KR20140119591A - Detecting device of body motion and control appartus for electric heating mat using the same - Google Patents

Abstract

A device for detecting body motion comprises: a heating wire arranged on the inside of a base of an electric heating mat in zigzags, comprising a structure shielded by a shield element on the outside of a heating element, and coated with an insulator on the outside; and an impedance sensing wire arranged with the heating wire at regular intervals on the inside of the base of the electric heating mat side by side, and formed as a closed circuit network by connecting both ends. The shield element is connected with a common ground of one side of AC power supply. In a state that DC reference voltage is provided between the impedance sensing wire and the common ground of the power supply, the shield element senses a voltage signal generated by time variation of capacitance changed between the impedance sensing wire and the common ground according to body motion on the electric heating mat, and generates a body motion sensing signal.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a motion detecting apparatus for a human body and an electric heating mat control apparatus using the same.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for detecting movement of a human body and an electric heating control apparatus for controlling electric heating apparatus using the apparatus.

An electric heating mat device that uses electricity as a heat source includes an electric mat, an electric panel, an electric mat, an electric furnace, and an electric carpet.

Such a conventional electric plate is continuously operated when the user moves from one place to another without emptying the place or turning off the power of the heating wire while the power is turned on for heating by the user so that the power loss is wasted and the risk of fire And the like.

Generally, an electric heating mat device, which is an electric heating device, is equipped with a temperature control device which continuously supplies electric power until the temperature set in the temperature control device And then heated.

Even if the user does not turn off the power or does not lower the temperature, the heating operation is continuously performed even if the user leaves the electric heating mat device. In this case, the electric appliance is wasted and the fire is caused .

Therefore, when the user leaves the electric heating mat device for a certain period of time on the electric heating mat device, it is necessary to stop the heating to prevent the accident.

In addition, in order to prevent the risk of fire or unnecessary power wastage in case that the user goes out without turning off the power switch, a product has been developed in which a timer is turned off after a certain time elapses.

These products have a timer set from 8 hours to 12 hours. If the user operates the thermostat in the early evening of winter, there is an inconvenience that the power is turned off during operation at dawn and the power is turned on again. In case of going out without turning off the power supply shortly after, the power is turned off only after the set time has elapsed, so that unnecessary power waste occurs.

As a technology to detect the human body, there are a number of panels with built-in pressure switch installed on the electric board in the utility model registration 20 - 0429211 (power saving and safety function electric mat), so that the pressure switch is operated by the weight of the human body Lt; / RTI > In order to embed a pressure switch having such a configuration, a case having a certain thickness and area is basically required to be secured. In the case of an electric mat which is thick and difficult to fold, it is possible to install it. However, In the case of an electric furnace, the pressure switch panel becomes thicker than the thickness of the electric furnace, which makes the installation itself very difficult. In addition, since the weight of the user varies, it is not economical to use a relatively low heating device, which is a relatively inexpensive heating device, because the weight reference of the operating point of the pressure switch is determined and the pressure sensor is installed at every position.

In addition, even when a heavy bed or a pillow is placed on the electric heating mat device, it is detected by the human body, so that the pressure switch remains attached, so that the power supply can be maintained.

In addition, Japanese Unexamined Patent Application Publication No. 7-198149 (an infrared sensor unit electric kotatsu and a manufacturing method thereof) is provided with a motion detection sensor by an infrared sensor disposed at one upper end of a controller or an electric control panel, There has been disclosed a technique for determining whether or not to use the apparatus.

Since this type of infrared sensing device detects only within the secured sensing area, it is necessary to use the sensing device in a flat state, so that the sensing area can be ensured. When the electric seating is bent or folded during use, It may malfunction.

Therefore, even when bent or folded like an electric heating mat, there is no fear of failure, and the user can always sense the movement of the user on the electric heating mat regardless of the position, and can be economically detected A device is required.

Japanese Unexamined Patent Application Publication No. 7-198149 (Electric Kotatsu part and infrared ray sensor part) Registered utility model 20 - 0429211 (electric mats with power saving and safety function)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a motion detection apparatus for a human body capable of detecting movement of a user at all places on an electric heating mat.

An object of the present invention is to provide a human body motion sensing device which can be economically manufactured by providing an electric heating mat which is relatively inexpensive and does not cause deformation even when the electric heating mat is folded or folded.

It is another object of the present invention to provide a method and apparatus for preventing a waste of electric power by preventing a heating voltage supplied to a heating wire when a user senses that there is no movement for a predetermined time by using a motion detecting device of a human body, And to provide a heating mat control device.

It is still another object of the present invention to provide an electric warm mat control device for reducing a set temperature by determining the number of times of movement per hour for a user who is in an impaired state, a senior citizen or a patient.

