JP2009247065A - Power feeder for freezer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain an arrangement that outputs a proper fault signal while discriminating a high-voltage fault of a coolant circuit from an fault generated in a power feeder in the power feeder for feeding power to a compressor of a freezer. <P>SOLUTION: When a fault is detected in an inverter circuit (3), a fault cause decision section (33) in a microcomputer (30) for inverter decides whether the cause of the fault is caused by interruption operation of a relay (18) in the inverter circuit (3) due to a high-voltage fault in the coolant circuit or caused by an fault generated in the inverter circuit (3). The fault cause decision section (33) is configured so that the decision of the fault generated in the inverter circuit (3) is delayed during a predetermined time (T) enabling decision of the high-voltage fault and if it decided that the fault is not caused by the high-voltage fault during the predetermined time (T), the fault is decided as an fault generated in the inverter circuit (3). <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a power supply apparatus for a refrigeration apparatus, and particularly relates to the technical field of abnormality detection.

Conventionally, in order to supply power to a compressor motor in a refrigeration system, a converter circuit that converts AC power from an AC power source into DC power, and DC power from the converter circuit is converted to AC power of a predetermined frequency. 2. Description of the Related Art There is known a power supply device that includes an inverter circuit and the like. As such a power supply device, for example, as disclosed in Patent Document 1, a plurality of diodes are connected in a bridge to form a converter circuit, and a plurality of switching elements are connected in a bridge to form an inverter circuit. What constitutes is generally known.
JP 2004-222421 A

  By the way, when the power supply device as in the above conventional example is used for power supply to the compressor motor of the refrigeration apparatus, when an abnormality occurs in the power supply apparatus or the refrigeration apparatus, the motor is quickly supplied to the motor. It is necessary to stop the power supply. Specifically, when overvoltage or overcurrent is detected in the power supply device, it is necessary to stop power supply to the motor in order to protect the components in the power supply device. Even when the high pressure becomes an abnormal value in the refrigerant circuit in the refrigeration apparatus, it is necessary to stop the power supply to the motor in order to protect the components in the refrigeration apparatus.

  Generally, when a high pressure abnormality is detected in the refrigerant circuit, power supply to the motor is immediately stopped. However, when an abnormality code indicating the cause of abnormality is output after the power supply is stopped, noise or the like In order to accurately determine the high voltage abnormality without being affected by the high voltage, the detection signal is output from the high voltage switch (HPS) for a predetermined period, and only when the signal is received, the high voltage abnormality is determined, and the abnormality code Is output.

  Then, when the power supply to the motor is stopped due to the high pressure abnormality in the refrigerant circuit, the abnormality detected in the power supply device due to the stop of the power supply is detected earlier than the high pressure abnormality. Thus, it is displayed on the remote control of the refrigeration apparatus as an abnormality in the power supply apparatus. In this case, an erroneous abnormality code is notified to the worker who performs the recovery operation of the refrigeration apparatus, and it takes time to identify the cause of the abnormality, and there is a possibility that the recovery operation may be delayed.

  The present invention has been made in view of such a point, and an object of the present invention is to generate a high-pressure abnormality in a refrigerant circuit in a power supply apparatus that supplies power to a compressor of a refrigeration apparatus. It is to obtain a configuration that can output an appropriate abnormal signal by distinguishing from the abnormal.

  In order to achieve the above object, in the power supply device (1) according to the present invention, the determination that there is an abnormality in the main circuit (3) is delayed for a predetermined time (T), during which the high pressure in the refrigerant circuit is When an abnormality is confirmed, a high-voltage abnormality signal is output. When the high-voltage abnormality is not confirmed, a signal corresponding to the abnormality in the main circuit (3) is output.

