JPH0788956B2 - Operation control device for heat storage type air conditioner - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an operation control device for controlling heat storage operation in a heat storage type air conditioner provided with a heat storage unit, and particularly to measures against abnormalities such as power failure. Is.

(Prior Art) Generally, in a heat storage type air conditioner, a refrigerant circuit is configured by connecting an outdoor unit and an indoor unit as disclosed in JP-A-61-125554, while a heat storage type air conditioner is configured. A heat storage unit having a heat storage tank that stores a possible heat storage medium is provided in the outdoor unit, the heat exchange coil in the heat storage tank and the refrigerant circuit are connected by a bypass path, and the bypass path and the refrigerant circuit are switched. Some are configured to connect. Then, by performing heat exchange between the refrigerant and the heat storage medium in the heat exchange coil, normal cooling and heating operation,
Cold storage operation, warm storage operation, etc. are performed.

(Problems to be Solved by the Invention) In the heat storage type air conditioner described above, when various operation controls are performed, for example, as disclosed in Japanese Utility Model Laid-Open No. 61-54129, an outdoor control unit and an indoor control unit. It is conceivable to send and receive a control signal to and from.

However, this has a problem that the outdoor control unit has to process various control data for controlling the operation of the heat storage unit, for example, control data of the switching valve, which increases the capacity of the outdoor control unit. In particular, the heat storage unit is not frequently used, and the control area of the heat storage unit is provided in the outdoor control unit, so that the outdoor control unit has a large capacity and becomes large in size.

Therefore, it is conceivable to provide a dedicated heat storage control system for controlling the operation of the heat storage unit. At this time, if the heat storage control system is simply provided, if the heat storage control system causes an abnormality such as a power failure, there is a problem that the abnormality cannot be easily known. In other words, if an abnormality is displayed only in the heat storage control system, it is not possible to know the abnormality indoors, and in particular, if the heat storage control system is poorly managed, or if there is little maintenance, the abnormality can be known for a long period of time. You will not be able to. This causes a problem that normal heat storage operation is not performed and comfortable air conditioning cannot be performed.

The present invention has been made in view of the above points, and it is an object of the present invention to reduce the capacity of the outdoor control unit and enable early detection of various abnormalities.

(Means for Solving the Problem) In order to achieve the above object, the means taken by the present invention is to provide a heat storage control unit for controlling the heat storage unit, and to display an abnormality of the heat storage controller in the indoor control unit. It was done.

Specifically, as shown in FIG. 1, in the means taken by the invention according to claim 1, first, the outdoor unit (X) and the indoor unit (A) are connected by a refrigerant pipe (9), and A heat storage unit (Y) having a heat storage medium capable of storing heat is connected by a refrigerant pipe (9) to form a main refrigerant circuit (10), and the main refrigerant circuit (10) normally performs normal cooling at least during cooling operation. The refrigerant flow direction is switchable so as to perform a cooling operation and a cold storage heat operation for storing cold heat in the heat storage unit (Y).

Further, an indoor control unit (50) for controlling the operation of the outdoor unit (X), and an indoor control unit for controlling the operation of the indoor unit (A) by exchanging a control signal between the outdoor control unit (50). (60), a heat storage control unit (70) that controls the operation of the heat storage unit (Y), and a heat storage controller (80) that outputs a control signal to the heat storage control unit (70). It is intended for operation control devices.

Then, the heat storage controller (80) includes a processor (81) that processes a control signal, and the processor (81) outputs an operation command for outputting a command signal of cold storage operation and stop to the heat storage control unit (70). Means (81b) and abnormality detecting means (81c) for detecting an abnormality of the heat storage controller (80) and outputting an abnormality signal to the heat storage control unit (70) are provided.

Further, the heat storage control unit (70) includes a processor (71) for processing a control signal, and the processor (71) receives the command signal of the operation command means (81b) and the outdoor control unit (50). ) To output the operation signal and the stop signal of the cold storage heat operation, and at the time of the cold storage heat operation, send and receive a control signal to and from the outdoor control unit (50) to perform operation control of the heat storage unit (Y). Means (71a)
And an abnormality signal transmitting means (71c) for receiving an abnormality signal from the abnormality detecting means (81c) and outputting an abnormality signal to the outdoor control unit (50).

Further, the outdoor control unit (50) includes a processor (54) for processing a control signal, and the processor (54) receives an operation signal and a stop signal of the cold storage heat operating means (71a) and A driving operation means (54a) for transmitting and receiving a control signal to and from the cold storage operation means (71a) to control the operation of the outdoor unit (X), and the heat storage control unit (7).
The abnormal signal transmitting means (54b) for receiving the abnormal signal from the abnormal signal transmitting means (71c) in 0) and outputting the abnormal signal to the indoor control unit (60) is provided.

