KR20010090141A - Remote control apparatus by communication in power line - Google Patents

Abstract

PURPOSE: A remote controller via a power line is provided to easily remote-control without arranging an additional control line by transceiving control signal via an AC power line using a spread spectrum modulating scheme. CONSTITUTION: A sensing and transmitting device(10) includes a number of setting and sensing units(12), a transmission controller(13), a spread spectrum modulator(14) and a radio frequency transmitter(15). A number of setting and sensing units(12) compare a control reference value set by a user with an actual value and output control signal. The transmission controller(13) controls the control signal output from the setting and sensing units(12) to be randomly transmitted. The spread spectrum modulator(14) modulates the control signal to PN code. The radio frequency transmitter(15) outputs the modulated signal to a power line. A controlling and receiving device(30) includes a radio frequency receiver(32), a spread spectrum demodulator(33) and a remote data processor(34). The radio frequency receiver(32) receives a radio frequency signal transferred via the power line. The spread spectrum demodulator(33) demodulates the received signal and recovers the original control signal. The remote data processor(34) processes the recovered control signal, distinguishes error signal, and generates continuous control signal.

Description

Remote control device by power line communication {REMOTE CONTROL APPARATUS BY COMMUNICATION IN POWER LINE}

The present invention relates to a remote control device for controlling a drive device installed in a predetermined place at another location, and more particularly, by transmitting and receiving a control signal through a power line for supplying AC power, without a separate control line. The present invention relates to a remote control device by power line communication that enables remote control.

In general, in a heating device that regulates the indoor temperature of a house or a building, a device such as a boiler for supplying hot water is installed in a corner or basement that is not easily seen by a person because of beauty or practicality. The hot water is heated in each room through a pipe to perform the heating function.

In such a heater, the heating temperature of the room may be controlled by turning on / off a hot water valve for supplying hot water heated in a boiler to each room, or by turning on / off the boiler.

As described above, since the actual boiler device is installed in a corner place where people do not enter well or where people live, i.e., away from a heating place, the boiler is moved back and forth to control the temperature every time. Has a lot of inconvenience. Therefore, the hot water discharge amount of the boiler in accordance with a control signal, such as a setting signal or a detection signal installed in the boiler apparatus and a temperature setter and a temperature sensor installed in a place where people can easily see, and output from the temperature setter and the temperature sensor. Promoting convenience by suggesting a remote control device consisting of a control device for controlling the.

By the way, the remote control device used up to now should be connected to a separate control line for the temperature setting and transmission and reception of the control signal between the sensor and the control device. In order to install a separate control line, conduit pipes are disposed in concrete structures from each room to hot water distributors, finished with concrete, and after finishing work, it is necessary to win work.

In addition, in the case of the old house, the control line must be laid through the concrete wall, so that the work becomes complicated. In order to reduce the labor, there is a method of exposing the wire to the outside as it is. There is a disadvantage. In addition, when a large number of households are concentrated in a building such as an apartment, the control lines need to be disposed for each household, thereby increasing installation costs and having a lot of work.

As a method for solving this problem, a method of further providing an antenna and a wireless transmission / reception means for converting and transmitting a control signal into a wireless signal in a control device at a temperature setting and a detector side and a boiler side have been proposed. Although there is an advantage of not needing a control line, there is a problem that the cost is high, and the use of radio waves is increasing in recent years as the use of wireless devices increases.

The present invention has been made to solve the conventional problems as described above, the object is that between the transmitting side and the receiving side through the AC power line basically provided in all buildings without having to provide a separate control line The present invention provides a remote control device by power line communication that enables remote control by transmitting and receiving a control signal without noise.

1 is a block diagram showing a remote control device applied to a heater as an embodiment of a remote control device according to the present invention.

2 is an operation timing diagram when one sensing unit is used in the remote control apparatus according to the present invention.

3 is a flowchart showing the operation of the remote data processing unit when the signal transmission is intermittently performed in the remote control apparatus according to the present invention.