According to an aspect of the present invention,

A heating wire which is disposed in a zigzag form inside the base of the electric heating mat and which has a structure that is shielded by a shield body outside the heating element and which is covered with an insulator at the outside thereof; And an impedance sensing line disposed in parallel with the heating wire at a predetermined interval in the base of the electric heating mat and connected to both ends to form a closed loop network; Wherein the shield is connected to a common ground on one side of the AC power supply and the DC reference voltage is supplied between the impedance sensing line and the common ground of the power supply, There is provided a motion detecting apparatus for a human body which senses a voltage signal generated by a temporal change amount of a capacitance that varies between a sensing line and the common ground to generate a human motion sensing signal.

In the case where a motion detection signal of a human body is not input for one hour or longer, the controller determines that there is no user in the electric heating mat, And the voltage supplied to the heating element is cut off.

According to another aspect of the present invention,

An impedance sensing line disposed in the base of the cool mat using a cooling device so as to surround the cool mat via an edge and connected to the end to form a closed loop network; And a ground wire disposed on one side of the cool mat; Wherein the ground line is connected to a common ground of the power supply and the DC reference voltage is supplied between the impedance sensing line and the common ground of the power supply, There is provided a motion detecting apparatus for a human body which detects a voltage signal generated by a temporal change amount of a capacitance that varies between common grounds to generate a human motion detection signal.

According to another aspect of the present invention,

An impedance sensing line disposed in the base of the hot water mat using a hot water pipe to surround the hot water pipe through an edge and connected to the end to form a closed loop network; And a ground wire disposed along the hot water pipe; Wherein the ground line is connected to a common ground of the power supply and the DC reference voltage is supplied between the impedance sensing line and the common ground of the power supply, There is provided a motion detecting apparatus for a human body which detects a voltage signal generated by a temporal change amount of a capacitance that varies between common grounds to generate a human motion detection signal.

According to an embodiment of the present invention, when the user leaves the room for a while or if the user does not turn off the power by mistake, the user can detect the presence or movement of the user when the user goes out, , And the risk of fire is prevented.

According to an embodiment of the present invention, since the impedance sensing line senses weak small voltage and small signal current, the thickness is thin, the installation is simple and the manufacturing cost is low, and the bending and impact It will not be affected by use.

According to an embodiment of the present invention, the impedance sensing line can be applied to an electric heating mat, such as an electric furnace, which can be washed by employing an insulated electric wire.

1 illustrates an arrangement of a heating wire and an impedance sensing wire according to an embodiment of the present invention.
2 illustrates an arrangement of a heating wire and an impedance sensing wire according to another embodiment of the present invention.
3 illustrates an impedance sensing wire and a heating wire according to an embodiment of the present invention.
FIG. 4 illustrates an apparatus for controlling an electric heating mat using a human motion detecting apparatus according to an embodiment of the present invention. Referring to FIG.
5 to 14 are oscilloscope waveform diagrams for explaining the relationship between an input voltage and a heating voltage and a human motion input signal voltage according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of the present invention will now be described in detail with reference to the accompanying drawings. Referring to the accompanying drawings, the same or corresponding components are denoted by the same reference numerals, A description thereof will be omitted.

It is also to be understood that the terms first, second, etc. used hereinafter are merely reference numerals for distinguishing between identical or corresponding components, and the same or corresponding components are defined by terms such as first, second, no.

An electric heating mat device according to an embodiment of the present invention is an apparatus for heating a mat by inserting an electric heating element on a mat and is called an electric mat, an electric panel, an electric mat, an electric stove, an electric carpet electric cushion, .

The motion detection method of the human body according to an embodiment of the present invention is as follows.

The human body corresponds to the medium of a conductor having a large area of 75% of water. When the medium of the conductor moves between the charged electric fields, the electric field changes and the polarized electric charge moves to the one electrode due to the changing electric field .

1 illustrates an arrangement of a heating wire and an impedance sensing wire according to an embodiment of the present invention.

Referring to FIG. 2, in the human body motion sensing apparatus according to the embodiment of the present invention, the impedance sensing wires 11 are disposed side by side with the heating wires and connected at both ends thereof to constitute a closed loop network as a whole.

A heating wire according to an embodiment of the present invention includes a structure that is shielded by a shield body 14 outside a heating element or a heating wire 12, and the outside is coated with an insulator.

The heating wires are arranged in a zigzag form in the base 10 of the electric heating mat and the impedance sensing wires 11 are arranged in parallel with the heating wires.

The impedance sensing lines 11 arranged side by side with the exothermic wires are charged with each other by the shielding body 14 wound around the outer surface of the heating wire 12 and the supplied control voltage. Since one side of the shield body 14 is connected to the common ground, the impedance sensing line 11 is kept charged with the common ground.