In addition, the indoor control unit (60) includes a processor (61) for processing a control signal, and the processor (61) includes an abnormal signal transmitting means (54) for the outdoor control unit (50).
An abnormality display means (91) for displaying an abnormality of the heat storage controller (80) in response to the abnormality signal output by b) is connected.

Further, the means taken by the invention according to claim 2 is the invention according to claim 1, wherein the indoor control unit (60) includes a remote control switch (90), and the abnormality display means (9).
The configuration 1) is provided on the remote control switch (90).

(Operation) With the above configuration, in the invention according to claim 1, the processor (54) of the outdoor control unit (50) includes the outdoor unit (X).
The processor (61) of the indoor control unit (60) controls the indoor unit (A) and the processor (71) of the heat storage control unit (70) controls the heat storage unit (Y). Control signals are exchanged between the outdoor control unit (50) and the indoor control unit (60) to control the capacity of the compressor (1) in the outdoor unit (X).

On the other hand, during cold heat storage operation, the heat storage controller (8
The operation instruction means (81b) of the processor (81) in 0) outputs an operation instruction signal or a stop instruction signal to the heat storage control unit (70). Then, the heat storage control unit (70) outputs the operation signal or the stop signal to the outdoor control unit (50) by the cold storage heat operating means (71a) corresponding to each of the command signals,
The outdoor control unit (50) drives and controls the compressor (1) and the like, and the heat storage control unit (70) controls the electric expansion valve (14) of the heat storage unit (Y) and the like, and the heat storage unit (Y). Store cold heat.

On the other hand, when an abnormality such as a power failure occurs in the heat storage controller (80), the abnormality detecting means (81c) detects the abnormality and outputs an abnormality signal to the heat storage control unit (70). Then, the heat storage control unit (70) receives the abnormal signal, the abnormal signal transmitting means (71c) outputs the abnormal signal to the outdoor control unit (50), and then the abnormal signal of the outdoor control unit (50). The transmitting means (54b) outputs an abnormal signal to the indoor control unit (60). Then, the indoor control unit (60) displays the abnormality of the heat storage controller (80) on the abnormality display means (91). Specifically, in the invention according to claim 2, the abnormality display means (91) of the remote control switch (90) provided in the indoor control unit (60) displays an abnormality.

(Effect of the invention) Therefore, according to the invention of claim 1, the heat storage control unit (70) for controlling the operation of the heat storage unit (Y) is provided as a dedicated control unit separately from the outdoor control unit (50). Since the capacity of the outdoor control unit (50) can be reduced, the overall size of the device can be reduced and signals can be easily exchanged between the outdoor control unit (50) and the indoor control unit (60). Can be done.

Further, even if the operating range of the heat storage unit (Y) is expanded, the capacity of the outdoor control unit (50) is not likely to expand, so that it is possible to easily cope with the expansion of the operating range.

In addition, since the abnormality of the heat storage controller (80) is displayed on the indoor control unit (60), it is possible to quickly and accurately know the disappearance of operation data due to a power failure, etc. Therefore, comfortable air conditioning can be surely performed.

Further, according to the invention of claim 2, since the remote control switch (90) displays an abnormality, the remote control switch (90) is an operating section that is always operated. Therefore, the abnormality of the heat storage controller (80) Can be quickly and reliably known, and the abnormality can be dealt with quickly.

(Example) Hereinafter, the Example of this invention is described in detail based on drawing.

FIG. 2 shows the overall configuration of the refrigerant system in the heat storage air conditioner, which is a so-called multi-type air conditioner in which a plurality of indoor units (A, B, ...) Are connected to the outdoor unit (X). .

In the outdoor unit (X), (1) is a compressor,
(2) is switched as shown by the solid line in the figure during cooling operation,
A four-way switching valve that switches as shown by the broken line in the figure during heating operation,
(3) is an outdoor heat exchanger that functions as a condenser during cooling operation and as an evaporator during heating operation, and (4) is an outdoor electric expansion valve that adjusts the refrigerant flow rate during cooling operation and reduces the refrigerant during heating operation. , (5) is a receiver for storing the condensed liquid refrigerant, and (8) is an accumulator for removing the liquid component in the suction refrigerant.

On the other hand, each indoor unit (A, B, ...) has the same structure,
(6) is an indoor electric expansion valve that functions as a decompression mechanism during cooling operation and adjusts the refrigerant flow rate during heating operation, (7)
Is an indoor heat exchanger that functions as an evaporator during cooling operation and as a condenser during heating operation.

The above-mentioned devices (1 to 8) are sequentially connected by a refrigerant pipe (9) so that the refrigerant can flow, and a main refrigerant having a heat pump function of releasing heat obtained by heat exchange with outdoor air to indoor air. A circuit (10) is constructed.