  Specifically, the first invention is a power supply shut-off means for shutting off the power supply to the compressor when a high-pressure abnormality is detected on the high-pressure side in the refrigerant circuit where the refrigerant circulates by the operation of the compressor. 18) and a power supply device for a refrigeration system comprising an abnormality detection means (14, 15, 17, 30) for detecting an abnormality in the main circuit (3) for supplying power to the compressor And

  When the abnormality detection means (14, 15, 17, 30) detects an abnormality in the main circuit (3), the cause of the abnormality occurs in the high-voltage abnormality or the main circuit (3). An abnormality cause determination unit (33) for determining which one is abnormal, and a signal output unit (35, 36) for outputting a signal corresponding to the abnormality cause determined by the abnormality cause determination unit (33). The abnormality cause determination unit (33) delays the determination that the abnormality occurring in the main circuit (3) is the cause of the abnormality for a predetermined time (T) during which the determination of the high voltage abnormality can be In the case where it is not determined that the high voltage abnormality is present, it is assumed that the abnormality is in the main circuit (3).

  With the above configuration, when a high pressure abnormality is detected on the high pressure side in the refrigerant circuit, power supply to the compressor is stopped by the power supply cutoff means (18), while power is supplied to the compressor. In the power supply device (1) configured to detect an abnormality in the main circuit (3) by the abnormality detection means (14, 15, 17, 30), the abnormality determination unit (33) includes the main circuit (3 ) Is delayed for a predetermined time (T) during which the high-pressure abnormality can be determined, and if the high-voltage abnormality is determined during that time, the signal output unit (35, 36) While outputting a signal corresponding to the abnormality, if the high voltage abnormality is not determined within the predetermined time (T), it is determined that the abnormality has occurred in the main circuit (3). 18) prevents erroneous determination that the error occurred in the main circuit (3). It can be.

  Therefore, by configuring as described above, the high-pressure abnormality in the refrigerant circuit can be reliably detected, and even when both the high-pressure abnormality and the abnormality in the main circuit (3) are detected, Thus, it is possible to reliably distinguish the abnormality and output a corresponding appropriate abnormality signal. As a result, the cause of the abnormality can be grasped accurately and quickly when the refrigeration apparatus is restored, and workability can be improved.

  In the above-described configuration, the abnormality cause determination unit (33), among the abnormalities that occur in the main circuit (3), when the power supply cutoff means (18) cuts off the power supply to the compressor It is assumed that the abnormality that occurs is determined to be delayed as the cause of the abnormality for the predetermined time (T) (second invention).

  As a result, when the power supply shut-off means (18) operates due to a high-pressure abnormality in the refrigerant circuit, an abnormality is detected in the main circuit (3) due to the power supply being cut off. (3) It is possible to output a signal as a high-pressure abnormality in the refrigerant circuit without outputting a signal as an abnormality occurring in (3). That is, even when a high-pressure abnormality in the refrigerant circuit and an abnormality occurring in the main circuit (3) are likely to be erroneously detected, the two can be accurately distinguished.

  The main circuit (3) is an inverter circuit (3) that supplies electric power of a predetermined frequency to the compressor. The abnormality cause determination unit (33) and the signal output unit (35, 36) It is preferably provided in the control means (30) for driving and controlling the inverter circuit (3) (third invention). In this way, the control means (30) of the inverter circuit (3) can discriminate between a high-pressure abnormality in the refrigerant circuit and an abnormality that has occurred in the inverter circuit (3), and output a signal corresponding to each abnormality. it can. Therefore, the first and second inventions can be easily realized by devising the configuration of the control means (30) of the inverter circuit (3).

  As described above, according to the power supply device (1) of the refrigeration apparatus according to the present invention, it is determined that the abnormality has occurred in the main circuit (3), and the predetermined time (T ), If it is determined that a high voltage abnormality is detected during that time, an abnormal signal corresponding to the high voltage abnormality is output. On the other hand, if the high voltage abnormality is not determined within the predetermined time (T), the main circuit (3 ) And output a corresponding abnormality signal, so that a high-pressure abnormality in the refrigerant circuit and an abnormality that occurred in the main circuit (3) can be accurately distinguished and output. it can. Therefore, the cause of the abnormality can be grasped accurately and quickly at the time of restoration work of the refrigeration apparatus, and workability can be improved.

