JPH0790008B2 - Vacuum cleaner - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Object of the Invention (Industrial field of application) The present invention is designed to automatically output the output of an electric blower for dust collection built in an electric vacuum cleaner body by sensor output such as filter clogging. The present invention relates to an electric vacuum cleaner that can be constantly corrected and used with a constant suction capacity.

(Prior Art) As a conventional vacuum cleaner of this type, for example, the configuration shown in FIGS. 14 and 15 is known.

In FIG. 14, reference numeral 1 denotes an electric vacuum cleaner main body, and inside the electric vacuum cleaner main body 1, a dust collecting part (not shown), an electric blower 2,
A control unit 3 for controlling the output of the electric blower 2 is provided. A changeover switch 4 for switching the output of the electric blower to “strong”, “automatic”, and “weak” is provided at the upper rear end of the electric vacuum cleaner body 1, and the hose portion 6 of the hose portion 6 is provided at the opening 5 of the inclined surface. The main body connecting portion 7 is connected.

In addition, a hose body 8 having a transmission line inside is connected to the body connecting portion 7, and the hose body 8 has a connecting pipe 9 at its tip.
The connection pipe 9 has a hand control unit 10, and the hand control unit 10 is provided with an on / off switch 11. Further, an extension pipe 12 is connected to the connection pipe 9, and a suction port body 13 is connected to the extension pipe 12.

Next, a block diagram of the electric vacuum cleaner will be described with reference to FIG.

In FIG. 15, reference numeral 21 is an AC power source, and this AC power source 21
The electric blower 2 is connected to the control unit 3 via the control unit 3.

Further, a rectifying means 23 for rectifying an alternating current into a pulsating current is connected to the AC power source 21 via a step-down transformer 22, and an opening / closing means 24 for turning off the power source in case of an abnormality is connected to the rectifying means 23. A constant voltage means 25 is connected to the opening / closing means 24 to smooth the pulsating flow to a constant voltage. Furthermore, this constant voltage means
25 is connected via a resistor 26 to a connection point between the on / off switch 11 of the hand control unit 10 and the current detection means 27, and the current detection means 27 is turned on or off. The opening / closing means 24 is connected through the comparing circuit 28 for detecting.

Further, in the constant voltage means 25, the manual setting means 31 for manually setting the output of the electric blower 2, the flow rate detecting means 32 for detecting the flow rate of the wind in the air passage, and the output of the flow rate detecting means 32 are electrically connected. Detection means 34 including conversion means 33 for converting into output
Are connected. The detecting means 34 includes an amplifying means.
A manual / automatic switching means 36 including a manual setting means 31 and a changeover switch 4 for switching between manual and automatic via 35
This manual / automatic switching means 36 is connected to the transformer 22.
The trigger means 37 is connected together with the zero-cross detection means 38 connected to the secondary winding of the AC power supply through the insulating means 39.
Power control means connected in series between 21 and the electric blower 2
40 are connected.

Next, the operation of the above conventional example will be described.

The voltage from the AC power source 21 is stepped down by the transformer 22, and the rectifying means 23
Rectify with. Then, the pulsating voltage is smoothed by the constant voltage means 25 to be a constant voltage, and the constant voltage is supplied.

Further, the manual / automatic switching means 36 switches between manual and automatic. In the case of manual setting, a constant input is made, and in the case of automatic setting, the flow rate detecting means 32 detects the flow rate in the air passage, and this flow rate is converted. It is converted into an electrical output at 33, amplified by the amplifying means 35 so that the suction force has a constant pressure or flow rate, and then inputted to the trigger means 37. At this time, the zero-cross detector 38 detects zero volts of the AC power supply 21.
Then, the power of the AC power source 21 is controlled by controlling the input of the electric blower 2 by providing the trigger output to the electric power control means 40 by insulating with the insulating means 39, thereby controlling the suction force of the electric blower 2. .

(Problems to be Solved by the Invention) In the configuration of the conventional vacuum cleaner described above, the deviation of the output from the conversion unit is corrected by adjusting the resistance value of the semi-fixed resistor at the time of assembly. The resistance value of the output output from the converter and converted by the converter may change due to aging, for example, and the output of the operating point may deviate during assembly and adjustment of the vacuum cleaner and during use. In addition, the resistance value may similarly change due to regional and seasonal changes in temperature, and the output of the conversion means may be displaced. As a result, the output control of the electric blower may be deviated, or the alarm operating point may be deviated.

Further, there is a problem in that it is difficult to completely adjust the output of the converting means by adjusting, for example, a semi-fixed resistor during assembly.

The present invention has been made in view of the above problems, and an electric blower that can stably control an electric blower regardless of changes over time and changes in temperature, and that facilitates adjustment during assembly to improve mass productivity. The purpose is to provide a vacuum cleaner.