Further, the main refrigerant circuit (10) is connected to a heat storage unit (Y) for storing cold heat or warm heat by exchanging heat with the refrigerant or for utilizing the cold heat or warm heat. . In the heat storage unit (Y), (11) is a heat storage tank that stores water (W) as a heat storage medium capable of storing cold heat and warm heat,
(12) is a heat storage heat exchanger arranged in the heat storage tank (11) for exchanging heat between water (W) and a refrigerant, and the heat storage heat exchanger (12) is a main refrigerant circuit ( The liquid line (9) between the outdoor electric expansion valve (4) and the indoor electric expansion valve (6) of 10).
a) to the first bypass path (13a) and the second bypass path (13)
It is connected by b) so that the refrigerant can flow. A heat storage electric expansion valve (14) for depressurizing the refrigerant when storing cold heat in the water (W) is provided in the first bypass passage (13a), and in the second bypass passage (13b), A first opening / closing valve (15) for opening and closing the second bypass passage (13b) is provided.

Further, the first on-off valve (15) of the second bypass passage (13a)
− Intermediate piping between the heat storage heat exchanger (12) and the main refrigerant circuit (10)
Is connected to the gas line (9b) by a third bypass passage (13c) so that the refrigerant can flow therethrough, and the third bypass passage (13c) is provided with a second opening / closing valve for opening and closing the bypass passage (13c). (16) is installed.

On the other hand, between the two joints of the first and second bypass passages (13a, 13b) in the liquid line (9a) of the main refrigerant circuit (10), a flow rate control valve for variably adjusting the flow rate of the refrigerant. (1
7) is installed.

The opening / closing or opening of each valve (2,4,6,14,15,16,17) is controlled by each control unit (50,60,70) described later, and the main refrigerant circuit (10) Is configured so that the circulation path of the refrigerant can be switched according to each operation mode. Further, during the cold storage heat recovery operation by the flow control valve (17), the first opening / closing valve (15) and the heat storage electric expansion valve (14). The refrigerant flow is divided into the second bypass path (13b) side and the liquid line (9a) side.

Further, sensors are arranged in this heat storage type air conditioner, (Thw) is arranged in the water of the heat storage tank (11), a water temperature sensor for detecting the water temperature Tw, and (Thi) is a liquid line (9a). ), A cooling inlet sensor disposed on the upstream side of the joint portion with the second bypass passage (13b) during cooling operation, (Th
o) is a cooling outlet sensor arranged on the downstream side of the junction of the liquid line (9a) with the first bypass passage (13a) during cooling operation, and (Cl) detects the water level in the heat storage tank (11). Water level sensor, (T H1) is a room temperature sensor that detects each room temperature,
(T H2) and (T H3) are the indoor liquid temperature sensor and the indoor gas temperature sensor that detect the temperature of the refrigerant in the liquid side and gas side piping of the indoor heat exchanger (12, ...), respectively, and (T H4) is the compression Pipe sensor for detecting the discharge pipe temperature of machine (1), (T H5)
Is a defrost sensor that detects the frosting state from the outlet temperature of the outdoor heat exchanger (6) during heating operation, and (TH6) is located at the air inlet of the outdoor heat exchanger (6) and detects the intake air temperature. The outside air temperature sensor (SP) is a pressure sensor that detects the pressure of the refrigerant pressure, that is, the saturation temperature Te corresponding to the evaporation pressure during the cooling operation, and the high pressure, that is, the saturation temperature Tc corresponding to the condensation pressure during the heating operation.

Then, the respective valves and sensors are connected to the outdoor control unit (50), the indoor control unit (60) and the heat storage control unit (70) by signal lines, as shown in FIGS. The outdoor control unit (50) is connected to each indoor control unit (60) and the heat storage control unit (70) by communication wiring so that control signals can be exchanged. Then, as shown in FIG. 3, the indoor control units (60) are connected in order, and an outdoor control unit (50), a plurality of indoor control units (60) and a heat storage control unit (70) are connected. This constitutes one control system corresponding to one refrigerant system.
Further, a plurality of control systems are provided corresponding to the plurality of refrigerant systems, the heat storage controller (80) is connected to one heat storage control unit (70), and each heat storage control unit (7
0) are connected in order.

FIG. 4 is an electric circuit diagram showing the wiring relationship between the inside of the outdoor control unit (50) arranged on the side of the outdoor unit (X) and the connected devices. In the figure, (MC) is a motor of the compressor (1) connected to the frequency conversion circuit (INV) of the inverter, (52C) is an electromagnetic contactor that operates the frequency conversion circuit (INV), and the above devices are fuses. Box (FS),
It is connected to the AC power supply (50a) via the earth leakage breaker (BR1), and the outdoor control unit (50) is connected to the AC power supply (50a).
connected to a). Further, (MF) is a fan motor for an outdoor fan, and (52FH) and (52FL) are electromagnetic contactors for operating the fan motor (MF), which respectively correspond to a single-phase component of the AC power supply (50a). When the electromagnetic contactor (52FH) is connected, the outdoor fan produces strong wind (standard air volume), and when the electromagnetic contactor (52FL) is connected, the outdoor fan produces strong wind. It is made possible to switch to alternative.

