43, and the blower control means 43 detects temperature sensing by the thermistor TH1. The blower control means 43 is grounded to the voltage conversion means 42 and grounded to the outside. Then, the blower control means 43 changes the step-up rate of the output voltage output from the secondary battery 11 by the voltage conversion means 42 in response to the temperature rise in the power source 51 of the secondary battery 11 by the thermistor TH1. Let

  The blower control means 43 is provided with timer means 55 capable of measuring time. The blower control means 43 uses the timer means 55 to measure the continuous drive time of the electric blower 6, and this timer means. When the driving time of the electric blower 6 measured at 55 reaches a predetermined time, for example, about 3 to 5 minutes, the voltage conversion means 42 changes the voltage boosting rate of the output voltage of the secondary battery 11 and specifically decreases it. Let

  Further, the blower control means 43 is used when the electric blower 6 is driven after the drive of the electric blower 6 is temporarily stopped for a predetermined time, for example, 30 seconds to 1 minute, by the operation of the manual operation unit 29. Assumes that the electric blower 6 has been driven continuously, and controls the voltage conversion means 42 to increase the output voltage of the secondary battery 11. The blower control means 43 resets the drive time of the electric blower 6 measured by the timer means 55 when the electric blower 6 is stopped for about 3 to 5 minutes.

  Further, the blower control means 43 detects the resistance value of the resistor R5 and the temperature sense of the thermistor TH1 via the voltage conversion control means 47, and from the resistance value and temperature information, the power supply unit 51 of the secondary battery 11 is detected. The voltage conversion means 42 changes the step-up rate of the output voltage of the secondary battery 11 in accordance with the detected discharge state, that is, the remaining battery potential of the secondary battery. Specifically, the blower control means 43 lowers the step-up rate of the output voltage of the secondary battery 11 by the voltage conversion means 42 when the discharge state of the power supply unit 51 of the secondary battery 11 falls below a predetermined value. .

  Further, the blower control means 43 detects a temperature rise of the electric blower 6 by a thermistor as a temperature sensor (not shown) attached to the electric blower 6 and responds to the detected temperature rise of the electric blower 6. Thus, the voltage conversion means 42 changes the step-up rate of the output voltage of the secondary battery 11. Specifically, the blower control means 43 outputs the output of the secondary battery 11 in order to suppress the temperature rise of the electric blower 6, the circuit device 41, and the secondary battery 11 when the electric blower 6 rises above a predetermined temperature. Reduce the voltage boost rate.

  As a result, the circuit device 41 shown in FIG. 5 similarly drives the electric blower 6 directly by the blower control means 43 with the output voltage of the secondary battery 11 by switching by the transistor TR1, or through the voltage conversion means 42. Since it is driven by the blower control means 43, the same operational effects as the circuit device 41 shown in FIG. 4 can be obtained.

  Further, based on the detection of the resistance value of the resistance R5 of the secondary battery 11, the output voltage of the secondary battery 11 is measured by the voltage conversion control means 47 to identify the type of the secondary battery 11, and this identification information In response, the voltage conversion control means 47 changes the step-up rate of the output voltage of the secondary battery 11 by the voltage conversion means 42. For this reason, even when a secondary battery 11 of a different type is connected to the voltage conversion means 42, the output voltage of the secondary battery 11 is boosted by the voltage conversion control means 47 at a boost rate suitable for the type of the secondary battery 11. it can.

  Accordingly, the electric blower 6 can be used even with the secondary battery 11 having different battery voltage, current capacity, battery characteristics, etc., such as nickel cadmium (Ni—Cd) battery, nickel metal hydride (Ni—H) battery, and lithium (Li) battery. Since the electric blower 6 can be efficiently operated even with the secondary battery 11 having a different output voltage because it can be driven efficiently, the secondary battery 11 can be replaced according to convenience, and the electric blower 6 can also be used with the secondary battery 11 with a low output voltage. Since the secondary battery 11 can be made smaller and lighter, the manufacturing cost can be reduced.

  Further, the change of the resistance value of the resistance R5 of the secondary battery 11 and the resistance value of the thermistor TH1 are detected, and the discharge state of the power supply unit 51 of the secondary battery 11 is detected by the blower control means 43, and the detected discharge state Accordingly, the blower control means 43 causes the voltage conversion means 42 to change the step-up rate of the output voltage of the secondary battery 11. For this reason, the consumption speed of the output voltage of the secondary battery 11, that is, the discharge speed can be reduced. Therefore, since the driving time of the electric blower 6 by the secondary battery 11 can be further secured, the electric blower 6 can be efficiently driven by the secondary battery 11 having a low output voltage. Therefore, the secondary battery 11 is made smaller and lighter. It is possible to prevent the secondary battery 11 from being unchargeable due to a rapid voltage consumption of the secondary battery 11.