[Structure of Invention]

(Means for Solving Problems) The present invention relates to an electric vacuum cleaner body having a dust collecting unit, an electric blower, a detection unit that detects the suction capacity of the electric blower, and a control unit that controls the output of the electric blower. In the electric vacuum cleaner having a hose portion detachably connected to the main body of the electric vacuum cleaner, wherein the hose portion, the dust collecting portion, and the air passage portion through the electric blower are formed, the detection means is An air passage detecting means for detecting a pressure or a flow rate in the air passage portion, a converting means for converting an output of the air passage detecting means into an electric output, and an air passage zero correcting means for correcting a zero point of the converting means. And the hose section has a hand control means for controlling the electric blower, the control means detecting a current from the hand control means, an output of the detection means and the output of the detection means. Current detection hand Storage means for converting and storing the output corresponding to the suction force set with respect to the output of the stage, arithmetic processing means for arithmetically processing the output from this storage means to the set suction capacity, and of this arithmetic processing means Output means for outputting an output for controlling the electric blower to the electric power control means according to the output, and when the electric blower operates according to the output of the detection means, the conversion means in the stopped state of the electric blower Is read, the zero point is corrected by the air passage zero correcting means, and the electric blower is controlled by the output of the converting means corrected by the air passage zero correcting means.

(Operation) According to the present invention, the pressure or flow rate in the air passage portion is detected by the air passage detecting means, the output from the air passage detecting means is converted into the electric output by the converting means, and the converting means is operated when the electric blower is stopped. The output is read, the zero point is corrected by the wind path zero correction means, and the electric blower is controlled by the output of the conversion means whose zero point is corrected by the wind path zero correction means. Is also corrected to a predetermined output and accurately corresponds to the pressure or flow rate in the air passage section.

(Embodiment) An embodiment of the electric vacuum cleaner of the present invention will be described below with reference to the drawings.

In FIG. 4 and FIG. 5, 41 is a vacuum cleaner body,
The vacuum cleaner main body 41 is composed of a main body case 43 having an opening 42 formed in an upper front portion thereof, and a lid body 44 having a rear end portion axially attached to the main body case 43 to open and close the opening 42.

Further, the main body case 43 is composed of a lower main body case member 45 and an upper main body case member 46 joined and fixed to the upper side of the lower main body case member 45, and has a front handle 47 at the front part of the main body case 43. A cover body 48 is pivotally mounted on the upper rear side of the upper body case member 46 so as to be openable and closable. A component storage section 49 is provided inside the cover body 48, the hanging opening 50 and the round brush 60 are stored therein, and the cover body 48 is locked by a locking piece 52.

Further, a display window 54 of an indicator 53 showing the suction capacity is arranged on the front side of the component storage section 49. And
Behind the display window 54, for example, light emitting diodes 55, 56, 57 and 58 for display are provided to form a level meter 59. The bumper 64 is located on the peripheral surface of the main body case 43 and is sandwiched between the main body case members 45 and 46.

Then, the inside of the main body case 43 is divided into front and rear by a partition wall 66 formed in a substantially central portion thereof and having a communication port 65, and an electric blower 67 is disposed in a space portion behind the partition wall 66, It is protected and fixed by an elastic member 68. further,
A circuit board 69 is provided above the electric blower 67, and a communication pipe 71 is provided between the circuit board 69 and the air passage 70 on the negative pressure side on the front side of the electric blower 67.

Further, the space portion in front of the partition wall 66 is a dust collecting portion 72 having the opening 42 on the upper surface and located on the negative pressure side of the electric blower 67. Also, on the rear surface of the main body case 43, an electric blower
An exhaust port 73 communicating with the pressure increasing side of 67 is formed.
Further, inside the body case 43, a cord reel 75, which is located behind the electric blower 67 and accommodates the power cord 74, is rotatably provided. And this cord reel
The cord 75 winds the power cord 74 by pressing the cord reel button 77 protruding from the button opening 76 of the cover body 48. Further, a pair of wheels 78 and a turning wheel 79 are rotatably provided on the lower side of the main body case 43 on the rear side of both side surfaces and the front side of the lower surface thereof.

Further, the lid body 44 is formed in a thin box shape having an opened lower surface, and a body clamp 81 urged by a spring 80 is pivotally attached to the front end portion of the lid body 44. The body clamp 81 is a locking portion formed on the upper end of the front surface of the body case 43.
The lid body 44 is held in the closed state by being removably engaged with the 82. Further, a handle 83 is provided near the joint between the lid body 44 and the main body case 43 so as to be rotatable and housed.

The front side of the upper surface of the lid body 44 is formed as an inclined surface 84 that descends toward the front, and a circular opening 85 is formed in the inclined surface 84.
Are formed. An inner wall 86 is joined and fixed to the lower surface side of the lid body 44 substantially parallel to the upper surface of the lid body 44,
A substantially cylindrical support body 87 is fixed between the inclined surface 84 and the inner wall 86.

