JP5246324B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner that can be used by combining indoor units and outdoor units having different model specifications.

  2. Description of the Related Art Conventionally, an air conditioner that can cut off power supply to an outdoor unit during operation stop is known for the purpose of reducing standby power.

  For example, Patent Document 1 includes an outdoor unit configured with a standby power compatible model in which power supply is interrupted during operation stop, and an activation unit for starting power supply to the outdoor unit from which power supply is interrupted. An air conditioner including an indoor unit configured with a standby power compatible model is disclosed.

JP 2010-243051 A

  By the way, in an air conditioner, an indoor unit and an outdoor unit having different model specifications may be used in combination. In such a case, it is conceivable to use a combination of an outdoor unit of a standby power compatible model and an indoor unit of a model not supporting standby power that does not have the above-described activation means. However, since the indoor unit that does not support the standby power does not have an activation unit, there is a problem that the outdoor unit cannot be activated.

  In order to avoid such a problem, it is conceivable to provide a forced activation mechanism in the outdoor unit. However, the forced activation setting of the forced activation mechanism is performed by the installation operator of the air conditioner at the site, and there is a possibility that the installation operator will make a setting error. And, when using a combination of a standby power compatible outdoor unit and a standby power compatible model indoor unit, if the forced startup setting is incorrect, the air conditioner can cut off the power supply to the outdoor unit. Nevertheless, a situation occurs in which the power supply to the outdoor unit cannot be interrupted.

  The present invention has been made in view of the above points, and an object of the present invention is to provide an air conditioner having a forced start mechanism for forcibly starting an outdoor unit of a standby power compatible model, in a forced start mechanism. It is to detect a setting mistake and enable smooth operation of the apparatus to improve reliability.

  The first invention is directed to an air conditioner that can be used by combining an indoor unit (20) and an outdoor unit (10) having different model specifications, and is provided in the outdoor unit (10). The outdoor control circuit (13), which is supplied with power from the power line (40a), and the power supply line (40a) are provided, and the outdoor line (10) is shut off when the operation is stopped. A switch (K13R) that is in a standby state in which no power is supplied to the power source, and the first and second short-circuit lines (17a, 17b) that are connected to the power line (40a) so as to bypass the switch (K13R) and are separated from each other ) Including an auxiliary circuit (17), a connector (18a) capable of connecting the first short circuit line (17a) and the second short circuit line (17b), the first short circuit line (17a) and the second short circuit line Short circuit detection means (19) for detecting that (17b) is connected, At least based on the model specification information of the indoor unit (20), it is determined whether or not it is possible to shift to the standby state. When it is determined that the transition to the standby state is possible, the short-circuit detecting means (19) causes the first short-circuit line ( 17a) and an abnormality detection means (23) for detecting an abnormal connection of the auxiliary circuit (17) when it is detected that the second short circuit line (17b) is connected. To do.

  In the first invention, for example, when the connection plug of the connector (18a) is removed and the short circuit lines (17a, 17b) of the auxiliary circuit (17) are not connected, the outdoor unit (10 ) And a standby state in which the power supply to the outdoor unit (10) is cut off.

  On the other hand, when both short-circuit lines (17a, 17b) of the auxiliary circuit (17) are connected by the connector (18a), the path from the AC power supply (40) to the outdoor control circuit (13) bypassing the switch (K13R) It is formed. Therefore, even if the power supply line (40a) is interrupted by the switch (K13R), power is always supplied from the AC power supply (40) to the outdoor control circuit (13) via the auxiliary circuit (17). Therefore, even if the indoor unit (20) that does not support standby power and the outdoor unit (10) that supports standby power are connected, the outdoor unit (10) is forcibly activated. That is, in the first invention, the auxiliary circuit (17) and the connector (18a) constitute a forced activation mechanism.

  Further, whether or not to shift to the standby state is determined by the abnormality detection means (23). For example, when the indoor unit (20) that does not support the standby power and the outdoor unit (10) that supports the standby power are combined, it is determined that the transition to the standby state is impossible. On the other hand, when it is determined that the transition to the standby state is possible, if the short-circuit detection means (19) detects that both short-circuit lines (17a, 17b) are connected, the abnormality detection means (23) Detects an abnormal connection of the auxiliary circuit (17).

  In a second aspect based on the first aspect, the short-circuit detection means (19) is connected to the ground (GND), the external power supply terminal (19a) to which an external power supply is supplied, and the external power supply terminal (19a). A detection unit (19b) for detecting a power supply voltage supplied from the external power supply terminal (19a), the first short circuit line (17a) and the second short circuit line (17b) and a ground (GND) It has the said connector (18a) comprised so that an external power supply terminal (19a) might be connected, It is characterized by the above-mentioned.

  In the second invention, when both short-circuit lines (17a, 17b) are not connected by the connector (18a), the ground (GND) and the external power supply terminal (19a) are not connected, while the connector (18a) When the two short-circuit lines (17a, 17b) are connected to each other, the ground (GND) and the external power supply terminal (19a) are connected. Therefore, a high level voltage is input to the detection unit (19b) when both short-circuit lines (17a, 17b) are not connected by the connector (18a), and both short-circuit lines (17a, 17b are connected by the connector (18a). ) Is connected, a low level voltage is input.

  In a third aspect based on the first aspect, the short-circuit detection means (19) is connected to a ground (GND), an external power supply terminal (19a) to which an external power supply is supplied, and the external power supply terminal (19a). Emitted when the detection unit (19b) for detecting the power supply voltage supplied from the external power supply terminal (19a) and the first short circuit line (17a) and the second short circuit line (17b) are connected. It has a diode (19d) and a phototransistor (19e) connected between the external power supply terminal (19a) and the ground (GND) and operated by the light of the light emitting diode (19d).