Next, inside the outdoor control unit (50), the normally open contacts (RY1 to RY4) of the electromagnetic relay are connected in parallel with the alternating current (50a), and these are in turn connected to the four-way switching valve ( 2)
Directly connected to the outdoor control unit (50) or directly connected to the coil of the electromagnetic relay (20S), frequency converter (INV) electromagnetic contactor (52C), and outdoor fan electromagnetic contactor (52FH, 52FL) It is opened / closed in response to the signals of the respective sensors (TH1 to TH6) input via the control unit (60, ...) To open / close the contacts of the respective electromagnetic contactors or electromagnetic relays.

A coil of a pulse motor (EV1) that adjusts the opening of the outdoor electric expansion valve (4) is connected to the outdoor control unit (50). In the circuit on the right side of the figure,
(CH) is a heater for preventing oil forming of the compressor (1), which is connected in series with each electromagnetic contactor (52C) so that a current flows when the compressor (1) is stopped.

Furthermore, (51C) is the overcurrent relay of the motor (MC), (53C)
Is a compressor (1) temperature rise protection switch, (53H) is a compressor (1) pressure rise protection switch, and (51F) is a fan motor (MF) overcurrent relay. These are connected in series. It is connected to form a protection circuit that turns on the electromagnetic relay (30Fx) at startup and turns it off in case of failure. A CPU (54) as a processor is built in the outdoor control unit (50), and the CPU (54) is a signal input from each indoor control unit (60), heat storage control unit (70) or each sensor. A driving operation means (54a) for controlling the operation of each device is configured in accordance with the above.

Next, FIG. 5 is an electric circuit diagram showing the main wiring of the inside of the indoor control unit (60) and each connected device. In the figure, (MF) is the motor for the indoor fan, which is a single-phase AC power supply (60
In response to a), the relay terminals (RY11 to RY13) are used to switch between strong wind and weak wind in descending order of air volume, and a slight wind is generated only when stopped by the signal from the room temperature sensor (TH1) during heating operation. A pulse motor (EV ₂ ) for adjusting the opening degree of the indoor electric expansion valve (6) is connected to the printed circuit board of the indoor control unit (60), while the room temperature sensor (TH
1) and temperature sensor (TH2, TH3) signals are input.

Further, each indoor control unit (60) is connected to the outdoor control unit (50) via a signal line so as to be able to send and receive signals, and has a remote control switch (90). Then, the indoor control unit (60) has a built-in CPU (61) which is a processor, and the CPU (61) has an indoor electric expansion valve (independent) in response to a signal from each sensor or the outdoor control unit (50). 6) Alternatively, a driving operation means (61a) for controlling the operation of the indoor fan is configured.

Next, the heat storage control unit (70) characterized by the present invention
Will be described.

As shown in FIG. 6, the heat storage control unit (70) is connected with a heat storage controller (80), and the heat storage unit (Y) is operated by a command signal from the heat storage controller (80).
Is configured to control driving.

The heat storage controller (80) is a CPU that is a processor.
A clock signal is input to the (81) from the clock circuit (82), and a transmission circuit (83) is connected to output a command signal to the heat storage control unit (70). Further, the CPU (81) is connected to an input unit (84) for inputting a program for cold storage operation, and the input unit (84) sets the time, sets the progress of cold storage operation,
CP for hour and minute settings, holiday designation, program setting completion, etc.
It is configured to enter U (81). Also, above C
An EEPROM (85) is connected to the PU (81), and the EEPROM
(85) is configured to store the operating state of the cold storage heat.

Furthermore, the CPU (81) includes an operation data storage means (8
1a) and the operation command means (81b) are configured, and the operation data storage means (81a) sets a predetermined cold storage heat operation time for each day based on the cold storage heat operation program set by the input section (84). It is configured to store the number of days, for example,
The cold storage heat operation time of each day from Sunday to Saturday is memorized. The operation command means (81b) outputs the operation command signal to the heat storage control unit (70) at the operation time based on the storage data of the operation data storage means (81a) and at the operation stop time. Is configured.