Further, the rotating body 88 is rotatably supported by the supporting body 87, which is located between the inclined surface 84 and the inner wall 86. Further, a pair of high-voltage terminal rings 89 for supplying power to the brush electric motor, for example, are fixed to the bottom surface of the rotating body 88, and these high-voltage terminal rings 89 are respectively connected to a pair of contacts 90 fixed to the inner wall 86. Slidably contacted.

On the other hand, on the outer peripheral surface of the rotating body 88, a pair of low-voltage terminal rings 91 are fixed side by side in the axial direction, and these low-voltage terminal rings 91 respectively slide on a pair of contacts fixed to a support 87 or the like. It is controlled freely.

A lid 94 that is opened by inserting the main body connecting portion 93 of the hose portion 92 is rotatably attached to the rotating body 88.
Further, an opening is formed between the inclined surface 84 of the lid body 44 and the rotating body 88.
A flexible sliding cover body 95 for opening and closing 85 is provided so as to be slidably housed.

The hose portion 92 forms an air passage portion that communicates with the dust collecting portion 72, the air passage 70, and the electric blower 67.

And the hose portion 92 is detachable from the electric vacuum cleaner body 41,
When the base end of a flexible hose body 96 having a power supply line and a two-wire transmission line is attached to the main body connecting portion 93 and the hose portion 92 is connected to the vacuum cleaner main body 41, the power supply lines form a pair. The transmission line is electrically connected to the high voltage terminal ring 89 and to the pair of low voltage terminal rings 91.

Further, at the tip of the hose body 96, a grip pipe 98 to which an extendable extension pipe 97 is inserted and detachably connected is provided, and a hand operation unit 99 is provided at the grip pipe 98. And
As shown in FIG. 6 and FIG. 7, a circuit board 101 of the hand permission control means 100 is provided in the hand permission operating portion 99, and the hand permission operating portion 99 has a cover pipe 102 connected to the hose body 96 and a grip pipe. The connection pipe 103 between 98 and this connection pipe 1
A display plate 104 is attached to 03.

Then, in the vicinity of, for example, a display of "strong" on the display board 104, a strong operation of operating a normally open contact (for example, a product name tact switch) 111 of -circuit-contact as an operation switch for varying the output of the electric blower 67. The operation button 112 and the display 113, which is composed of, for example, a light emitting diode, for displaying the operation position of the operation button 112 are provided. Similarly,
In the vicinity of the display of "automatic", the operation button 115 and the display device 116 of the automatic normally open contact 114, and in the vicinity of the display of "weak", the operation button 118 and the display device 11 of the normally open contact 117 for the sofa.
9, operation buttons 121 of the normally open contact 120 for the curtain are arranged near the display of "OFF". No display corresponding to the operation button 121 for cutting is provided.

Further, a connecting pipe 123 of a suction port body 122 having a built-in brush electric motor therein is attached to the extension pipe 97 in a freely attachable / detachable manner, and the suction port body 122 is selected from the vine 59 or the round brush 60. It can be used as a replacement.

Next, a block diagram of the above embodiment will be described.

In FIG. 1, 131 is a commercial AC power supply, and a control means 132 is connected to the commercial AC power supply 131.
An electric blower is connected to 2 to control the output of the electric blower 67.

A primary winding 134 of a step-down transformer 133 is connected to the commercial AC power source 131, and the transformer 133 is connected to the control means 132.
A rectifying means 136 for rectifying an alternating current into a pulsating flow is connected to the secondary winding 135 of the first and second constant voltage means 137, 13 for converting the rectifying means 136 into constant voltages of different voltages.
8 is connected. Then, for example, the permission control means 100
The first constant voltage means 137 for supplying a current to the opening and closing means 139 for opening and closing the power supply of the hand control means 100 in the event of an abnormality.
Are connected to the terminal A. Also, terminals A and B
A protection means 140 for protecting the hand permission control means 100 is connected between them, a current detection means 141 for detecting a current from the hand permission control means 100 is connected to the terminal B, and a central processing unit 142 constituted by a microcomputer is formed. It is connected.

Further, a constant current means 143 for holding a constant current value is connected to the first constant voltage means 137, and the constant current means 143 detects the pressure or the flow rate in the air passage 70. A detection unit 146 including a conversion unit 145 that converts the detection value of the wind path detection unit 144 into an electrical output is connected. A central processing unit 142 is connected to the detecting means 146 via an amplifying means 147 which amplifies the output of the detecting means 146. Further, the second constant voltage means 138 is directly connected to the central processing unit 142 for driving the central processing unit 142, and the central processing unit 142 is connected when the power is turned on again.
The central processing unit 142 is connected through the initializing means 148 for initializing the progress of the program of FIG.

Further, the secondary winding 135 of the transformer 133 is connected to the commercial AC power supply 131.
Is connected to a central processing unit 142, which is connected to a zero-cross detecting means 149 for detecting the zero volt of the signal and discriminating the frequencies of 50 Hz and 60 Hz. Further, the first constant voltage means 137 includes the current limiting means 150.
The display means 151 for displaying the output of the electric blower 67 or the operation position of the hand control means 100 is connected via the, and the display means 151 is connected to the central processing unit 142. Further, the central processing unit 142 is connected to a sounding means 153 for notifying an abnormality such as clogging via a sounding driving means 152.