  In the third invention, the light-emitting diode (19d) and the phototransistor (19e) constitute a photocoupler. When both short-circuit lines (17a, 17b) are not connected by the connector (18a), the light-emitting diode (19d) does not emit light and the phototransistor (19e) does not operate, so the ground (GND) and external power supply terminal (19a) is in a substantially non-connected state, but when both short-circuit lines (17a, 17b) are connected by the connector (18a), the light emitting diode (19d) emits light and the phototransistor (19e) Therefore, the ground (GND) and the external power supply terminal (19a) are electrically connected. Therefore, a high level voltage is input to the detection section (19b) when both short-circuit lines (17a, 17b) are not connected by the connector (18a), as in the second aspect of the invention, and the connector (18a) Thus, when both short-circuit lines (17a, 17b) are connected, a low level voltage is input.

  According to a fourth invention, in any one of the first to third inventions, when the air conditioner detects a connection abnormality between the remote control (30) and the abnormality detection means (23), the auxiliary circuit (17). And a notification means (23) for notifying the remote controller (30) of the connection abnormality.

  In the fourth invention, when the abnormality detection means (23) detects a connection abnormality of the auxiliary circuit (17), the notification means (23) notifies the remote control (30) of the connection abnormality of the auxiliary circuit (17). The

  According to the first aspect of the present invention, when both short-circuit lines (17a, 17b) of the auxiliary circuit (17) are connected by the connector (18a) in the air conditioner capable of shifting to the standby state, the abnormality detection means (23) Thus, since the connection abnormality of the auxiliary circuit (17) is detected, the installation operator can notice that both the short-circuit lines (17a, 17b) of the auxiliary circuit (17) are erroneously connected. Thereby, the installation operator can reset both short-circuit lines (17a, 17b) to a non-connection state. Therefore, when the user uses an air conditioner that can shift to a standby state, a situation in which the power supply to the outdoor unit (10) cannot be interrupted is avoided, enabling smooth operation of the device, Reliability can be improved.

  According to the second invention, the detection unit (19b) can detect that both short-circuit lines (17a, 17b) of the auxiliary circuit (17) are connected when a low-level voltage is input. .

  In addition, since the short-circuit detection means (19) is configured using the connector (18a) that connects both the short-circuit lines (17a, 17b), the number of parts is reduced and the short-circuit lines (17a, 17b ) Can be detected.

  According to the third invention, similar to the second invention, the detection unit (19b) is connected to both short-circuit lines (17a, 17b) of the auxiliary circuit (17) when a low level voltage is inputted. Can be detected.

  According to the fourth invention, when the abnormality detecting means (23) detects the connection abnormality of the auxiliary circuit (17), the notification means (23) causes the connection abnormality of the auxiliary circuit (17) to the remote control (30). Since the notification is made, the installation operator will definitely notice that both short-circuit lines (17a, 17b) of the auxiliary circuit (17) are connected by mistake, and put both short-circuit lines (17a, 17b) in a disconnected state. Can be set again. Therefore, when the user uses an air conditioner that can shift to the standby state, the situation where the power supply to the outdoor unit (10) cannot be cut off can be avoided more reliably and the reliability can be improved. it can.

Drawing 1 is a figure showing the whole air harmony device composition concerning an embodiment. FIG. 2 is an electrical system block diagram of the air conditioner (suspended state) when the outdoor unit, the standby power compatible model indoor unit, and the standby power compatible model remote controller are connected. FIG. 3 is an enlarged view of the vicinity of the forced activation mechanism. FIG. 4 is a view corresponding to FIG. 3 when the connection plug is inserted into the short-circuit connector. FIG. 5 is a state transition diagram of the air conditioner. FIG. 6 is a diagram illustrating the state of the relay at the time when the circuit charged in the smoothing capacitor is formed. FIG. 7 is a diagram illustrating a state of the relay after the transition to the charging state is completed. FIG. 8 is a diagram illustrating the state of the relay in the wait state. FIG. 9 is a diagram illustrating the state of the relay in the operating state. FIG. 10 is an electrical system block diagram of the air conditioner when an outdoor unit, an indoor unit that does not support standby power, and a remote controller that does not support standby power are connected. FIG. 11 is a flowchart for detecting a setting error of the forced activation mechanism. FIG. 12 is a flowchart for determining whether or not to shift to the suspended state. FIG. 13 is a diagram illustrating a modification of the short-circuit detection unit.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following description of the preferred embodiment is merely exemplary in nature.
<Embodiment>
<overall structure>
Drawing 1 is a figure showing the whole air harmony device (1) composition concerning an embodiment of the present invention. This air conditioner (1) is an air conditioner that can be used by combining indoor units and outdoor units having different model specifications.

  The air conditioner (1) includes an outdoor unit (10), an indoor unit (20), and a remote controller (hereinafter abbreviated as a remote controller) (30).

  The outdoor unit (10) is configured with a standby power compatible model that can cut off the power supply while the operation is stopped.

  The indoor unit (20) is a standby power compatible model having start means for starting power supply to an outdoor unit (10) of a standby power compatible model in which power supply is interrupted and starting the outdoor unit (10) or It is configured with a model that does not have standby means and does not support standby power.

  The remote controller (30) does not transmit a standby power compatible model that transmits a cutoff request signal to the indoor unit (20) to shut off the power supply to the outdoor unit (10) or the cutoff request signal to the indoor unit (20). Consists of models that do not support standby power.

  The present invention will be specifically described below.

  FIG. 2 is an electrical system block diagram of the air conditioner (1) when the outdoor unit (10), the standby power compatible model indoor unit (20), and the standby power compatible model remote control (30) are connected. .

