JP6223060B2 - Heat source machine system - Google Patents

Description

  The present invention relates to a heat source apparatus system that communicates communication signals with a plurality of terminal devices via a wired communication path.

  Conventionally, as a heat source machine system comprising a control unit that performs operation control of a water heater body as a heat source machine, and a remote controller as a plurality of terminal devices that communicate communication signals via a wired communication path shared with the control unit. A hot water supply apparatus is known (Patent Document 1). In this heat source machine system, the control unit of the heat source machine detects whether there is an abnormality in communication with each terminal device based on information obtained by communication with each terminal device. . When there is a terminal device that is detected as having an abnormality in communication, the control unit stops communication with the terminal device in which the abnormality has occurred.

JP 2000-249395 A

  In a heat source system as described in Patent Document 1, a communication signal that does not contain valid information may be continuously output from a terminal device due to a failure of a communication circuit of any terminal device.

  In this case, since the communication signal received on the control unit side of the heat source unit is maintained as an abnormal communication signal that does not include valid information, the control unit recognizes which terminal device is abnormal. There are many cases where this is not possible. Further, in this case, since the heat source device cannot block communication with the terminal device that outputs an abnormal communication signal, it cannot communicate with other normal terminal devices.

  The present invention provides a heat source apparatus system capable of normally communicating between a control unit of a heat source apparatus and a terminal apparatus in which no abnormality occurs when an abnormality occurs in a communication signal output from a communication circuit of any terminal apparatus. The purpose is to provide.

The present invention includes a control unit that performs operation control of a heat source unit, and a plurality of terminal devices that communicate communication signals via a wired communication path shared with the control unit, and each of the plurality of terminal devices includes A communication circuit connected to a wired communication path; an abnormality detection unit that detects a communication abnormality in which a communication signal output from the communication circuit to the wired communication path becomes abnormal; and between the communication circuit and the wired communication path A switch circuit capable of selectively switching between an ON state for conducting the signal line to the wired communication path and an OFF state for interrupting the conduction, and when the abnormality detection unit detects the communication abnormality, The output of the communication signal from the communication circuit to the wired communication path is cut off by controlling the switch circuit between the communication circuit that outputs the communication signal in which a communication abnormality is detected and the wired communication path to be in an OFF state. You Characterized in that it comprises a blocking portion.

According to the present invention, each terminal device includes an abnormality detection unit and a blocking unit. For this reason, when a communication error (such as a communication signal that does not contain valid information is continuously output from the terminal device) due to a failure in the communication circuit of any terminal device, the communication error is Then, an abnormality detection unit of a terminal device (hereinafter referred to as “abnormal terminal device”) having a communication circuit that outputs an abnormal communication signal detects. And the interruption | blocking part of an abnormal terminal device controls the said switch circuit between the communication circuit of the said abnormal terminal device, and the said wired communication path | route to an OFF state, and is abnormal from this communication circuit to the said wired communication path | route. Shut off the communication signal output.

  This prevents an abnormal communication signal from being continuously output from the communication circuit of the abnormal terminal device to the wired communication path. For this reason, it can communicate normally between the control part of a heat source machine, and the terminal device in which abnormality has not arisen.

  In the present invention, the abnormality detection unit determines whether a predetermined parameter of a communication signal generated by the communication circuit included in a terminal device including the abnormality detection unit satisfies a reference condition, and determines a predetermined value of the communication signal. It is preferable to detect that the communication abnormality has occurred in the communication circuit included in the terminal device including the abnormality detection unit when it is determined that the parameter does not satisfy the reference condition.

  When a communication abnormality has occurred, a predetermined parameter of the communication signal output from the communication circuit to the wired communication path does not satisfy the reference condition that should be satisfied when normal. Therefore, with the configuration of the abnormality detection unit, the abnormality detection unit of the abnormal terminal device can detect a communication abnormality.

  In the present invention, the predetermined parameter may include a frequency of the communication signal. According to this configuration, when a communication abnormality occurs such that the frequency of the communication signal does not satisfy the reference condition, the communication abnormality can be detected.

  In the present invention, the predetermined parameter may include a voltage value of the communication signal. According to this configuration, when a communication abnormality occurs such that the voltage value of the communication signal does not satisfy the reference condition, the communication abnormality can be detected.

The block diagram of the heat-source equipment system of embodiment of this invention.