Then, the central processing unit 142 is connected to the output means 156 consisting of the driving means 154 and the insulating means 155, and this output means
The power control means 157 connected between the commercial AC power supply 131 and the power supply blower 67 is connected to 156.

Here, the central processing unit 142 will be described with reference to FIG.

The zero-cross detection means 149 receives the input from the current detection means 141 and the amplification means 147 via the zero-cross input means 161, the initialization means 148 via the initialization input means 162, and the current detection means 141 and the amplification means 147. It is connected to the input switching means 163 that alternately switches, and is connected to the data carrying means 165 that reads and reads data via the A / D conversion means 164 that digitizes. The display means 151 is connected to the display opening / closing means 166 for turning on / off the display.

Further, the data carrying means 165 is connected to a storage means 173 composed of a data storage means 171 and a temporary storage means 172,
This storage means 173 converts the output of the current detection means 141 and the output of the conversion means 145 into an output corresponding to the suction force set and stores the data. Furthermore, data transfer means
The processing unit 165 calculates the outputs from the input switching unit 163 and the storage unit 173 to the set suction capacity and also has a zero point correction function as a wind path zero correction unit.
174 is connected. Further, the data transfer means 165 is connected to the display opening / closing means 166, and the display opening / closing means 166 is connected.
A sound output unit 17 which is connected to a display output unit 175 for activating the sound generation drive unit 152 and operates the sound generation drive unit 152.
6. Output means 177 connected to the driving means 154 and operating the driving means 154 are connected respectively.

Next, the permission control means 100 will be described with reference to FIG.

In FIG. 2, terminals A and B of the hand control means 100 are connected to the control means 132 of the electric vacuum cleaner body 41, respectively.
Further, between the terminals A and B of the hand permission control means 100, a protection means 181 for protecting the hand permission control means 100 from a surge or the like is connected.

Further, 182 is an opening / closing means, and this opening / closing means 182 includes a strong opening / closing means 183, an automatic opening / closing means 184, a weak opening / closing means 185, and a cutting opening / closing means 186.
84, 185, 186 are load means 187 for setting the load resistance, respectively
Heavy load means 188, automatic load means 189, weak load means
190 and a cutting load means 191. The load means 188, 189, 190, 191 are connected to the terminal A, and the load means 188, 189, 190, 190 are connected to the terminal A.
The amplification means 193 for amplifying the output of the load resistance value of 191 is connected to the strong amplification means 193, the automatic amplification means 194, the weak amplification means 195, and the cutting amplification means 196, respectively, and is connected to the cutting amplification means 196. Is connected to reset means 197 for resetting to off when the power is disconnected.

Then, each amplification means 193, 194, 195, 196 is connected to each opening / closing means 18
3,184,185,186, which are memory means for storing the operation content of the memory means 201, automatic memory means 203, automatic memory means 203, weak memory means 204, cutting memory means 205 are mutually set and reset. Mutual resetting means
206, the mutual reset means 206 is connected to each of the storage means 202, 203, 204, 205, respectively.
For 2,203,204,205, each storage means 20
A power supply backup means 207 for protecting the stored contents of 2,203,204,205 is connected.

Then, each of the storage means 202, 203, 204 is connected to the strong display means 212, the automatic display means 213 and the weak display means 214 of the display means 211 for displaying the operated contents, and the current value to the control means 132. Is connected to the strong current changing means 216, the automatic current changing means 217, and the weak current changing means 218 of the current changing means 215, and is connected to the terminal B of the hand control means 100. The display means 211 and the current varying means 216 are not connected to the storage means 205 for cutting.

Next, a specific circuit of the above embodiment will be described with reference to FIGS. 8 and 9.

The commercial AC power supply 131 is connected to the control means 13 via a fuse 221.
The triac 222, which is a bidirectional control element of the second power control means 157, and the electric blower 67 are connected in series, and the triac 222 is connected to the snubber circuit 225 for protecting the triac 222 including the resistor 223 and the capacitor 224.
In addition, the electric blower 67 has a fuse and a fuse.
A noise prevention circuit 2 for preventing noise, which is composed of capacitors 226, 227, 228 Δ-connected to both ends of a commercial AC power supply 131 via 221.
29 is connected.

Further, a primary winding 134 of a transformer 133 is connected to a commercial AC power supply 131 via a fuse 221, and a protective fuse 231 and a varistor 232 connected in series in parallel are connected to the primary winding 134. Has been done. Further, a diode bridge 239 composed of diodes 235, 236, 237, 238 as a rectifying means 136 is connected to the secondary winding 135, and a direct current output side of this diode bridge 239 is used for a constant voltage of, for example, 12 V of the first constant voltage means 137. 3 terminal regulator 241 is connected.