4 is a flowchart showing the operation of the transmission control unit in the remote control apparatus according to the present invention.

FIG. 5 is a timing diagram illustrating a general signal transmission / reception method when two or more detection units exist in the remote control apparatus according to the present invention.

* Description of the symbols for the main parts of the drawings *

10: sensing and transmitting unit 20: power line

30: control and receiving unit 11, 31: power conversion unit

12: temperature setting and sensing unit 13: transmission control unit

14: spread spectrum modulation unit 15: high frequency transmission unit

32: high frequency receiver 33: spread spectrum demodulator

34: remote data processing unit 35: multi temperature controller

As a construction means for achieving the above object of the present invention, the apparatus according to the present invention

When the user sets the control reference value, a plurality of setting and sensing units outputting control signals by comparing them with actual values, and a transmission for controlling the continuous control signals outputted from the setting and sensing units to be transmitted at random intervals. A spread spectrum modulator for modulating a control signal output from the setting and sensing unit into a PN code under control of the control unit, the transmission control unit, and a transmission signal modulated by the spread spectrum modulator at high frequency; Sensing and transmitting unit consisting of a high frequency transmission unit for output to the power line;

A high frequency receiver for receiving a high frequency signal transmitted through the power line, a spread spectrum demodulator for reproducing the original control signal by demodulating the signal received by the high frequency receiver with a spread spectrum code, and the spread spectrum demodulator And a control and reception unit comprising a remote data processing unit for processing the control signal reproduced by the control unit to determine an error signal and to generate a continuous control signal from control signals received at irregular intervals.

Hereinafter, a heating control apparatus according to the present invention with reference to the accompanying drawings.

1 is a block diagram showing the configuration in the case of applying the remote control device by the power line communication according to the present invention to the temperature control of the boiler, the device detects the actual temperature and compares the set temperature and then spreads the result band After converting into a PN code by modulation, a high frequency signal is loaded on a high frequency signal and transmitted to the power supply line 20, and a high frequency signal carrying a spread spectrum code transmitted to the power supply line 20 is received. After demodulating the signal of the control unit according to the temperature control and receiving unit 30 is configured.

In the above, the temperature sensing and transmitting unit 11 receives the AC power from the power supply line 20 of the commercial AC power supply AC / DC power conversion unit 11 for supplying the DC power required for the operation of the device below, and the user Temperature setting means for designating the desired temperature and temperature sensing means for detecting the actual temperature of the heating place, and a plurality of temperature setting for outputting a control signal to turn the heater on and off by comparing the difference between the set temperature and the actual temperature And a transmission control unit 13 for controlling transmission at a random interval when the control unit 12 outputs a control signal from the temperature setting and detection unit 12, and controls the transmission control unit 13. Therefore, a spread spectrum modulator 14 for modulating a control signal output from the temperature setting and sensing unit 12 into a PN code by spread spectrum modulation, and a transmission signal modulated by the spread spectrum modulator 14 I put on It consists of a high frequency transmitter 15 for output to line 20. The

In addition, the temperature control and reception unit 30 converts the AC power supplied through the power line 20 into DC power to supply the power required for the operation of each device below, and the AC / DC power conversion unit 31; A high frequency receiver 32 for receiving a high frequency signal transmitted through the power line 20 and a spread spectrum demodulator for reproducing the original control signal by demodulating the signal received by the high frequency receiver 32 into a spread spectrum code. And a remote temperature data processor 34 for processing the control signal reproduced by the spread spectrum demodulator 33 to determine an error signal and to obtain a continuous temperature control signal from control signals received at irregular intervals. The multi-temperature controller 35 applies a direct control signal to the actual heater according to the temperature control signal output from the remote temperature data processor 34.

In the above configuration, the temperature sensing and transmitting section 12 is a side for transmitting a control signal, and is installed at a position that can be easily operated and easily seen in each room that is controlled by a heater to which the apparatus is applied. When the user sets the desired temperature, the temperature setting and detecting unit 12 compares the temperature set by the user with the sensed room temperature and outputs a control signal for operating the heater when the room temperature is lower than the set temperature. .