  A heat source machine system according to an embodiment of the present invention will be described with reference to FIG. In the present embodiment, the heat source system is the hot water supply system 1. The heat source system may be a heat source system other than the hot water supply system 1.

  As shown in FIG. 1, the hot water supply system 1 includes a heat source device 2 as a hot water heater body, a plurality of terminal devices 11 and 12, and a wired communication path 3.

  In addition, the option terminal 13 shown with the dashed-two dotted line in FIG. 1 is a structure with which the heat-source equipment system of the modification mentioned later is provided instead of the structure of this embodiment. Therefore, the option terminal 13 will be described later.

  Each device 2, 11, 12 (specifically, each of the heat source device control unit 22 provided in the heat source device 2 and the communication circuit 6 provided in each terminal device 11, 12) is connected to the common wired communication path 3. Yes. The devices 2, 11, and 12 communicate with each other via the wired communication path 3.

  The wired communication path 3 is composed of a pair of communication lines 31 and 32 arranged so as to pass through the arrangement locations of the devices 2, 11 and 12. The communication lines 31 and 32 may be shielded.

  The devices 2, 11, and 12 are configured to output communication signals at different timings.

  In the present embodiment, the communication signal is a signal including an information signal by frequency modulation, for example. The communication signal is not limited to frequency modulation, and may be a signal obtained by other modulation methods such as amplitude modulation and pulse width modulation.

  In the present embodiment, the communication lines 31 and 32 of the wired communication path 3 are also used as power supply lines for supplying power (DC power) from the heat source device 2 to the terminal devices 11 and 12. For this reason, the communication signal is output to the wired communication path 3 from each device 2, 11, 12 in a form superimposed on the power supply power.

  The heat source device 2 includes a heating source 21 that heats hot water and a heat source device control unit 22 (corresponding to the “control unit” of the present invention) that controls the operation of the hot water supply system 1 including the heating source 21. Although the detailed illustration is omitted, for example, the heating source 21 is configured to heat hot water with a burner and a heat exchanger, and supplies the heated hot water from the heat exchanger to a hot water supply port via a pipe.

  The heat source controller 22 is configured by an electronic control unit having a CPU, a memory, and the like (not shown), and is connected to the wired communication path 3. The heat source control unit 22 controls the amount of hot water heated by the heating source 21 (burner combustion amount) using information (for example, a target hot water supply temperature) acquired through communication with the terminal devices 11 and 12. Thereby, the heat source machine control part 22 controls the temperature of the hot water supplied from the heating source 21 to the hot water supply port.

  The heat source unit control unit 22 includes a power supply circuit (not shown) that generates power supply power to be supplied to the terminal devices 11 and 12 from a commercial power supply, and outputs power supply power from the power supply circuit to the wired communication path 3. To do.

  In the present embodiment, the plurality of terminal devices 11 and 12 are a first remote controller 11 (for example, a so-called kitchen installed in the kitchen) for operating the heat source unit 2 (for example, a target hot water supply temperature setting operation). A remote controller) and a second remote controller 12 (for example, a so-called bathroom remote controller installed in a bathroom). Note that the number of terminal devices may be three or more.

  In FIG. 1, the detailed configuration of only the first remote controller 11 is shown, and other terminal devices are omitted, but each terminal device has the same configuration as the first remote controller 11 described below. It has. Hereinafter, the first remote controller 11 will be described on behalf of the terminal devices 11 and 12.

  The first remote controller 11 includes a power supply circuit 4, a switch circuit 5, a communication circuit 6, a communication monitoring circuit 7, and a terminal device control unit 8.

  The power supply circuit 4 is a circuit that acquires power supply power from the wired communication path 3 and supplies the power supply power to each circuit (communication circuit 6 or the like) of the first remote controller 11. The power supply circuit 4 is connected to the wired communication path 3 via power supply lines 31A and 32A that are electrically connected to the communication lines 31 and 32 of the wired communication path 3, respectively. The power supply circuit 4 generates power supply power to be supplied to each circuit (communication circuit 6 or the like) of the first remote controller 11 from the power supply power input from the wired communication path 3 via a voltage smoothing circuit or a regulator.

  The communication circuit 6 is a circuit for transmitting and receiving communication signals. The communication circuit 6 includes signal lines 31a and 32a connected to the power supply lines 31A and 32A via the switch circuit 5, respectively.

  The switch circuit 5 is configured to be selectively controllable between an on state in which the signal lines 31a and 32a are electrically connected to the power supply lines 31A and 32A and an off state in which the conduction is interrupted.

