Abstract:
An air conditioner and a power line communication system high in reliability and free of malfunction facilitates the installation work such as the wiring. The air conditioner for conducting communication through a power line includes a bridge unit connected to at least an outdoor unit through a transmission line, and at least an indoor unit connected from the power line through a blocking filter. A side of the bridge unit far from the outdoor unit is connected between the blocking filter and the indoor unit. The bridge unit subjects a signal from the outdoor unit to spread spectrum modulation and transmits it by superposing the resulting signal on the power line. The superposed signal is received and demodulated by the indoor unit.

Description:
BACKGROUND OF THE INVENTION  
       [0001]     This invention relates to an air conditioner for conducting data communication mainly with a power line as a communication medium, or in particular to an air conditioner suitably used for controlling the air condition over a plurality of divided areas in a building or the like while at the same time conducting the centralized control and management of equipment and devices.  
         [0002]     A conventional air conditioner is known which conducts communication through a power line between an indoor unit and an outdoor unit to reduce the number of wirings. In the centralized control and management of the housing equipment and devices, the power line carrier communication is conducted, and to prevent signal leakage and interference, the impedance is balanced and a high-pass filter arranged between two power lines in a power line communication area (see JP-A-7-245576).  
         [0003]     In the conventional air conditioner comprising an outdoor unit and a multiplicity of indoor units, the indoor units are installed in a plurality of areas into which a building or the like is divided in accordance with the layout of rooms. The indoor units exchange the operating information (start/stop, operation mode, set temperature, set air flow rate, the temperature and pressure of the essential parts of the refrigeration cycle) with each other as control information and a comparatively large amount of power is consumed. Therefore, it is difficult to reduce the leakage signal which deteriorates the effective transmission rate. In the case where the open signal of the expansion valve transmitted from the outdoor unit to the indoor units is delayed, for example, the refrigeration cycle may not be normally controlled.  
       BRIEF SUMMARY OF THE INVENTION  
       [0004]     An object of this invention is to solve the above-mentioned problem and provide an air conditioner and a power line communication system reliable and free of malfunction, in which the wiring work is easily conducted in any scale of the system.  
         [0005]     Another object of the invention is to provide a power line communication system for conducting a reliable power line communication easily without any special device.  
         [0006]     Still another object of this invention is to improve the workability and facilitate the renewal without adversely affecting the system design freedom.  
         [0007]     In order to achieve the above-mentioned objects, according to one aspect of this invention, there is provided an air conditioner for conducting communication between at least an outdoor unit and at least an indoor unit through a power line, comprising a bridge unit connected to the outdoor unit through a transmission line and the indoor unit connected through a blocking filter from the power line, wherein the side of the bridge unit far from the outdoor unit is connected between the blocking filter and the indoor unit, and wherein the bridge unit transmits the signal from the outdoor unit in supervision on the power line by spread spectrum modulation, and the superposed signal is received and demodulated by the indoor unit.  
         [0008]     In the air conditioner described above, a noise generator for applying a noise is preferably inserted between the blocking filter and the indoor unit.  
         [0009]     Further, in the air conditioner described above, a plurality of indoor units are divided into groups, each preferably including a bridge unit and a blocking filter.  
         [0010]     Furthermore, in the air conditioner described above, a plurality of indoor units are divided into groups, each including a bridge unit and a blocking filter. At the same time, a noise larger than the leakage signal between the group areas is preferably applied between the blocking filter and the indoor units.  
         [0011]     In addition, in the air conditioner described above, a plurality of indoor units are divided into groups, each including a bridge unit and a blocking filter. At the same time, a white noise is preferably applied between the blocking filter and the indoor units.  
         [0012]     Furthermore, in the system described above, a plurality of indoor units are divided into groups, and the bridge unit and the blocking filter are provided for each group area. At the same time, a noise generator for applying a white noise in a plurality of stages of magnitude is preferably inserted between the blocking filter and the indoor unit.  
         [0013]     What is more, in the system described above, a noise generator for applying a noise is preferably inserted between the blocking filter and the indoor unit. The noise generator has the function of measuring the floor noise of the power line and the function of determining the noise applied as related to the measurement.  