A smoothing electrolytic capacitor 242 and a capacitor 243 connected in parallel are connected between one end of the three-terminal regulator 241 and the negative electrode of the diode bridge 239.
An electrolytic capacitor 244 and a capacitor 245 are connected between the other end of the terminal regulator 241 and the negative electrode of the diode bridge 239, respectively.

Further, the DC output side of the diode bridge 239 is connected to the second constant voltage means 138, which is a three-terminal regulator 246 for a constant voltage of 5 V, for example.
A capacitor 247 is connected between one end of the three-terminal regulator 246 and the negative electrode of the diode bridge 239, and a smoothing electrolytic capacitor 248 and a capacitor 249 are connected between the other end of the three-terminal regulator 246 and the negative electrode of the diode 239. . The collector of an NPN transistor 252 having a bias resistor 251 is connected to the positive output side of the diode bridge 239 between the emitter and base of the switching means 139.
The base of the bias resistor 253
Is connected to the NPN type transistor 254, and the emitter of the transistor 254 is connected to the negative side of the diode bridge 239.

In addition, the base of transistor 252 and transistor 2
54 collector is 3 terminal regulator 241 via resistor 255
In addition, the base of the transistor 254 is connected to the central processing unit 142 via the resistor 256. In addition, the transistor 252
An electrolytic capacitor 257 for smoothing and a capacitor 258 are connected in parallel between the emitter of the capacitor and the emitter of the transistor 254. The terminal A is connected to the negative electrode of the diode bridge 239 through the parallel circuit of the varistor 261 and the capacitor 262 in the protection means 140, and
It is connected to terminal B via a parallel circuit of 263 and capacitor 264. Also, this terminal B and the diode bridge 239
A resistor 141 as a current detecting means is connected to the negative electrode of the above, and a resistor 265 is connected between the terminal B and the central processing unit 142.

Also, a three-terminal regulator 241 and a diode bridge 239
An electrolytic capacitor 271 for smoothing is connected between
The terminal regulator 241 is an operational amplifier 1 as a constant current means.
The inverting input terminal of 43 is connected, and the forward input terminal has a resistor 27
2 is connected. Further, a semiconductor such as silicon as the detecting means 146 is diffused between the output terminal of the operational amplifier 143 and the resistor 272 to form a resistance bridge equivalently composed of resistors 273, 274, 275 and 276. Resistance of these 273
A variable resistor 277 serving as an offset gain for adjusting the gain is connected between the resistor 274 and the resistor 274, and the sliding terminal of the variable resistor 277 is connected to the non-inverted input terminal of the operational amplifier 279 of the amplification means 147 via the resistor 278. The connection point of the resistors 275 and 276 is connected to the inverting input terminal of the operational amplifier 279 via the resistor 280, and the resistor 281 is connected between the inverting input terminal and the output terminal.

Further, a resistor 283 connected from the inverting input terminal of the operational amplifier 143 to the output terminal of the operational amplifier 282 forming the voltage follower circuit is connected to the non-inverting input terminal of the operational amplifier 279. The output terminal of the operational amplifier 279 is connected to the inverting input terminal of the operational amplifier 285 via the resistor 284, and the non-inverting input terminal is connected to the output terminal of the operational amplifier 282 via the resistor 286. A resistor 287 and a semi-fixed resistor 288 for adjusting the amplification degree are connected between the inverting input terminal and the output terminal of the operational amplifier 285, and the output terminal has a central processing unit 142.
Is also connected to the negative electrode of the diode bridge 239 via the resistor 289.

In addition, the 3-terminal regulator 241 has an initialization means 1
The negative electrode of the diode bridge 239 is connected via the resistor 291, the Zener diode 292, and the resistor 293 of 48.
Furthermore, the base of an NPN transistor 294 is connected to the connection point of the cathode of the Zener diode 292 and the resistor 293, and the collector of this transistor 294 is connected to the first via the resistor 295.
The three-terminal regulator 241 of the constant voltage means 137, the base of the NPN transistor 296 is the emitter of the transistor 294, and the collector of the transistor 296 is the diode bridge 239 via the central processing unit 142 and the resistor 297.
Of the transistor 296 is connected to the negative electrode of the diode bridge 239, respectively.

A resistor 301 is connected to both ends of the secondary winding 135 of the transformer 133.
The light-emitting diodes 302 and 303 connected in anti-parallel to the zero-cross detection means 149 are connected via the light-emitting diodes 302 and 303, and the phototransistor 304 is photocoupled to these light-emitting diodes 302 and 303. Also, this phototransistor 304
Is connected to the three-terminal regulator 245 of the second constant voltage means 138, and the emitter of the phototransistor 304 is connected to the negative electrode of the diode bridge 239 via the central processing unit 142 and the resistor 305.