  In the air conditioner (1), the outdoor unit (10) receives AC (three-phase AC of 200 V in this example) from the commercial AC power supply (40) and receives a circuit or electric compressor ( In addition to being used as electric power (not shown), two phases of the three-phase alternating current are supplied to the indoor unit (20). In addition, communication is performed between the outdoor unit (10) and the indoor unit (20) for the purpose of controlling the outdoor unit (10) from the indoor unit (20) side. Therefore, in the air conditioner (1), power wiring (L) for transmitting AC power from a commercial AC power supply (40) (hereinafter also simply referred to as AC power supply), and a signal line (S) for transmitting the signal Three wires (internal / external wiring) of a common line (N) shared for transmission of the AC power and transmission of the signal are provided between the outdoor unit (10) and the indoor unit (20). In this embodiment, the power wiring (L) is connected to the R phase of the AC power supply (40) in the outdoor unit (10), and the common line (N) is connected to the S of the AC power supply (40) in the outdoor unit (10). Connected to the phase. That is, the indoor unit (20) is connected to the R phase and the S phase of the AC power supply (40) and supplied with single-phase AC.

<Outdoor unit (10)>
The outdoor unit (10) includes, as an electrical system, a first outdoor power circuit (14), a second outdoor power circuit (12), an outdoor unit transmission circuit (11), an outdoor control circuit (13), and an outdoor storage unit (15). And a forcible start mechanism (16) and relays (K13R, K14R, K15R). Although not shown, the outdoor unit (10) is provided with devices such as an electric compressor, an outdoor heat exchanger, an outdoor fan, and an expansion valve.

-First outdoor power circuit (14)-
The first outdoor power supply circuit (14) converts the three-phase alternating current received from the alternating current power supply (40) into direct current, and supplies it to a so-called intelligent power module (hereinafter abbreviated as IPM) or an outdoor fan motor. . The IPM converts the input direct current into alternating current having a predetermined frequency and voltage, and supplies power to the motor of the electric compressor. The first outdoor power supply circuit (14) includes a noise filter (14a), two main relays (14b), two diode bridge circuits (14c), a reactor (14d), and a smoothing capacitor (14e). .

  The noise filter (14a) is formed of a capacitor and a coil. The two main relays (14b) are respectively provided in the three-phase AC R-phase and T-phase supply lines. Of the two diode bridge circuits (14c), one inputs the R phase and S phase of the three-phase AC and the other inputs the S phase and T phase of the three-phase AC and inputs the AC Is full-wave rectified. The outputs of these diode bridge circuits (14c) are input to the smoothing capacitor (14e) via the reactor (14d) and smoothed by the smoothing capacitor (14e). The direct current smoothed by the smoothing capacitor (14e) is supplied to the IPM and the outdoor fan motor.

-Second outdoor power circuit (12)-
The second outdoor power supply circuit (12) converts the two phases of the three-phase alternating current R phase and S phase into direct current (5 V in this example) and supplies it to the outdoor control circuit (13). The second outdoor power supply circuit (12) includes a diode bridge circuit (12a), a smoothing capacitor (12b), and a switching power supply (12c).

  The diode bridge circuit (12a) has one input connected to the three-phase AC R-phase power line (40a) via a relay (K13R), and the other input connected to the three-phase AC S-phase. Connected to the power line (40a). The output of the diode bridge circuit (12a) is smoothed by the smoothing capacitor (12b) and then input to the switching power supply (12c). The switching power supply (12c) is composed of, for example, a DC-DC converter, converts the input direct current into a predetermined voltage (5V), and outputs the same to the outdoor control circuit (13).

-Outdoor unit transmission circuit (11)-
The outdoor unit transmission circuit (11) communicates with the indoor unit transmission circuit (21) by transmitting and receiving signals. In this communication, high-level and low-level binary digital signals are communicated based on the potential difference between the signal line (S) and the common line (N). The communication circuit (not shown) in the indoor unit transmission circuit (21) has one end connected to the common line (N) and the other end connected to the signal line (S) via the relay (K14R). ing.

−Relay (K13R) −
The relay (K13R) shuts off the power supply from the AC power supply (40) to the second outdoor power supply circuit (12) by shutting off the three-phase AC R-phase power line (40a) while the operation is stopped. This is a switch that switches to a suspended state, and is a relay that switches the AC supply path to the second outdoor power supply circuit (12). The relay (K13R) is a so-called C contact relay. Specifically, the relay (K13R) has two fixed contacts and one movable contact. When the relay (K13R) coil (not shown) is not energized, one fixed contact (normally closed contact) When the coil is energized, the other fixed contact (referred to as a normally open contact) and the movable contact are connected. The outdoor control circuit (13) controls switching of the relay (K13R) (whether or not the coil is energized).

  The movable contact of the relay (K13R) is connected to the input of the diode bridge circuit (12a). The normally closed contact is connected to the signal line (S), and the normally open contact is connected to the three-phase AC R-phase power line (40a). That is, when the coil of the relay (K13R) is not energized, the normally closed contact and the movable contact are connected, and one input of the diode bridge circuit (12a) is connected to the signal line (S). When the coil of the relay (K13R) is energized, the movable contact and the normally open contact are connected and AC is input to the diode bridge circuit (12a) of the second outdoor power supply circuit (12).

−Relay (K14R) −
The relay (K14R) is a relay that switches connection (on) and non-connection (off) between the signal line (S) and the outdoor unit transmission circuit (11). The outdoor control circuit (13) controls on / off of the relay (K14R).

−Relay (K15R) −
A relay (K15R) is a relay which switches the presence or absence of the electric power supply to an outdoor unit transmission circuit (11). When the relay (K15R) is turned on, power is supplied from the AC power source (40) to the outdoor unit transmission circuit (11). When the relay (K15R) is turned off, the AC power source (40) is connected to the outdoor unit transmission circuit (11). ) Is cut off. The outdoor control circuit (13) controls on / off of the relay (K15R).

-Outdoor control circuit (13)-
The outdoor control circuit (13) includes a microcomputer and a memory storing a program for operating the microcomputer. The outdoor control circuit (13) controls, for example, the electric compressor according to the signal received by the outdoor unit transmission circuit (11) from the indoor unit transmission circuit (21), and when the outdoor unit (10) is started. Also controls.

