JP2022170222A - air conditioner - Google Patents

Abstract

To provide an air conditioner which can inform a user of refrigerant leakage even in a time period before a countermeasure device is actuated.SOLUTION: A control unit (AC) of an air conditioner causes an informing part (71) to provide predetermined information when a detection valve of a refrigerant sensor (45) exceeds a first value and causes countermeasure devices (50, 55, 60) to operate when the detection value of the refrigerant sensor (45) exceeds a second value larger than the first value.SELECTED DRAWING: Figure 4

Description

The present disclosure relates to air conditioners.

Patent Literature 1 discloses an air conditioner equipped with a shutoff valve as a countermeasure device. A shutoff valve is provided in a refrigerant pipe of an air conditioner. When the refrigerant leaks in the target space, the refrigerant sensor detects the leakage of the refrigerant. The shut-off valve is closed accordingly. Thereby, leakage of the refrigerant in the target space can be suppressed.

JP 2017-9267 A

In the air conditioner as disclosed in Patent Document 1, the refrigerant may slowly leak into the target space. In such a case, although the refrigerant is leaking into the target space, the countermeasure device does not operate unless the refrigerant concentration in the target space is increased to some extent. For this reason, even though the refrigerant is leaking, there have been cases where the manager or the like cannot know the leakage of the refrigerant.

The air conditioner of the first aspect comprises a usage unit (30), a refrigerant sensor (45) for detecting the concentration of refrigerant in a space (S) to be air-conditioned by the usage unit (30), and a countermeasure device (50, 55, 60) for refrigerant leakage, a reporting unit (71), and a control unit (AC) for controlling the countermeasure device (50, 55, 60) and the reporting unit (71) . The control section (AC) causes the notification section (71) to issue predetermined information when the detection value of the refrigerant sensor (45) exceeds a first value, and the detection value of the refrigerant sensor (45) is The countermeasure device (50, 55, 60) is activated when a second value larger than the first value is exceeded.

According to the first aspect, the controller (AC) activates the countermeasure device (50, 55, 60) when the detected value of the refrigerant sensor (45) exceeds the second value. Refrigerant leakage can be suppressed by operating the countermeasure device (50, 55, 60). When the detected value of the refrigerant sensor (45) exceeds the first value smaller than the second value, the control section (AC) causes the notification section (71) to issue predetermined information. Since the first value is relatively small, the reporting section (71) issues a report even when the refrigerant leaks relatively slowly. Therefore, the reporting unit (71) issues a report so that a person such as an administrator can know about the refrigerant leakage. Therefore, before the countermeasure device (50, 55, 60) operates, a person can take countermeasures against refrigerant leakage.

An air conditioner according to a second aspect is the air conditioner according to the first aspect, wherein the control unit (AC) controls the notification unit ( 71) issues first information, and when the detected value of the refrigerant sensor (45) exceeds a second value, the reporting section (71) issues second information different from the first information.

According to the second aspect, the control section (AC) provides different information to the reporting section (71) depending on whether the detected value of the refrigerant sensor (45) exceeds the first value or exceeds the second value. alert.

In the air conditioner of the third aspect, in the second aspect, the second information is information about refrigerant leakage and information about the operation of the countermeasure device (50, 55, 60). , and at least one of information about the inoperability of the air conditioner.

According to the third aspect, when the detected value of the refrigerant sensor (45) exceeds the second value, the reporting section (71) outputs information about refrigerant leakage, the countermeasure device (50, 55, 60). ) is operating and at least one of the information that the air conditioner cannot be operated is issued as the second information.

A fourth aspect is that in any one of the first to third aspects, the refrigerant sensor (45) detects the space to be air-conditioned in the usage unit (30) while the air conditioner (10) is stopped. (S) to detect the refrigerant concentration. The control section (AC) issues predetermined information from the reporting section (71) when the detection value of the refrigerant sensor (45) exceeds a first value while the air conditioner (10) is stopped. Let The control section (AC) activates the countermeasure device (50, 55, 60) when the detected value of the refrigerant sensor (45) exceeds the second value.

According to the fourth aspect, the control section (AC) performs the same control as in the first aspect even while the air conditioner (10) is stopped. Therefore, even when the refrigerant leaks relatively slowly while the air conditioner (10) is stopped, the reporting unit (71) can notify the manager or the like of the leakage of the refrigerant. When the refrigerant concentration in the target space (S) becomes relatively high while the air conditioner (10) is stopped, the countermeasure device (50, 55, 60) can be activated.