  Further, according to the second invention, an abnormality in the main circuit (3) that occurs when the power supply to the compressor is interrupted due to a high pressure abnormality in the refrigerant circuit has occurred in the main circuit (3). In order to delay the determination that there is an abnormality for the predetermined time (T) above, an abnormality signal in the main circuit (3) due to a high voltage abnormality is regarded as an abnormality that has occurred in the main circuit (3) by mistake. Output can be prevented. Therefore, with the above-described configuration, even when the cause of the abnormality is misleading, it is possible to accurately identify the cause of the abnormality, and it is possible to improve the workability during the recovery operation of the refrigeration apparatus with certainty.

  Further, according to the third invention, the abnormality determination and signal output as in the first and second inventions described above are performed on the abnormality determination unit (33) provided in the control means (30) of the inverter circuit (3) Since it is performed by the signal output unit (35, 36), the configurations of the first and second inventions can be easily realized with a simple configuration.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

-Overall configuration-
Embodiments of the present invention are described below. As shown in FIG. 1, the power supply device (1) according to the present embodiment includes a converter circuit (2), an inverter circuit (3) (main circuit), and a capacitor circuit (4). The converter circuit (2) has an input side connected to a commercial power supply (5) for supplying AC power, and an output side connected in parallel with the capacitor circuit (4) and the inverter circuit (3). Yes. Further, for example, an electric motor (motor) (6) of a compressor of an air conditioner is connected to the inverter circuit (3).

  The converter circuit (2) is for converting three-phase AC power output from the commercial power source (5) into DC power, and is configured as a so-called rectifier circuit. In general, the converter circuit (2) is configured by a diode bridge circuit. In this embodiment, a switching element such as an IGBT (insulated gate bipolar transistor) is three-phased to reduce harmonics. It is configured by bridge connection. In FIG. 1, the description of the bridge circuit of the switching element is omitted for the sake of simplicity.

  Further, as shown in FIG. 1, a reactor (7, 7, 7) is provided for each phase between the converter circuit (2) and the commercial power source (5). Further, a zero-cross detection circuit (11) described later (Z / C in FIG. 1) is provided between the commercial power source (5) and the reactor (7, 7, 7) so as to straddle two of the three phases. Is provided.

Further, a DCCT (8, 8) is provided between the reactor (7) and the converter circuit (2) for detecting a current i ₁ of two phases out of the three phases. The current of each phase detected by the DCCT (8, 8) is converted into a corresponding signal and then transmitted to the converter microcomputer (10), which will be described later, to control the drive of the switching element in the converter circuit (2). It is used as one of the parameters.

  Furthermore, between the reactor (7,7,7) and the DCCT (8,8), a relay (18) that cuts off the power supply to the electric motor (6) of the power supply device (1) (power supply cut-off) Means). The relay (18) is configured to cut off two-phase current among the three phases. The relay (18) is configured to cut off the current by an instruction signal from the inverter microcomputer (30) when an abnormality is detected in the inverter circuit (3) by the inverter microcomputer (30) described later. Has been. The relay (18), when a high-pressure abnormality signal is output from a high-pressure switch (hereinafter referred to as HPS) (50) that detects the pressure on the high-pressure side in the refrigerant circuit (not shown) of the refrigeration apparatus, It is configured to mechanically interrupt the current. The high voltage abnormality signal output from the HPS (50) is also input to the inverter microcomputer (30).

  The capacitor circuit (4) has two capacitors (4a, 4b) connected in series, and is connected in parallel to the converter circuit (2) and the inverter circuit (3). The capacitor circuit (4) is configured to be able to charge and discharge the DC power converted by the converter circuit (2), and to supply DC power to the inverter circuit (3) by discharging the DC power. belongs to.

  The inverter circuit (3) is for converting DC power discharged from the capacitor circuit (4) into AC power. Specifically, the inverter circuit (3) includes a plurality of switching elements connected in a three-phase bridge, and a DC voltage discharged from the capacitor circuit (4) is required for the motor (6). It is comprised so that it may convert into the alternating voltage of the frequency. The switching element used in the inverter circuit (3) is also a switching element such as an IGBT, for example, like the converter circuit (2). In FIG. Description of the configuration of is omitted.

In addition, two resistors (9, 9) connected in series between the capacitor circuit (4) and the inverter circuit (3) are connected to the capacitor circuit (4) and the inverter circuit (3). Connected in parallel. Voltage e _d between the resistors (9, 9) is detected by a voltage sensor (15), after being converted to a corresponding signal, the converter microcomputer (20), an inverter microcomputer to be described later (30), the overvoltage It is sent to the detection means (12) (OVP in FIG. 1) and the like. The resistors (9, 9) are provided so that a divided voltage is input to the voltage sensor (15).