-Outdoor storage (15)-
The outdoor storage unit (15) is connected to the outdoor control circuit (13).

  In the outdoor storage unit (15), model specification information (bits “1” and “0”) indicating whether or not the outdoor unit (10) is a standby power compatible model is stored in advance.

-Forced start mechanism (16)-
The forced activation mechanism (16) is a mechanism for forcibly starting the outdoor unit (10) when the indoor unit (20) that does not support standby power is connected to the outdoor unit (10). As shown in FIGS. 2 and 3, the forced start mechanism (16) includes an auxiliary circuit (17) connected to the R-phase power line (40a) of the three-phase alternating current so as to bypass the relay (K13R). And a connecting portion (18).

  The auxiliary circuit (17) includes a first short-circuit line (17a) connected to the normally open contact side of the relay (K13R) in the three-phase AC R-phase power line (40a) and the three-phase AC R-phase. And the second short-circuit line (17b) connected to the movable contact side of the relay (K13R) in the power line (40a).

  The second short-circuit line (17b) is provided with a diode (D3) whose anode is connected to a connection node (ND3) between the second short-circuit line (17b) and the power supply line (40a).

  The connecting part (18) detects that the short-circuit connector (18a) that can connect the first short-circuit line (17a) and the second short-circuit line (17b) and the short-circuit line (17a, 17b) are connected. And a short-circuit detecting unit (19) as a short-circuit detecting means.

  The short-circuit connector (18a) includes a connector body (18b) and a four-pole connection plug (18c) (see FIG. 4).

  The connector body (18b) is provided with four plug insertion holes (18d, 18d,...) Corresponding to the connection plugs (18c). The first and second short-circuit lines (17a, 17b) are connected to locations corresponding to the two plug insertion holes (18d, 18d) in the plug insertion holes (18d, 18d,...). .

  The short-circuit detection unit (19) is connected to the ground (GND), the external power supply terminal (19a) to which an external power supply (in this example, 5 V) is supplied, and the external power supply terminal (19a) via a resistor. It includes a microprocessor (19b) (hereinafter abbreviated as MPU) as a detection unit.

  The ground (GND) is connected to one of the remaining two plug insertion holes (18d, 18d) not connected to the first and second short-circuit lines (17a, 17b) via a resistor, and is connected to an external power supply terminal ( 19a) and MPU (19b) are connected to the other of the remaining two plug insertion holes (18d, 18d).

  In this forced start mechanism (16), when the connection plug (18c) is inserted into the plug insertion hole (18d, 18d,...) Of the connector body (18b), the first and second short-circuit lines (17a, 17b) Are connected, the auxiliary circuit (17) becomes conductive, and the external power supply terminal (19a) and the ground (GND) are connected. On the other hand, if the connection plug (18c) is removed from the plug insertion hole (18d, 18d, ...) of the connector body (18b), the first and second short-circuit lines (17a, 17b) are disconnected, and the auxiliary circuit (17) is cut off, and the external power supply terminal (19a) and the ground (GND) are disconnected. Therefore, a high level voltage is input to the MPU (19b) when both short-circuit lines (17a, 17b) are not connected by the short-circuit connector (18a), and both short-circuit lines (17a, 17b) are input by the short-circuit connector (18a). A low level voltage is input when 17b) is connected. Therefore, the MPU (19b) detects that both short-circuit lines (17a, 17b) of the auxiliary circuit (17) are connected when a low level voltage is input.

<Indoor unit (20)>
The indoor unit (20) has, as an electrical system, an indoor power supply circuit (22), an indoor unit transmission circuit (21), an indoor control circuit (23), an outdoor storage unit (24), a relay (K2R), a first diode (D1 ), And a second diode (D2). Although not shown, the indoor unit (20) is provided with devices such as an indoor heat exchanger and an indoor fan.

-Indoor power circuit (22)-
The indoor power supply circuit (22) includes a noise filter (22a), a diode bridge circuit (22b), a smoothing capacitor (22c), and a switching power supply (22d). The indoor power supply circuit (22) converts the alternating current supplied from the alternating current power supply (40) through the power wiring (L) and the common line (N) into direct current (in this example, direct current of 5V), and the indoor control circuit Supply to (23).

  The noise filter (22a) is formed by two coils. The diode bridge circuit (22b) performs full-wave rectification on the alternating current input from the power wiring (L) and the common line (N) via the noise filter (22a). The smoothing capacitor (22c) is formed of, for example, an electrolytic capacitor, and smoothes the output of the diode bridge circuit (22b). The switching power supply (22d) is composed of, for example, a DC-DC converter or the like, converts the direct current smoothed by the smoothing capacitor (22c) into a predetermined voltage (5V), and outputs it to the indoor control circuit (23).

-Indoor unit transmission circuit (21)-
As described above, the indoor unit transmission circuit (21) performs signal communication with the outdoor unit transmission circuit (11). In this communication, since communication is performed based on the potential difference between the signal line (S) and the common line (N), one end of the communication circuit of the indoor unit transmission circuit (21) is connected to the signal line (S), The other end of the communication circuit is connected to a common line (N).

−Relay (K2R) −
The relay (K2R) is provided on the bypass line (B) that connects the power line (L) and the signal line (S), and switches between connecting and disconnecting the power line (L) and the signal line (S). It is a relay. The relay (K2R) functions as an activation unit that starts power supply to the outdoor unit (10) from which power supply is interrupted. When the relay (K2R) is turned on, the power wiring (L) and the signal line (S) are connected. When the relay (K2R) is turned off, the power wiring (L) and the signal line (S) are connected. Is disconnected. The indoor control circuit (23) controls on / off of the relay (K2R).

-First diode (D1)-
The first diode (D1) has an anode connected to a connection node (ND1) between the bypass line (B) and the signal line (S), and a cathode connected to a relay (K2R). The first diode (D1) has a function of blocking an alternating current in a direction flowing into the indoor unit transmission circuit (21).

