RU2484757C1 - Electric vacuum cleaner - Google Patents

Abstract

FIELD: personal use articles.

SUBSTANCE: invention relates to an electric vacuum cleaner with the electric blower phase adjustment function; the vacuum cleaner contains an electric blower, a control element for setting the electric blower input current phase angle, a variable resistor that can set the resistance magnitude (so that to enable its adjustment) and thus set the electric blower power (so that to enable its adjustment), and a control means for setting the electric blower input current phase angle (in accordance with the variable resistor resistance magnitude), the phase angle set (by means of the control element) from the pre-set phase angle range the harmonics whereof are generated with a magnitude the value whereof is no les than the preset limit value.

EFFECT: improvement of technical properties.

4 cl, 8 dwg

Description

The embodiments described herein generally relate to an electric vacuum cleaner with a phase control function of an electric fan.

Typically, an electric vacuum cleaner of this type includes a main body of the vacuum cleaner containing an electric fan. In the main body of the vacuum cleaner, the dust collecting chamber (dust collecting chamber) is formed communicating with the suction side of the electric fan. The dust collecting chamber has a dust collecting member, such as a dust bag or dust collecting container, and holds dust that is sucked in by driving an electric fan of the vacuum cleaner.

In such an electric vacuum cleaner, it is desirable that the suction power of the electric fan is variable depending, for example, on the amount of dust on the surface being cleaned. If the suction power is variable, then the input current of the electric fan, in general, can have an adjustable phase.

This technical problem was solved due to the fact that the electric vacuum cleaner according to the invention contains an electric fan; a control element for setting the phase angle of the input current of the electric fan; a variable resistor, which sets the resistance value with a possibility of change and thereby sets the power of the electric fan with a possibility of change; and control means for setting, in accordance with the resistance value of the variable resistor, the phase angle of the input current of the electric fan specified by the control element from the range of the predefined phase angle, the harmonics of which are generated with a value of at least a predetermined limit value.

Preferably, the electric vacuum cleaner further comprises current measuring means for measuring a current value of the electric fan, wherein when the current value of the electric fan measured by the current measuring means is not less than a predetermined value, the control means sets a phase angle of the input current of the electric fan, defined by the control from the range of the predefined phase angle, the harmonics of which are generated from value whose value is not less than a given limit value.

Preferably, in cases where the phase angle of the input current of the electric fan specified by the control element is less than or more than a predetermined phase angle, the harmonics of which are generated with a value whose value is not less than the specified limit value, the control means changes the magnitude of the change in the phase angle of the input current of the electric a fan, set by means of a control element, in accordance with the magnitude of the change in the resistance value of the variable resistor.

Preferably, the control means sets the magnitude of the change in the phase angle of the input current of the electric fan, set by the control element, in accordance with the magnitude of the change in the resistance value of the variable resistor, in the region in which the phase angle of the input current of the electric fan is less than a predetermined phase angle, the harmonics of which are generated with , the value of which is not less than a predetermined limit value, and also relatively increases the coefficient of variation of the phase angle of the input current of the electric fan, which will be set by means of a control element corresponding to the coefficient of change of the resistance value of the variable resistor, in a relatively small region in which the phase angle of the input current of the electric fan is greater than the predetermined phase angle, the harmonics of which are generated with the value which is not less than a given limit value.

The invention will now be explained in more detail with reference to the accompanying drawings, in which:

1 is a block diagram illustrating an internal structure of an electric vacuum cleaner of a first embodiment of the invention.

Figure 2 is a perspective view of an electric vacuum cleaner.

Figure 3 (a) is a graph schematically illustrating a characteristic of a change in a resistance value of a variable resistor of an electric vacuum cleaner.

Figure 3 (b) is a graph schematically illustrating a table of ratios of the stroke of a variable resistor and the input current of an electric fan, determined by means of a control, the input current being set by the control element.

4 is a graph illustrating the relationship between the input current of the electric fan and the current of the (third) harmonic.

5 is a block diagram illustrating an internal structure of an electric vacuum cleaner of a second embodiment of the invention.

6 (a) is a graph schematically illustrating a characteristic of a change in a resistance value of a variable resistor of an electric vacuum cleaner.

6 (b) is a graph schematically illustrating a table of ratios of the stroke of a variable resistor and the input current of an electric fan installed by means of a control, the input current being set by the control element.