Since the impedance sensing line 11 is charged by DC 2 [V] which is the common ground and the control voltage (reference voltage), but the impedance sensing line 11 is insulated by the ground and the insulator, The current does not flow when there is no movement of the user.

Since the electric heating mat is installed on the floor or the bed, the impedance sensing line 11 and the floor surface having the ground potential are charged with each other.

In the state in which there is no movement of charges, there is no movement of charges, so that no signal is kept in the impedance sensing line 11.

At this time, when the user (human body) rises or climbs up on the electric heating mat, the human body corresponds to the conductive medium at the instant of movement, and therefore, the impedance sensing line, which is installed side by side with the shield wire 11 of the heating wire, The electrostatic capacity depending on the total dielectric constant changes between the human body 11 and the shield body 14 according to the movement of the human body.

When an object is approached in the electric field, an electrostatic induction voltage is induced between the electrode surface and the approaching object surface by a polarization action, and the instantaneous changing current flows between the electrode and the ground due to the induced voltage.

In the human motion detecting apparatus according to the embodiment of the present invention, when there is no movement in the network, no current flows through the impedance sensing line 11, but when the human body moves within the closed circuit network formed by the impedance sensing line 11 When a motion occurs, it is detected that an instantaneous voltage signal is generated between the impedance sensing line 11 and the ground, so that the motion of the human body can be determined.

As a result of the experiment according to the embodiment of the present invention, the voltage signal generates an AC signal having a very low frequency of about 0.5 [Hz] to several [mV] every time the human body moves.

A person is always turned on or off when he or she wakes up. According to the experimental report (Improvement of the sleeping environment using sensor), according to the Korean Society of Oceanographic Information and Communication Engineers (2010) 14, 11, the normal person during the sleep has an average of 254 times (150 ~ 300 times) It has been reported to have at least 30 to 40 misses per hour.

Therefore, if there is no return for a predetermined time, the user can be regarded as having no user on the electric heating mat. At this time, the electric heating mat control apparatus according to the embodiment of the present invention activates the control signal, By cutting off the current, it is possible to prevent waste of electric power and to prevent an accident in advance.

As described above, between the impedance sensing line 11 and the ground, when the user (human body) is turned on or moved on the electric heating mat, the charged area and the dielectric constant are changed in accordance with the change in the interval according to the movement of the human body The voltage due to the electrostatic induction phenomenon instantaneously occurs on the impedance sensing line.

Since the user (human body) is used in close contact with the user due to the characteristics of the electric heating mat, the distance between the user and the impedance sensing line 11 is large and the distance is close to each other.

According to an embodiment of the present invention, even when the impedance tangent line 11 and the small movement of the user (human body) in proximity to the shield body 14 are used, the gap t or the area The instantaneous change of the dielectric constant of the medium between the entirety and the entirety changes instantaneously, so that a voltage signal is generated in the impedance sense line 11 due to the temporal change of the instantaneous dielectric constant, that is, the capacitance change value.

That is, when the human body is turned over, the distance and the area of the dielectric constant are changed to change the capacitance. The voltage signal generated from the impedance sensing line 11 increases instantly as the distance becomes closer or the contact area increases When the distance is reduced or the contact area is reduced, the voltage signal that is sensed decreases in reverse and then becomes undone.

According to an embodiment of the present invention, the impedance sensing line provided inside the electric heating mat between the impedance sensing line and the ground may be formed by using a wire-type wire to increase the symmetric area inside and insulate the outer covering with PVC Insulated conductors were adopted.

According to an embodiment of the present invention, the impedance sensing lines 11 insulated with vinyl or PVC are arranged side by side with the exothermic wires, and the length of the impedance sensing wires 11 is set to 20M or more as the length of the exothermic wires So that they are uniformly distributed over a wide area along the shield member 14. [

In the embodiment of the present invention, the impedance sensing lines 11 are arranged side by side with the heating wires so that the large area of the heating wires facing the shielding body 14 is maximized, The impedance sensing lines 11 can be arranged together during the process of arranging the heating wires in the manufacturing process of the electric heating mat, so that the time and cost of the manufacturing process of the impedance sensing line 11 can be reduced.

2 illustrates an arrangement of a heating wire and an impedance sensing wire according to another embodiment of the present invention.

In another embodiment of the present invention, the impedance sensing line may be formed as a whole closed circuit network along the entire edge of the electric heating mat, and a heating wire having a shield wire in a zigzag shape may be disposed therein.

In this case, a sensing voltage is generated between the closed loop network and the ground of the shield line when the human body moves in the entire closed loop network.