The CPU (81) has one transmission block composed of 8 bits, and the one transmission block is, as shown in FIG.
Two bits are formed as an operation mode signal (S1), one bit is a program setting completion signal (S2), one bit is a time signal (S3), and four bits are a checksum signal (S4). The operation mode signal (S1) is set to "11" for cold storage prohibition mode, "10" for operation mode, "01" for trial operation mode, "00" for stop mode, and the operation command means (81b) Each mode signal is output.
When the program setting completion signal (S2) above is "0", setting is complete,
"1" indicates unset, and hourly signal (S3) is 1 from midnight
The checksum signal (S4) is configured to set a bit for a minute, and the checksum signal (S4) is configured to include the two's complement of the above-mentioned four bits.

Further, the CPU (81) is provided with an abnormality detecting means (81c), and the abnormality detecting means (81c) has a defect in the backup power supply due to a power failure or the like, data disappearance in the operation data storage means (81a), and EEPROM ( 85) etc. are configured to detect various abnormalities. The abnormality detecting means (81
When c) detects an abnormality, it outputs an abnormality signal to the heat storage control unit (7
This abnormal signal is configured by setting the operation mode signal (S1) and the program setting completion signal (S2) of one transmission block to "001".

The heat storage control unit (70) is connected to a power supply (70a) to be supplied with electric power, and also has a CPU (7
A receiving circuit (72a), a transmitting circuit (72b) and a transmitting / receiving circuit (73) are connected to 1), and a control signal is exchanged with the outdoor control unit (50) via the transmitting / receiving circuit (73). Is configured to. In addition, the heat storage controller (8a) is provided in the receiving circuit (72a) of one heat storage control unit (70).
0) is connected, and the heat storage control unit (70) and each of the other heat storage control units (70) are connected in order to the transmission circuit (72b) and the reception circuit (72a), and the heat storage control unit (7).
0) is configured to receive the output signals of the heat storage controller (80) in order.

Further, the CPU (71) receives the detection signals of the water temperature sensor (Thw), the cooling inlet sensor (Thi), the cooling outlet sensor (Th0), and the water level sensor (Cl), and the heat storage electric expansion valve ( 14) and each drive motor (EV) for the flow control valve (17)
3, EV4) is configured to output a drive signal for drive control. In addition, the heat storage control unit (70) includes the electromagnetic relays (20R1, 20R) of the first and second opening / closing valves (15, 16).
2) and relay contacts (RY21, RY22) are connected to the power supply (70a).

Further, the heat storage control unit (70) is provided with a cold storage heat operation changeover switch (74) and a heat storage heat operation changeover switch (75), and a timer (76) is configured in the CPU (71). There is.

The cold storage heat operation change-over switch (74) is configured to switch to either a cold storage heat exclusive operation for performing only the cold storage heat or a cooling heat simultaneous operation for simultaneously performing the cold storage heat and the indoor cooling during the cold storage heat operation. The exclusive operation signal and the simultaneous operation signal of the operation changeover switch (74) are input to the CPU (71).

The heat storage / heat storage operation changeover switch (75) is configured to switch between a normal heating operation for performing only indoor heating during a heating operation and a heating / heat storage simultaneous operation for simultaneously performing indoor heating and heat storage. The switching signal of the thermal operation switching switch (75) is input to the CPU (71).

The timer (76) is configured to start counting by a time signal output from the heat storage controller (80).

Further, the CPU (71) includes a cold storage heat operating means (71a) and a warm storage heat operating means (71b), and the cold storage heat operating means (71a) is output by the heat storage controller (80). The operation command signal and the stop command signal, that is, the operation mode signal (S1) of FIG. 7 is received, and the switching signal of the cold storage heat operation changeover switch (74) is received, and the outdoor control unit (50) and the control signal are received. Heat transfer electric expansion valve to exchange heat (14)
And so on.

The heat storage / heat operation means (71b) is configured to receive a switching signal of the heat storage / heat operation switching switch (75) and control the heat storage electric expansion valve (14) and the like.

That is, specifically, the frequency command signal of the compressor (1) and the frequency signal of the current operation are exchanged between the CPU (71, 54) of the heat storage control unit (70) and the outdoor control unit (50). In addition, the heat storage control unit (70) outputs an operation signal and a stop signal, while the outdoor control unit (50) outputs an oil return signal, a pump down signal and an outdoor abnormality signal to store cold heat or warm heat. It is configured to control driving.

Further, the CPU (71) is provided with an abnormal signal transmitting means (71c), and the abnormal signal transmitting means (71c) outputs an abnormal signal output from the abnormality detecting means (81c) of the heat storage controller (80). Upon reception, an abnormal signal of the heat storage controller (80) is output to the outdoor control unit (50). Then, the CPU (5
4) is provided with an abnormal signal transmitting means (54b) for outputting an abnormal signal to the heat storage control unit (60).