  Further, the blower control means 43 changes the step-up rate of the output voltage of the secondary battery 11 by the voltage conversion means 42 in response to sensing the temperature rise of the power source 51 of the secondary battery 11 by the thermistor TH1, so Heat generation from the power supply unit 51 of the secondary battery 11 can be suppressed, and a temperature rise of the power supply unit 51 can be suppressed. Therefore, since the drive time of the electric blower 6 by the power supply unit 51 of the secondary battery 11 can be further secured, the electric blower 6 can be efficiently driven by the secondary battery 11 having a low output voltage. Can be reduced in size and weight.

  Furthermore, the continuous drive time of the electric blower 6 is measured by the blower control means 43 using the timer means 55, and when this drive time reaches a predetermined time, the blower control means 43 uses the voltage conversion means 42 to recharge the secondary battery. Decrease the output voltage boost rate of 11. For this reason, the temperature rise of each of these electric blower 6, circuit device 41, and secondary battery 11 can be controlled. Therefore, since the deterioration of each of the electric blower 6, the circuit device 41, and the secondary battery 11 can be prevented, the capacity of each of the electric blower 6, the circuit device 41, and the secondary battery 11 can be further reduced, and the cleaner body 1 can be further reduced. Can be reduced in size and weight.

  Further, the blower control means 43 continuously stops the electric blower 6 when the electric blower 6 is driven after temporarily stopping the drive of the electric blower 6 for a predetermined time, for example, about 30 seconds to 1 minute. Since the voltage conversion means 42 controls the step-up rate of the output voltage of the secondary battery 11 assuming that it is driven, the electric blower 6 is temporarily stopped during cleaning and the temperature of the electric blower 6 is not sufficiently lowered. Even when the electric blower 6 is driven again, the temperature rise of each of the electric blower 6, the circuit device 41, and the secondary battery 11 can be suppressed.

  For this reason, for example, the temperature rise of each element such as a power transistor and a capacitor (not shown) can be prevented, and thus the capacitance of each element such as the power transistor and the capacitor can be reduced. As a result, since each element such as the power transistor and the capacitor can be reduced in size and weight, the cleaner body 1 can be further reduced in size and weight.

  Further, when the electric blower 6 is stopped for about 3 to 5 minutes, the drive time of the electric blower 6 measured by the timer means 55 is reset by the blower control means 43. For this reason, the temperature rise of the secondary battery 11 when the drive of the electric blower 6 is stopped and the power supply unit 51 of the secondary battery 11 is cooled to a predetermined temperature can be more efficiently suppressed.

  Further, the blower control means 43 detects a temperature rise of the electric blower 6 by a thermistor attached to the electric blower 6, and according to the detected temperature rise of the electric blower 6, the output voltage boost rate of the secondary battery 11 is increased. Is changed by the voltage conversion means 42. For this reason, when the electric blower 6 rises above a predetermined temperature due to continuous driving, the temperature rise of the electric blower 6, the circuit device 41, and the secondary battery 11 is suppressed, so that the output voltage of the secondary battery 11 is increased. If the rate is lowered, the electric blower 6, the voltage conversion means 42 and the secondary battery 11 can be prevented from deteriorating, so that the capacity of the electric blower 6, the voltage conversion means 42 and the secondary battery 11 can be further reduced. Moreover, since the drive time of the electric blower 6 by this secondary battery 11 can be ensured more, the electric blower 6 can be efficiently driven with the secondary battery 11 with a low output voltage. Therefore, the cleaner body 1 can be further reduced in size and weight.

  In the above embodiment, the type of the secondary battery 11 is identified by the resistor R5 attached to the secondary battery 11. For example, a protrusion is provided on the secondary battery 11, and the position of the protrusion is determined. Even in the configuration in which the type of the secondary battery 11 can be identified by the shape or the shape, the same operational effects as those of the third embodiment can be obtained.

It is a block diagram which shows the 1st premise technique of the vacuum cleaner of this invention. It is sectional drawing which shows the vacuum cleaner main body of a vacuum cleaner same as the above. It is a perspective view which shows a vacuum cleaner same as the above. It is a block diagram which shows the 2nd prerequisite technique of this invention. It is a block diagram which shows one embodiment of this invention.

Explanation of symbols

6 Electric blower
11 Secondary batteries as battery means
42 Voltage conversion means
47 Voltage conversion control means as control means

Claims (2)

An electric blower,
A voltage conversion means for changing the step-up rate of the output voltage of the battery means and supplying power to the electric blower;
A vacuum cleaner comprising: control means for changing a step-up rate of the output voltage of the battery means by the voltage conversion means according to the drive time of the electric blower. An electric blower,
A voltage conversion means for changing the step-up rate of the output voltage of the battery means and supplying power to the electric blower;
A vacuum cleaner comprising: control means for changing a step-up rate of the output voltage of the battery means by the voltage conversion means according to the temperature of the electric blower.

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