One of the two lines of the heating line 12 is connected from the input AC power source AC1 via the power control element and the other end of the heating wire is connected together with the input AC power source AC2 and the ground power source of the operating power source of the electric heating mat control device 20 .

3 illustrates an impedance sensing line and a heating wire according to an embodiment of the present invention.

As shown in FIG. 3 (a), the impedance sensing line according to an embodiment of the present invention has a winding shape in which a heating wire 32 made of copper is wrapped around the central PE yarn 33 to increase the unit area, Heat-resistant PVC insulated wire with heat-resistant PVC (31) used in general heating line was adopted.

However, the above is only an embodiment, and the cover may be made of other insulating material.

A commonly used heating wire is of type b in Fig.

The b type heating wire is wound around the central PE yarn 43 with a heating wire 44 and the periphery thereof is insulated by a nylon thermistor 42 which is a temperature sensing medium and a heating wire 43 is wound around the nylon thermistor 42, This becomes the winding.

Heat-resistant PVC insulated wires using heat-resistant PVC (41) are used for outer sheathing of hot wire. Since the b-type heating wire does not have an external shield wire, electromagnetic waves are generated from the heating wire and the sensing wire.

Further, the silicon heating line of d type in which the temperature sensor is separately installed is not suitable as the heating wire according to the embodiment of the present invention because there is no shield layer.

The C type heating wire to which the AL shielding layer 52 is attached to the outer periphery to block the generation of electromagnetic waves may be suitable as a heating wire according to an embodiment of the present invention.

An embodiment of the present invention employs a d-type heating wire having a thin thickness, a double structure, an AL shield attached to the outside, and a comparatively low price than the C type.

The present invention can be applied to any heating element as long as it can use not only the heating element but also the surface heating element and the outside of the heating element.

FIG. 4 illustrates an apparatus for controlling an electric heating mat using a human motion detecting apparatus according to an embodiment of the present invention. Referring to FIG.

Referring to FIG. 4, the DC operation power source unit 101 receives the AC input power AC1 and AC2 and converts the AC input power AC1 and AC2 into a DC driving voltage Vcc.

According to an embodiment of the present invention, one side (AC2) of the AC input power source and the ground side of the DC operation power source unit 101 are connected together and used as a common ground.

For example, regardless of whether the DC operation power source unit 101 uses the simple power source circuit or the transformer, the ground side of the DC power source unit is connected as one side of the AC power source unit and used as a common ground.

According to an embodiment of the present invention, when one terminal S1 of the shielding body 14 surrounding the heating wire 12 is connected to the common ground, the shielded external potential of the heating body coincides with the ground potential of the power supply, It is possible to reduce the generation of electromagnetic waves.

Referring to FIG. 4, after the power source is connected, when the temperature is adjusted by adjusting the temperature regulating resistor VR1 having the temperature regulating function, an ON signal is outputted from the output node A of the microcomputer 102 to the set voltage The power supply element for voltage supply SCR is turned on by the ON signal of the output node A of the microcomputer to supply the heating current to one terminal H1 of the heating wire provided inside the electric heating mat .

According to an embodiment of the present invention, the controller of the electric heating mat alternates between the heating function and the sensing function every half cycle.

That is, when the direction of the current, which is the heat generation period, flows from AC1 to AC2, it generates heat, and performs the function of detecting the temperature in the half wave period flowing from AC2 to AC1.

When the temperature rises, the signal through the ground (AC2) - S1, S2 - nylon thermistor N - H1, H2 - temperature sensor 103 is input to the microcomputer 102 at the temperature sensing period, An OFF signal is generated at the node A. By the OFF signal of the microcomputer, the power device for supplying the heating voltage SCR is turned off and the power supply to the heating line is stopped.

Since the temperature sensing and heat generation processes are common, a detailed description thereof will be omitted.

By repeating this process, the temperature of the electric heating mat is kept constant.

According to the embodiment of the present invention, the DC supply voltage Vcc is 5 [V], and the voltage of the sensing input node (point C) of the microcomputer input to the microcomputer is 2 [V] And the motion of the human body is determined.

This reference voltage can be determined by resistors R2, R3 and R6, R7 connected to the DC supply voltage Vcc.

According to an embodiment of the present invention, when a human body detection signal of ± 2 [mV] or more is input with the reference potential set at 2 [V], the input node (B node) of the first operational amplifier OP1 amplifies The output is amplified again by the second operational amplifier OP2 and output to the sensing input node (point C) of the microcomputer.

According to an embodiment of the present invention, the output voltage of the second operational amplifier OP2 obtained by amplifying the human sense signal of more than ± 2 [mV] in two stages is 2.5 [V] or more or 1.5 [V] When this voltage is input to the microcomputer, it is programmed to recognize a voltage of 2.5 [V] or more or 1.5 [V] or less as a human motion signal in the microcomputer.