Furthermore, a three-terminal regulator 241 is connected to one end of a resistor 150 as a current limiting means, and the anodes of the light emitting diodes 55, 56, 57 and 58 connected in parallel to the display means 151 are connected to the other end thereof. A central processing unit 142 is connected to the cathodes of 55, 56, 57 and 58. Then, one end of the resistor 311 of the sound generation driving means 152 is connected to the central processing unit 142, and the other end thereof is connected to the bias resistor 312 between the emitter and the base.
Is connected to the base of a transistor 313 having a negative pole of a diode bridge 239 and the collector of the transistor 313 is connected to a buzzer 316 of a sounding means 153 having a resistor 315 in parallel. It is connected to the three-terminal regulator 241 of the constant voltage means 137.

Further, capacitors 321 and 322 are connected in parallel between the central processing unit 142 and the negative electrode of the diode bridge 239, and the connection point between the central processing unit 142 and the capacitor 321 and the central processing unit 14 are connected.
A resistor 323 and an oscillator 324 for the clock of the central processing unit 142 are connected in parallel between 2 and the connection point of the capacitor 322.

Further, the central processing unit 142 includes a transistor 333 having a bias resistor 332 between the emitter and the base via the resistor 331.
Is connected to the emitter of the transistor 333, and the negative electrode of the diode bridge 239 is connected to the emitter of the transistor 333, and the collector of the transistor 333 is connected to the light emitting diode 334 and the resistor 335 of the insulating means 155.
Via the three-terminal regulator 241 of the first constant voltage means 137
Are connected. Further, the light emitting diode 334 is photo-coupled with the photo triac 336, and is electrically insulated so that the photo triac 336 has a triac 2
The connection point between the triac 222 and the electric blower 67 is connected via the gate of 22 and the resistor 337.

Next, a specific circuit of the hand permission control means 100 shown in FIG. 2 will be described with reference to FIG.

A capacitor 340 is connected between the terminals A and B, and a resistor 342, a Zener diode 343, and an electrolytic capacitor 345, which are connected in parallel as a protection means 181, are connected via a diode 341 for preventing backflow. Further, the cathode of the diode 345 is connected to the anode of the diode 345 for backflow prevention, and between the cathode of the diode 343 and the terminal B, the resistor 351 and the capacitor 352 of the power backup means 207.
Are connected in parallel. Further, at the connection point of the cathode of the diode 341 and the anode of the diode 343, a series circuit of a resistor 356, in which a resistor 216 serving as a current variable means for high power is connected in parallel, and a light emitting diode 113 for high power, and an automatic current for parallel are connected. A series circuit of a resistance 357 having a resistance 217 as a variable means and an automatic light emitting diode 116 is connected, and a series circuit of a resistance 358 having a resistance 218 as a weak current changing means and a series circuit of a weak light emitting diode 119 are connected in parallel. Are connected to the integrated circuit 360 having the functions of the amplification means 192, the mutual reset means 206, and the storage means 201, respectively. No light emitting diode for cutting is provided.

Also, pull-up resistors 188, 189, 190, 191 as load means 187 are connected from the cathode of the diode 343, the pull-up resistors 188, 189, 190, 191 are connected to the integrated circuit 360, and the heavy-duty pull-up resistor 188 serves as a heavy-duty opening / closing means. The strong switch 183, the automatic pull-up resistor 189 are the automatic switch 184 as the automatic opening / closing means,
The weak pull-up resistor 190 is connected to the weak switch 185 serving as the weak opening / closing means, and the off pull-up resistor 191 is connected to the off switch 186 serving as the off opening / closing means. A capacitor 197 as a reset means is connected between the connection point of the switching switch 186 and the switching pull-up resistor 191 and the terminal B.

Next, the operation of the above embodiment will be described with reference to the flowcharts shown in FIGS.

First, when the power is turned on (step 1), the commercial AC power supply
The voltage of 131 is reduced by the transformer 133, rectified by the rectifying means 136, then made constant by the second constant voltage means 138, and the contents of the central processing unit 142 are initialized by the initializing means 148 (step 2). .

Further, when the voltage is converted to a constant voltage by the first constant voltage means 137 and is output to the hand permission control means 100 via the transmission line, the opening / closing means 139 temporarily turns off the power of the hand permission control means 100 and resets the hand permission control means 100. At 197, the contents of the storage means 201 are reset (step 3).

Further, at this time, the electric blower 67 is in a stopped state A / D conversion means for converting the output of the air path detection means 144 into an electrical output.
The output of 164 is read (step 4), and this output value is stored in the temporary storage means 172 as a reference value (step 5). It should be noted that this memory is not erased even if the outlet is unplugged, but is erased by storing a new reference value for the next time.

When the AC power supply 131 shown in FIG. 13 has a phase angle of 0 ° or 180 °, the zero cross detection means 149 detects the voltage Zelvolt (step 6) (point a), and the output of the current detection means 141 is changed to the input switching means. It outputs to the A / D conversion means 164 via 163 (step 7), averages the output current value, and stores it in the temporary storage means 172 (step 8).

