JP2020171101A - Air conditioning system control device, air conditioning system control method and program - Google Patents

Abstract

To provide a control device of an air conditioning system capable of appropriately suppressing the consumption of the life of an electrolytic capacitor mounted on a power conversion circuit.SOLUTION: An air conditioning system comprises: a rectifier that converts AC power from commercial power to DC power; an inverter that converts the DC power into AC power for driving a motor; and an electrolytic capacitor that smooths the DC power. A control device of the air conditioning system comprises: a life calculation unit that calculates an instantaneous estimated life of the electrolytic capacitor during operation on the basis of a measured value of a ripple current input to the electrolytic capacitor; a cumulative life consumption rate calculation unit that calculates the cumulative life consumption rate for each cumulative operation time on the basis of the instantaneous estimated life; and a rotation speed command output unit that outputs a rotation speed command of a motor according to set temperature set by a user. The rotation speed command output unit reduces the rotation speed command such that the cumulative life consumption rate does not exceed a predetermined upper limit value.SELECTED DRAWING: Figure 1

Description

The present invention relates to a control device for an air conditioning system, a control method and a program for the air conditioning system.

The air conditioning system (air conditioning system) includes a power conversion circuit that converts three-phase AC power input from an input power source (commercial power source) into AC power for driving a motor. This power conversion circuit has a large weight ratio of passive elements such as a reactor (reactor) and an electrolytic capacitor, and there is a demand for miniaturization and weight reduction of these electrical components. However, if the size of the reactor and the electrolytic capacitor is reduced, the life of the electrolytic capacitor may be shortened.

It is known that the life of an electrolytic capacitor largely depends on the ambient temperature of the electrolytic capacitor and the ripple current input to the electrolytic capacitor. This ripple current increases significantly, especially when a voltage imbalance of three-phase AC power from the input power source occurs.

Patent Document 1 describes a life-prolonging device capable of accurately determining whether or not life-prolonging measures for a capacitor are necessary by using the amount of drop in the output voltage of the power supply circuit.

JP-A-2016-217986

In the above-mentioned air conditioning system, there is a demand for a function capable of appropriately suppressing the consumption of the life of the electrolytic capacitor mounted on the power conversion circuit.

An object of the present invention is to provide a control device for an air conditioning system, a control method and a program for the air conditioning system, which can appropriately suppress the consumption of the life of the electrolytic capacitor mounted on the power conversion circuit.

According to the first aspect of the present invention, the control device of the air conditioning system includes a rectifier that converts AC power from a commercial power source into DC power, an inverter that converts the DC power into AC power for driving a motor, and the above. A control device for an air conditioning system including an electrolytic capacitor that smoothes DC power, and calculates an instantaneous estimated life of the electrolytic capacitor during operation based on a measured value of a ripple current input to the electrolytic capacitor. The life calculation unit, the cumulative life consumption rate calculation unit that calculates the cumulative life consumption rate for each cumulative operation time based on the instantaneous estimated life, and the motor rotation speed command according to the set temperature set by the user. The rotation speed command output unit includes a rotation speed command output unit to output, and the rotation speed command output unit reduces the rotation speed command so that the cumulative life consumption rate does not exceed a predetermined upper limit value.

According to the second aspect of the present invention, the upper limit value is set to be proportional to the cumulative operation time by a predetermined coefficient.

According to the third aspect of the present invention, the upper limit value can be changed by the user.

According to the fourth aspect of the present invention, the control method of the air conditioning system includes a rectifier that converts AC power from a commercial power source into DC power, an inverter that converts the DC power into AC power for driving a motor, and the above. It is a control method of an air conditioning system including an electrolytic capacitor for smoothing DC power, and calculates an instantaneous estimated life of the electrolytic capacitor during operation based on a measured value of a ripple current input to the electrolytic capacitor. There are a step, a step of calculating the cumulative life consumption rate for each cumulative operation time based on the instantaneous estimated life, and a step of outputting a motor rotation speed command according to a set temperature set by the user. Then, in the step of outputting the rotation speed command, the rotation speed command is reduced so that the cumulative life consumption rate does not exceed a predetermined upper limit value.

According to the first aspect of the present invention, the program smoothes the rectifier that converts the AC power from the commercial power source into the DC power, the inverter that converts the DC power into the AC power for driving the motor, and the DC power. A step of calculating the instantaneous estimated life of the electrolytic capacitor during operation based on the measured value of the ripple current input to the electrolytic capacitor in the control device of the air conditioning system including the electrolytic capacitor, and the instantaneous estimation. A step of calculating the cumulative life consumption rate for each cumulative operating time based on the life and a step of outputting a motor rotation speed command according to a set temperature set by the user are executed, and the rotation speed command is executed. In the step of outputting the above, the rotation speed command is reduced so that the cumulative life consumption rate does not exceed a predetermined upper limit value.