7 is a graph illustrating the relationship between the input current of the electric fan and the current of the (third) harmonic.

Fig. 8 (a) is a graph schematically illustrating a characteristic of a change in a resistance value of a variable resistor of an electric vacuum cleaner of a third embodiment of the invention.

Fig. 8 (b) is a graph schematically illustrating a table of the ratios of the stroke of a variable resistor and the input current of an electric fan, determined by means of a control, the input current being set by the control element.

In FIG. 2, the reference numeral 11 denotes a so-called container-type electric vacuum cleaner, wherein the electric vacuum cleaner 11 has a main body 12 of the vacuum cleaner and an air duct forming member 13 that is a tube and can be disconnected from the main body 12 of the vacuum cleaner.

The main body 12 of the vacuum cleaner can rotate and move along the surface to be cleaned, and also includes an electric fan 15 and a dust collection part (not shown) that communicates with the suction side of the electric fan 15. The suction hole 17 of the main body, which communicates with the dust collection part, and also to which the end of the duct forming element 13 is joined from the base side, openly on the front of the main body 12 of the vacuum cleaner. The power switch 18, which serves to turn on / off the electric part, including the electric fan 15, that is, serves to turn on / off the electric vacuum cleaner 11, is located on the upper part of the main body 12 of the vacuum cleaner in a position that is facing the user and can be visually recognized by the user. The adjustment part 19, which serves to enable the user to set with the possibility of changing the suction power of the electric fan 15, is located approximately in the central part of the upper part of the main body 12 of the vacuum cleaner. An outlet 20 is formed on the main body 12 of the vacuum cleaner to effect a discharge.

The duct forming member 13 includes: a connecting pipe 21 connected to a suction hole 17 of the main body; a flexible hose 22 connected to the tip of the connecting tube 21; a manual control part 23 provided at the tip of the hose 22, which allows the user to hold and control the duct forming member 13; a telescopic tube 24 connected to the tip of the part 23 of the manual control with the possibility of disconnection; and a floor brush 26 as an element of the suction opening connected to the tip of the telescopic tube 24. The air duct forming element 13 is a component of the air duct, in which the air duct connected to the suction side of the electric fan 15, together with the dust collecting part, etc. divided into several parts.

For example, the dust collection part may be a dust bag, such as, for example, a paper bag, a dust collecting device, such as, for example, a cyclone (centrifugal) separation device, or simply a filter and retains dust that is sucked together with air through the forming element 13 the duct by driving the electric fan 15 of the vacuum cleaner.

Next, the internal structure of the electric vacuum cleaner 11 will be described.

As shown in FIG. 5, the series connection of the electric fan 15 and the control element 31 of the electric vacuum cleaner 11 is electrically connected to an AC power supply, for example, with a voltage range of 100-240V by means of a power cord (not shown). The power cord is wound on a cord reel located in the main body 12 of the vacuum cleaner (FIG. 2), and the plug end of the cord connected to a power outlet on a wall surface or the like is located outside the main body 12 of the vacuum cleaner (FIG. 2). The plug part of the power cord is pulled out of the cord coil to connect to a power outlet located far from the main body 12 of the vacuum cleaner (FIG. 2), and also wound around the cord coil so that the main part of the power cord is housed in the main body 12 of the vacuum cleaner (FIG. .2).

The control element 31 controls the phase of the AC mains e to set the phase angle of the input current of the electric fan 15. For example, the control element 31 may be an AC control element, such as a symmetrical triode thyristor, and the control contact 31a is electrically connected to the control means 32.

The control means 32 turns the control element 31 on / off by transmitting the trigger signal to the control terminal 31a of the control element 31, and also determines the phase angle of the input current of the electric fan 15, which will be set by the control element 31. The control means 32 is electrically connected to the variable resistor 33. For example, the control means 32 may be a digital microcomputer circuit or the like, and may also detect a zero crossing point of the waveform of the AC voltage e AC using the zero crossing detection means 34, such as Known zero crossing detection scheme.