Under the control of the transmission control section 13, this control signal is converted into a PN code by the spread spectrum modulator 14, and is then carried on the high frequency signal by the high frequency transmitter 15 to the AC power supply line 20. The PN code converted by the spread spectrum modulator 14 is set differently for each transmitter and detector 10 so that the receiver can recognize the PN code. For example, when more than ten generations of power lines, such as an apartment, are connected, the setting of the PN code is different for each sensing and transmitting unit 10 for each generation. In this connection, when the PN code to be received by the control and reception unit 30 is registered, and the code received by the high frequency reception unit 32 and demodulated by the spread spectrum demodulation unit 33 is registered, The control signal is applied to the remote temperature data processor 34.

Such a signal is received via the AC power supply line 20 to the actual driving device, for example, a control device installed in a boiler, that is, the high frequency receiving part 32 of the temperature control and receiving part 30 in FIG. The control unit 33 demodulates the original control signal and processes the demodulated data in the remote temperature data processing unit 34 to generate an appropriate control signal. The multi-temperature controller 35 is an actual driving device, for example, a boiler. Temperature control is performed by turning on / off the hot water valve of the hot water distributor to distribute hot water to each room.

In this way, the remote control device according to the present invention, while the temperature detection and transmission unit 10 transmits a control signal, the temperature control and reception unit 30 receives this and executes a control operation. Since the transmission efficiency becomes worse and no other signal can be received in the meantime, the transmission control unit 10 transmits the control signal for operating the heater at predetermined intervals as shown in FIG. In addition, the remote data processing unit 34 of the temperature control and reception side 30 connects the signals received within a predetermined time after the first transmission signal S1 is received, as shown in FIG. To form a continuous control signal. Therefore, in the timing diagram shown in FIG. 2C, the high level section is a section for receiving a control signal to turn on the heater or hot water valve of the boiler, and the low level section is a section for turning off the boiler or hot water valve of the boiler. to be.

At this time, the transmission control unit 13 of the transmitting side may randomize the transmission interval of the signal, as shown in FIG. 2D. In this case, the remote data processing unit 34 of the receiving side of FIG. The received signal is processed by the same control flow as the flow chart of FIG. Here, the presence of the received signal is regarded as a control command to turn on the heater.

That is, if there is a received signal (s301), the heater is turned on (s302), and then it is checked whether the current counter value is 0 (s303). At this time, if the counter is 0, the current received signal is the first signal of the continuous control signal, and if the counter is not 0, it is the control signal following the previously received signal.

Therefore, if the counter value is not 0, since it is the first received signal, the counter value is set to a preset value x, and the counter value is decremented by one after a predetermined time delay (s305). Each time the signal is decremented, it is checked whether there is a next received signal. If there is a received signal, the heater is continuously turned on (s307). If there is no received signal, it is checked whether the counter value is "0" (s308). The operation of checking the received signal is repeated while decreasing by "1" until "0" (s305 to s308).

Thus, if there is a reception signal until the counter value becomes "0", the heater continues to be turned on, and if there is no reception signal until the counter value becomes "0", the heater is turned off (s309).

The control operation of the temperature control and receiver unit 30 as described above is repeatedly executed.

Therefore, even when the transmission signals are transmitted at random intervals, the temperature control and reception unit 30 can perform the control operation without any problem.

At this time, the transmission control unit 13 of the temperature sensing and transmitting unit 10 generates random random numbers as shown in FIG. 4 (s401), loads them into a counter (s402), and then counters When the value of " 1 " decreases by " 1 " to " 0 " The spread spectrum modulator 14 is controlled so that the signal is not transmitted if the control signal is off-level (s405).

Up to now, the case where the temperature sensing and transmitting unit 10 has been described as an example, since a common house is divided into a number of spaces, it is to install the temperature sensing and transmitting unit 10 for each divided space respectively It is convenient.

