RU2153836C1 - Vacuum cleaner remote-control device - Google Patents

Abstract

FIELD: domestic appliances. SUBSTANCE: push-button output signal coming from push-button input unit mounted in handle is conversion into radio- frequency signal by means of radio-signal transmitter; then radio- frequency signal is converted into primary push-button signal by means of radio-signal receiver mounted on main part of vacuum cleaner, and transmitted to controller which, in its turn, controls operation of motor in response to push-button signal so that installation of communication cable in hose can be dispensed with; such provision facilitates hose manufacture and reduced its mass. EFFECT: facilitated handling of vacuum cleaner. 2 cl, 5 dwg

Description

 The present invention relates to vacuum cleaners and, more specifically, to a device for remote control of a vacuum cleaner for remote radio control of operations performed by the main part of the vacuum cleaner using a push-button input unit located on the handle.

 Typically, a vacuum cleaner is provided as shown in FIG. 1, the suction inlet 10 for suctioning dust, other foreign objects and the like located on the floor surface, the transitional part 20 for the unimpeded movement of dust, sucked by the suction inlet 10 into the dust collecting chamber, usually located in the main part 30, and the main part 30 for collecting dust moving along the transition part 20, and to create a suction force. The suction inlet 10 comprises two first transition elements 11 located at both ends thereof, and a connecting tube 12, made as a unit at its upper rear end.

 In addition, the adapter portion 20 is provided with first and second extension tubes 21 and 22 made of plastic material and connected to the hollow portion of the connecting tube 12 by a handle 23 connected to the first and second extension tubes 21 and 22, and a sleeve 24 having a conventional configuration and connected to the handle 23 to receive a message between them.

 The handle 23 is equipped with a button for stepwise regulation of the air suction force and for controlling the on / off operations of the vacuum cleaner, the input button unit 40 being located thereon for generating a button signal as a result of the button manipulation. The sleeve 24 is equipped with a communication cable (not shown) mounted therein for transmitting an output signal from the input key unit 40 to the main body 30.

 The main part 30 is provided externally with an installation connecting hole 31 into which the end of the sleeve 24 is inserted, a dust quantity display 33 for displaying the amount of dust collected in the dust collecting chamber (described below), a pair of support wheels 34 mounted on both sides thereof, a handle 35 and a fork 36 for power supply.

 In addition, the main part 30 is provided with an internal motor (not shown), an impeller (not shown) connected to the motor to create a suction force, and a dust chamber (described below) for collecting dust absorbed by the impeller.

 However, with conventional vacuum cleaners of this design, there is a problem in the difficulty of manufacturing the composite sleeve 24, since there is a communication cable for transmitting the button signal therein, and it is difficult to use the handle 23 due to the unacceptable weight of the sleeve 24.

 Closest to this invention is a remote control device for a vacuum cleaner having a suction inlet, a transitional part with a handle and a main part in which an engine and a dust chamber are installed, the transitional part connecting the suction inlet to the main part and is designed to move the assembled suction inlet foreign objects, such as dust, into the dust chamber by suction in accordance with the suction force generated by driving a device comprising a button input unit provided with a plurality of buttons for controlling on / off operations and engine rotation speed and for generating a button signal corresponding to the button manipulation, radio transmitting / receiving means for transmitting or receiving by radio a button signal generated by the button input unit, and means controlling the driving of an engine to control on / off operations and engine speed in accordance with a button signal received from a radio transmitting / receiving means (see US patent 4369543, CL A 47 L 9/00, 1983).

 A disadvantage of the known device is the low efficiency of the device for remote control of a vacuum cleaner.

 The technical result of this invention is the provision of a remote control device for a vacuum cleaner, designed and adapted for remote control of the engine.