In this case, the adjustment element 33a of the variable resistor 33 is connected to the adjustment part 19 (FIG. 2) and is moved by sliding the adjustment part 19 (FIG. 2), and thus the resistance value can be set to change it. The characteristic of changing the resistance value of the variable resistor 33 is smooth, without bending points, at least in the region corresponding to the range of the predefined phase angle of approximately 90 ^° , harmonics of which are generated with a value whose value is not less than the specified limit value L (k for example, the limit value established by the IEC standards, Figure 4). In an embodiment, in particular, as shown in FIG. 3 (a), the resistance value of the variable resistor 33 increases, for example, as the adjustment part 19 (FIG. 2) moves in one direction (for example, in the left side) and decreases as you move the adjusting part 19 (Figure 2) to the other side (for example, to the right side). That is, the resistance value of the variable resistor 33 varies linearly. In addition, one end of the variable resistor 33 is electrically connected to a predetermined constant voltage power supply (not shown), the other end is grounded, the voltage of the constant voltage power supply is divided by changing the resistance value, and the divided voltage is read using the control means 32.

That is, the control means 32 digitally converts and reads the divided voltage corresponding to the resistance value, which is an analog value, of the variable resistor 33 in each zero crossing cycle detected by the zero crossing detecting means 34, and thus determines the timing of the trigger signal ( trigger pulse), which must be transmitted to the control element 31, in addition, additionally determines the phase angle of the input current of the electric fan and 15, which will be set by the control element 31. In other words, the control means 32 supplies a trigger signal corresponding to the turn-off time from the zero transition point to the control terminal 31a of the control element 31 for turning the control element 31 on / off, and also controls the input current of the electric fan 15. Accordingly, the electric vacuum cleaner 11 sets the power electric fan 15 with the possibility of changing by variable setting the resistance value of the variable resistor 33.

For example, when determining the phase angle, the control means 32 compares the read divided voltage with a table of ratios stored in the storage means (not shown). For example, as shown in FIG. 3 (b), in the ratio table, the input current linearly increases (decreases) as the resistance value decreases in area A, in which the resistance value of the variable resistor 33 is less than the predefined first threshold, which was is set in advance, the constant input current is set regardless of the change (increase / decrease) in the resistance value of the variable resistor 33 in region B, in which the value of the resistance value of the variable resistor 33 is no less than previously set of the first threshold and a less predetermined second threshold, which were set in advance, in a phase angle of approximately 90 °, the harmonics of which are generated with a value whose value is not less than the specified limit value L (Figure 4), and the input current increases linearly ( decreases) with a decrease (increase) in the resistance value in region C, in which the value of the resistance value of the variable resistor 33 is not less than a predefined second threshold, which was set in advance. That is, in the ratio table, the phase angle defined by the control element 31 is set from a phase angle range of approximately 90 °, the harmonics of which are generated with a value whose value is not less than a given limit value L (Figure 4). Moreover, for example, the degree of change in the input current, that is, the magnitude of the change in the input current corresponding to the magnitude of the change in the resistance values in region A and region C, are set approximately equal to each other.

Moreover, in the embodiment, since the control means 32 is a digital circuit, changing the input current of the relationship table has a clear step shape. However, since the difference between the steps can be arbitrarily set small in a range that does not have problems in practical use, the description will be presented with the assumption that the change in the input current of the ratio table is smooth.

Next, operations with the first embodiment of the invention will be described.

The user electrically connects the electric vacuum cleaner 11 to the AC power supply by connecting the power cord to a socket, starts the electric vacuum cleaner 11 by switching the power switch 18, moves the adjustment part l9 to the left or right depending on the situation, taking into account the type, amount of dust or the like on the cleaned surface and stops the adjustment part 19 in a position in which the suction power of the electric fan 15 corresponds to the desired power ty suction.

That is, the control means 32 digitally converts and reads the divided voltage in each zero-crossing cycle detected by the zero-crossing detection means 34, wherein the divided voltage corresponding to the resistance value of the variable resistor 33 is set based on the movement position of the variable resistor control element 33 a 33, corresponding to the movement position of the adjustment part 19 set by the user, and the control means 32 is divided depending voltage determines the moment of transmission of the trigger signal to the control element 31 and thus sets the phase angle of the input current of the electric fan 15, set by the control element 31.

In particular, as shown in FIG. 3 (b), when the resistance value of the variable resistor 33 is in region A, the control means 32 linearly increases (decreases) the input current as the resistance value decreases (increases).