According to at least one of the above aspects, the consumption of the life of the electrolytic capacitor mounted on the power conversion circuit can be appropriately suppressed.

It is a figure which shows the whole structure of the air-conditioning system which concerns on 1st Embodiment. It is a figure which shows the functional structure of the system control part which concerns on 1st Embodiment. It is a figure which shows the functional structure of the motor control part which concerns on 1st Embodiment. It is a figure explaining the function of the low frequency ripple current measuring part which concerns on 1st Embodiment. It is a figure explaining the function of the high frequency ripple current measuring part which concerns on 1st Embodiment. It is a figure for demonstrating the function of the cumulative life consumption rate calculation unit which concerns on 1st Embodiment. It is a figure for demonstrating the function of the cumulative life consumption rate calculation unit which concerns on 1st Embodiment. It is a figure for demonstrating the function of the rotation speed command output part which concerns on 1st Embodiment. It is a figure for demonstrating the function of the rotation speed command output part which concerns on the modification of 1st Embodiment.

<First Embodiment>
Hereinafter, the life prediction device according to the first embodiment and the air conditioning system including the life prediction device will be described with reference to FIGS. 1 to 7.

(Overall configuration of air conditioning system)
FIG. 1 is a diagram showing an overall configuration of an air conditioning system according to the first embodiment.
The air conditioning system 1 shown in FIG. 1 is a system mounted on an outdoor unit to rotate and drive a compressor. Note that in FIG. 1, the illustration of the compressor and the like is omitted.

The air conditioning system 1 according to the present embodiment includes a power conversion circuit 10 and a control device 11. The power conversion circuit 10 is a circuit that is connected to the AC power supply PS and converts the three-phase AC power input from the AC power supply PS into AC power for driving the motor 102. The AC power supply PS is a general commercial power system that outputs three-phase AC power. The motor 102 is, for example, a three-phase AC motor that rotationally drives a compressor.
In the following description, in each configuration of the power conversion circuit 10, the side close to the AC power supply PS is also referred to as “upstream side”, and the side close to the motor 102 is also referred to as “downstream side”.

The configuration of the power conversion circuit 10 will be described.
As shown in FIG. 1, the power conversion circuit 10 includes a rectifier 100, an inverter 101, and a motor 102.

The rectifier 100 is, for example, a diode module, which converts three-phase AC power input from the AC power supply PS into DC power.

The inverter 101 is, for example, an IPM (Intelligent Power Module), and generates three-phase AC power for driving a motor from DC power by switching (ON / OFF) operation of an internal power transistor. The inverter 101 performs a switching operation according to a drive command (PWM (Pulse Width Modulation) signal) from the control device 11 (motor control unit 111 described later).

As shown in FIG. 1, the high potential side output of the rectifier 100 is connected to the high potential terminal Tp of the inverter 101 through the high voltage line P. Further, the low potential side output of the rectifier 100 is connected to the low potential terminal Tn of the inverter 101 through the low voltage line N. A reactor L and a smoothing capacitor FC for smoothing the DC power output by the rectifier 100 are connected to the high voltage line P and the low voltage line N.
The reactor L is a passive element for smoothing the DC power output from the rectifier 100, and is connected to the downstream side of the rectifier 100 and the upstream side of the smoothing capacitor FC on the high voltage line P.
The smoothing capacitor FC is a passive element for smoothing the DC power output from the rectifier 100, and has a high voltage line P and a low voltage line N on the downstream side of the reactor L and the upstream side of the inverter 101. Connected in between. The smoothing capacitor FC is an electrolytic capacitor. A ripple current is input to the smoothing capacitor FC. It is known that the magnitude of this ripple current has a great influence on the life of the smoothing capacitor FC. The ripple current input to the smoothing capacitor FC includes the low frequency ripple current IL (first ripple current) input from the rectifier 100 side and the high frequency ripple current IH (second ripple current) input from the inverter 101 side. ). The frequency of the low-frequency ripple current IL is a frequency that depends on the power supply frequency of the AC power supply PS, and varies at a frequency of, for example, about 300 Hz. The high-frequency ripple current IH is a frequency that depends on the frequency of the switching operation of the inverter 101, and has, for example, a frequency of several kHz to several tens of kHz.

Further, a snubber capacitor SC is connected between the high potential terminal Tp and the low potential terminal Tn of the inverter 101. The snubber capacitor SC alleviates the spike current generated due to the switching operation of the inverter 101.