         [0014]     According to another aspect of the invention, there is provided a power line communication system comprising an air conditioner for conducting communication through a power line between an outdoor unit and an indoor unit, an illumination unit and a ventilator, the power line communication area being divided into groups, each group including a blocking filter arranged midway of the power line in such a manner that the secondary side constitutes the communication area, a bridge unit connected to the secondary side of the communication area from the outdoor unit through a transmission line, and a noise generator for applying a noise larger than the leakage signal between the communication areas to the secondary side of the communication area, wherein the bridge unit modulates by spread spectrum the signal from the outdoor unit and transmits the resulting signal in superposed form to the secondary side of the communication area, the superposed signal being received and demodulated by the indoor unit, the illumination unit or the ventilator.  
         [0015]     In addition, in the system described above, the noise generator has the function of measuring the floor noise of the power line and determining the magnitude of the noise applied as related to the measured value.  
         [0016]     According to still another aspect of the invention, there is provided a power line communication system for conducting communication between a transmitting unit and a receiving unit through a power line, the power line communication area being divided into groups, each including a blocking filter arranged midway of the power line in such a manner that the communication area is on the secondary side, a bridge unit connected to the secondary side of the communication area from the transmitting unit through a transmission line, and a noise generator for applying a noise larger than the leakage signal between the communication areas to the secondary side of the communication area, and wherein the bridge unit modulates by spread spectrum the signal from the transmitting unit and transmits the signal in superposed form to the secondary side of the communication area, the superposed signal being received and demodulated by the receiving unit.  
         [0017]     According to this invention, a reliable air conditioner free of malfunction is obtained, in which the wiring and the like installation work can be conducted easily regardless of the size of the system. Especially, a reliable power line communication system is easily implemented with an improved workability and renewal performance without adversely affecting the system design freedom including the centralized control and management of the equipment as well as the air-conditioning operation.  
         [0018]     Other objects, features and advantages of the invention will become apparent from the following description of the embodiments of the invention taken in conjunction with the accompanying drawings. 
     
    
     BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING  
       [0019]      FIG. 1  is a block diagram showing an air-conditioner according to an embodiment of the invention.  
         [0020]      FIG. 2  is a graph showing the relation between the level and frequency of the signal superposed on the power line according to an embodiment of the invention.  
         [0021]      FIG. 3  shows the relation between the level and frequency of the signal superposed on the power line.  
         [0022]      FIG. 4  shows the relation between the level and frequency of the signal superposed on the power line.  
         [0023]      FIG. 5  is a block diagram showing a noise generator according to an embodiment of the invention.  
         [0024]      FIG. 6  is a block diagram showing a noise generator according to another embodiment of the invention.  
         [0025]      FIG. 7  is a block diagram showing a noise generator according to still another embodiment of the invention.  
         [0026]      FIG. 8  is a block diagram showing an air-conditioning system according to another embodiment of the invention. 
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0027]     In the air-conditioning system, the indoor units  1  are arranged in a plurality of areas defined in accordance with the room layout, and each defined area includes a bridge unit  4 , through which communication is conducted with the outdoor units  7  through a power line. The bridge unit  4  and the indoor units  1  include power line communication modems  2  and  19  using the spread spectrum communication.  
         [0028]     The bridge units  4  are arranged in each of the divided areas. Even under different control conditions for different rooms, therefore, the total communication throughput can be improved by separating the transmission path. In the spread spectrum communication system, a minuscule spectrum is spread over a wide frequency band. The divided areas are mutually liable to be affected by the leakage signals. Also, in the transmission path access method of CSMA/CD or CSMA/CA, the transmission from other communications units is detected by the carrier signal. In the conventional communication devices such as the baseband modem or the modem used for the telephone line, the carrier is detected by determining the relative strength of the input signal and a reference spread signal. In the communication unit using the spread spectrum method, however, the carrier signal is detected by determining the relative strength of the input signal and a reference spread signal. Therefore, the method of carrier detection as described in JP-A-7-245576 is not sufficient. Embodiments of this invention are described in detail below.  