When the resistance value of the variable resistor 33 is in region B, the control means 32 sets a constant input current regardless of the change (increase / decrease) in the resistance value of the variable resistor 33.

In addition, when the resistance value of the variable resistor 33 is in region C, the control means 32 linearly increases (decreases) the input current as the resistance value decreases (increases).

As a result, as shown in FIG. 4, the current value of the (third) harmonic does not exceed a predetermined limit value L.

The user prompts the electric vacuum cleaner to suck in dust with air through the negative pressure generated by driving the electric fan 15 operating at the desired power from the surface to be cleaned through the duct forming member 13 including the floor brush 26, etc. The sucked-in dust is transferred with air and is held in the dust collection part. Moreover, the air remaining after dust separation reaches the electric fan 15, and then is discharged outside the main body 12 of the vacuum cleaner through the outlet 20.

After the cleaning is completed, the user switches the power switch 18 to turn off the electric vacuum cleaner 11 (electric fan 15).

As described above, in accordance with the first embodiment, the control means 32 sets, depending on the resistance value of the variable resistor 33, the phase angle of the input current of the electric fan 15 set by the control element 31 from a range of a predetermined phase angle of approximately 90 °, harmonic which are generated with a value whose value is not less than the specified limit value L, so that the harmonics contained in the input current can be suppressed when Using a universal variable resistor 33.

Next, a second embodiment will be described with reference to FIGS. In addition, since the same reference numerals refer to the same configurations and actions with the first embodiment, a description thereof will be omitted.

In the second embodiment, as shown in FIG. 5, the control means 32 of the first embodiment, using the current measuring means 37, measures the amount of current supplied to the electric fan 15.

Only when the current magnitude measured by the current measuring means 37 of the electric fan 15 is at least a predetermined value that has been set in advance, the control means 32 sets the phase angle of the input current of the electric fan 15 set by the control element 31 from the range of the a given phase angle of approximately 90 °, the harmonics of which are generated with a value whose value is not less than a given limit value L.

In particular, as shown in FIG. 6, the control means 32, depending on the current value measured by the current measuring means 37, the electric fan 15 selects the desired relationship table from the plurality of relationship tables stored in the storage means, or sets the first to be changed and / or the second threshold of the correlation table and thus can change the range of region B corresponding to the range of a predefined phase angle of approximately 90 °, the harmonics of which are generated from a current, the value of which is not less than a predetermined limit value L. In particular, the control means 32 reduces the region B when the current value measured by the current measuring means 37 of the electric fan 15 is relatively small (less than a predetermined value), and also increases region B, when the magnitude of the current measured with the current measuring means 37 of the electric fan 15 is relatively large (not less than a predetermined value). In addition, the range of region B can be changed in a plurality of steps or without a step. Moreover, region B should not exist when setting the minimum.

When the amount of air sucked by the vacuum cleaner into the electric fan 15 is relatively reduced, for example, in the dust collecting part, etc. no less than a predetermined amount of dust has been accumulated, the current value of the electric fan 15 is relatively reduced. Therefore, as shown in FIG. 7 by an additional dash-dot line, the current of the (third) harmonic also decreases. Accordingly, when the current value measured by the current measuring means 37 of the electric fan 15 is relatively reduced (does not exceed a predetermined value), the (third) harmonic current does not exceed the predetermined limit value L, even if the control means 32 decreases the region B.

As described above, in accordance with the second embodiment, the control means 32, when the value of the current detected by the current detection means 37 of the electric fan 15 of at least a predetermined value that has been set in advance determines the phase angle of the input current of the electric fan 15 , which will be set by the control element 31, from a range of a predetermined phase angle of approximately 90 °, the harmonics of which are generated with a value of the value of which is not less than a predetermined value of L, and thus, for example, in the case where the current value of the electric fan 15 is less than a predetermined value, and the harmonics are almost not generated, the control by means of the control 32 can be simplified, and the change in the electric power the fan 15 can become smoother, corresponding to the stroke operation of the adjustment part 19, that is, a change in the resistance value of the variable resistor 33.

In addition, in each of the above embodiments, the input current set by the control means 32 in the region B does not always have to be constant until the predetermined harmonic value exceeds a predetermined limit value L.

Next, a third embodiment will be described with reference to FIG. In addition, since the same reference numerals refer to the same configurations and operations for each of the above described embodiments, a description thereof will be omitted.