-Second diode (D2)-
The second diode (D2) has an anode connected to the connection node (ND1) of the signal line (S) and a cathode connected to the signal input node (ND2) in the indoor unit transmission circuit (21). The second diode (D2) has a function of blocking an alternating current flowing in the direction from the indoor unit transmission circuit (21).

-Indoor control circuit (23)-
The indoor control circuit (23) includes a microcomputer and a memory storing a program for operating the microcomputer. The indoor control circuit (23) receives a command from the remote control (30) and controls the operation state of the air conditioner (1). As will be described later, the indoor control circuit (23) functions as an abnormality detection means for detecting a setting error of the forced activation mechanism (16). The indoor control circuit (23) also serves as a notification means for notifying the remote controller (30) of the abnormality when a setting error of the forced activation mechanism (16) is detected.

-Indoor storage (24)-
The indoor storage unit (24) is connected to the indoor control circuit (23). In the indoor unit storage unit (24), model specification information (bits “1” and “0”) indicating whether or not the indoor unit (20) is a standby power compatible model is stored in advance.

<Remote controller (30)>
The remote controller (30) receives a user operation and transmits a signal corresponding to the user operation to the indoor control circuit (23). For example, the user can start and stop the air conditioner (1), adjust the set temperature, and the like by operating a button on the remote controller (30). The remote controller (30) is a wired remote controller including a remote controller storage unit (31).

-Remote control memory (31)-
In the remote control storage unit (31), model specification information (bits “1” and “0”) indicating whether or not the remote control (30) is a standby power compatible model is stored in advance.

<Forced startup mechanism settings>
When the air conditioner (1) is shipped, the connection plug (18c) is inserted into the connector body (18b) as shown in FIG. Therefore, the installation operator of the air conditioner (1) determines whether or not the indoor unit (20) is a standby power compatible model when the apparatus is installed. Then, when it is determined that the indoor unit (20) is a standby power compatible model, the worker performs an operation of removing the connection plug (18c) from the connector body (18b). Here, since the indoor unit (20) is a standby power compatible model, the connection plug (18c) is removed from the connector body (18b) as shown in FIG. Therefore, the first short circuit line (17a) and the second short circuit line (17b) are disconnected, and the auxiliary circuit (17) is shut off.

<Operation of air conditioner>
FIG. 5 is a state transition diagram of the air conditioner (1). The air conditioner (1) transitions between four states: a suspended state, a charged state, a wait state, and an operating state, which will be described below. In this specification, the standby power means “power that is constantly consumed when the device is not in use or is waiting for some input (command instruction, etc.)”. Specifically, in the air conditioner (1), the standby power is the power required to perform only the standby of the remote control (30).

(1) Suspended state The suspended state is a state in which power is supplied to the indoor unit (20) and power is not supplied to the outdoor unit (10). This suspended state is a standby state according to the present invention.

  As an example, the suspended state of the present embodiment is a state in which the power consumption of the entire air conditioner (1) is minimized. Specifically, in the suspended state of the present embodiment, the outdoor unit (10) receives power and supplies it to the indoor unit (20), but each circuit in the outdoor unit (10) and the electric compressor In such a state, no power is supplied. That is, in the suspend state, the outdoor control circuit (13) also cuts off the power supply and stops operating. Thus, in the suspended state, power supply to each circuit of the outdoor unit (10) is cut off, and standby power can be reduced.

  On the other hand, in the indoor unit (20), the standby power is in a minimum state, but unlike the outdoor unit (10), the part related to signal reception from the remote control (30) in the indoor control circuit (23) Operates by receiving power from the power circuit (22).

  In addition, the remote control (30) is in a state where standby power is minimized, but the user can accept button operations. The degree of power consumption (standby power) of the indoor unit (20) and the remote controller (30) is not limited to this.

(2) Charging state In the outdoor unit (10), a path for charging the smoothing capacitor (12b) of the second outdoor power supply circuit (12) is formed in the outdoor unit (10), and the outdoor unit transmission circuit (11) and the indoor unit It means a state in a period until signal transmission between the transmission circuits (21) is started. At this time, the power consumption of the indoor unit (20) is the same as in the suspended state.

(3) Wait state The wait state is a state in which the above charging state is exited at the start of operation, and a transition from the operation state (described later) when the operation is stopped. In both cases, the outdoor unit (10) This refers to the state that can be shifted to the operating state. In the weight state, both the outdoor unit transmission circuit (11) and the outdoor control circuit (13) are operating. In particular, the weight state at the time of operation stop (weight state that transitions from the operation state) is for equalizing the refrigerant pressure in the electric compressor or when a schedule operation that repeats operation start and operation stop is set. The time is, for example, 10 minutes. The power consumption of the indoor unit (20) is the same as in the suspended state.

(4) Operational state The operational state refers to a state where the main relay (14b) is turned on and the electric compressor and the outdoor fan can be operated or are in operation. The so-called phase loss energization and the thermo-off state also correspond to this. In the indoor unit (20), the indoor fan or the like is in an operating state, and the power consumption is higher than in each of the above states. In addition, the suspended state, the charged state, and the wait state, excluding this operating state, correspond to “stopping operation” in this specification.

-Operation start operation-
In the air conditioner (1), when the operation is started, the air conditioner (1) transitions from the suspended state to the operating state in the order indicated by solid arrows in FIG.

<Electrical system in suspended state>
First, the state of the electrical system in the suspended state will be described with reference to FIG.

  In the outdoor unit (10), the main relay (14b) is in an off state, and power is not supplied to the first outdoor power supply circuit (14), and power is supplied from the first outdoor power supply circuit (14) to the IPM and the outdoor fan motor. Not supplied.

  The relay (K14R) and the relay (K15R) are also off. For this reason, the outdoor unit transmission circuit (11) is disconnected from the signal line (S) and also supplied with power.