Further, the power supply device (1) includes a shunt resistor (current sensor (16, 17)) for detecting current on the output side of the converter circuit (2) and the input side of the inverter circuit (3). 10a, 10b). Current i _d of the shunt resistor (10a) provided on the output side is measured by the current sensor (16) of the converter circuit (2) is converted to a corresponding signal, described later converter microcomputer (20 ) And overcurrent detection means (13) (OCP in FIG. 1). On the other hand, after the current i ₂ measured by the current sensor (17) in the shunt resistor (10b) provided on the input side of the inverter circuit (3) is converted into a corresponding signal, the microcomputer for inverter described later is used. (30) and overcurrent detection means (14).

  The overcurrent detection means (13, 14) is configured to be able to detect an overcurrent state. When the overcurrent state is detected, switching is performed for the converter circuit (2) and the inverter circuit (3), respectively. A compulsory signal for stopping the driving of the element is output.

  The power supply device (1) is provided with a zero cross detection circuit (11) on the input side connected to the commercial power source (5). This zero cross detection circuit (11) is provided so as to straddle two of the three phases, and is configured to detect the zero cross point of the input voltage by detecting the voltage difference between the two phases. It is. Based on the zero cross point of the input voltage detected by the zero cross detection circuit (11), the switching element of the converter circuit (2) is driven and controlled.

  The power supply device (1) having the circuit configuration as described above includes a converter microcomputer (20) for performing drive control of the switching element of the converter circuit (2) and a switching element of the inverter circuit (3). An inverter microcomputer (30) (control means) for drive control, and a control microcomputer (40) that transmits an operation control signal for the entire power supply device (1) to these microcomputers (20, 30) I have.

The converter microcomputer (20) includes a zero-cross point detected by the zero-cross detection circuit (11), a current value i ₁ on the input side detected by the DCCT (8), and a current sensor based on the shunt resistor (10a). the detected output side by (16) the current value i _d, based on such detected voltage value e _d between the resistors (9, 9), controls the driving of the switching elements of the converter circuit (2) It is configured as follows. That is, the converter microcomputer (20) generates a drive signal for the switching element based on the zero cross point, the input side and output side current values, voltage values, etc., and outputs the drive signal generation unit (21). I have.

Further, the converter microcomputer (20), based on the DC current i _d measured by the shunt resistor provided on the output side of the converter circuit (2) (10a), is configured to detect an overcurrent ing. That is, the DC current i _d measured by the shunt resistor (10a), said by an overcurrent detector (13) detects overcurrent is performed, detected to be overcurrent overcurrent detection means (13) When this is done, a drive stop forcing signal is sent from the overcurrent detection means (13) to the switching element of the converter circuit (2). Then, the converter microcomputer (20) detects that the switching element of the converter circuit (2) is not driven, and thereby recognizes that the converter microcomputer (20) is in an overcurrent state. Is done.

Further, the converter microcomputer (20), an overvoltage condition is detected on the basis of the voltage e _d between the resistors (9, 9) measured by a voltage sensor (15), so as to be input as a signal It is configured. That is, the voltage e _d measured by the voltage sensor (15) is input to the overvoltage detector (12), an overvoltage condition is detected by the overvoltage detector (12). When the overvoltage state is detected by the overvoltage detection means (12), an overvoltage signal is transmitted to the converter microcomputer (20), and the converter microcomputer (20) detects the overvoltage.

Further, the converter microcomputer (20) is configured to generate a different signal according to an abnormality occurring in the converter circuit (2). Specifically, the converter microcomputer (20) includes a signal generation unit (22) that generates a signal in response to an abnormality. In addition, abnormalities in the converter microcomputer (20) include abnormalities in the DCCT (8), current sensors (16, 17) provided in the shunt resistor (10a), and overvoltage detection means (12). when detecting an overvoltage condition, the instantaneous overcurrent state detected through the operation of the resistance (9, 9) abnormality of the voltage sensor (15) for detecting the voltage e _d between said overcurrent detection means (13) If the switching element is not synchronized with the power supply frequency (deviation between the actual zero cross point and the zero cross point detected on the microcomputer (20) side) or the input voltage is out of phase or missing, an error in the zero cross signal is detected. In such a case, there may be a case where an abnormality of the switching element is detected.