 This technical result is achieved due to the fact that in the remote control device of the vacuum cleaner having a suction inlet, a transition part with a handle and a main part in which a motor and a dust chamber are installed, the transition part connecting the suction inlet to the main part and is designed to move foreign objects, such as dust, collected by the suction inlet into the dust chamber by suction in accordance with the suction force created by bringing an engine comprising a button input unit provided with a plurality of buttons for controlling on / off operations and engine speed and for generating a button signal corresponding to the button manipulation, radio transmitting / receiving means for transmitting or receiving by radio the button signal generated by the button input unit, and engine driving control means for controlling on / off operations and engine rotation speed in accordance with a button signal obtained the radio transmitting / receiving means according to the invention, the transmitting / receiving means comprises a radio frequency signal transmitter for modulating a button signal emitted from the button input unit into a corresponding radio frequency signal and for emitting this radio frequency signal, and a radio frequency signal receiver for receiving and demodulating the radio frequency signal transmitted from the transmitter of the radio frequency signal, and for converting the radio frequency signal into the primary signal of the button, wherein the button input unit and the transmitter of the radio frequency signal are located in the handle of the transitional part, and the receiver of the radio frequency signal and the means for driving the engine are located in the main part of the vacuum cleaner, and also because the transmitter of the radio frequency signal is a two-tone multi-frequency pulse transmitter and is designed to convert the button signal coming from the button input unit, in the corresponding two-tone multi-frequency pulses and gears their superimposed on a carrier wave, and the radio-frequency signal receiver is DTMF and pulse receiver for receiving and demodulating the dual-tone multifrequency pulses transmitted DTMF pulse transmitter on a carrier wave, and converting them into primary signal button.

 The present invention is intended to solve the above problems, and the aim of the present invention is to provide a remote control device for a vacuum cleaner, designed and adapted to remotely control the operation of the engine located in the main part, using the push-button input unit located on the handle on the radio frequency, thereby eliminating the need to use a communication cable in the sleeve to simplify the production of the sleeve and reduce the weight of the sleeve for ease of use.

According to an object of the present invention, there is provided a remote control device for a vacuum cleaner for collecting dust in a dust collecting chamber by suction of foreign objects, such as dust, etc., by a suction force generated by engine operation, the device comprising:
a button input unit provided with a plurality of buttons for controlling on / off operations and engine rotation speed and for generating a button signal corresponding to button manipulation;
radio transmitting / receiving means for transmitting or receiving by radio a button signal generated by a signal input button unit;
engine operation control means for controlling on / off operations and engine rotation speed in accordance with a button signal received from the radio transmitting / receiving means.

The essence and objectives of the present invention are obvious from the following detailed description given with reference to the accompanying drawings, in which:
FIG. 1 is a schematic illustration of a vacuum cleaner according to the prior art;
FIG. 2 is a schematic view of a vacuum cleaner in accordance with the present invention;
FIG. 3 is a schematic partial view showing buttons on a signal input button unit shown in FIG. 2;
FIG. 4 is a block diagram of a remote control device of a vacuum cleaner in accordance with a first embodiment of the present invention;
FIG. 5 is a block diagram of a remote control device of a vacuum cleaner in accordance with a second embodiment of the present invention.

 DETAILED DESCRIPTION OF THE INVENTION

 Preferred embodiments of the present invention are described below with reference to the accompanying drawings.

 In FIG. 2 is a schematic view of a vacuum cleaner in accordance with the present invention, wherein the vacuum cleaner comprises a suction inlet 100 for sucking in foreign objects, such as dust, etc., an adapter 200 for easily moving dust sucked by a suction inlet 100 into a dust collecting chamber, as typically located in the main part 300, and the main part 300 for collecting dust entering the transition part 200.

 The adapter portion 200 comprises an extension pipe 210, a handle 220 connected to the extension pipe 210, and a sleeve 230 of a conventional configuration connected to the handle 220.

 Handle 220, as shown in FIG. 3 is provided with a key input unit 400 arranged thereon, equipped with a plurality of mode selection buttons for entering a service command such that step-by-step control of on / off operations and suction power of the vacuum cleaner can be carried out, and a button signal corresponding to the button manipulation can be generated and the unit 500 transmitting an RF signal (described below).

 In addition, the main part 300 is equipped with an external RF signal receiving unit 600 (described below) and an internal motor 810 (described below) and an impeller (not shown) to create a suction force when it is rotated together with the motor 810, as well as a dust chamber (not shown) where impeller dust collects.

 In FIG. 4 is a block diagram of a remote control device for a vacuum cleaner according to a first embodiment of the present invention, where the remote control device according to the present invention consists of a key input unit 400, an RF signal transmitting unit 500, and an RF signal receiving unit 600, a controller 700, an 800 driving the engine and engine 810.