  The relay (K13R) has a normally closed contact and a movable contact connected, and one input of the diode bridge circuit (12a) of the second outdoor power supply circuit (12) is connected to the signal line (S). Yes. In this state, power is not supplied to the second outdoor power supply circuit (12) and power is not supplied to the outdoor control circuit (13). Thus, in the suspended state, the outdoor unit (10) is cut off from the power supply.

  On the other hand, in the indoor unit (20), the relay (K2R) is in an off state, and the signal line (S) and the power wiring (L) are not electrically connected.

<Transition from suspended state to charged state>
FIG. 6 is a diagram illustrating a state of each relay at the time when a circuit charged in the smoothing capacitor (12b) is formed. FIG. 7 is a diagram illustrating a state of each relay after the transition to the charging state is completed.

  For example, when the user performs a driving start operation with the remote control (30), a driving command signal is transmitted from the remote control (30) to the indoor unit (20).

  When the indoor unit (20) receives the operation command signal, the indoor control circuit (23) turns on the relay (K2R). Then, in the air conditioner (1), from the R phase of the three-phase alternating current, the power wiring (L), the relay (K2R), the first diode (D1), the signal line (S), and the relay (K13R) Thus, a power transmission path to one input of the diode bridge circuit (12a) is formed. Since the other input of the diode bridge circuit (12a) is connected to the S phase of the three-phase AC, the diode bridge circuit (12a) has a single-phase AC half-wave rectified by the first diode (D1). Is supplied. Thus, a circuit charged in the smoothing capacitor (12b) is formed (see FIG. 6).

  On the other hand, in the outdoor unit (10), the smoothing capacitor (12b) is charged so that the input to the switching power supply (12c) is stabilized, so that the switching power supply (12c) can output the specified DC voltage (5V in this example). Then, the outdoor control circuit (13) is activated. The activated outdoor control circuit (13) energizes the coil of the relay (K13R) to connect the normally open contact and the movable contact. Thereby, one input of the diode bridge circuit (12a) is connected to the R phase of the three-phase AC via the power line (40a) of the outdoor unit (10). That is, the outdoor control circuit (13) switches to a state where power is supplied from the AC power supply (40) without passing through the signal line (S) (see FIG. 7). Thus, the transition from the suspended state to the charged state is completed.

<Transition from charge state to wait state>
FIG. 8 is a diagram illustrating the state of each relay when the transition to the wait state is completed. In the indoor unit (20), the relay (K2R) is turned off after a predetermined time (a sufficient time for the outdoor control circuit (13) to start) has elapsed since the relay (K2R) was turned on. As a result, the signal line (S) can be used for signal transmission and reception.

  In the outdoor unit (10), the outdoor control circuit (13) turned on the relay (K15R) and supplied power to the outdoor unit transmission circuit (11) in anticipation that the relay (K2R) was turned off. At the same time, turn on the relay (K14R). As a result, the communication circuit in the outdoor unit transmission circuit (11) is connected to the indoor unit transmission circuit (21) via the signal line (S) and the common line (N), and communicates with the indoor unit transmission circuit (21). It becomes possible. Thus, the air conditioner (1) enters a wait state in which it can exit the charged state and shift to the immediate operation state.

<Transition from wait state to operation state>
FIG. 9 is a diagram illustrating the state of each relay in the operating state. When shifting from the wait state to the operation state, the outdoor control circuit (13) turns on the two main relays (14b). Thereby, electric power is supplied to the IPM and the outdoor fan motor by the first outdoor power supply circuit (14), and the electric compressor and the like are in an operating state. In the air conditioner (1), the cooling operation or the heating operation is performed while the outdoor unit (10) and the indoor unit (20) communicate.

-Stop operation-
When the operation is stopped, the operation state is changed to the suspend state in the order indicated by the broken-line arrows in FIG.

  In the driving state, for example, when the user performs a driving stop operation with the remote controller (30), the operation state, the wait state, and the suspend state are changed in this order. Hereinafter, operations from the operating state to the suspended state will be described in order.

<Transition from operating state to wait state>
When the user performs a stop operation with the remote control (30), a stop signal is sent from the remote control (30) to the indoor unit (20), and a stop operation signal is sent from the indoor unit (20) to the outdoor unit (10). .

  In the outdoor unit (10), when the operation stop signal is received, the outdoor control circuit (13) switches the main relay (K14b) from on to off. Thereby, the power supply to the IPM and the outdoor fan motor is cut off, and the electric compressor and the like are stopped. Thus, the transition from the operating state to the wait state is completed (see FIG. 8).

<Transition from wait state to suspend state>
When the user performs the operation stop operation with the remote control (30), the predetermined remote suspension prohibition condition is determined with the remote control (30). This suspend transition prohibition condition is, for example, when the time when the user has stopped the operation with the remote control (30) is within a predetermined time from the scheduled operation start time reserved by the scheduling function, the transition from the wait state to the suspend state Is prohibited. When the suspend transition prohibition condition is not satisfied, a cutoff request signal is transmitted from the remote control (30) to the indoor unit (20), and a cutoff request signal is transmitted from the indoor unit (20) to the outdoor unit (10).

  In the outdoor unit (10), when the cutoff request signal is received, the outdoor control circuit (13) turns off the relay (K14R) and the relay (K15R). Thereby, the connection between the outdoor unit transmission circuit (11) and the indoor unit transmission circuit (21) is disconnected, and the outdoor unit (10) and the indoor unit (20) cannot communicate. The indoor control circuit (13) switches the relay (K13R) from the state where the normally open contact and the movable contact are connected to the state where the normally closed contact and the movable contact are connected. Thereby, the electric power supply to a 2nd outdoor unit power supply part (12) is interrupted | blocked. Further, the outdoor unit (10) transmits a cutoff execution signal to the indoor unit (20) immediately before the relays (K13R, K14R, K15R) are operated. Thus, the transition to the suspended state is completed (see FIG. 2).