According to an embodiment of the present invention, the first operational amplifier OP1 performs inverse amplification three times, and the second operational amplifier OP2 performs inverse amplification by a factor of 100, and this amplification factor is applied to the resistors R1, R4, and R5, R8 value.

According to an embodiment of the present invention, even if the human motion signal is not input from the impedance sensing line 11 for the first hour while the power is on, do.

Thereafter, when the human motion signal is input from the impedance detection line 11 again, the microcomputer is programmed to extend the normal operation time by one hour even if no separate input signal is input therebetween.

When the user does not use the electric heating mat for more than one hour while the power is turned on, the signal inputted from the impedance sensing line 11 is not supplied for more than one hour. At this time, the microcomputer 102 determines that the user does not exist on the electric heating mat, and the microcomputer 102 generates an OFF signal to the microcomputer output node A, The power supply is interrupted.

In an embodiment of the present invention, the display lamp (Led 1) is programmed to emit light at this time.

Since the dielectric constant of the entire medium between the impedance sensing line 11 and the ground changes temporally as soon as the user rises above the electric heating mat while the power of the electric heating mat is ON, A human motion input signal is generated.

This human motion input signal is filtered by a low pass filter circuit (C2, R1) through a input capacitor (C1) to remove a noise signal exceeding 10 [Hz], and only a low frequency signal of 0.5-5 [Hz] (B node) of the operational amplifier OP1. The human motion input signal is input to the microcomputer via the second operational amplifier OP2, and the microcomputer 102 extends the normal temperature control operation function in units of one hour.

In an embodiment of the present invention, the normal temperature control operation function is extended every 1 hour every time a human body motion detection signal is generated, but it can be changed in units of 30 minutes or 2 hours.

In another embodiment of the present invention, the temperature control method based on the human motion input signal can be selectively selected.

In normal people, sleeping usually lasts three times or more per hour, while in the case of less than three times, it may be a weak patient or a runner.

For example, the microcomputer measures the number of times per hour the human body detection signal is detected. If the movement is more than three times per hour after the first hour has elapsed, the microcomputer recognizes the microcomputer as being in use by the normal person and generates normal output for one hour. However, If it is two times, it is determined that the patient is a tall or weak patient, and the microcomputer can automatically set the set temperature to be low.

That is, even if the user sets the temperature at a high temperature of 60-70 degrees, it is programmed to perform temperature control at a low temperature of 40 degrees or less.

If a signal is input one to two times per hour, the microcomputer's control signal keeps the temperature of 40 degrees to prevent the low temperature image. If more than three signals are input again, the microcomputer sets the initial temperature Control operation.

If the electric heat mats continue to be used without any movement, the temperature may rise locally to cause burns. If it is determined that there is no input signal at all, it is determined that there is no user, and after one hour, the temperature control operation function of the electric heating control device is cut off and the power supply is stopped to be programmed in the microcomputer.

Of course, these criteria can be changed through the microcomputer program.

If the user goes out without turning off the power, there will be no movement for one hour to elapse, so no output signal is generated from the impedance sensing line, the operation of the microcomputer is stopped through the above process, Is blinking.

At this time, when the user comes back after going out and used again on the electric heating mat, the signal is inputted again from the impedance sensing line, and power supply through the control device starts again for one hour from this point through the above process.

5 to 14 are oscilloscope waveform diagrams for explaining the relationship between an input voltage and a heating voltage and a human motion input signal voltage according to an embodiment of the present invention.

5 shows input signals of an AC input voltage and an impedance sensing line in a state where a heating voltage is not applied to a heating wire.

Channel 1-1 shows the waveform of the input AC 220V and channel 2-1 shows the state of the input signal of the impedance sensing line in the state that the heating voltage is not supplied to the heating line.

Referring to FIG. 5, in a state where the input AC 220V is supplied and the heating element SCR is turned off so that the heating voltage is not supplied to the heating wire, the input signal of the impedance sensing wire sensed from the mat becomes the reference voltage There is little change in the.

6 shows an input voltage (point H) of the heating line and an input signal (B node) of the impedance sensing line in a state where no heating voltage is supplied to the heating line.

Referring to FIG. 6, channel 1-2 shows a waveform appearing on the heating line H1 based on the ground potential, and channel 2-1 shows the state of an input signal of the impedance sensing line in a state in which no heating power is supplied to the heating line.

Referring to FIG. 6, the voltage of the heating line is equal to the ground potential when no heating voltage is supplied to the heating line, and the input signal of the impedance sensing line is substantially unchanged from the reference voltage.