 The RF signal transmission unit 500 shown in FIG. 4, is equipped with an RF signal generator 510, a transmitter generator 520, a modulator 530, a transmitter 540 and a transmit antenna 550, where the RF signal generator 510 is used to generate a signal wave corresponding to the button signal, when the signal is received from the input button unit 400, the transmitter generator 520 is intended to generate a carrier wave with a frequency adequate to radio communication, the modulator 530 serves to superimpose the wave of the signal from the RF signal generator 510 onto the carrier wave generated by the generator rum transmitter 520 to modulate it into a radio frequency signal, and a transmitter 540 amplifies an RF signal modulated by the modulator 530 for transmission through a transmitting antenna 550.

 In addition, the RF signal receiving unit 600 is equipped with a receiving antenna 610, a receiver 620, a receiver generator 630, a demodulator 640, and an RF signal processor 650, where the receiver 620 amplifies the RF signal received by the receiving antenna 610, the receiver generator 630 being configured to generate the same frequency that the carrier wave of transmitter generator 520 has, demodulator 640 serves to generate a primary signal wave from a radio frequency signal amplified by receiver 620 according to the frequency generated by the generator m receiver 630, a processor 650 and an RF signal is used for processing the signal wave coming from the demodulator 640, by converting it into its primary signal button and supply to the controller 700.

 Controller 700 provides a control signal for controlling on / off operations and engine speed 810 in accordance with a button signal provided by the radio frequency processor 650 of the radio frequency signal receiving unit 600. The engine actuation unit controls the input energy in accordance with a control signal supplied by the controller 700 to thereby control on / off operations and the rotation speed of the engine 810, and the engine 810 is driven by the energy supplied from the engine actuation unit 800 , for rotation by means of this impeller.

 Further in detail and with reference to FIG. 2-4, a method of operating a device made according to the present invention will be disclosed.

 When energy is supplied from a predetermined source of energy (e.g., a battery) to an RF signal transmitter 500 located in the handle 200, a carrier wave with a frequency adequate to radio communication is generated by the generator 520 of the RF signal transmitter 500 and when the plug is electrical (see position 36 on Fig. 1) the main part 300 is inserted into a socket (not shown), energy is supplied to the main part 300, and a frequency identical to the frequency of the carrier wave from the transmitter generator 520 is generated by the generator 630 of the radio frequency receiver 600 Ignal.

 At this point, buttons (for example, “maximum revolutions”, “high revolutions”, “medium revolutions”, “low revolutions”, “stop”) on the input keypad 400 when the keys are manipulated provide a signal to the input keypad 400.

 The output signal of the input keypad 400 is converted to a signal wave corresponding to it by the radio frequency signal generator 510 of the transmitter of the radio frequency signal 500, and the output wave of the signal from the radio frequency generator 510 in the radio frequency transmitter 500 is superimposed by the modulator 530 on the carrier wave generated by the transmitter generator 520 and converted to radio frequency signal for subsequent output.

 The output RF signal from the transmitter generator 520 is amplified by the transmitter 540 with a predetermined gain required to provide radio communication through the transmit antenna 550. The output RF signal from the transmit antenna 550 of the transmitter 500 of the radio frequency signal is received by the receive antenna 610 of the radio frequency signal receiving unit 600, and the radio frequency signal, the received antenna 610 is amplified with a predetermined gain by the receiver 620 for subsequent output. The RF output signal from the receiver 620 is demodulated by the demodulator 640 into a primary signal wave corresponding to the frequency generated by the receiver generator 630, and the demodulated signal wave is processed by the RF signal processor 650 and converted into a primary button signal for subsequent transmission to the controller 700.

 In this case, the controller 700 recognizes the user command corresponding to the button signal and arrives from the radio frequency signal processor 650 of the radio frequency signal receiver unit 600, namely, it recognizes the air suction force selected by the user and generates a control signal corresponding to the recognition result.

 In other words, the controller 700 provides a control signal for driving the engine 810 at a speed corresponding to the suction force selected by the user in accordance with the user command, or outputs a control signal for stopping the driving of the engine 810.

 Energy is supplied to or disabled from the engine 810 by the engine driving unit 800 in accordance with a control signal from the controller 700, and when energy is supplied to the engine 810 from the engine driving unit 800, the engine 810 rotates by the supplied energy.