       Embodiment 1  
       [0029]      FIG. 1  shows an air conditioner comprising a plurality of indoor units  1 , a plurality of outdoor units  7 , and a refrigeration cycle (not shown) for recirculating the refrigerant between the indoor units  1  and the outdoor units  7 . The outdoor units  7  each include an outdoor controller  15  for controlling the devices such as a compressor or a fan for blowing the air to an outdoor heat exchanger to drive the outdoor units  7 . The outdoor controller  15  is supplied with the operation data such as the temperature of the outdoor heat exchanger, the refrigerant pressure, the atmospheric temperature and the rotational speed of the compressor. Based on these data of the outdoor units  7  and the data transmitted from the indoor controllers  3  of the indoor units  1 , the outdoor units  7 , i.e. the refrigeration cycle is controlled.  
         [0030]     Each indoor unit  1  includes an indoor controller  3  for controlling the devices such as a fan for blowing the air to the indoor heat exchanger to control the indoor unit  1 . Each indoor controller  3  controls the corresponding indoor unit  1  based on the data such as the temperature of the indoor heat exchanger and the set temperature input from a remote controller to the indoor unit  1  and the data transmitted from the outdoor controller  15 .  
         [0031]     Specifically, the indoor units and the outdoor units exchange the operation information (intake pressure, discharge pressure, compressor temperature, outdoor unit expansion valve opening, indoor unit expansion valve opening, compressor current, compressor frequency, atmospheric temperature, evaporation temperature, suction temperature, blowout temperature, gas pipe temperature, liquid pipe temperature and set temperature) with each other. In other words, data communication is conducted between the outdoor controller  15  and the indoor controller  3  thereby to control the various devices.  
         [0032]     In signal transmission from the outdoor controller  15 , the communication data outputted from the microcomputer in the outdoor controller  15  is converted into a signal pulse by the communication circuit  16  of the outdoor controller  15 , and inputted to the bridge unit  4  through a transmission line  17 . The bridge unit  4  includes the communication circuit  18 , which converts the signal pulse to the communication data. In the power line communication unit  2  in the bridge unit  4 , the spread spectrum modulation is conducted. Specifically, the signal data is multiplied by a pseudo-random number sequence having a certain bandwidth by the direct spread system, so that the frequency band of the data string is widened and modulated, and then transmitted in superposition on the power line  10  for the indoor units  1 .  
         [0033]     The power line communication unit  19  in the adaptor  21  of each indoor unit  1  receives the spread spectrum modulation signal superposed on the power line, and by demodulation, converts it to the communication data. This communication data is converted into a signal pulse and inputted to the indoor controller  3 . The communication circuit  22  in the indoor controller  3  converts the signal pulse into the communication data, which is received by the microcomputer in the indoor controller  3 .  
         [0034]     In signal transmission from each indoor controller  3 , on the other hand, the communication data outputted from the microcomputer of the indoor controller  3  is converted into a signal pulse by the communication circuit  22  and inputted to the adaptor  21 . The communication circuit  20  converts the pulse signal to the communication data, which is subjected to the spread spectrum modulation by the power line communication unit  19  and superposed on the indoor unit power line  10 . The spread spectrum modulation signal superposed on the power line  10  is received and demodulated by the power line-communication unit  2  into the communication data. The communication data thus converted is converted into a pulse signal by the communication circuit  18 , and inputted to the outdoor controller  15  through the transmission line  17 . Next, the signal pulse is converted into the communication data by the communication circuit  16 , and received by the microcomputer in the outdoor controller  15 .  
         [0035]     A blocking filter  5  is arranged midway of the power line  10  connected to the indoor units  1 . The blocking filter  5  functions to attenuate the primary noise on the one hand and prevents the spread spectrum modulation signal superposed on the power line from leaking to the primary side. As a result, the secondary side of the blocking filter  5  is used exclusively for the power line communication for an improved operating convenience.  
         [0036]     Next, the signal superposed on the secondary power line  10  of the blocking filter  5  is described with reference to  FIG. 2 .  