Further, the CPU (61) of the indoor control unit (60) is provided with an abnormal signal transmitting means (61b) for outputting an abnormal signal output by the outdoor control unit (50) to the remote control switch (90). When the control switch (90) receives an abnormal signal, the heat storage controller (8
0) Anomaly display means (9)
1) is provided.

Next, the opening / closing (or opening degree adjustment) of each valve and the circulation path of the refrigerant in each operation mode of the heat storage type air conditioner will be described.

First, during normal cooling operation, the four-way switching valve (2) is switched as shown by the solid line in FIG. 2, and the outdoor electric expansion valve (4), the flow control valve (17), and the indoor electric expansion valve (6) are opened. , The other valves are all closed, the refrigerant condensed in the outdoor heat exchanger (3) passes through the indoor electric expansion valves (6), evaporates in the indoor heat exchangers (7), and is compressed. Return to (1).

During the cold storage heat operation, during the cold storage heat exclusive operation in which only the cold storage heat is performed, the outdoor electric expansion valve (4), the flow control valve (17), the heat storage electric expansion valve (14) and the second opening / closing valve (16) are opened, With the electric expansion valve (6) and the first opening / closing valve (15) closed, the liquid refrigerant condensed in the outdoor heat exchanger (3) flows from the first bypass passage (13a) to the heat storage electric expansion valve (14). ),
It circulates so as to evaporate in the heat storage heat exchanger (12) and return to the compressor (1) to store cold heat.

In the cold storage operation, the outdoor electric expansion valve (4), the flow control valve (17), and the indoor electric expansion are shown as indicated by the broken arrow in FIG. With the valve (6), the heat storage electric expansion valve (14) and the second opening / closing valve (16) open and the first opening / closing valve (15) closed, the liquid refrigerant condensed in the outdoor heat exchanger (3) A part of the heat is evaporated through the indoor electric expansion valve (6) in the indoor heat exchanger (7), while the rest of the liquid refrigerant is transferred from the bypass passage (13a) through the heat storage electric expansion valve (14). It vaporizes in (12), merges in the gas line (9b), and returns to the compressor (1).

During the cold storage heat recovery operation utilizing the cold heat stored in the cold storage heat operation, as shown by the solid arrow in FIG. 2, the outdoor electric expansion valve (4), the flow control valve (17), the indoor electric expansion valve (6 ,
...), a part of the liquid refrigerant condensed in the outdoor heat exchanger (3) with the heat storage electric expansion valve (14) and the first opening / closing valve (15) opened and the second opening / closing valve (16) closed. Is the second bypass (13
b), is supercooled by the heat storage heat exchanger (12) and returns from the first bypass path (13a) to the liquid line (9a), while the rest of the liquid refrigerant flows through the liquid line (9a) as it is, and after joining. After passing through each indoor electric expansion valve (6), each indoor heat exchanger (7) evaporates and returns to the compressor (1). At that time, the partial flow rate of the refrigerant is adjusted by adjusting the relative opening of the flow control valve (17) and the heat storage electric expansion valve (14), and the cooling inlet sensor (Th
i), Liquid refrigerant temperature Tl detected by the cooling outlet sensor (Tho)
The degree of supercooling of the refrigerant as the temperature ΔTl of 1, Tl2 is appropriately adjusted.

Next, in the normal heating operation, the four-way switching valve (2) is switched to the broken line side in FIG. 2, and each indoor electric expansion valve (6), flow control valve (17), outdoor electric expansion valve (4). Is opened and all the other valves are closed, the liquid refrigerant condensed in each indoor heat exchanger (7) is evaporated and compressed in the outdoor heat exchanger (3) through the outdoor electric expansion valve (4). Return to machine (1).

At the time of simultaneous heating and heat storage simultaneous operation in which normal heating and stored heat are simultaneously performed, as shown by the alternate long and short dash line arrow in FIG. 2, each indoor electric expansion valve (6), the second on-off valve (16), the heat storage electric expansion valve ( 1
4), the flow control valve (17), the outdoor electric expansion valve (4) are opened, and the first opening / closing valve (15) is closed, and a part of the discharge gas is discharged from the gas line (9b) to the third bypass passage ( 13c) and condenses in the heat storage heat exchanger (12), while the rest of the discharged gas flows in the gas line (9b) and condenses in each indoor heat exchanger (7). After merging, the outdoor electric expansion valve ( After passing through 4), it evaporates in the outdoor heat exchanger (3) and returns to the compressor (1).

Further, during the storage heat recovery defrost operation, the four-way switching valve (2) is switched to the solid line side in the figure, and the outdoor electric expansion valve (4), the flow control valve (17), each indoor electric expansion valve (6),
The heat storage electric expansion valve (14) and the second opening / closing valve (16) open,
With the on-off valve (15) closed, part of the liquid refrigerant condensed in the outdoor heat exchanger (3) passes through the first bypass passage (13a), the heat storage electric expansion valve (14), and the heat storage heat exchanger. While the remaining part of the liquid refrigerant passes through each indoor electric expansion valve (6) and evaporates in each indoor heat exchanger (7, ...) While evaporating in (12), the gas line (9).
Merge at b) and return to compressor (1).