In the third embodiment, as in each of the aforementioned embodiments, in cases where the phase angle of the input current of the electric fan 15 set by the control element 31 is less than or greater than a predetermined phase angle of 90 °, harmonics of which are generated with a value whose value is not less than a predetermined limit value L, the control means 32 changes the amount of change in the phase angle of the input current of the electric fan 15, set by the control element 31, in accordance with the amount of change of the resistance value of the variable resistor 33.

In particular, the control means 32 sets a change in the phase angle of the input current of the electric fan 15 set by the control element 31 corresponding to a change in the resistance value of the variable resistor 33, relatively small in a region D in which the phase angle of the input current of the electric fan 15 is smaller than the phase angle 90 ° in this embodiment, the harmonics of which are generated with a value whose value is not less than the specified limit value L, and sets the values well, the change in the phase angle of the input current of the electric fan 15, set by the control element 31, corresponding to the change in the resistance value of the variable resistor 33 is relatively large in the region E, in which the phase angle of the input current of the electric fan 15 is not less than the 90 ° phase angle in this embodiment whose harmonics are generated with a value whose value is not less than a given limit value L. That is, since the degree of change in the phase angle is specified by t Blitz in region E ratios greater than in the region D, control means 32 sets the phase angle defined by the control member 31, from the phase angle (approximately equal to 90 °), which harmonics are generated with a magnitude which is not less than a predetermined limit value L.

Accordingly, the input current linearly increases (decreases) as the resistance value decreases (increases) when the resistance value of the variable resistor 33 is in region D, in addition, the input current linearly increases (decreases) with a degree of change greater than in region D, as the resistance value decreases (increases), when the resistance value of the variable resistor 33 is in the region E.

As described above, in accordance with the third embodiment, in cases where the phase angle of the input current of the electric fan 15 specified by the control element 31 is less than or greater than a predetermined phase angle, the harmonics of which are generated with a value whose value is not less than a predetermined limit value L, the control means 32 changes the amount of change in the phase angle of the input current of the electric fan 15 set by the control element 31 in accordance with the amount of change Nia value of resistance of the variable resistor 33 and thus can more smoothly change the power of the electric blower 15 in accordance with control of the regulating portion 19 by the user, i.e. the change of the variable resistor 33, the resistance value.

Basically, the user needs to fine-tune the power of the electric fan 15 when setting a relatively low power and does not need to fine-tune the power of the electric fan 15 when setting a relatively high power. Then, the magnitude of the change in the phase angle of the input current of the electric fan 15 set by the control element 31 corresponding to the magnitude of the change in the resistance value of the variable resistor 33 is set relatively small in a region D in which the phase angle of the input current of the electric fan 15 is smaller than the phase angle (90 °), which harmonics are generated with a value whose value is not less than a given limit value L, and the magnitude of the change in the phase angle of the input current of the electric fan 15, for dictated by the control element 31, corresponding to the change in the resistance value of the variable resistor 33, is set relatively large in the region E, in which the phase angle of the input current of the electric fan 15 is greater than (not less than) the phase angle (90 °), the harmonics of which are generated with the value which is not less than the specified limit value L. Therefore, when the power of the electric fan 15 is relatively small, the magnitude of the change in the input current (power) of the electric valve torus 15 is small even when the user specifies a large stroke adjusting portion 19, and thus accurate power control can be performed. When the power of the electric fan 15 is relatively high, the user can widely change the input current (power) of the electric fan 15 without setting a large stroke adjustment part 19.

In accordance with at least one of the above embodiments, the control means 32, in accordance with the resistance value of the variable resistor 33, sets the phase angle of the input current of the electric fan 15 set by the control element 31 from the range of the predetermined phase angle, i.e. approximately equal to 90 °, the harmonics of which are generated with a value whose value is not less than the specified limit value L, and thus the harmonics contained in the input current can be suppressed using a universal variable resistor 33. Thus, it is not necessary to use an expensive specialized variable resistor even, for example, for an electric vacuum cleaner 11 having different supply voltages and a maximum input current, and an inexpensive multi-function electric vacuum cleaner 11 can be provided, as well as power factor reduction and noise generation due to harmonics can be eliminated.