Fig. 7 shows the input voltage (point H) of the heating wire and the input signal (B node) of the impedance sensing wire in a state where a heating voltage is supplied to the heating wire without the shielding body.

Referring to FIG. 7, channel 1 - 3 shows a voltage waveform appearing on the heating line H 1 based on the ground potential, channel 2 - 3 indicates the state of the input signal of the impedance sensing line in a state where a heating voltage is supplied to a heating line .

Referring to FIG. 7, a heating power is supplied to the heating line by a power device (SCR) for supplying a heating voltage. On the other hand, the induction voltage is induced in the impedance sensing line 11 by the influence of the electromagnetic wave generated from the heating line. That is, harmonics of about several tens [V] such as channel 2-3 are induced in the input node (node B) of the impedance sensing line.

When the harmonics of several tens of volts are inputted to the input node B of the first operational amplifier OP1, even if a signal is detected when the human body is sensed on the impedance sensing line, since the signal is only a few mV, It becomes very difficult.

Accordingly, in one embodiment of the present invention, the shielded heating wire is used as the heating wire, and the shield side is connected to the power ground so that the impedance sensing wire 11 detects the human motion detection signal without being influenced by electromagnetic waves generated from the heating wire .

8 shows a waveform output to the output node of the second operational amplifier OP2 (the sensing signal input node (point C) of the microcomputer) without the low-pass filter section.

Referring to FIG. 8, the channel 2-4 represents a voltage waveform output to the output node of the second operational amplifier OP2 (the sensing signal input node (point C) of the microcomputer) without the filter section.

8, when the filter C2 is not provided even when power is not supplied to the heating line, various noises are amplified through the impedance sensing line, so that the output node of the second operational amplifier OP2 Signal input node (point C)) includes a frequency of 60 [Hz] having a voltage of about ± 0.5 [V] like channel 2-4.

The input signal voltage from the impedance sensing line is input through the human body sensing signal input node B and the input stage capacitor C1. The input signal voltage by the human body senses 0.5 [Hz] [to 5 [Hz] Of very low alternating current low frequency signal.

Since the signal voltage due to human body motion is a pulse voltage signal of about several [mV] having a very low frequency of 0.5-5 [Hz], when the noise as shown in the channel 2-4 comes in, An error occurs in determining the motion detection signal of the camera.

Since the impedance sensing line 11 is formed of a wide closed loop network even when there is no human motion in a state where the heating line is shielded, the noise of 60 Hz and various high frequency bands of the peripheral power supply is inputted through the closed loop network.

9 shows waveforms output to the output node of the second operational amplifier OP2 (the sensing signal input node (point C) of the microcomputer) in a state where the low-pass filter is installed.

Referring to FIG. 9, channel 2-5 represents a voltage waveform output to the output node of the second operational amplifier OP2 (the sensing signal input node (point C) of the microcomputer) with the low-pass filter installed.

In the embodiment of the present invention, the filter unit is constituted by the parallel capacitor C2 and the input resistor R1 so that the noise frequency of 60 Hz or more shown in FIG. 8 flows to the ground, Filter.

In addition, as described above, a pulse voltage signal of about several [mV] having a very low frequency of 0.5-5 [Hz] is input to the motion detection signal of the human body, and noise caused by unnecessary DC voltage is removed The DC noise component is removed by connecting the input node input capacitor C1 to the human body detection signal input node B in series.

9, when there is no signal from the impedance sensing line in the state where the low-pass filter is installed, the voltage output from the output node of the second operational amplifier OP2 (the sensing signal input node (C node) of the microcomputer) The waveform becomes a standby state flat with the reference potential like channel 2-5.

10 and 11 show output voltages of the heating input terminal (point H) of the heating line and the output node (the sensing signal input node (point C) of the microcomputer) of the second operational amplifier OP2 in a state where a heating voltage is supplied to the unshielded heating wire FIG.

The difference in the presence or absence of the shield line of the heating line is influenced by the high frequency noise generated from the heating line as described above. However, even when the high frequency noise is blocked, the current flowing to the heating line starts to be supplied, An induced voltage is generated in the impedance sensing line 11 due to the influence of the instantaneous induced voltage.

10 and 11, the channels 1-6 and 1-7 are input voltages (point H) of the heating line in a state where the heating voltage is supplied to the unshielded heating line, and the channels 2-6 and 2-7 are the second calculation And output to the output node of the amplifier OP2 (detection signal input node (point C) of the microcomputer).

10 shows a moment when an exothermic current flows in the heating wire, reaches a set temperature, and the power supply is interrupted. Generally, the temperature control method is to supply the power up to the set temperature. When the set temperature is reached, the power supply is stopped. When the temperature is lowered, the power is supplied again. In order to maintain the set temperature, the power supply to the heating wire is repeatedly turned on and off.