Next, each control unit (50, 60,
The control operation of 70) will be described.

First, the indoor control unit (60) and the outdoor control unit (5
0), the indoor control unit (60) is transmitting and receiving the operation signal and the like based on the operation signal and the stop signal of the cooling and heating operation and the set temperature signal input from the remote control switch (90). Is the room temperature sensor (Th
Based on the temperature detected in 1), the thermostat on / off of the indoor units (A, ...) and the indoor electric expansion valve (6) are controlled. And the outdoor control unit (50) is the indoor control unit (60)
The frequency converter (IN
V) to control the capacity of the compressor (1) and also to control the outdoor electric expansion valve (4) and the like.

On the other hand, in the heat storage controller (80), a cold storage operation program is input from the input section (84), and a control signal indicating whether or not the setting of the operation program is completed is given at a predetermined timing with the heat storage control unit (70). Have been sent to.
That is, as shown in FIG. 7, the operation mode signal (S1), which is a command signal, is transmitted at a predetermined timing.
At 1:00 am, the operation mode signal (S1) is transmitted thereafter, while at 6:00 am, for example, the stop mode signal (S1) is transmitted instead of the operation mode signal.

Then, the heat storage control unit (70) controls the operation of the heat storage unit (Y) based on the control signal of the heat storage controller (80), that is, when the program setting completion signal (S2) is "0" and the setting is completed, Operation control can be started,
The timer (76) starts counting by the time signal (S3). Further, during the cooling operation, the control for the exclusive cold storage operation or the simultaneous cooling and heat storage operation is controlled based on the switching signal of the cold storage heat operation changeover switch (74), and when the cold storage heat operation time comes, the operation mode which is a command signal The operation signal is output to the outdoor control unit (50) by the signal (S1). While the outdoor control unit (50) controls the drive of the compressor (1) and capacity control by this operation signal, the heat storage control unit (70) controls the heat storage electric expansion valve (14) etc. in the operation mode. Control.

Then, when the stop mode signal (S1) is input to the heat storage control unit (80) from the heat storage controller (80), the heat storage control unit (80) outputs a stop signal to the outdoor control unit (50), While the heat storage electric expansion valve (14) is fully closed, the outdoor control unit (50) controls the compressor (1) to stop.

By the operation control described above, cold heat is stored at a predetermined time of day, and cold heat such as ice is stored in the heat storage tank (11).

On the other hand, during heating operation, when the heat storage / heat storage operation changeover switch (75) of the heat storage control unit (70) is switched to heating / heat storage simultaneous operation, the heat storage control unit (70) switches the heat storage electric expansion valve (14) and the like. It controls and stores warm heat in the heat storage tank (11).

In the air conditioning control described above, if a power failure occurs, the backup power supply failure of the heat storage controller (80), the operation data disappears, or the EEPROM (85) fails, the abnormality detection means (81c) stores heat. An abnormality of the controller (80) is detected and an abnormality signal is output to the heat storage control unit (70). Specifically, the operation mode signal (S1) and the program setting completion signal (S2) of one transmission block output from the heat storage controller (80) are set to "001" and output to the heat storage control unit (70). .

Subsequently, the heat storage control unit (70) receives an error signal from the heat storage controller (80) and sends an error signal transmission means (71).
c) outputs an abnormal signal to the outdoor control unit (50), and the outdoor control unit (50) is connected to the heat storage controller (80).
The abnormal signal transmitting means (54b) outputs the abnormal signal to the indoor control unit (60). Then, the indoor control unit (60) outputs an abnormality signal of the heat storage controller (80) to the remote control switch (90) by the abnormality signal transmitting means (61b), and an abnormality display means (91) of the remote control switch (90). ) Displays an abnormality of the heat storage controller (80). This abnormality display informs the abnormality of the heat storage controller (80) indoors.

Therefore, since the heat storage control unit (70) that controls the operation of the heat storage unit (Y) is provided as a dedicated control unit separately from the outdoor control unit (50), the capacity of the outdoor control unit (50) can be reduced. Therefore, it is possible to reduce the size of the entire apparatus, and it is possible to easily exchange signals between the outdoor control unit (50) and the indoor control unit (60).

Further, even if the control range of the heat storage unit (Y) is expanded, the capacity of the outdoor control unit (50) does not increase so much, so that it is possible to easily cope with the expansion of the operating range.