-Forced start operation-
As shown in FIG. 10, the air conditioner (1) can be used in combination with an outdoor unit (10) and an indoor unit (20) of a model that does not support standby power. However, the indoor unit (20) that does not support standby power does not have a relay (K2R) unlike the indoor unit (20) that supports standby power, so it activates the outdoor unit (10) in the suspended state. I can't let you.

  Therefore, the installation operator of the air conditioner (1) does not remove the connection plug (18c) from the connector body (18b) when the forced activation mechanism (16) is set, and as shown in FIG. ) Is inserted into the connector body (18b). By doing so, the auxiliary circuit (17) becomes conductive, and a path from the AC power supply (40) to the relay (K13R) to reach the second outdoor power supply circuit (12) is formed. Thereby, electric power is always supplied from the AC power supply (40) to the outdoor control circuit (13) through the second power supply circuit (12). Thus, the outdoor unit (10) can be activated. In this case, the air conditioner (1) is not in the suspended state, but is in two states, a weight state and an operating state.

-Detection of setting error of forced startup mechanism-
In the air conditioner (1), as described above, the installation operator determines the setting of the forced activation mechanism (16) on site. For this reason, there is a possibility that the installation operator will erroneously set the forced activation mechanism (16). And, when using the outdoor unit (10) in combination with the standby power compatible model indoor unit (20), the setting of the forced start mechanism (16) is wrong, that is, from the short-circuit connector (18) to the connection plug (18c) If you forget to remove the power, a path is formed from the AC power supply (40) to the second outdoor power supply circuit (12) via the auxiliary circuit (17), so power is supplied to the outdoor unit (10). A situation occurs where it cannot be blocked.

  Therefore, in this air conditioner (1), when the outdoor unit (10), the indoor unit (20), and the remote control (30) are connected for the first time to start up, the standby power compatible model indoor unit (20) The indoor control circuit (23) is configured to detect a setting error of the forced activation mechanism (16).

  Specifically, the indoor control circuit (23) detects a setting error of the forced activation mechanism (16) based on the flowchart shown in FIG. That is, first in step S1, the indoor control circuit (23) determines whether or not it is possible to shift to the suspended state. This determination process for determining whether or not to enter the suspended state is executed based on the flowchart shown in FIG.

  That is, in step S1a, the indoor control circuit (23) acquires model specification information of the outdoor unit (10) and the remote control (30) from the outdoor storage unit (15) and the remote control storage unit (31).

  In subsequent step S1b, the indoor control circuit (23) determines whether the outdoor unit (10), the indoor unit (20), and the remote controller (30) are standby power compatible models based on the model specification information. . When the outdoor unit (10), the indoor unit (20), and the remote control (30) are all standby power compatible models, the process proceeds to step S1c, while the outdoor unit (10), the indoor unit (20), and the remote control If any of (30) is not a standby power compatible model, the process proceeds to step S1d.

  In step S1c, it is determined that the transition to the suspended state is possible. On the other hand, in step S1d, it is determined that the transition to the suspended state is impossible.

  Then, returning to the flowchart shown in FIG. 11 again, when it is determined that the transition to the suspend state is possible, the process proceeds to step S2. On the other hand, when it is determined that the transition to the suspend state is impossible, the process ends. To do.

  In step S2, it is determined whether or not it is detected that the first short circuit line (17a) and the second short circuit line (17b) are connected by the short circuit detector (19). When it is detected by the short-circuit detection unit (19) that both short-circuit lines (17a, 17b) are connected, the process proceeds to step S3, while the short-circuit detection unit (19) detects both short-circuit lines (17a, 17b). If it is detected that 17b) is not connected, the process ends.

  In step S3, the indoor control circuit (23) detects a connection abnormality of the auxiliary circuit (17). Thus, the indoor control circuit (23) detects a setting error of the forced activation mechanism (16).

  When the indoor control circuit (23) detects the connection abnormality of the auxiliary circuit (17), it notifies the remote control (30) of the connection abnormality of the auxiliary circuit (17).

<Effects of the embodiment>
According to the present embodiment, when it is possible to shift to the suspended state, the installation operator of the device mistakes the setting of the forced activation mechanism (16), that is, the connection plug (18c) is removed from the connector body (18b). If you forget, the indoor control circuit (23) detects an abnormal connection of the auxiliary circuit (17). Then, the connection error of the auxiliary circuit (17) is notified from the indoor control circuit (23) to the remote control (30). Thereby, the installation operator can be sure that he has forgotten to remove the connection plug (18c) from the connector body (18b), and can remove the connection plug (18c) from the connector body (18b). Therefore, when the air conditioner (1) that allows the user to enter the suspended state is used, the situation where the power supply to the outdoor unit (10) cannot be cut off is avoided, and the apparatus can be operated smoothly. And reliability can be improved.

  In addition, since the short-circuit detection part (19) is configured using the short-circuit connector (18a) for connecting the first and second short-circuit lines (17a, 17b), both the short-circuit lines can be simplified with a reduced number of parts. It is possible to detect that (17a, 17b) is connected.

<Modification>
As shown in FIG. 13, the present modification is different from the above embodiment in the configuration of the short-circuit detection unit. Therefore, the configuration of the short circuit detection unit will be mainly described. In FIG. 13, the same reference numerals are given to the same components as those in the above embodiment.

  Connect the 1st short circuit line (17a) and the 2nd short circuit line (17b) by inserting the connection plug (18c) of 2 poles, not 4 poles, into the connector body (18b). It is configured to be able to.

  The short-circuit detection unit (19) is connected to the ground (GND), the external power supply terminal (19a) to which an external power supply (in this example, 5 V) is supplied, and the external power supply terminal (19a) via a resistor. A microprocessor (19b) (hereinafter abbreviated as MPU) as a detection unit and a photocoupler (19c) are provided.