The power conversion circuit 10 further includes a current sensor SE1 (first current sensor) and current sensors SE2-1 and SE2-2 (second current sensor).
The current sensor SE1 is provided on the high voltage line P connecting the rectifier 100 and the reactor L, and detects the reactor current IDC (direct current) flowing from the rectifier 100 to the inverter 101.
The current sensors SE2-1 and SE2-2 are provided in two phases (U phase and W phase in the example of FIG. 1) of the wiring connecting the inverter 101 and the motor 102, and detect the motor current IM.
The current sensor SE1 and the current sensors SE2-1 and SE2-2 may be, for example, a clamp type current sensor. The current detection signals output from the current sensor SE1 and the current sensors SE2-1 and SE2-2 are input to the control device 11 (motor control unit). The control device 11 sequentially samples and acquires the reactor current value, which is the measured value of the reactor current IDC, and the motor current value, which is the measured value of the motor current IM, based on the detection signals input from each current sensor. ..

The configuration of the control device 11 will be described.
As shown in FIG. 1, the control device 11 includes a system control unit 110 and a motor control unit 111 that outputs a drive command to the inverter 101 to control the drive of the motor 102. The system control unit 110 and the motor control unit 111 may be processors such as a microcontroller, respectively.
The control device 11 according to the present embodiment functions as a life prediction device for predicting the life of the smoothing capacitor FC, as will be described later.

The system control unit 110 controls the entire operation of the air conditioning system 1. The system control unit 110 inputs the set temperature T * set by the user of the air conditioning system 1 and the current observation temperature T acquired through the temperature sensor from the outside (indoor unit controller), and responds to these values. The rotation speed command RPS * is output to the motor control unit 111.

The motor control unit 111 outputs a drive command to the inverter 101 so that the rotation speed corresponds to the rotation speed command RPS * input from the system control unit 110. The motor control unit 111 also refers to the motor current value acquired through the current sensors SE2-1 and SE2-2 when outputting the drive command.

The motor control unit 111 outputs the reactor current value acquired through the current sensor SE1 and the motor current value acquired through the current sensors SE2-1 and SE2-2 to the system control unit 110. Then, the system control unit 110 performs a protection operation based on these current values input from the motor control unit 111. The "protective operation" is a function for preventing deterioration or damage of circuit parts due to heat generated by a large current. The system control unit 110 rotates the system control unit 110 in order to reduce the load on the power conversion circuit 10 when the reactor current value or the motor current value input from the motor control unit 111 exceeds a predetermined threshold value for each. Perform a protective action to reduce the command RPS *.

Further, the motor control unit 111 according to the first embodiment measures the low frequency ripple current IL input to the smoothing capacitor FC and the high frequency ripple current IH input from the inverter 101 side, respectively, and measures each measured value. Output to the system control unit 110. The system control unit 110, which has input the measured values of the low frequency ripple current IL and the high frequency ripple current IH, predicts the life of the smoothing capacitor FC using these measured values.
Hereinafter, the above-mentioned functions of the system control unit 110 and the motor control unit 111 will be described in detail.

(Functional configuration of control device)
FIG. 2 is a diagram showing a functional configuration of the system control unit according to the first embodiment.

The functional configuration of the system control unit 110 will be described with reference to FIG.
As shown in FIG. 2, the system control unit 110 functions as a rotation speed command output unit 1100, a life calculation unit 1101, and a cumulative life consumption rate calculation unit 1102 by operating according to a predetermined program.

The rotation speed command output unit 1100 outputs the rotation speed command RPS * based on the set temperature T * and the observed temperature T. Further, the rotation speed command output unit 1100 has a function of reducing the rotation speed command RPS * based on the life consumption suppression operation. Here, the "lifetime consumption suppression operation" is an operation different from the above-mentioned protection operation, and is an operation for suppressing excessive consumption of the life of the smoothing capacitor FC. Specifically, the operation of limiting the rotation speed command RPS * so that the cumulative life consumption rate does not exceed the upper limit value (cumulative life consumption rate upper limit value) specified in advance for each cumulative operation time. Point to. The details of this life consumption suppression operation will be described later.
The life calculation unit 1101 calculates the life of the smoothing capacitor FC by substituting the total ripple current value (measured value of the total ripple current) input from the motor control unit 111 into a predetermined life calculation formula.
The cumulative life consumption rate calculation unit 1102 calculates the cumulative life consumption rate of the smoothing capacitor FC based on the life calculation result (instantaneous estimated life) sequentially calculated by the life calculation unit 1101 during operation.

FIG. 3 is a diagram showing a functional configuration of the motor control unit according to the first embodiment.
The functional configuration of the motor control unit 111 will be described with reference to FIG.
As shown in FIG. 3, the motor control unit 111 operates according to a predetermined program, so that the drive command output unit 1110, the low frequency ripple current measurement unit 1111, the high frequency ripple current measurement unit 1112, and the total ripple current calculation unit Demonstrate the function as 1113.