  Therefore, the communication circuit 6 can output a communication signal to be transmitted to the wired communication path 3 or receive a communication signal from the wired communication path 3 while the switch circuit 5 is on. In addition, when the switch circuit 5 is in the off state, the communication circuit 6 cannot output a communication signal to the wired communication path 3 or receive a communication signal from the wired communication path 3.

  The communication circuit 6 includes a communication IC 61, low-pass filters 62 and 67, an amplifier circuit 63, a transformer 64, a capacitor 65, and a band-pass filter 66.

  The communication IC 61 frequency-modulates the information signal input from the terminal device control unit 8 to generate a communication signal. Then, the communication IC 61 outputs the generated communication signal from the transmission port.

  A low pass filter 62 is connected to the transmission port of the communication IC 61. An amplifier circuit 63 (amplifier circuit having a transistor in the illustrated example) that amplifies the signal output from the low-pass filter 62 is connected to the low-pass filter 62.

  One end of a primary coil 64 a of the transformer 64 is connected to the output of the amplifier circuit 63. A constant bias voltage Vb is applied to an intermediate portion of the primary coil 64a. The other end of the primary coil 64 a is connected to the reception port of the communication IC 61 through a low pass filter 67.

  A signal line 31a is connected to the secondary coil 64b of the transformer 64 through a capacitor 65, and a signal line is connected through a bandpass filter 66 (a circuit in which a coil and a capacitor are connected in series in the illustrated example). 32a is connected. Here, the capacitor 65 is a capacitor for removing a DC component. The band pass filter 66 is a filter that removes a direct current component and passes only a frequency band used as a communication signal.

  Thus, in the communication circuit 6, a circuit (primary coil 64 a, communication IC 61, low-pass filters 62 and 67, amplifier circuit 63, etc. on the primary coil 64 a side of the transformer 64. And a circuit on the secondary coil 64b side of the transformer 64 (a circuit constituted by the secondary coil 64b, the capacitor 65, the band-pass filter 66, etc., hereinafter referred to as “secondary circuit”). Two circuits are configured.

  Here, the operation of the communication circuit 6 when a communication signal is transmitted to the wired communication path 3 will be described.

  The communication circuit 6 outputs a communication signal from the transmission port. The output communication signal is amplified by the amplifier circuit 63 after the high frequency component is removed by the low pass filter 62. The amplified signal is transmitted to the secondary circuit via the transformer 64.

  The signal transmitted to the secondary circuit is output to the wired communication path 3 via the switch circuit 5 as a final communication signal after the noise component contained therein is removed by the band pass filter 66. At this time, the final communication signal is superimposed on the power supply power given to the wired communication path 3.

  Furthermore, the operation of the communication circuit 6 when receiving a communication signal from the wired communication path 3 will be described. A communication signal is extracted through a capacitor 65 and a bandpass filter 66 from a signal (a superimposed signal of power supply power and a communication signal) given to the wired communication path 3. The extracted communication signal is transmitted to the primary circuit via the transformer 64, and after high frequency noise is removed by the low-pass filter 67, the extracted communication signal is input to the reception port of the communication IC 61.

  The communication monitoring circuit 7 detects a communication signal (communication signal output from the amplification circuit 63) at the monitoring point A between the amplification circuit 63 and the primary coil 64a, and determines a predetermined parameter (for details) of the communication signal. , Which will be described later) is output to the outside of the terminal device control unit 8.

  The terminal device control unit 8 is configured by an electronic control unit (configured by a CPU, memory, etc.) (not shown). The terminal device control unit 8 has functions as an abnormality detection unit 81 and a cutoff control unit 82.

  The abnormality detection unit 81 detects a communication abnormality in which the communication signal output from the communication circuit 6 to the wired communication path 3 becomes abnormal.

  Specifically, a signal representing a predetermined parameter of the communication signal is input from the communication monitoring circuit 7 to the abnormality detection unit 81. Then, the abnormality detection unit 81 determines whether or not the communication signal is abnormal based on the predetermined parameter (hereinafter, such determination is referred to as “abnormal determination”).

  Specifically, the abnormality detection unit 81 determines whether or not a predetermined parameter of the communication signal satisfies a reference condition that should be satisfied when the abnormality is normal in the abnormality determination. When the abnormality detection unit 81 determines that the reference condition is not satisfied, the abnormality detection unit 81 detects that a communication abnormality has occurred in the communication circuit 6 included in the first remote controller 11 including the abnormality detection unit 81.