         [0037]     The transmission output of the power line communication units  2 ,  19  is designated by S 1  in  FIG. 2 . At the receiving end, on the other hand, the signal level is reduced to S 2  due to the attenuation of the power line  10  and the deterioration caused by signal reflection. Also, assume that the floor noise generated by the power line  10  is FN and the lower receivable level limit S 3  of the power line communication units  2 ,  19  is given as FN-dS.  
         [0038]     Further, assume that the spread spectrum modulation signal transmitted over the power line  10  from other power line communication areas is S 42 , the spread spectrum modulation signal leaked by the magnetic coupling or the capacitive coupling between the power lines  10  in the power line communication areas  13 ,  14  is S 41 , and the total thereof S 4 . As long as S 3  is larger than S 4 , the signals of other power line communication areas are not received.  
         [0039]     In the case where the relation between the lower receivable level limit S 3  of the power line communication units  2 ,  19  and the leakage signal S 4  is S 3 &lt;D 4  as shown in  FIG. 3 , on the other hand, the signals are received undesirably from other power line communication areas. To obviate this problem, as shown in  FIG. 4 , a noise MN higher than the leakage signal S 4  by at least dS is applied to the power line  10 . Then, the leakage signal S 4  from the other power line communication areas is not received. Also, by reducing the noise MN to a value lower than the receiving end signal level S 2 , no effect is had on the normal communication in the power line communication areas.  
         [0040]     Next, the noise generator  6  for applying a noise to the power line  10  described above is described in detail.  
         [0041]     In  FIG. 5 , a Zener diode which is inexpensive and easy to acquire is used as a noise source  6 . The Zener diode is known to generate a white noise before entering the Zener operation with a small forward current. The small white level noise is amplified by an amplifier  32 . Also, in view of the fact that the spread spectrum frequency is set to 100 to 400 kHz as shown in  FIG. 2 , a LPF  33  for cutting off the components of higher than 400 kHz is attached to reduce the unrequited spurious signals.  
         [0042]     Further, the magnitude of the white noise generated by the Zener diode  33  constituting a noise source undergoes so great a change that an output stabilization circuit  34  is added. The signal with the spurious component thereof reduced by the LPF  33  is further amplified by the output amplifier circuit  35 , and connected to the indoor unit power line  10  by an insulating transformer  36 . Also, a capacitor  37  is added between the power line  10  and the insulating transformer  36  to superpose only the high-frequency component on the power line  10 .  
         [0043]     Each indoor unit  1  or the bridge unit  4  has the function to suspend the transmission. As a result, the communication amount of the power line  10  for power line communication can be reduced. Even in the case where a multiplicity of indoor units  1  are connected, therefore, the minimum communication required for controlling the air conditioner can be conducted in stable fashion.  
       Embodiment 2  
       [0044]     A case is described in which the magnitude of the noise generated by the noise generator  6  shown in  FIG. 5  can be changed.  
         [0045]     In  FIG. 6 , a group of 4-bit switches  38 , for example, are manually adapted to be set so that the amplitude degree of the output amplifier circuit  35  can be changed in any of 16 ways. As a result, after installing and wiring the air conditioner and the actually transmitting the signal between the indoor units  1  and the outdoor units  7 , the magnitude of the noise applied to the power line  10  can be determined. Thus, the signal can be accurately transmitted for a higher reliability.  
       Embodiment 3  
       [0046]     Next, a case is described in which the magnitude of the noise applied to the power line  10  can be automatically changed.  
         [0047]     In  FIG. 7 , a noise measuring circuit  39  measures the magnitude of the noise of the power line  10  before generation of the noise from the noise generator  6 . In accordance with the magnitude of the noise, a noise amount determining circuit determines the magnitude of the noise and in accordance with the magnitude of the noise thus determined, changes the amplitude degree of an output amplifier circuit  35 .  
         [0048]     Specifically, before applying a noise, the floor noise of the power line  10  is passed through an insulating transformer  36  and a bandpass filter, so that only the signal in the spread spectrum frequency band is extracted and measured. The floor noise is small in level and therefore amplified by an amplifier circuit. Also, the floor noise, which is an AC signal, is converted into a DC voltage by an AC-DC converter circuit and inputted to an A/D converter circuit of the microcomputer. The microcomputer performs the arithmetic operation to output a noise 1.2 times as large as the floor noise thereby to determine the amplitude degree of the output amplifier circuit  35 .  