 When the motor 810 is driven as described above, the impeller in the main body 300 rotates together with the motor 810 to create a suction force corresponding to the rotation speed of the motor 810, so that foreign objects such as dust and the like are sucked into a dust chamber in the main part 300 through the suction inlet 100 and the transition part 200.

 Therefore, when the buttons on the input button unit 400 located in the handle 220 are manipulated to change the air suction force or to stop the operation of the vacuum cleaner, the button signal from the input button unit 400 is transmitted or received as a radio frequency signal supplied to the controller 700, and the engine is controlled during its operation by control signals coming from the controller 700.

 Now in detail with reference to FIG. 5, a second embodiment of the present invention will be described. In FIG. 5 is a block diagram of a remote control device of a vacuum cleaner according to a second embodiment of the present invention, where the remote control device includes a key input unit 400, a dual-tone multi-frequency pulse transmitter 900, a controller 700, a dual-tone multi-frequency pulse receiver 1000, an engine driving unit 800, and an engine 810.

 Here, the basic construction of the present embodiment is similar to the construction of the first embodiment of the invention, with the same reference numerals and symbols used to denote similar or equivalent parts or parts as in FIG. 2-4.

 In FIG. 5, a dual-tone multi-frequency pulse transmitter 900 comprises a dual-tone multi-frequency pulse generator 910, a transmitter generator 920, a modulator 930, a transmitter 940 and a transmit antenna 950. A dual-tone multi-frequency pulse generator 910 generates dual-tone multi-frequency pulses corresponding to a button signal when a button signal is input from the input key block 400 , transmitter generator 920 generates a carrier wave with a frequency adequate to radio communication, modulator 930 generates a carrier wave generated by the transmitter generator 920 a sensor with superimposed dual-tone multi-frequency pulses generated by a dual-tone multi-frequency pulse generator 910, and a transmitter 940 serves to amplify dual-tone multi-frequency pulses modulated by a modulator 930 for subsequent transmission through a transmit antenna 950.

 In addition, the dual-tone multi-frequency pulse receiving unit 1000 is equipped with a receiving antenna 1010, a receiver 1020, a receiver generator 1030, a demodulator 1040 and a dual-tone multi-frequency pulse processor 1050, where the receiver 1020 is designed to amplify the signal coming from the transmitter 900 and the received receiving antenna 1010, namely amplification of two-tone multi-frequency pulses superimposed on the carrier wave, and the receiver generator 1030 serves to generate a frequency identical to the frequency provided by the transmitter generator 920.

 The demodulator 1040 extracts the primary two-tone multi-frequency pulses from the signal amplified by the receiver 1020, in accordance with the frequency generated by the receiver generator 1030, and the dual-tone multi-frequency pulse processor 1050 serves to process the two-tone multi-frequency pulses allocated by the demodulator 1040 and converts them into a signal corresponding to the button signal , and issues it to the controller 700.

 Next, a method of operating a device made in accordance with a second embodiment of the present invention is disclosed with reference to FIG. 5.

 When energy is supplied to the dual-tone multi-frequency pulse transmitter 900 from a predetermined source of energy (e.g., batteries) in the initial position, a carrier wave having a frequency adequate to radio communication is generated by the transmitter generator 920 of the dual-tone multi-frequency pulse transmitter 900, and when an electrical plug (see position 36 in Fig. 1) the main part 300 is inserted into a socket (not shown), energy is supplied to the main part 300, and a frequency identical to the frequency generated by the transmitter generator 920 is generated They are generated by a generator 1030 of a dual-tone multi-frequency pulse receiver 1000.

 Further, when the buttons are manipulated (for example, the “maximum revolutions”, “high revolutions”, “middle revolutions”, “low revolutions” and “stop” mode selection buttons) of the input keypad 400 on the handle 220, the button signal corresponding to the key manipulation, issued from the input keypad 400.

 The signal from the button coming from the input keypad 400 is converted to its corresponding two-tone multi-frequency pulses by a two-tone multi-frequency pulse generator 910 of a two-tone multi-frequency pulse transmitter 900 for subsequent output, and the output of two-tone multi-frequency pulses from a two-tone multi-frequency pulse generator 910 of a two-tone multi-frequency pulse transmitter 930 are superimposed to the carrier wave generated by the transmitter generator 920 for subsequent final conclusion. The output two-tone multi-frequency pulses superimposed on the carrier wave by the transmitter generator 920 are amplified by a generator 940 with a predetermined gain corresponding to radio communication and transmitted by a transmitting antenna 950.