In addition, since the abnormality of the heat storage controller (80) is displayed on the indoor control unit (60), it is possible to quickly and accurately know the disappearance of operation data due to a power failure, etc. It can be operated, and comfortable air conditioning can be surely performed. In particular,
Since the remote control switch (90) displays an error, the remote control switch (90) is an operating section that is always operated. Therefore, the heat storage controller (80)
It is possible to quickly and surely know the abnormality of No. 1 and to promptly deal with the abnormality.

In addition, although the present embodiment has been described with respect to the multi-type air conditioner, the present invention is not limited to the multi-type air conditioner, as long as it has the heat storage unit (Y), the main refrigerant circuit (10).
Is not limited to the embodiment.

Further, the abnormality display may be directly performed by the indoor control unit (50).

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of the present invention. 2 to 7 show an embodiment of the present invention, FIG. 2 is a refrigerant circuit diagram showing a refrigerant system, FIG. 3 is a system diagram showing a control system,
FIG. 4 is a circuit block diagram of an outdoor control unit, FIG. 5 is a circuit block diagram of an indoor control unit, FIG. 6 is a circuit block diagram showing a heat storage control unit and a heat storage controller, and FIG. 7 is an output signal of the heat storage controller. It is explanatory drawing which shows the content. (10) …… Main refrigerant circuit, (50) …… Outdoor control unit,
(54a) …… Operation control means, (54b, 61b, 71c) …… Abnormal signal transmission means, (60) …… Indoor control unit, (70) ……
Heat storage control unit, (71a) …… Cold heat operation means, (71
b) ...... Heat storage heat operation means, (80) ...... Heat storage controller, (81b) ...... Operation command means, (81c) ...... Abnormality detection means, (A) ...... Indoor unit, (X) ...... Outdoor Unit, (Y) ... Heat storage unit.

Front page continuation (72) Inventor Akira Horikawa 1304 Kanaoka-machi, Sakai City, Osaka Prefecture Daikin Industries, Ltd. Kanaoka Plant, Sakai Manufacturing Co., Ltd. (56) References: Showa Sho 59-118938 (JP, U)

Claims (2)

[Claims] 1. An outdoor unit (X) and an indoor unit (A)
Are connected by a refrigerant pipe (9), and a heat storage unit (Y) having a heat storage medium capable of storing heat is connected by a refrigerant pipe (9) to form a main refrigerant circuit (10). (10) is configured to be capable of switching the refrigerant flow direction so as to perform at least a normal cooling operation in which normal cooling is performed during a cooling operation and a cold storage operation in which cold heat is stored in the heat storage unit (Y), while the outdoor unit ( X), the outdoor control unit (50), an indoor control unit (60) that exchanges control signals between the outdoor control unit (50) to control the operation of the indoor unit (A), and A heat storage control unit (70) that controls the operation of the heat storage unit (Y), and a heat storage controller (8) that outputs a control signal to the heat storage control unit (70).
0) and a heat storage type air conditioner operation control device, wherein the heat storage controller (80) includes a processor (81) for processing a control signal, and the processor (81) includes a heat storage control device. Abnormality detection that outputs an abnormal signal to the heat storage control unit (70) by detecting an abnormality in the operation command means (81b) that outputs a command signal for cold heat storage operation and stop to the unit (70) and the heat storage controller (80) Means (81c) is provided, the heat storage control unit (70) includes a processor (71) for processing a control signal, and the processor (71) receives a command signal from the operation command means (81b). The operation signal and the stop signal of the cold storage heat operation are output to the outdoor control unit (50) and the heat storage unit (Y) is exchanged with the outdoor control unit (50) during the cold storage operation. Storage to control the operation The heat control means (71a) and the abnormality signal transmission means (71c) for receiving an abnormality signal from the abnormality detection means (81c) and outputting an abnormality signal to the outdoor control unit (50) are provided. The (50) includes a processor (54) for processing a control signal, and the processor (54) receives the operation signal and the stop signal of the cold storage heat operating means (71a), and at the same time, the cold storage heat operating means (71a). ) Receiving and transmitting a control signal to and from the operation unit (54a) for controlling the operation of the outdoor unit (X), and an abnormality signal from the abnormality signal transmitting means (71c) in the heat storage control unit (70). An abnormal signal transmitting means (54b) for outputting an abnormal signal is provided to the indoor control unit (60), and the indoor control unit (60) includes a processor (61) for processing a control signal, and the processor (61) ) Is the outdoor control unit. (50) abnormal signal transmitting means (54b) output an abnormal signal output from the heat storage controller (80) for displaying an abnormality display means (91) is connected to the heat storage type air. Operation control device for the harmony device. 2. The operation control device for a heat storage type air conditioner according to claim 1, wherein the indoor control unit (60) includes a remote control switch (90), and an abnormality display means (9).
1) is an operation control device for a heat storage type air conditioner, which is provided in the remote control switch (90).