  The converter microcomputer (20) is connected to the inverter microcomputer (30) by a plurality of ports. When a signal is generated by the signal generation unit (22), a dedicated signal port is set. And transmitting a signal to the inverter microcomputer (30). Further, the converter microcomputer (20) transmits a waveform output state signal indicating the state of the output waveform from the converter circuit (2) to the inverter microcomputer (30) via a dedicated port, and An operation permission signal (a signal related to whether or not the converter circuit (2) can be driven) is received from the inverter microcomputer (30) via a dedicated port.

The inverter microcomputer (30), the output of the current sensor (17) at the output and the shunt resistance of the resistor (9, 9) a voltage sensor for detecting the voltage e _d between (15) (10b), said converter The switching element of the inverter circuit (3) is driven and controlled based on the waveform output state signal transmitted from the microcomputer (20). That is, the inverter microcomputer (30) includes a drive signal generation unit (31) that generates a drive signal for the switching element based on detected values of voltage and current.

  The inverter microcomputer (30) includes an abnormal signal generator (32) that generates an abnormal signal when an abnormality occurs in the inverter circuit (3). When an abnormal signal is generated by the abnormal signal generator (32), it is transmitted to the control microcomputer (40), and the inverter circuit (3) is driven from the control microcomputer (40) to the inverter microcomputer (30). An operation stop signal instructing the stop is output. Examples of the abnormality in the inverter circuit (3) include an abnormality of a switching element in the inverter circuit (3) and a case where an overcurrent is detected by the overcurrent detection means (14). Here, since the abnormality of the inverter circuit (3) can be detected by the overcurrent detection means (14) and the inverter microcomputer (30), the overcurrent detection means (14), the inverter microcomputer (30), the inverter The abnormality detection means according to the present invention is configured by the current sensor (17) and the voltage sensor (15) that output a current value or a current value to the microcomputer (30).

  Further, as will be described in detail later, the inverter microcomputer (30) is provided at a high pressure (a discharge side of the compressor) of a refrigerant circuit (not shown) when an abnormality occurs in the inverter circuit (3). In consideration of the output signal from the HPS (50), it is determined which part has an abnormality, and an abnormality code corresponding to the cause of the abnormality is output.

  Further, although not particularly illustrated, the inverter microcomputer (30) generates a flag and a code based on the signal transmitted from the converter microcomputer (20), and the converter circuit (2) and the inverter circuit (3) When it is necessary to stop driving, a standby request signal is generated. When the standby request signal is generated, the inverter microcomputer (30) transmits the signal to the control microcomputer (40), and the control microcomputer (40) sends the signal to the inverter microcomputer (30). An operation stop signal instructing to stop driving the converter circuit (2) and the inverter circuit (3) is output.

  Here, the inverter microcomputer (30) and the control microcomputer (40) are connected so as to be able to exchange signals by serial communication or parallel communication.

  The control microcomputer (40) is for controlling the operation of the power supply device (1). The inverter microcomputer (30) drives the converter circuit (2) and the inverter circuit (3). An operation control signal for controlling is output. Further, as described above, the control microcomputer (40) is configured to output an operation stop signal when receiving an abnormal signal or a standby request signal from the inverter microcomputer (30).

-Abnormality judgment by inverter microcomputer-
Next, the abnormality determination operation by the inverter microcomputer (30), which is a characteristic part of the present invention, will be described.

  As described above, when an abnormality occurs in the inverter circuit (3), the inverter microcomputer (30) outputs an output signal from the HPS (50) that detects the pressure of the refrigerant on the high pressure side of the refrigerant circuit (not shown). In consideration, the cause of the abnormality is determined, and the corresponding abnormality code is output.