At this time, in the impedance detection line 11, the induction voltage is induced by a change in the current of the heating line, which is instantaneously changed to a reduced state, and the waveform output to the output node C of the second operational amplifier OP2, - A signal that goes down to 0.5 [V] or more appears and then returns.

11 shows a moment when the heating current does not flow to the heating wire and reaches the set temperature and the power supply is resumed.

In this case, as opposed to FIG. 10, the induction voltage is induced by the current change of the heating line instantaneously increased in the impedance sense line 11, and the waveform, which is output to the output node C of the second operational amplifier OP2, 2-7 shows a signal that is higher than +0.5 [V] than the reference potential, and then returns.

In such a state that the heating line is not shielded, a signal generated in accordance with the change of the power supply start and stop time at the heating line may be erroneously determined as the human motion detection signal.

FIGS. 12 and 13 show waveforms output to the output node C of the second operational amplifier OP2 and the input voltage (point H) of the heating line in the state where the heating voltage is supplied to or disconnected from the shielded heating wire.

Referring to FIGS. 12 and 13, in the above-described FIG. 9. 10, the induced voltage is generated at the output node C of the second operational amplifier OP2 according to the on-off of the exothermic current. The induction voltage is blocked by the shield of the heating wire even when the heating current is supplied or at the moment when the heating current is interrupted in the channels 2-8 and 2-9 of FIG.

FIG. 14 illustrates waveforms generated by detecting a user's turning on an electric heating mat equipped with an impedance sensing wire according to an embodiment of the present invention.

14, channel 2-10 represents a waveform output to the output node (C node) of the second operational amplifier OP2, and channel 1-10 represents an input voltage (H point) waveform of the heating line.

The PVC-insulated impedance-sensing wires are arranged side-by-side with the shielded heating wires. The impedance sensing terminal Z connected from the impedance sensing line 11 receives the sensing signal from which the DC component is removed by the series capacitor C1 and passes through the human sensing signal input node B only under 10 Hz And inputted to the first operational amplifier OP1 through the low-pass filters C2 and R1. This signal is input to the input terminal of the microcomputer 102 from the output node C of the second operational amplifier OP2 through the first and second operational amplifiers OP1 and OP2.

When all unnecessary noise is removed, the output waveform of the output node (point of detection signal input node (point C) of the microcomputer) shows ± 0.7 [V] at about 1.5 [Hz] Able to know.

Accordingly, the microcomputer 102 senses that the user is on the electric heating mat and continuously operates the control device.

According to one embodiment of the present invention, when the person normally turns on the electric warm mat, it is usually not more than 5 [Hz].

In addition, even if it moves slowly, it keeps 0.5 [Hz] or more.

Therefore, according to the embodiment of the present invention, when the electric plate user moves, a very slow 2 [mV] to 10 [mV] low frequency signal of about 0.5-5 [Hz] is generated from the impedance sensing line. If the signal is amplified by the first and second operational amplifiers OP1 and OP2, the signal is at least 0.5 V or less than -0.5 V (that is, 2.5 V or more) or 1.5 [V]) and input to the microcomputer.

The above-described example is described as an embodiment of the present invention, and the microcomputer can be programmed to extend the normal operation time from 0.5 hour to 2 hours according to the input signal of the human body detection signal.

The reference value of the reference voltage of the first operational amplifier OP1 or the voltage of the output-side voltage may be changed according to the configuration of the circuit.

In the embodiment of the present invention, the electric heating mat control device is separated from the electric heating mat, which is an electric heating mat. However, the present invention can be applied even when the electric heating mat and the control device (temperature controller) are combined.

In addition, in the embodiment of the present invention, the motion sensing device of the human body using the impedance sensing line is limited to the electric heating mat device having the heating element. However, in another embodiment, the hot mat or cool mat It is applicable.

In order to apply the impedance sensing line according to an embodiment of the present invention to a hot mat or a cool mat, the whole area where the user touches the impedance sensing line is formed of a closed loop network, and the outer surface of the hot water or cooling pipe is grounded Or by connecting the outer surface of the hot water or cooling pipe with a conductor and connecting it to ground.

That is, when the impedance sensing line is connected to the input terminal of the sensing circuit according to an embodiment of the present invention, the sensing signal input terminal of the microcomputer determines the input signal to detect the movement of the user on the hot mat or the cool mat have.

For example, an impedance sensing line may be disposed in the base of a cool mat using a cooling device so as to surround the cool mat through an edge and connected to the end to form a closed loop network. A ground wire is disposed on one side of the cool mat. The ground wire is connected to the common ground of the power source.