The drive command output unit 1110 is a measured value (motor current value) of the motor current IM acquired through the rotation speed command RPS * input from the system control unit 110 and the current sensors SE2-1 and SE2-2 (FIG. 1). ), A drive command is output to the inverter 101. The drive command output unit 1110 according to the present embodiment outputs the applied modulation factor to the high frequency ripple current measurement unit 1112 as a result of the drive command output to the inverter 101. Here, the "modulation rate" is a motor that the inverter 101 applies to each phase of the motor 102 with respect to the DC voltage VDC [V] (FIG. 1) applied between the high voltage line P and the low voltage line N. It means the ratio of the peak values (√2 · VM) of the line voltage VM [Vrms] (FIG. 1). For example, when the peak value (√2 · VM) of the motor line voltage VM matches the DC voltage VDC, the modulation factor is 100%. The drive command output unit 1110 calculates the modulation factor achieved when the inverter 101 is driven by the drive command currently being output, and outputs the modulation factor to the high-frequency ripple current measurement unit 1112.

The low-frequency ripple current measuring unit 1111 measures the low-frequency ripple current IL input to the smoothing capacitor FC from the rectifier 100 side.

The high-frequency ripple current measuring unit 1112 measures the high-frequency ripple current IH input to the smoothing capacitor FC from the inverter 101 side. Specifically, the high-frequency ripple current measuring unit 1112 acquires the motor current value, which is the measured value of the motor current IM, through the current sensors SE2-1 and SE2-2. Then, the high-frequency ripple current measuring unit 1112 specifies the measured value of the high-frequency ripple current IH with reference to the ripple current table tb prepared in advance. Here, the ripple current table tb is an information table in which the relationship between the modulation factor applied in the operation of the inverter 101 based on the drive command, the motor current value, and the high frequency ripple current IH value is defined. ..

The total ripple current calculation unit 1113 calculates the total ripple current input to the smoothing capacitor FC based on the measured value of the low frequency ripple current IL and the measured value of the high frequency ripple current IH. The specific calculation method of the total ripple current will be described later.

(Function of low frequency ripple current measurement unit)
FIG. 4 is a diagram illustrating the function of the low frequency ripple current measuring unit according to the first embodiment.
The function of the low-frequency ripple current measuring unit 1111 of the motor control unit 111 will be described in detail with reference to FIG.

FIG. 4 shows a case where the AC power input from the AC power supply PS is balanced (when the power supply is balanced) and a case where the AC power input from the AC power supply PS is unbalanced (when the power supply is unbalanced). The waveforms of the reactor current IDC, the time average value IDC_avg of the reactor current IDC, and the low frequency ripple current IL in the case are shown.

The procedure for processing the low-frequency ripple current measuring unit 1111 will be described.
First, the low-frequency ripple current measuring unit 1111 sequentially samples, acquires, and accumulates the measured value [A] (reactor current value) of the reactor current IDC through the current sensor SE1 (step S1). This reactor current IDC is the current immediately after the three-phase AC power from the AC power supply PS is rectified by the rectifier 100. Therefore, the waveform of the reactor current IDC contains both an AC component and a DC component, as shown in FIG.

Next, the low-frequency ripple current measuring unit 1111 calculates the time average value IDC_avg [A], which is the average value for the most recent predetermined time among the measured values of the reactor current IDC acquired and accumulated in step S1 (step). S2). For the above-mentioned predetermined time for calculating the average value, for example, even when the power supply is unbalanced (when the AC component increases significantly) as shown on the right side of FIG. It is preferably a constant time (for example, 100 msec or more). The time average value IDC_avg [A] calculated in this way has a waveform substantially equivalent to the DC component of the reactor current IDC. That is, the time average value IDC_avg obtained by the calculation can be regarded as the DC component of the reactor current IDC.

Next, the low-frequency ripple current measuring unit 1111 performs a calculation of sequentially subtracting the time mean value IDC_avg [A] calculated in step S2 from the measured value [A] of the reactor current IDC acquired and accumulated in step S1 (step). S3). As shown in FIG. 4, the value calculated in this way becomes equivalent to the AC component of the reactor current IDC, and can be regarded as the low-frequency ripple current IL. Therefore, the low-frequency ripple current measuring unit 1111 outputs the current value [Arms] obtained by subtracting the time mean value IDC_avg from the measured value of the reactor current IDC as the measured value of the low-frequency ripple current IL.

The low-frequency ripple current measuring unit 1111 sequentially outputs the measured value of the low-frequency ripple current IL while repeating the processes of steps S1 to S3.