  Here, when a high-pressure abnormality occurs on the high-pressure side in the refrigerant circuit, the signal output from the HPS (50) is a predetermined period (for example, 2 msec) per time in order to prevent erroneous detection due to noise or the like. And detected multiple times (for example, 8 times). When the inverter microcomputer (30) receives these signals, it is determined that the cause of the abnormality is a high voltage abnormality, and a corresponding abnormality code is output.

  The inverter microcomputer (30) configured to perform abnormality determination and abnormality code output as described above includes an abnormality cause determination unit (33) for determining the cause of the abnormality and the abnormality cause determination unit (33). The timer part (34) that counts a predetermined time (T) that delays the abnormality determination in the inverter circuit (3) when determining the cause of abnormality in, and the abnormality cause determined by the abnormality cause determination part (33) above An abnormal code generation unit (35) that generates an abnormal code in response to the error code, and an abnormal code output unit (36) that outputs the abnormal code generated by the abnormal code generation unit (35).

  The abnormality cause determination unit (33) is a refrigerant detected by the HPS (50) as to whether an abnormality has occurred due to the cause of the inverter circuit (3) when an abnormality occurs in the inverter circuit (3). It is configured so that it can be determined whether or not an abnormality has occurred due to a high voltage abnormality in a circuit (not shown). Specifically, when the abnormality cause determination unit (33) detects an abnormality in the inverter circuit (3), an operation of the relay circuit (18) according to the output signal of the HPS (50) causes the inverter circuit ( 3) If there is an abnormality that may occur within (hereinafter also referred to as an abnormality of the mask target), the determination of the cause of the abnormality is delayed for a predetermined time (T) (for example, 500 msec), and the output of the HPS (50) is output. The high voltage abnormality is determined based on the signal. Examples of the abnormality to be masked include undervoltage, instantaneous overcurrent, timed overcurrent, overload stop, current sensor abnormality, and the like.

  Here, the predetermined time (T) takes into account the rise time of the signal output from the HPS (50), the change of the start point of the signal due to an interrupt to the inverter microcomputer (30), etc. It is set with a sufficient margin so that the microcomputer (30) can reliably receive.

  Then, the abnormality cause determination unit (33) detects an abnormality in the inverter circuit (3), and then receives an output signal from the HPS (50) within the predetermined time (T). When the high pressure abnormality is confirmed, it is determined that the cause of the abnormality is not the abnormality of the inverter circuit (3) but the high pressure abnormality in the refrigerant circuit. On the other hand, the abnormality cause determination unit (33) does not receive the output signal from the HPS (50) within the predetermined time (T) after detecting the abnormality in the inverter circuit (3), and the refrigerant circuit If the high pressure abnormality is not determined, it is determined that the abnormality has occurred in the inverter circuit (3) after the predetermined time (T) has elapsed.

  The timer unit (34) is configured to count the predetermined time (T). That is, after an abnormality is detected in the inverter circuit (3), the time is measured by the timer unit (34), thereby making it possible to determine the cause of the abnormality according to the time as described above.

  The abnormality code generation unit (35) is configured to generate an abnormality code corresponding to the abnormality cause determined by the abnormality cause determination unit (33). Specifically, when the cause of the abnormality is an abnormality in the inverter circuit (3), the abnormality code generation unit (35) displays an abnormality code corresponding to the abnormality and the cause of the abnormality is the HPS (50). When the high pressure abnormality is detected in the refrigerant circuit, the high pressure abnormality abnormality code is generated.

  The abnormal code output unit (36) is configured to output the abnormal code generated by the abnormal code generation unit (35). The output destination of the abnormal code output unit (36) is a remote controller such as an air conditioner or a storage unit (not shown) for storing the abnormal code. The storage unit may be a storage unit (not shown) in the inverter microcomputer (30) or a storage unit (not shown) in the control microcomputer (40).

  Here, the abnormal code generation unit (35) and the abnormal code output unit (36) constitute a signal output unit according to the present invention.

  The abnormality determination operation and the abnormality code output operation by the inverter microcomputer (30) having the above-described configuration will be described based on the flow shown in FIG. 2 and the time chart shown in FIG.