Therefore, when there are two or more temperature sensing and transmitting units 10, as illustrated by way of example in Figs. 5A to 5D, each of the temperature sensing and transmitting units operates to transmit signals at random intervals. . In this case, since the control signal output from each temperature sensing and transmitting unit 10 is set arbitrarily as shown in Fig. 4, there is almost no possibility of overlapping.

Further, the control signals output from the respective temperature sensing and transmitting units 10 have unique PN code values representing the corresponding temperature sensing and transmitting units 10 by band spread modulation. Therefore, the temperature control and reception unit 30 processes each control signal as shown in FIG. 3 in the order of reception, as shown in FIGS. 5E and 5F, to generate a continuous control signal. In this case, there may be a slight delay between the signal output of the temperature sensing and transmitting unit 10 and the control operation of the temperature controlling and receiving unit 30, but there is a big problem when the control speed may be slow, such as the temperature control of the heater. It doesn't work.

The external appearance of the sensing and transmitting unit 10 operating as described above is inserted into a power outlet installed on a wall and connected to an output terminal of the high frequency transmitting unit 15 and an input terminal of the AC / DC power conversion unit 11. Has a plug (not shown), and is integrally connected to the plug and made of a separate case (not shown) made in consideration of aesthetics and practicality to protect the circuit elements, simply detecting and transmitting unit 10 Insert the power cord into the wall outlet to complete the installation.

Therefore, when replacing the boiler or installing the heating device in the building being built, the labor can be significantly reduced.

As described above, the control signal is transmitted and received by using the spread spectrum modulation method through the AC power line, which is already provided, so that a remote control through the power line is possible without a noise problem, thereby providing a separate control line. There is an excellent effect to enable a simple remote control without the need to do, and there is an excellent effect to add a remote control function to a specific device at a lower cost.

Claims (4)

When the user sets the control reference value, a plurality of setting and sensing units outputting control signals by comparing them with actual values, and a transmission for controlling the continuous control signals outputted from the setting and sensing units to be transmitted at random intervals. A spread spectrum modulator for modulating a control signal output from the setting and sensing unit according to control of the control unit, the transmission control unit into a PN code set by spread spectrum modulation, and a transmission signal modulated by the spread spectrum modulation unit A sensing and transmitting unit comprising: a high frequency transmitting unit configured to output to a power line; A high frequency receiver for receiving a high frequency signal transmitted through the power line, a band spread demodulator for demodulating the signal received by the high frequency receiver with a spread spectrum code and outputting a control signal according to whether or not it is a registered code; A control and reception unit comprising a remote data processing unit for processing a control signal reproduced by a spread demodulation unit to determine an error signal and generating a continuous control signal from control signals received at irregular intervals; Remote control device by The method of claim 1, wherein the transmission control unit When a random number is generated and loaded into a counter, the value of the counter is decremented by "1", and becomes "0". When the control signal output from the setting and sensing unit is on level, the spread spectrum modulation unit And a band spread modulator to control a modulation operation so that a signal is transmitted, and if the control signal is an off level, the spread spectrum modulator is controlled so that the signal is not transmitted. The method of claim 1, wherein the remote data processing unit If there is a received signal, operate the remote control object, check whether the current counter value is 0 or not, and if the counter value is not 0, set the counter value to a preset value x, and then counter after a predetermined time delay. Decreases the value by 1 and checks if there is a next received signal. If there is a received signal, the remote control target continues to operate. If there is no received signal until the counter value is "0", the remote control target stops operating. Remote control device by power line communication, characterized in that. According to any one of claims 1 to 3, wherein the setting and sensing unit sets the temperature, the user senses the room temperature and compares it with the set temperature and outputs a temperature control signal, The control and reception unit further comprises a multiple temperature controller for turning on / off the hot water valve of the actual boiler according to the continuous temperature control signal output from the remote data processing unit.