(Function of high frequency ripple current measurement unit)
FIG. 5 is a diagram illustrating the function of the high frequency ripple current measuring unit according to the first embodiment.
The function of the high-frequency ripple current measuring unit 1112 of the motor control unit 111 will be described in detail with reference to FIG.

FIG. 5 is a diagram showing an example of the ripple current table tb.
The ripple current table tb shows the relationship between the modulation factor (horizontal axis) applied to the operation of the inverter 101, the high-frequency ripple current [Arms] (vertical axis), and the motor current IM [Arms] (each series in the graph). It is a figure which shows. Such a ripple current table tb is created in advance by actual measurement, circuit simulation, or the like.

The high frequency ripple current measuring unit 1112 acquires the modulation factor from the drive command output unit 1110. Further, the high frequency ripple current measuring unit 1112 acquires the motor current value through the current sensors SE2-1 and SE2-2. Then, the high-frequency ripple current measuring unit 1112 specifies the high-frequency ripple current value [Arms] from the ripple current table tb by using the obtained modulation factor and the motor current value. The high-frequency ripple current measuring unit 1112 outputs the high-frequency ripple current value thus specified as the measured value.

(Function of total ripple current calculation unit)
The total ripple current calculation unit 1113 of the motor control unit 111 has a low frequency ripple current measurement value [Arms] input from the low frequency ripple current measurement unit 1111 and a high frequency ripple current measurement value input from the high frequency ripple current measurement unit 1112. The measured value [Arms] (total ripple current value) of the total ripple current is calculated using [Arms]. Specifically, the total ripple current calculation unit 1113 calculates the following equation (1).

In the formula (1), the reference numeral "In" is the total ripple current value [Arms], and the reference numerals "IL" and "IH" are the measured value of the low frequency ripple current [Arms] and the measurement of the high frequency ripple current, respectively. The value is [Arms].

(Function of life calculation unit)
Next, the function of the life calculation unit 1101 of the system control unit 110 will be described in detail.
The life calculation unit 1101 of the system control unit 110 calculates the life of the smoothing capacitor FC based on the measured value [Arms] of the ripple current input from the motor control unit 111 (total ripple current calculation unit 1113). Specifically, the life calculation unit 1101 substitutes the measured value of the ripple current input from the motor control unit 111 into the equations (2) and (3).

Equation (2) is an example of a lifetime calculation equation for a smoothing capacitor FC (electrolytic capacitor). The reference numeral “Ln” in the equation (2) is the life [Hour] of the smoothing capacitor FC, and is based on “Tn” which is the ambient temperature of the smoothing capacitor FC and “Δtn” which is a variable depending on the ripple current. It is decided. Note that "α" is a constant value. The ambient temperature Tn is acquired through a temperature sensor included in the air conditioning system 1.

The variable “Δtn” is represented by the equation (3).

In the equation (3), “In” is the total ripple current value [Arms], and the value measured from the motor control unit 111 is substituted. Further, in the equation (3), “Δt0” is the temperature rise value at the time of rated ripple, “Im” is the rated ripple current, “K (f)” is the ripple current frequency correction coefficient, and “K (r)” is the temperature correction. It is a coefficient, and any of them may be a constant.

The life calculation unit 1101 substitutes the total ripple current value sequentially input from the motor control unit 111 into the equation (3), and sequentially calculates the life Ln [Hour] based on the total ripple current value. The life Ln calculated sequentially in this way is also referred to as an instantaneous estimated life.

(Function of cumulative life consumption rate calculation unit)
6 and 7 are diagrams for explaining the function of the cumulative life consumption rate calculation unit according to the first embodiment.
Hereinafter, the function of the cumulative life consumption rate calculation unit 1102 of the system control unit 110 will be described in detail with reference to FIGS. 6 and 7.

FIG. 6 shows a graph G1 showing the transition of the instantaneous estimated life, which is sequentially calculated by the life calculation unit 1101. Hereinafter, the instantaneous estimated life will be described as the instantaneous estimated life G1.
As shown in FIG. 6, the cumulative life consumption rate calculation unit 1102 divides the cumulative operating time of the air conditioning system 1 into sections for each predetermined unit time (for example, 1 hour), and the sections (A section, B section, Calculate the life consumption rate [%] for each C section, D section, ...). The cumulative life consumption rate calculation unit 1102 sets the minimum value of the instantaneous estimated life G1 observed in the section as the representative life of the smoothing capacitor FC in the section. In the case of the example shown in FIG. 6, since the minimum value of the instantaneous estimated life G1 observed in the section A is 30,000 hours, the typical life of the smoothing capacitor FC in the section A is 30,000 hours. Similarly, since the minimum value of the instantaneous estimated life G1 observed in the B section is 60,000 hours, the representative life of the smoothing capacitor FC in the B section is 60,000 hours. Similarly, since the minimum value of the instantaneous estimated life G1 observed in the C section is 20,000 hours, the representative life of the smoothing capacitor FC in the C section is 20,000 hours. Similarly, since the minimum value of the instantaneous estimated life G1 observed in the D section is 70,000 hours, the representative life of the smoothing capacitor FC in the D section is 70,000 hours.