  In the present embodiment, the predetermined parameter of the communication signal includes the voltage value of the communication signal at the monitoring point A. The reference condition in this case includes a condition that the amplitude value (that is, the voltage value) of the communication signal at the monitoring point A is within a predetermined range.

  The predetermined range is a range of amplitude values that the communication signal satisfies when the communication signal at the monitoring point A is normal. The lower limit value of the range is set to a minimum amplitude value assumed as a normal communication signal or a voltage value slightly smaller than the amplitude value. The upper limit value of the range is set to a maximum amplitude value assumed as a normal communication signal or a voltage value slightly larger than the amplitude value.

  For example, when an abnormality such as the occurrence of a short circuit occurs in the primary circuit of the communication circuit 6 (a circuit constituted by the primary coil 64a, the communication IC 61, the low-pass filters 62 and 67, the amplifier circuit 63, and the like), the monitoring point A In some cases, the amplitude value of the communication signal at is lower than the lower limit value of the predetermined range. When such an abnormality occurs in the primary circuit of the communication circuit 6, the abnormality detection unit 81 can detect the communication abnormality.

  In this embodiment, the frequency of the communication signal at the monitoring point A is also included as the predetermined parameter, and the reference condition in this case is a condition that the frequency as the predetermined parameter is within a predetermined range. Is included.

  At this time, the predetermined range is a frequency range that the communication signal satisfies when the communication signal at the monitoring point A is normal. The lower limit value of the range is set to a minimum frequency assumed as a normal communication signal or a frequency slightly lower than the frequency. The upper limit value of the range is set to a frequency slightly higher than the maximum frequency assumed as a normal communication signal.

  It should be noted that aspects of the predetermined parameters and reference conditions may be aspects other than the present embodiment.

  When the abnormality detection unit 81 does not detect a communication abnormality, the cutoff control unit 82 outputs a control signal to the switch circuit 5 so that the switch circuit 5 is turned on. Moreover, the interruption | blocking control part 82 outputs a control signal with respect to the said switch circuit 5 so that the switch circuit 5 will be in an OFF state, when the abnormality detection part 81 detects a communication abnormality. Thereby, when the abnormality detection unit 81 detects a communication abnormality, the output of the communication signal from the communication circuit 6 to the wired communication path 3 is blocked.

  In the present embodiment, the switch circuit 5 and the cutoff control unit 82 correspond to the “cutoff unit” of the present invention.

  The configuration of the first remote controller 11 described above is the same for the second remote controller 12.

  Next, the operation of the hot water supply system 1 when a communication abnormality occurs will be described by taking as an example a case where a communication abnormality occurs in the first remote controller 11.

  When an abnormal communication signal is continuously output from the communication circuit 6 of the first remote controller 11, the communication signal is output from the first remote controller 11 at a timing other than the timing at which the first remote controller 11 should output the communication signal. End up.

  Such a phenomenon is caused by, for example, a case where a communication signal of an abnormal frequency is continuously output due to a failure of the communication IC or a short circuit in the primary circuit of the communication circuit 6 or the like. This occurs when a communication signal having a large amplitude is continuously output.

  At this time, the abnormality detection unit 81 of the first remote controller 11 in which the communication abnormality has occurred is that the predetermined parameter (frequency or voltage value, etc.) of the abnormal communication signal at the monitoring point A is outside the predetermined range described above. Then, it is detected that the communication signal output from the communication circuit 6 of the first remote controller 11 is abnormal. As a result, the shut-off control unit 82 of the first remote controller 11 outputs a control signal for turning off the switch circuit 5 of the first remote controller 11.

  This prevents an abnormal communication signal from being continuously output from the communication circuit 6 of the first remote controller 11 to the wired communication path 3. For this reason, it can communicate normally between the heat source unit control part 22 of the heat source unit 2 and the communication circuit 6 of the second remote controller 12 in which no abnormality has occurred.

  Even if the terminal device in which the communication abnormality has occurred is not the first remote controller 11 but the second remote controller 12, the abnormality detection unit 81 of the second remote controller 12 similarly performs the communication of the second remote controller 12. Detecting that the communication signal output from the circuit 6 is abnormal, the shut-off control unit 82 of the second remote controller 12 outputs a control signal for turning off the switch circuit 5 of the second remote controller 12. .