It is judged whether or not this current value is a current value of a first predetermined value which is slightly lower than the current value when it is set to "strong" (step 9), and when the current value is the first predetermined value or more Is a triac
The trigger time of 222 corresponds to "strong" output a [ms]
When the current is less than the first predetermined value (step 10), it is determined whether the current value is slightly higher than the second predetermined value which is slightly higher than the current value when the current value is set to "weak" (step 11), and the current is determined. If the value is not equal to or greater than the second predetermined value, it is determined whether the value is equal to or greater than the third predetermined value, which is the current value when set to "weak" (step 1
2) If the current value is lower, the electric blower 67 is turned off (step 13). If the current value is higher than the third predetermined value, the trigger time of the triac 222 corresponds to a weak output b [m].
s] (step 14).

When the current value is equal to or higher than the second predetermined value, the electric blower
It is determined whether or not 67 is within a predetermined time, for example, 2.0 [S] after starting (step 16), and if it is not within the predetermined time, the previous triac tree reads the time (step 17), and within the predetermined time. At this time, the triac trigger time, which is a constant output signal, is set to C [ms] in order to prevent the operation from becoming unstable by operating in accordance with the output of the wind path detecting means 144 of the detecting means 146 (step 1).
8). Then, the output means 177 outputs a trigger at the set triac trigger time (step 19).
(Period b).

After that, the wind path detecting means 144 read by the A / D converting means 164.
(Step 20) (section C), the reference value stored in step 5 is subtracted from the output of the A / D conversion means 164, and the correction value is calculated by the calculation processing means 174 (step 21). ). For example, it is determined in step 4 that the input of the A / D conversion means 164 is outputting 2V by the airway detection means 144 at a pressure of 0 mmH ₂ O, and the reference value is set to 2V in step 5. At this time, if the output is detected as 5V, the reference value of 2V is subtracted and the correction value is set to 3V. And then
Judge as the pressure of 2000 mmH ₂ O corresponding to this 3V.

Then, the average value (SENAV) of the correction values of this output voltage is set (step 22). Then, this average value (SENA
V) is compared with the data in the data storage means 171, and the arithmetic processing means 174 performs arithmetic processing (period d). That is, the average value (S
If ENAV) is greater than data (SENDA1) and less than data (SENDA2) (step 23), set the triac trigger time to d.
[Ms] (step 24), and when the average value (SENAV) is greater than or equal to the data (SENDA2) and less than the data (SENDA3) (step 25), the triac trigger time is set to e [ms] (step 26).

Similarly, when the average value (SENAV) is more than the data (SENDA3) and less than the data (SENDA4) (step 27), the triac trigger time is set to f [ms] (step 28), and the average value (SENAV) is the data (SENDA4). ) Or more and less than data (SENDA5) (step 29), set the traac trigger time to g [ms] (step 30), and if data (SENDA5) or more and less than data (SENDA6) (step 31), triac trigger The time is set to h [ms] (step 32), and when the data (SENDA6) is more than the data (SENDA7) less than (step 33), the triac trigger time is set to i [ms] (step 34), the data (SENDA7) or more data (SENDA
If it is less than 8) (step 35), the triac trigger time is set to j [ms] (step 36) and the data (SENDA
8) or more and less than the data (SENDA9) (step 3
7), triac trigger time is set to k [ms] (step 38), and when data (SENDA9) is more than data (SENDA10) (step 39), triac trigger time is set to 1 [ms] (step 40), average When the value (SENAV) is more than data (SENDA10) and less than data (SENDA11) (step 41), set the triac trigger time to m [ms].
(Step 42).

Further, it is determined whether the average value (SENAV) is less than the data (SENDA1) outside the lower limit setting range (step 43) or more than the data (SENDA10) outside the upper limit setting range (step 44). If not, step 22
Return to. Also, it is determined whether or not any of the above is the Nth time or more after a certain time or more (step 45). N
When it is less than N times, the process returns to step 22, and when it is N times or more, the detecting means 146 or the amplifying means 147 fails and the triac trigger time is set to the optimum value n [ms] (step 46).

In this way, 11 kinds of TRIAC trigger time are set,
Any one of these triac trigger times is stored in the temporary storage means 172 (step 47). That is, after the triac trigger, the arithmetic processing means 174 performs arithmetic processing (period D, E) on the data extraction of the A / D conversion means 164 (period C) and the triac trigger time.

Then, for example, when the output of the electric blower 67 is set to "strong", the operation button 112 for high power is pressed, the opening / closing means 183 for heavy power is operated, and the load means 188 for heavy power is operated, and the amplification means 193 for strong power is used. After amplification, the mutual storage means 206 resets the previous memory and stores it in the overuse memory means 202.