Next, the cumulative life consumption rate calculation unit 1102 calculates the life consumption rate [%] in each section (A section, B section, C section, D section, ...). The life consumption rate is the ratio of the consumed life to the total life (representative life for each section) of the smoothing capacitor FC. For example, in the section A, one hour out of the representative life of 30,000 hours was used, so that the life consumption rate of the smoothing capacitor FC is 1 [Hour] / 30,000 [Hour] × 100 = 0.00333%. Similarly, in the B section, one hour out of the representative life of 60,000 hours was used, so that the life consumption rate of the smoothing capacitor FC is 1 [Hour] / 60,000 [Hour] × 100 = 0.00167%. .. Similarly, in the C section, one hour out of the representative life of 20,000 hours was used, so that the life consumption rate of the smoothing capacitor FC is 1 [Hour] / 20000 [Hour] × 100 = 0.005%. .. Similarly, in the D section, one hour out of the representative life of 70,000 hours was used, so that the life consumption rate of the smoothing capacitor FC is 1 [Hour] / 70000 [Hour] × 100 = 0.00143%. ..

As shown in FIG. 7, the cumulative life consumption rate calculation unit 1102 integrates the life consumption rates calculated for each section and calculates the cumulative life consumption rate. Graph G2 shown in FIG. 7 shows the transition of the cumulative life consumption rate. Hereinafter, the cumulative life consumption rate is also referred to as the cumulative life consumption rate G2.

(Function of rotation speed command output unit)
FIG. 8 is a diagram for explaining the function of the rotation speed command output unit according to the first embodiment.
Hereinafter, the life consumption suppression operation by the rotation speed command output unit 1100 will be described in detail with reference to FIG.

The rotation speed command output unit 1100 of the system control unit 110 determines the rotation speed command RPS * based on the life consumption suppression operation. Here, the rotation speed command output unit 1100 has a predetermined cumulative life consumption rate upper limit value Gth. The cumulative life consumption rate upper limit value Gth is an upper limit value of the cumulative life consumption rate G2 determined for each cumulative operation time. The cumulative life consumption rate upper limit value Gth is based on the target life, which is the target value of the cumulative operation time that can be operated without failure, and its slope (that is, the rate of increase of the cumulative life consumption rate upper limit value Gth per unit operation time) is "100". It is defined by a straight line that gives "% / target life". For example, when the target life is set to "30,000 hours", the cumulative life consumption rate upper limit value Gth is defined by a straight line having a slope of "100% / 30,000 hours" as shown in FIG.

The rotation speed command output unit 1100 suppresses (reduces) the rotation speed command RPS * so that the cumulative life consumption rate G2 input from the cumulative life consumption rate calculation unit 1102 does not exceed the cumulative life consumption rate upper limit value Gth. To do. By suppressing the rotation speed command RPS *, the rotation speed of the motor 102 is reduced, and the reactor current IDC and the motor current IM are reduced accordingly. Further, by reducing the reactor current IDC and the motor current IM, the total ripple current In is also reduced. As a result, the pace of increase in the cumulative life consumption rate can be suppressed.

However, the air conditioning system 1 should be operated to satisfy the user's request (set temperature T *) as long as the cumulative life consumption rate G2 does not exceed the cumulative life consumption rate upper limit value Gth. Therefore, the rotation speed command output unit 1100 considers the cumulative life consumption rate G2 accumulated up to the current section and the cumulative life consumption rate upper limit value Gth applied to the next section, and by the next section. Outputs the maximum rotation speed command RPS * that does not exceed the permissible cumulative life consumption rate G2 increase pace.

Further, according to the equation (2), the instantaneous estimated life of the smoothing capacitor FC also depends on the ambient temperature Tn. Therefore, when the ambient temperature Tn drops during operation, there is a margin for increasing the total ripple current by that amount. Therefore, in this case, the rotation speed command output unit 1100 relaxes the suppression of the rotation speed command RPS * according to the decrease in the ambient temperature Tn as long as the cumulative life consumption rate G2 does not exceed the cumulative life consumption rate upper limit value Gth. Let me.