         [0049]     As a result, the magnitude of the noise applied to the power line is optimally determined in accordance with the actual wiring conditions of the air conditioner and the conditions of the air conditioner. Thus, the signal can be accurately transmitted between the indoor units  1  and the outdoor units  7  for an improved reliability of the refrigeration cycle.  
       Embodiment 4  
       [0050]     An example in which such equipment as the illumination unit and the ventilator as well as the air conditioner can be controlled by power line communication is described with reference to  FIG. 8 .  
         [0051]     In  FIG. 8 , the illumination controller  50  is connected to the power line  10  through the power line communication unit  19  and the communication unit  52  thereby to communicate with the indoor unit controller  3 . As a result, the interlocked control operation is made possible between each indoor unit  1  and the illumination unit  51  controlled by the illumination controller  50 . Also, the ventilation controller  52  is connected to the power line  10  through the power line communication unit  19  and the communication unit  54  to communicate with the indoor unit controller  3 . As a result, the interlocked control operation is made possible between each indoor unit  1  and the ventilator  53  controlled by the ventilation controller  52 . A similar interlocked control operation is made possible also for other equipment than the illumination unit and the ventilator by power line communication.  
         [0052]     As described above, in order to minimize the receipt of the spread spectrum modulation signal S 42  leaking from the other power line communication areas  13 , a noise larger than the signal leaking into a power line communication area  13  and smaller than the signal in the particular power line communication area  13  is applied. Therefore, the leaking spread spectrum modulation signal S 42  is not received by the indoor unit  6  or the bridge  4 , and the normal signal communication is made possible.  
         [0053]     As an alternative, the noise of the power line  10  is measured, and the threshold for determining the output of the correlator in the communication unit is adjusted in accordance with the magnitude of the noise. In this way, the leakage signal from other power line communication areas is prevented from being received without applying a noise to the power line.  
         [0054]     In the case where the communication data mounted on the power line exceeds a predetermined level, on the other hand, the increase is considered due to the spread spectrum modulation signal S 42  from other areas  13 , and the noise output of the noise generator  6  is increased to the upper limit.  
         [0055]     Further, as long as only the leaking spread spectrum modulation signal S 42  is electrically masked, the indoor unit  6  and the bridge  4  can perform normal signal communication and the malfunction can be eliminated.  
         [0056]     Furthermore, the magnitude of the noise applied to the power line  10  is changed manually in arbitrary fashion in accordance with the magnitude of the spread spectrum modulation signal S 42  leaking from the other areas  13  where the air conditioner is installed. In this way, the level of the noise applied to the power line  10  required for electrical masking can be reduced to the required minimum. Thus, the unrequited radiation (spurious signal) of the applied noise can be suppressed.  
         [0057]     Further, by measuring the power line noise and determining the magnitude of the noise applied in accordance with the power line noise, the level of the noise applied to the power line  10  for electrically masking the magnitude of the spread spectrum modulation signal S 42  leaking from the other areas  13  where the air conditioner is installed can be automatically reduced to the required minimum. Thus, the system can be maintained effectively even when the power line noise undergoes a change during the communication at the place of installation.  
         [0058]     Furthermore, by measuring the noise of the power line  10  and adjusting the threshold for determining the output of the correlator in the communication unit in accordance with the magnitude of the noise, the magnitude of the noise applied to the power line  10  can be determined by the threshold. Thus, the receipt of the spread spectrum modulation signal S 42  leaking from the other power line communication areas  13  is prevented without applying the noise to the power line  10 .  
         [0059]     In addition, since the communication amount of the air conditioner is statistically substantially constant, the noise due to the spread spectrum modulation signal S 42  from other areas  13  is determined -without any special noise measuring unit. By thus increasing the noise output of the noise generator  6  up to the requirement upper limit, stable communication can be effected.  
         [0060]     It should be further understood by those skilled in the art that although the foregoing description has been made on embodiments of the invention, the invention is not limited thereto and various changes and modifications may be made without departing from the spirit of the invention and the scope of the appended claims.