Since the electric vacuum cleaner 11 uses an electric fan 15, which mainly uses a large current of approximately 10A, controls the output of the electric fan 15 in a wide range from 0 to maximum and is a fixed used set input current set by the user, harmonics are easily generated. Accordingly, since the control means 32 of each of the above described embodiments determines the phase angle of the input current of the electric fan 15 set by the control element 31, harmonics can be effectively suppressed uniformly in such an electric vacuum cleaner 11.

In addition, the user can freely check the power of the electric fan 15 by visually determining the position of the adjustment part 19, so that the electric vacuum cleaner becomes easy to handle.

In addition, since the control means 32 is formed by a digital circuit, it is possible to freely control the setting of the phase angle of the input current of the electric fan 15.

Moreover, in each of the above embodiments, since the change in the resistance value of the variable resistor 33 is smooth, without bending points, at least in the region corresponding to the range of the predetermined phase angle, the harmonics of which are generated with a value whose value is not less than the specified limit value L, it does not always have to be linear. That is, the resistance value of the variable resistor 33 can be changed, for example, according to the so-called LOG curve, or a bend point can be formed in the upper limit value, lower limit value, or the like, in the region other than the region corresponding to the range of the predetermined phase angle whose harmonics are generated with a value whose value is not less than a given limit value L.

The variable resistor 33 can be located in any position, for example, on the element 13 of the formation of the duct (part 23 of the manual control).

It is conceivable that, for example, instead of the known zero-crossing detection circuit, means for detecting zero-crossing are implemented so that the magnitude of the AC voltage e is directly read by means of control 32, and also a zero-crossing point is determined in control means 32. In particular, the control means 32 exposes the alternating current of the AC mains e to half-wave rectification, divides and receives the mains voltage e, digitally converts the divided voltage and transmits to the control element 31 a trigger signal corresponding to the turn-off time at the time when the divided voltage becomes equal 0.

In addition, the control means 32 may be formed by an analog circuit using, for example, a comparator, etc.

Although specific embodiments have been described, these embodiments have been presented for illustrative purposes only and are not intended to limit the scope of the invention. Moreover, the new embodiments described herein may be implemented in many other forms; among other things, without departing from the essence of the invention in the form of the embodiments described herein, various exceptions, substitutions and changes can be made. The appended claims and their analogues are intended to cover such forms or modifications, which should be within the scope and essence of the invention.

Claims (4)

1. An electric vacuum cleaner comprising an electric fan; a control element for setting the phase angle of the input current of the electric fan; a variable resistor, which sets the resistance value with a possibility of change and thereby sets the power of the electric fan with a possibility of change; control means for setting, in accordance with the resistance value of the variable resistor, the phase angle of the input current of the electric fan, specified by the control element, from the range of the predefined phase angle, the harmonics of which are generated with a value of at least a predetermined limit value. 2. The electric vacuum cleaner according to claim 1, further comprising a current measuring means for measuring a current value of the electric fan, wherein when the current value of the electric fan measured using the current measuring means is not less than a predetermined value, the control means sets the phase angle the input current of the electric fan, set by means of a control element, from the range of a predetermined phase angle, the harmonics of which are generated with d, the value of which is not less than a given limit value. 3. The electric vacuum cleaner according to claim 1 or 2, in which in cases where the phase angle of the input current of the electric fan specified by the control element is less than or greater than a predetermined phase angle, the harmonics of which are generated with a value whose value is not less than a predetermined limit value , the control means changes the magnitude of the change in the phase angle of the input current of the electric fan specified by the control element, in accordance with the magnitude of the change in the magnitude of the resistance to Foot resistor. 4. The electric vacuum cleaner according to claim 3, in which the control means sets the amount of change in the phase angle of the input current of the electric fan, set by the control element, in accordance with the amount of change in the resistance value of the variable resistor in the region in which the phase angle of the input current of the electric fan is less than previously a certain phase angle, the harmonics of which are generated with a value whose value is not less than a predefined limit value, as well as significantly increases the coefficient of variation of the phase angle of the input current of the electric fan, which will be set by means of a control corresponding to the coefficient of change of the resistance value of the variable resistor, in a relatively small area in which the phase angle of the input current of the electric fan is greater than the predetermined phase angle, the harmonics of which are generated with whose value is not less than the specified limit value.

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