(Action, effect)
As described above, the control device 11 (life prediction device) according to the first embodiment includes a rectifier 100 that converts AC power from the AC power source PS, which is a commercial power source, into DC power, and the DC power for driving the motor. It is provided between the inverter 101 that converts AC power and functions as a device for predicting the life of an electrolytic capacitor (smoothing capacitor FC) that smoothes the DC power.
The control device 11 measures the low-frequency ripple current measuring unit 1111 that measures the low-frequency ripple current IL input to the smoothing capacitor FC from the rectifier 100 side, and the high-frequency ripple current IH that is input to the smoothing capacitor FC from the inverter 101 side. High-frequency ripple current measuring unit 1112, and total ripple current calculating unit 1113 that calculates the total ripple current In input to the smoothing capacitor FC based on the measured values of the low-frequency ripple current IL and the high-frequency ripple current IH. It is provided with a life calculation unit 1101 for calculating the life of the smoothing capacitor FC by substituting the calculated value of the total ripple current In into predetermined life calculation formulas (formulas (2) and (3)).
By doing so, the life of the smoothing capacitor FC is predicted in consideration of both the low-frequency ripple current input from the rectifier 100 side and the high-frequency ripple current input from the inverter 101 side. The prediction accuracy can be improved as compared with the case where the prediction is made by considering only one of the current IL and the high frequency ripple current IH.

When predicting the life of the smoothing capacitor FC in consideration of both the low-frequency ripple current and the high-frequency ripple current, on the wiring connecting the high-voltage line P (or low-voltage line N) and the smoothing capacitor FC. A method of directly measuring the total ripple current by providing a current sensor is also conceivable. However, in this way, it becomes necessary to additionally install a current sensor on the wiring, and the manufacturing cost increases.
On the other hand, in the air conditioning system 1 according to the present embodiment, the low frequency ripple current IL is measured through the current sensor SE1 provided on the high voltage line P connecting the rectifier 100 and the reactor L. Further, in the air conditioning system 1 according to the present embodiment, through the current sensors SE2-1 and SE2-2 provided in one phase (W phase in the example of FIG. 1) of the wiring connecting the inverter 101 and the motor 102. , Measure the high frequency ripple current IH.
Here, the current sensor SE1 is a current sensor originally provided for a protective operation for protecting the rectifier 100 and the reactor L, which are diode modules. Further, the current sensors SE2-1 and SE2-2 are current sensors originally provided for controlling the inverter 101 and for protective operation. Therefore, according to the air conditioning system 1 according to the present embodiment, it is necessary to add a new current sensor when predicting the life of the smoothing capacitor FC in consideration of both the low frequency ripple current IL and the high frequency ripple current IH. Absent.

Further, the air conditioning system 1 according to the first embodiment has a life calculation unit 1101 that calculates the instantaneous estimated life of the smoothing capacitor FC during operation based on the measured value of the ripple current input to the smoothing capacitor FC, and a life. Based on the instantaneous estimated life calculated by the calculation unit 1101, the cumulative life consumption rate calculation unit 1102 that calculates the cumulative life consumption rate of the smoothing capacitor FC and the rotation speed command are output according to the set temperature set by the user. The rotation speed command output unit 1100 is provided with a rotation speed command output unit 1100, and the rotation speed command output unit 1100 limits the rotation speed command RPS * so that the cumulative life consumption rate does not exceed a predetermined upper limit value (cumulative life consumption rate upper limit value Gth). To do.
By doing so, the rotation speed command RPS * is limited so that the cumulative life consumption rate of the smoothing capacitor FC does not exceed the predetermined upper limit value, so that the life of the smoothing capacitor FC exceeds the target life. It is possible to suppress failure in a short operation time.

Further, according to the air conditioning system 1 according to the first embodiment, the cumulative life consumption rate upper limit value Gth is set to be proportional to the cumulative operation time by a predetermined coefficient (100% / target life). ..
By doing so, the pace of increase in the cumulative life consumption rate can be made uniform over the entire operating time until the target life. As a result, the degree of suppression of the rotation speed command RPS * can be made uniform over the entire operating time until the target life.

Although the control device 11 (life prediction device) and the air conditioning system 1 including the control device 11 (life prediction device) according to the first embodiment have been described in detail above, the specific embodiments of the control device 11 and the air conditioning system 1 are limited to those described above. It is possible to make various design changes, etc. within the range that does not deviate from the gist.