  The second short-circuit line (17b) is connected to the other end of a detection line (19f) having one end connected to the three-phase AC S-phase power line (40a).

  The detection line (19f) includes a voltage dividing resistor (R1) and a voltage dividing resistor (R2) in order from the second short circuit line (17b) side to the three-phase AC S-phase power line (40a) side. Are connected in series.

  The light emitting diode (19d) of the photocoupler (19c) is provided in parallel with the voltage dividing resistor (R2). Thereby, the light emitting diode (19d) is configured to emit light when the first short circuit line (17a) and the second short circuit line (17b) are connected.

  The phototransistor (19e) of the photocoupler (19c) is connected between the external power supply terminal (19a) and the ground (GND).

According to this configuration, when the first short circuit line (17a) and the second short circuit line (17b) are not connected by the short circuit connector (18a), the light emitting diode (19d) does not emit light, and the phototransistor (19e) Do not work. For this reason, the ground (GND) and the external power supply terminal (19a) are electrically disconnected from each other. On the other hand, when the first short circuit line (17a) and the second short circuit line (17b) are connected by the short circuit connector (18a), the light emitting diode (19d) emits light and the phototransistor (19e) operates. The ground (GND) and the external power supply terminal (19a) are electrically connected. Therefore, a high level voltage is input to the MPU (19b) when the first short circuit line (17a) and the second short circuit line (17b) are not connected by the short circuit connector (18a), and the short circuit connector (18a). Thus, when the first short circuit line (17a) and the second short circuit line (17b) are connected, a low level voltage is input. Therefore, the MPU (19b) detects that both short-circuit lines (17a, 17b) of the auxiliary circuit (17) are connected when a low level voltage is input.
<< Other Embodiments >>
The present invention may be configured as follows for the above embodiment.

  That is, in the determination process of whether or not to transition to the suspended state, it is determined that the outdoor unit (10), the indoor unit (20), and the remote controller (30) can be shifted to the suspended state only when the standby power compatible model is used. This is not necessary from the viewpoint of detecting a setting error of the forced activation mechanism. Specifically, in FIG. 12, when the model specification information of the outdoor unit (10) and the remote controller (30) is not acquired in step S1a, and the indoor unit (20) is a standby power compatible model in step S1b, On the other hand, when the indoor unit (20) is a model that does not support standby power, it is determined that transition to the suspended state is impossible.

  In addition, the indoor control circuit (23) detects a setting error of the forced activation mechanism (16) (connection error of the auxiliary circuit (17)), but this is not a limitation. For example, the outdoor control circuit (13) is forced You may make it detect the setting mistake of a starting mechanism (16).

  INDUSTRIAL APPLICABILITY The present invention is useful in that it can detect a setting error of the forced activation mechanism, enable smooth operation of the air conditioner, and improve reliability.

DESCRIPTION OF SYMBOLS 1 Air conditioning apparatus 10 Outdoor unit 13 Outdoor control circuit 17 Auxiliary circuit 17a 1st short circuit line 17b 2nd short circuit line 18 Connection part 18a Connector 19 Short circuit detection part (short circuit detection means)
19a External power supply terminal 19b Microprocessor (detection unit)
19c Photocoupler 19d Light emitting diode 19e Phototransistor 20 Indoor unit 23 Indoor control circuit (abnormality detection means, notification means)
30 Remote controller (remote control)
40 AC power supply 40a Power supply line K2R relay (starting means)
K13R relay (switch)
GND ground

Claims (4)

An air conditioner that can be used by combining an indoor unit (20) and an outdoor unit (10) with different model specifications,
An outdoor control circuit (13) provided in the outdoor unit (10) and supplied with power from an AC power supply (40) via a power supply line (40a);
A switch (K13R) that is provided in the power line (40a), shuts off the power line (40a) during operation stop, and enters a standby state in which power is not supplied to the outdoor unit (10);
An auxiliary circuit (17) including first and second short-circuit lines (17a, 17b) connected to the power line (40a) so as to bypass the switch (K13R) and separated from each other;
A connector (18a) capable of connecting the first short circuit line (17a) and the second short circuit line (17b);
A short circuit detecting means (19) for detecting that the first short circuit line (17a) and the second short circuit line (17b) are connected;
Based on at least the model specification information of the indoor unit (20), it is determined whether or not to shift to the standby state. When it is determined that the transition to the standby state is possible, the short-circuit detecting means (19) causes the first short-circuit line (17a ) And the second short-circuit line (17b), it is provided with an abnormality detection means (23) for detecting an abnormal connection of the auxiliary circuit (17) when it is detected that the second short-circuit line (17b) is connected. Air conditioner. In the air conditioning apparatus according to claim 1,
The short circuit detection means (19) is connected to the ground (GND), the external power supply terminal (19a) to which an external power supply is supplied, and the external power supply terminal (19a), and is supplied from the external power supply terminal (19a). A detection unit (19b) for detecting a power supply voltage is connected to the first short circuit line (17a) and the second short circuit line (17b), and to the ground (GND) and the external power supply terminal (19a). It has the said connector (18a) comprised, The air conditioning apparatus characterized by the above-mentioned. In the air conditioning apparatus according to claim 1,
The short circuit detection means (19) is connected to the ground (GND), the external power supply terminal (19a) to which an external power supply is supplied, and the external power supply terminal (19a), and is supplied from the external power supply terminal (19a). A detector (19b) for detecting a power supply voltage, a light emitting diode (19d) that emits light when the first short circuit line (17a) and the second short circuit line (17b) are connected, and the external power supply terminal (19a) ) And a ground (GND), and has a phototransistor (19e) operated by light of the light emitting diode (19d). In the air conditioning apparatus according to any one of claims 1 to 3,
Remote control (30),
The air further comprising notification means (23) for notifying the remote controller (30) of the connection abnormality when the abnormality detection means (23) detects a connection abnormality of the auxiliary circuit (17). Harmony device.

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