Further, in the heavy-duty storage means 202, the heavy-duty display means 212 is activated to turn on the heavy-duty indicator 113, and the heavy-duty current varying means 216 is activated. Then, again output to the control means 132 via the transmission line, the control means 132 inputs from the current detection means 141 to the central processing unit 142 to detect that it is "strong",
The data is stored in the data storage means 171. Furthermore, "strong"
Data is output to the output means 177, and the electric power control means 157 outputs the "strong" electric power from the driving means 154 to the electric blower 67 via the insulating means 155 to drive the electric blower 67 strongly. In addition,
At this time, the level meter 59 of the main body 41 of the electric vacuum cleaner indicates "strong" by, for example, all the issuing diodes 55, 56, 57, 58 being turned on.

On the other hand, when the weak operation button 118 is pressed, the electric blower 67 outputs “weak” by the same operation, and the manual operation unit
The indicator 119 for weak use of 99 lights up, and the level meter 59 of the vacuum cleaner body 41 displays the light emitting diodes 55, 56,
"Weak" by turning on one of 57 and 58
Is shown.

Next, a case where the output of the electric blower 67 is automatically set will be described.

When the automatic operation button 115 is pressed to make it automatic, the automatic display 116 of the automatic display means 213 lights up, the automatic current varying means 217 is operated, and the electric vacuum cleaner body 41 is transmitted through the transmission path.
Is transmitted to the control means 132. Then, the triac trigger time is set according to the pressure or flow rate of the air passage 70, and the electric blower 67 is driven. At this time, the number of the light emitting diodes 55, 56, 57, 58 of the display means 151 is turned on according to the output of the electric blower 67, for example.

Further, when the transmission line is cut off for a short time, the power supply backup means 207 holds the storage of the storage means 201, and after the backup is completed, the reset means 197 resets the storage and sets it to off.

According to the above-described embodiment, the trigger can be performed by the central processing unit 142 composed of a microcomputer, and the fine control can be made inexpensive.

Further, the reference value is not limited to being read after the power is turned on, and may be immediately after inserting the outlet.

〔The invention's effect〕

According to the electric vacuum cleaner of the present invention, the air passage detecting means detects the pressure or the flow rate in the air passage portion, the converting means converts the output from the air passage detecting means into an electrical output, and the electric blower is stopped. The output of the conversion means is read, the zero point is corrected by the wind path zero correction means, and the electric blower is controlled by the output of the conversion means whose zero point is corrected by the wind path zero correction means. Even if it occurs, it can be corrected to a predetermined output each time it is used, it can accurately respond to the pressure or flow rate in the air passage, stably control the electric blower regardless of aging and temperature changes, and at the time of assembly Since adjustment is not required to be complete, it is easy and mass productivity can be improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing a vacuum cleaner main body of an embodiment of the present invention, FIG. 2 is a block diagram showing a hand operation unit of the same, FIG. 3 is a block diagram showing a central processing unit of the same, and FIG. 5 is a perspective view showing the same electric vacuum cleaner main body, FIG. 5 is a vertical sectional view of the same as above, FIG. 6 is a plan view showing the hand operation part of the same above, FIG. 7 is a vertical sectional view of the same above, and FIG. Fig. 9 is a circuit diagram showing the hand operation unit of the same as above. Fig. 10 to Fig. 12 are flow charts. Fig. 13 is a timing chart of the same as above. Fig. 14 is a perspective view of the same vacuum cleaner body. FIG. 15 is a block diagram showing a conventional example. 41 …… Vacuum cleaner body, 67 …… Electric blower, 72 …… Dust collector, 92 …… Hose section, 96 …… Hose body, 100 …… Hand control means, 132 …… Control means, 141 …… Current Resistance as detecting means, 144 ... Wind path detecting means, 145 ... Converting means, 14
6 ... Detection means, 173 ... Storage means, 174 ... Arithmetic processing means that also has a function as zero-point correction means.

Claims (1)

[Claims] 1. A vacuum cleaner main body having a dust collecting part, an electric blower, a detection means for detecting the suction capacity of the electric blower, and a control means for controlling the output of the electric blower, and the vacuum cleaner main body being detachable. And a hose connected to
In an electric vacuum cleaner in which an air passage portion is formed through the hose portion, the dust collecting portion, and the electric blower, the detection means includes an air passage detection means for detecting a pressure or a flow rate in the air passage portion, It has a conversion means for converting the output of the path detection means into an electrical output, and a wind path zero correction means for correcting the zero point of the conversion means, and the hose portion has a hand control means for controlling the electric blower. And the control means converts the output from the current control means into an output corresponding to the output of the detection means and the output of the detection means and the suction force set for the output of the current detection means. Storage means for storing, arithmetic processing means for arithmetically processing the output from the storage means to the set suction capacity, and output for causing the power control means to control the electric blower according to the output of the arithmetic processing means. When the electric blower operates according to the output of the detection means, the output of the conversion means in the stopped state of the electric blower is read, and the zero point is corrected by the air passage zero correction means. An electric vacuum cleaner is characterized in that the electric blower is controlled by the output of the conversion means corrected by the zero air passage correction means.