  When the flow shown in FIG. 2 starts, it is first determined whether or not an abnormality is detected in the inverter circuit (3) in step S1. If it is determined in step S1 that no abnormality has been detected in the inverter circuit (3) (in the case of NO), the determination in step S1 is repeated until an abnormality is detected. If it is determined that an abnormality in the inverter circuit (3) has been detected (in the case of YES), the process proceeds to step S2 to determine whether the detected abnormality is an abnormality to be masked.

  If it is determined in step S2 that the abnormality detected in step S1 is not an abnormality to be masked (in the case of NO), the process proceeds to the subsequent step S3 and an abnormality code corresponding to the abnormality detected in step S1 is obtained. It generates and outputs this abnormal code (step S4). Thereafter, this flow is ended (END).

  On the other hand, when it is determined in step S2 that the abnormality detected in step S1 is an abnormality to be masked (in the case of YES), the process proceeds to step S5, and the predetermined time (T ) Measurement (start timer).

  Thereafter, in step S6, it is determined whether or not the predetermined time (T) (mask time) has elapsed. If it is determined in step S6 that the predetermined time (T) has elapsed (in the case of YES), the process proceeds to steps S3 and S4 to output an abnormality code corresponding to the abnormality detected in step S1. On the other hand, when it is determined that the mask time has not elapsed (in the case of NO), the process proceeds to step S7, and it is determined whether or not the high voltage abnormality is confirmed by receiving the output signal from the HPS (50). I do.

  If it is determined in step S7 that the high pressure abnormality (HPS operation) has been confirmed (YES), the abnormality factor detected in step S1 is cleared in subsequent step S8, and the high pressure abnormality (HPS operation) is detected. An abnormal code is generated (step S9), and the abnormal code is output (step S10). Thereafter, this flow is ended (END).

  On the other hand, when it is determined in step S7 that the high pressure abnormality (HPS operation) has not been established (in the case of NO), the process returns to step S6 and the predetermined time (T) (mask time) has elapsed. Until this is done, the determination of the high pressure abnormality (HPS operation) in step S7 is performed.

  An example of the abnormality determination operation and the abnormality code output operation by the inverter microcomputer (20) as described above will be described based on the time chart shown in FIG.

  In the example of FIG. 3 described above, first, when the HPS (50) is activated at t1 and a high pressure abnormality is detected in the refrigerant circuit, the relay (18) is turned off (cut off). Thereby, although not particularly shown, a signal is output from the HPS (50). As described above, the state (OFF state in FIG. 3) in which the operation (high pressure abnormality) of the HPS (50) is not confirmed is continued until the signal output from the HPS (50) is detected a plurality of times. The

  As described above, when the relay (18) is cut off, no current flows through the inverter circuit (3). Therefore, the inverter microcomputer (30) detects an abnormality in the inverter circuit (3) at t2. Since the abnormality of the inverter circuit (3) detected at this time is an abnormality to be masked, the determination of the cause of the abnormality is delayed for a predetermined time (T). In order to count this predetermined time (T), the timer unit (34) operates at t2.

  The inverter microcomputer (30) detects the signal output from the HPS (50) a plurality of times, and when the predetermined time (T) has elapsed, the operation of the HPS (50) is confirmed at t3. (ON state in FIG. 3), an abnormal code of high voltage abnormality is generated by the abnormal code generation unit (35), and the abnormal code is output by the abnormal code output unit (36).

  When the HPS (50) does not operate or when the operation of the HPS (50) is not confirmed within the predetermined time (T), the inverter microcomputer (30 ) Is output at t4 after the predetermined time (T) has elapsed (indicated by a two-dot chain line in FIG. 3).

-Effect of the embodiment-
As described above, according to this embodiment, when an abnormality is detected in the inverter circuit (3), the abnormality is detected by the HPS (50) as a high-pressure abnormality in the refrigerant circuit, and the relay (18) is in a cut-off state. If there is an abnormality that occurs in the case of an abnormality (mask target abnormality), the cause of the abnormality is delayed for a predetermined time (T), during which the operation of the HPS (50) is confirmed, that is, a high-pressure abnormality is confirmed. In this case, an abnormal code corresponding to the abnormality in the inverter circuit (3) is output when the high voltage abnormality is not determined within the predetermined period while the abnormal code of the high voltage abnormality is generated. Even if it takes time to determine the operation of the HPS (50) and an abnormality in the inverter circuit (3) is detected first, the operation of the HPS (50) can be reliably detected. In the inverter circuit (3) Rather than fault code can be output reliably abnormality code of the high-pressure abnormality.