According to a fifth aspect, in any one of the first to fourth aspects, the control unit (AC), in synchronism with the detection value of the refrigerant sensor (45) exceeding the first value, Information about refrigerant leakage is acquired based on the operation data of the air conditioner (10).

According to the fifth aspect, when the detection value of the refrigerant sensor (45) exceeds the first value, the notification unit (71) issues an alarm, so that even when the refrigerant is slowly leaking, the manager or the like can people can know the leakage of the refrigerant. Further, the control section (AC) acquires information on refrigerant leakage based on the operating data of the air conditioner (10) in synchronization with the detected value of the refrigerant sensor (45) exceeding the first value. As a result, when the refrigerant leaks, a person such as an administrator can know where the refrigerant is leaking based on the information on the refrigerant leakage.

FIG. 1 is a schematic piping system diagram of an air conditioner according to an embodiment. FIG. 2 is a schematic configuration diagram of an air conditioner and a safety device. FIG. 3 is a schematic configuration diagram of an air conditioning system. FIG. 4 is a flowchart showing the operation of the air conditioner when refrigerant leaks. FIG. 5 is a block diagram showing a control unit of an air conditioner according to Modification 1 and its peripheral configuration. FIG. 6 is a diagram corresponding to FIG. 4 according to Modification 1. As shown in FIG.

<<Embodiment>>
Hereinafter, embodiments of the present disclosure will be described in detail with reference to the drawings. Note that the present disclosure is not limited to the embodiments shown below, and various modifications are possible without departing from the technical idea of the present disclosure. Since each drawing is for conceptually explaining the present disclosure, dimensions, ratios, or numbers may be exaggerated or simplified as necessary for easy understanding.

(1) Overall Configuration of Air Conditioner The air conditioner (10) will be described. FIG. 1 is a piping system diagram of an air conditioner (10). FIG. 2 is a schematic configuration diagram showing basic elements of the air conditioner (10). In FIG. 2, illustration of the second usage unit (30B) is omitted.

The air conditioner (10) adjusts the temperature of air in a space (S) to be air-conditioned. The target space (S) in this example is an indoor space such as a building. The air conditioner (10) cools or heats the target space (S). The air conditioner (10) is of a multi-type having a plurality of usage units (30). An air conditioner (10) has a heat source unit (20), a plurality of utilization units (30), a connecting pipe (12), and a controller (AC). The plurality of utilization units (30) and the heat source unit (20) are connected to each other via a connecting pipe (12). This connection forms a closed refrigerant circuit (11).

(2-1) Refrigerant Circuit The refrigerant circuit (11) includes a heat source circuit (20a) provided in the heat source unit (20) and a utilization circuit (30a) provided in each utilization unit (30).

The refrigerant circuit (11) is filled with a slightly flammable refrigerant. The mildly flammable refrigerant in this example is R32 (difluoromethane). R32 has a relatively low GWP (Global Warming Potential), but has mild flammability. For this reason, the refrigerant may leak into the target space (S), and when the concentration of the refrigerant in the target space (S) increases, the refrigerant may burn. The density of refrigerant is greater than that of air. Therefore, when the coolant leaks into the target space (S), the coolant flows to the bottom of the target space (S).

(2-2) Connecting Pipe The connecting pipe (12) includes the first connecting pipe (13) and the second connecting pipe (14).

The first communication pipe (13) is a liquid communication pipe. The first communication pipe (13) includes a first main pipe (13a) and a plurality of first branch pipes (13b) branching from the first main pipe (13a). One end of the first main pipe (13a) is connected to the heat source circuit (20a) through the first shutoff valve (15), which is a liquid shutoff valve. One end of each of the plurality of first branch pipes (13b) is connected to the first main pipe (13a). The other end of each of the plurality of first branch pipes (13b) is connected to the corresponding utilization circuit (30a).

The second communication pipe (14) is a gas communication pipe. The second communication pipe (14) includes a second main pipe (14a) and a plurality of second branch pipes (14b) branching from the second main pipe (14a). One end of the second main pipe (14a) is connected to the heat source unit (20) through the second shutoff valve (16), which is a gas shutoff valve. One end of each of the plurality of second branch pipes (14b) is connected to the second main pipe (14a). The other ends of the plurality of second branch pipes (14b) are connected to corresponding utilization units (30).