The motion detecting apparatus of the present invention is characterized in that, in a state in which a DC reference voltage is supplied between the impedance sensing line and the common ground of the power supply, a capacitance of the capacitance changing between the impedance sensing line and the common ground And detects a voltage signal generated by a temporal change amount to generate a human motion detection signal.

10: Base of electric heating mat
11: Impedance detection line
12: Heating line
14: shield
20: Electric heating mat control device
31, 41: PVC Cloth
32, 44: Heating line
33, 43: PE company
42: Nylon thermistor
43:
52: AL shielding layer
101: DC operation power source
AC1, AC2: AC input power
C1 to C5: Capacitor
OP1, OP2: Operational amplifier
R1 to R8: Resistance
S1, S2: terminals of the shield
SCR: Power device for supply of exothermal voltage
H1, H2: Terminal of heating wire
VR1: Temperature control resistor
Z; Terminal of impedance sensing line

Claims (14)

A heating wire which is disposed in a zigzag form inside the base of the electric heating mat and which has a structure that is shielded by a shield body outside the heating element and which is covered with an insulator at the outside thereof; And
An impedance sensing line disposed in parallel with the heating wire at a predetermined interval in the base of the electric heating mat and formed by a closed loop network connecting both ends thereof; / RTI >
Wherein the shield body is connected to a common ground on one side of an AC power source, and the DC reference voltage is supplied between the impedance sensing line and the common ground of the power source, A human body motion sensing signal generating a human motion sensing signal by sensing a voltage signal generated by a temporal change amount of capacitance that varies between grounds. The method of claim 1, wherein
Wherein the DC reference voltage receives the AC power and converts the AC power to a DC driving voltage, and the ground of the DC driving voltage is connected to one common ground of the AC power source. The method according to claim 1,
Wherein the signal sensed by the impedance sensing line is amplified by a first operational amplifier through a low pass filter passing only a frequency signal within 10 [Hz]. The method according to claim 1,
Wherein the signal sensed by the impedance sensing line is amplified by a second operational amplifier through a first operational amplifier through a low-pass filter passing only a frequency signal within 10 [Hz]. The method according to claim 1,
Wherein the direct current reference voltage is 2 [V], and the signal sensed by the impedance sensing line is a low frequency signal in the range of 0.5-5 [Hz]. The method according to claim 1,
Wherein the DC reference voltage is 2 [V], and the signal sensed by the impedance sensing line is a signal having a voltage in the range of 2 [mV] to 10 [mV] and a low frequency in the range of 0.5 - 5 [Hz] Human motion detection device
5. The method of claim 4,
Wherein the first operational amplifier amplifies the human detection signal of ± 2 [mV] or more when the reference potential is set to 2 [V], and outputs the amplified human detection signal to the second operational amplifier. 5. The method of claim 4,
Wherein when the voltage value outputted to the second operational amplifier is 2.5 V or more or 1.5 V or less is outputted, it is determined as a human motion detection signal. The method of claim 3,
And a series capacitor for removing a direct current component from signals sensed by the impedance sensing line.
And a microcomputer for receiving a movement detection signal of a human body from the human motion detection apparatus according to any one of claims 1 to 8,
Wherein the microcomputer determines that there is no user in the electric heating mat and cuts off the voltage supplied to the heating element when the microcomputer does not input the motion detection signal of the human body for one hour or longer, The method of claim 10, wherein
Wherein the electric heating mat control device is one of an electric mattress, an electric panel, an electric mattress, an electric stove, an electric carpet electric cushion, and an electric blankets. 11. The method of claim 10,
Wherein when the microcomputer detects a motion detection signal of a human body less than three times in one hour, the control unit controls the temperature upper limit of the electric heating mat to be set to 40 degrees or less.
An impedance sensing line disposed in the base of the cool mat using a cooling device so as to surround the cool mat via an edge and connected to the end to form a closed loop network; And
A ground wire disposed on one side of the cool mat; / RTI >
Wherein the ground line is connected to a common ground of the power source and is connected between the impedance sensing line and the common ground in accordance with movement of the human body on the electric heating mat, And a human body movement detection signal is generated by sensing a voltage signal generated by a temporal change amount of the capacitance. An impedance sensing line disposed in the base of the hot water mat using a hot water pipe to surround the hot water pipe through an edge and connected to the end to form a closed loop network; And
A ground wire disposed along the hot water pipe; / RTI >
Wherein the ground line is connected to a common ground of the power source and is connected between the impedance sensing line and the common ground in accordance with movement of the human body on the electric heating mat, And a human body movement detection signal is generated by sensing a voltage signal generated by a temporal change amount of the capacitance.

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