  Therefore, when an abnormality occurs in the inverter circuit (3) and when the high-pressure abnormality in the refrigerant circuit is detected by the HPS (50), an appropriate abnormality code is output. can do. Thereby, at the time of restoration work of the refrigeration apparatus, the operator can grasp an accurate abnormality code, and the workability at the time of restoration work can be improved.

<< Other Embodiments >>
About the said embodiment, it is good also as following structures.

  In the above embodiment, the IGBT is used as the switching element constituting the converter circuit (2) and the inverter circuit (3). However, the present invention is not limited to this. For example, a switching element having another configuration such as a MOS-FET may be used. Good.

  Moreover, in the said embodiment, it is comprised so that abnormality determination may be delayed only in the case of abnormality of a mask object among abnormality detected in an inverter circuit (3), but it is not this limitation, For example, an inverter You may make it delay abnormality determination about all the abnormality detected in the circuit (3).

  As described above, the present invention is particularly useful for a power supply device for supplying power to a refrigeration apparatus including a refrigerant circuit.

FIG. 1 is a circuit diagram showing a schematic configuration of a power supply apparatus according to an embodiment of the present invention. FIG. 2 is a flowchart showing the flow of the abnormality determination operation and the abnormality code output operation. FIG. 3 is a time chart illustrating an example of an abnormality determination operation and an abnormality code output operation.

Explanation of symbols

1 Power supply device 2 Converter circuit 3 Inverter circuit (main circuit)
4 Capacitor circuit 5 Commercial power supply (AC power supply)
6 Motor 14 Overcurrent detection means (abnormality detection means)
15 Voltage sensor (abnormality detection means)
16 Current sensor 17 Current sensor (abnormality detection means)
18 Relay (Power supply cutoff means)
20 Microcomputer for converter 21 Drive signal generation unit 22 Signal generation unit 30 Microcomputer for inverter (abnormality detection means, control means)
31 Drive signal generation unit 32 Abnormal signal generation unit 33 Abnormal cause determination unit 34 Timer unit 35 Abnormal code generation unit (signal output unit)
36 Abnormal code output part (signal output part)
40 Control microcomputer 50 HPS

Claims (3)

When a high-pressure abnormality is detected on the high-pressure side in the refrigerant circuit where the refrigerant circulates due to the operation of the compressor, power supply shut-off means (18) for shutting off the power supply to the compressor and supplying power to the compressor A power supply device for a refrigeration system comprising abnormality detection means (14, 15, 17, 30) for detecting an abnormality in the main circuit (3)
When an abnormality in the main circuit (3) is detected by the abnormality detection means (14, 15, 17, 30), the cause of the abnormality is the high voltage abnormality or an abnormality that has occurred in the main circuit (3). An abnormality cause determination unit (33) for determining which is,
A signal output unit (35, 36) for outputting a signal corresponding to the abnormality cause determined by the abnormality cause determination unit (33),
The abnormality cause determination unit (33) delays the determination that the abnormality occurring in the main circuit (3) is the cause of the abnormality by a predetermined time (T) during which the determination of the high pressure abnormality is possible, A power supply device for a refrigeration apparatus, wherein the power supply device is configured to determine that there is an abnormality in the main circuit (3) when it is not determined that the high voltage abnormality has occurred. In claim 1,
The abnormality cause determination unit (33) is an abnormality that occurs when the power supply shut-off means (18) shuts off the power supply to the compressor among the abnormalities that occur in the main circuit (3). A power supply device for a refrigeration apparatus, configured to delay the determination as the cause of abnormality for the predetermined time (T). In claim 1 or 2,
The main circuit (3) is an inverter circuit (3) that supplies electric power of a predetermined frequency to the compressor,
The abnormality cause determination unit (33) and the signal output unit (35, 36) are provided in a control means (30) for driving and controlling the inverter circuit (3), and the power supply for the refrigeration apparatus apparatus.

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