  Thereby, the abnormality detection part 81 of the 2nd remote control 12 detects a communication abnormality, and the interruption | blocking control part 82 of the said 2nd remote control 12 makes the switch circuit 5 an OFF state. For this reason, it can communicate normally between the heat source machine control part 22 of the heat source machine 2, and the communication circuit 6 of the 1st remote control 11 in which abnormality has not arisen.

  In the present embodiment, each of the terminal devices 11 and 12 is a remote control. However, the terminal device of the present invention is not limited to this, for example, an optional terminal indicated by a two-dot chain line in FIG. 13 may be sufficient.

  Here, the option terminal is, for example, a connection unit for connecting a solar water heater that heats hot water using solar heat and a heat source device. For example, the option terminal 13 receives a communication signal indicating the target hot water supply temperature set by the second remote controller 12 via the wired communication path 3. Thereby, option terminal 13 has acquired target hot-water supply temperature from the received communication signal. And the option terminal 13 supplies the hot water which mixed the hot water from a solar water heater and the water from a water supply pipe to a heat-source device so that the temperature of the hot water to supply hot water may become the said target hot-water supply temperature.

  The option terminal 13 has a configuration similar to that of the first remote controller 11 as described above. The option terminal 13 is connected to the remote controllers 11 and 12 and the heat source device 2 through the wired communication path 3.

  Thereby, each apparatus of the heat-source equipment 2, the 1st remote control 11, the 2nd remote control 12, and the option terminal 13 can transmit / receive a communication signal mutually. Further, when a communication abnormality occurs in each of the devices 2, 11, 12, 13, the switch circuit 5 of the device in which the communication abnormality has occurred is turned off by the cutoff control unit 82 of the device in which the communication abnormality has occurred. become. For this reason, it can communicate normally between the communication circuit 6 of each terminal device in which no communication abnormality has occurred and the heat source unit control unit 22 of the heat source unit 2.

  In the above-described embodiment, the abnormality detection unit 81 detects a communication abnormality according to a signal output from the communication monitoring circuit 7 that has detected a communication signal at the monitoring point A. However, if only the abnormality detection unit of the terminal device in which the communication abnormality has occurred can detect the abnormality of the communication signal, the communication abnormality may be detected based on the communication signal at any location. For example, in the above embodiment, a communication abnormality may be detected based on a communication signal other than the monitoring point A of the primary circuit in the communication circuit 6.

  In the above-described embodiment, the signal in which the power source power and the communication signal are superimposed flows in the wired communication path. However, the present invention is not limited to this, and the wired communication path is a mode in which only the communication signal flows. There may be.

  DESCRIPTION OF SYMBOLS 1 ... Hot water supply system (heat source machine system), 11, 12 ... Terminal equipment (terminal equipment), 2 ... Heat source machine, 22 ... Heat source machine control part (control part), 3 ... Wired communication path, 5 ... Switch circuit (cut-off part) ), 6... Communication circuit, 81. Abnormality detection unit, 82. Blocking control unit (blocking unit), 13.

Claims (4)

A control unit for controlling the operation of the heat source unit;
A plurality of terminal devices that communicate communication signals via a wired communication path shared with the control unit;
Each of the plurality of terminal devices is
A communication circuit connected to the wired communication path;
An abnormality detection unit for detecting a communication abnormality in which a communication signal output from the communication circuit to the wired communication path becomes abnormal;
A switch circuit that can be selectively switched between an on state for connecting a signal line between the communication circuit and the wired communication path to the wired communication path and an off state for blocking the conduction; and the abnormality detection unit When the communication abnormality is detected, the switch circuit between the communication circuit that outputs the communication signal in which the communication abnormality is detected and the wired communication path is controlled to be in an off state. A heat source unit system comprising: a blocking unit that blocks output of a communication signal to a wired communication path. The heat source machine system according to claim 1,
The abnormality detection unit
Determining whether a predetermined parameter of a communication signal generated by the communication circuit included in the terminal device including the abnormality detection unit satisfies a reference condition;
When it is determined that a predetermined parameter of the communication signal does not satisfy the reference condition, it is detected that the communication abnormality occurs in the communication circuit included in the terminal device including the abnormality detection unit. Heat source machine system.   The heat source apparatus system according to claim 2, wherein the predetermined parameter includes a frequency of the communication signal.   4. The heat source apparatus system according to claim 2, wherein the predetermined parameter includes a voltage value of the communication signal. 5.