(Modification example)
FIG. 9 is a diagram for explaining the function of the rotation speed command output unit according to the modified example of the first embodiment.
According to the air conditioning system 1 according to the first embodiment, the slope (the rate of increase of the cumulative life consumption rate upper limit Gth per unit operating time) of the cumulative life consumption rate upper limit value Gth is "100% / target life". It has been described as being defined by a straight line (see FIG. 8).
However, the air conditioning system 1 according to another embodiment is not limited to this mode. For example, in the air conditioning system 1 according to the modified example, as shown in FIG. 9, the cumulative life consumption rate upper limit value Gth has a range defined by the first inclination and a second inclination (≠ first inclination). It may have a specified range. In the example shown in FIG. 9, as the cumulative life consumption rate upper limit value Gth, "first slope = 100% / 20,000 hours" is applied in the range of the cumulative operation time from 0 hours to 10,000 hours, and the cumulative operation time. However, "second slope = 100% / 40,000 hours" is applied in the range of 10,000 hours to 30,000 hours. In this example, after the cumulative operation time exceeds 10,000 hours, the degree of being restricted by the rotation speed command RPS * becomes large.
Further, the air conditioning system 1 according to another embodiment may have a function of changing (editing) the cumulative life consumption rate upper limit value Gth. As a result, the user can freely determine whether to prioritize the capacity or the life as the usage pattern of the air conditioning system 1 for each operation time.

Further, the control device 11 (lifetime prediction device) according to the first embodiment has been described as predicting the lifespan of the smoothing capacitor FC in consideration of both the low frequency ripple current IL and the high frequency ripple current IH. Other embodiments are not limited to this aspect. That is, the control device 11 according to the other embodiment may predict the life of the smoothing capacitor FC in consideration of only one of the low frequency ripple current IL and the high frequency ripple current IH.

As described above, some embodiments of the present invention have been described, but all of these embodiments are presented as examples and are not intended to limit the scope of the invention. The above-described embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the gist of the invention. The above-described embodiments and modifications thereof are included in the scope and gist of the invention, as well as in the scope of the invention described in the claims and the equivalent scope thereof.

1 Air conditioning system 10 Power conversion circuit 100 Rectifier 101 Inverter 102 Motor 11 Control device (life prediction device)
110 System control unit 1100 Rotation command output unit 1101 Life calculation unit 1102 Cumulative life consumption rate calculation unit 111 Motor control unit 1110 Drive command output unit 1111 Low frequency ripple current measurement unit (1st ripple current measurement unit)
1112 High frequency ripple current measurement unit (second ripple current measurement unit)
1113 Total ripple current calculation unit SE1 current sensor (first current sensor)
SE2-1, SE2-2 current sensor (second current sensor)
L Reactor FC Smoothing Capacitor SC Snubber Capacitor PS AC Power Supply

Claims (5)

A control device for an air conditioning system including a rectifier that converts AC power from a commercial power source into DC power, an inverter that converts the DC power into AC power for driving a motor, and an electrolytic capacitor that smoothes the DC power. There,
A life calculation unit that calculates the instantaneous estimated life of the electrolytic capacitor during operation based on the measured value of the ripple current input to the electrolytic capacitor.
A cumulative life consumption rate calculation unit that calculates the cumulative life consumption rate for each cumulative operation time based on the instantaneous estimated life,
A rotation speed command output unit that outputs a rotation speed command of the motor according to the set temperature set by the user,
With
The rotation speed command output unit is a control device for an air conditioning system that reduces the rotation speed command so that the cumulative life consumption rate does not exceed a predetermined upper limit value. The control device for an air conditioning system according to claim 1, wherein the upper limit value is determined to be proportional to the cumulative operating time by a predetermined coefficient. The control device for an air conditioning system according to claim 1 or 2, wherein the upper limit value can be changed by the user. A control method for an air conditioning system including a rectifier that converts AC power from a commercial power source into DC power, an inverter that converts the DC power into AC power for driving a motor, and an electrolytic capacitor that smoothes the DC power. There,
A step of calculating the instantaneous estimated life of the electrolytic capacitor during operation based on the measured value of the ripple current input to the electrolytic capacitor, and
A step of calculating the cumulative life consumption rate for each cumulative operating time based on the instantaneous estimated life, and
A step to output a motor rotation speed command according to the set temperature set by the user, and
Have,
A control method for an air conditioning system that reduces the rotation speed command so that the cumulative life consumption rate does not exceed a predetermined upper limit value in the step of outputting the rotation speed command. A control device for an air conditioning system including a rectifier that converts AC power from a commercial power source into DC power, an inverter that converts the DC power into AC power for driving a motor, and an electrolytic capacitor that smoothes the DC power. ,
A step of calculating the instantaneous estimated life of the electrolytic capacitor during operation based on the measured value of the ripple current input to the electrolytic capacitor, and
A step of calculating the cumulative life consumption rate for each cumulative operating time based on the instantaneous estimated life, and
A step to output a motor rotation speed command according to the set temperature set by the user, and
To execute,
A program that reduces the rotation speed command so that the cumulative life consumption rate does not exceed a predetermined upper limit value in the step of outputting the rotation speed command.

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