 The signal transmitted by the transmit antenna 950 of the dual-tone multi-frequency pulse transmitter 900 is received by the receive antenna 1010 of the dual-tone multi-frequency pulse receiver 1000, and the signal received by the receive antenna 1010 is amplified by the receiver 1020 with a predetermined gain for subsequent output. The output signal from the receiver 1020 is demodulated by the demodulator 1040 to obtain the primary two-tone multi-frequency pulses corresponding to the frequency generated by the receiver generator 1030, and the demodulated signal is processed by the two-tone multi-frequency pulse processor 1050 and converted into a primary button signal for subsequent transmission to the controller 700.

 In this case, the controller 700 recognizes the user command corresponding to the button signal from the dual-tone multi-frequency pulse processor 1050 of the dual-tone multi-frequency pulse receiver 1000, namely, it recognizes the suction force selected by the user and generates a control signal resulting from the recognition.

 In other words, the controller 700 provides a control signal for driving the engine 810 at a speed corresponding to the suction force selected by the user in accordance with the user command, or provides a control signal for stopping the driving of the engine 810.

 The energy supplied from the engine driving unit 800 is supplied to the engine 810 or turned off in accordance with a control signal from the controller 700, and when the energy is supplied from the engine driving unit 800 to the engine 810, the engine is rotated by the supplied energy.

 When the motor 810 is driven as described above, the impeller in the main body 300 rotates together with the motor 810 to create a suction force corresponding to the rotation speed of the motor 810, so that foreign objects such as dust and the like are sucked into a dust chamber in the main part 300 through the suction inlet 100 and the transition part 200.

 Therefore, when the buttons on the button input unit 400 located in the handle 220 are manipulated to change the suction force of the air or to stop the operation of the vacuum cleaner, the button signal from the button input unit 400 is transmitted or received in dual tone multi-frequency pulses, which are then fed to a controller 700, and the engine 810 is controlled during its operation by a control signal coming from the controller 700.

 As can be seen from the preceding description, the advantage of the remote control device of the vacuum cleaner according to the present invention is that the engine is controlled remotely by radio using a push-button input unit located in the handle, thereby eliminating the need to install a communication cable in the sleeve, thereby simplifying production of the sleeve, the weight of the sleeve is reduced, and therefore ease of use is ensured.

Claims (2)

 1. A remote control device for a vacuum cleaner having a suction inlet, a transitional part with a handle and a main part in which an engine and a dust chamber are installed, wherein the transitional part connects the suction inlet to the main part and is intended to move foreign objects collected by the suction inlet, such like dust into the dust collecting chamber by suction in accordance with the suction force created by actuating the engine, comprising a push-button input unit, provided with a plurality of buttons for controlling on / off operations and engine speed and for generating a button signal corresponding to the button manipulation, radio transmitting / receiving means for transmitting or receiving by radio the button signal generated by the button input unit, and engine driving control means for controlling on / off operations and engine speed in accordance with the button signal received from the radio transmitting / receiving means, distinguishing the fact that the radio transmitting / receiving means comprises a radio frequency signal transmitter for modulating a button signal emanating from a button input unit into a corresponding radio frequency signal and for emitting this radio frequency signal, and a radio frequency signal receiver for receiving and demodulating the radio frequency signal, transmitted from the transmitter of the radio frequency signal, and for converting the radio frequency signal into the primary signal of the button, and the button input and transmission unit snip RF signal are arranged in the handle of the transition portion, and the receiver RF signal and control means for actuation of the motor disposed in the main body of the vacuum cleaner.  2. The device according to claim 1, characterized in that the radio frequency signal transmitter is a two-tone multi-frequency pulse transmitter and is designed to convert the button signal coming from the push-button input unit into its corresponding two-tone multi-frequency pulses and transmit them superimposed on the carrier wave, and the radio frequency receiver The signal is a two-tone multi-frequency pulse receiver and is designed to receive and demodulate two-tone multi-frequency pulses transmitted by a two-tone m ogochastotnym pulse transmitter on a carrier wave, and converting them into primary signal button.

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