(2-3) Heat Source Unit The heat source unit (20) is an outdoor unit arranged outdoors. The heat source unit (20) is arranged, for example, on the roof of a building or on the ground.

The heat source unit (20) has a compressor (21), a heat source heat exchanger (22), and a heat source fan (23). The heat source unit (20) has a switching mechanism (24) for switching a refrigerant flow path, and a heat source expansion valve (25).

The compressor (21) compresses the sucked refrigerant. The compressor (21) discharges compressed refrigerant. The compressor (21) is a rotary compressor such as a scroll compressor, an oscillating piston compressor, a rolling piston compressor, or a screw compressor. The compressor (21) is configured such that its operating frequency (rotational speed) is variable by an inverter device.

The heat source heat exchanger (22) is an outdoor heat exchanger. The heat source heat exchanger (22) is a fin-and-tube air heat exchanger. The heat source heat exchanger (22) exchanges heat between the refrigerant flowing therein and the outdoor air.

The heat source fan (23) is arranged outdoors near the heat source heat exchanger (22). The heat source fan (23) of this example is a propeller fan. The heat source fan (23) conveys air passing through the heat source heat exchanger (22).

The switching mechanism (24) changes the flow path of the refrigerant circuit (11) so as to switch between the first refrigerating cycle, which is the cooling cycle, and the second refrigerating cycle, which is the heating cycle. The switching mechanism (24) is a four-way switching valve. The switching mechanism (24) has a first port, a second port, a third port and a fourth port. A first port of the switching mechanism (24) is connected to a discharge portion of the compressor (21). A second port of the switching mechanism (24) is connected to the suction portion of the compressor (21). A third port of the switching mechanism (24) is connected to the second communication pipe (14) through the second shutoff valve (16). A fourth port of the switching mechanism (24) is connected to the gas end of the heat source heat exchanger (22).

The switching mechanism (24) switches between a first state and a second state. The switching mechanism (24) in the first state (the state indicated by the solid line in FIG. 1) communicates the first port and the fourth port and communicates the second port and the third port. The switching mechanism (24) in the second state (the state indicated by the dashed line in FIG. 1) communicates the first port and the third port, and communicates the second port and the fourth port.

The heat source expansion valve (25) reduces the pressure of the refrigerant. The heat source expansion valve (25) is an outdoor expansion valve. The heat source expansion valve (25) is arranged between the first closing valve (15) and the heat source heat exchanger (22) in the heat source circuit (20a). The heat source expansion valve (25) is an electronic expansion valve whose degree of opening is adjustable.

The heat source unit (20) has a first controller (C1).

(2-4) Usage Units The multiple usage units (30) of this example include a first usage unit (30A) and a second usage unit (30B). The number of utilization units (30) may be three or more. The configurations of the first usage unit (30A) and the second usage unit (30B) are basically the same. Hereinafter, for convenience, the first usage unit (30A) and the second usage unit (30B) may be simply referred to as the usage unit (30).

A utilization unit (30) is an indoor unit installed in a room such as a building. The term "indoor" as used herein is meant to include the space behind the ceiling panel. The utilization unit (30) of this example is a ceiling installation type. The term "ceiling installation type" as used herein includes a ceiling hanging type in which the usage unit (30) is suspended and a ceiling embedded type in which the usage unit (30) is arranged in an open part of the ceiling surface.

The utilization unit (30) has a utilization expansion valve (31), a utilization heat exchanger (32), and a utilization fan (33).

The utilization expansion valve (31) reduces the pressure of the refrigerant. The utilization expansion valve (31) is an indoor expansion valve. The utilization expansion valve (31) is arranged in the flow path on the liquid side of the utilization heat exchanger (32) in the utilization circuit (30a). The utilization expansion valve (31) is an electronic expansion valve whose degree of opening is adjustable.

The utilization heat exchanger (32) is an indoor heat exchanger. The utilization heat exchanger (32) is a fin-and-tube air heat exchanger. The utilization heat exchanger (32) exchanges heat between the refrigerant flowing therein and the indoor air.

The utilization fan (33) is arranged indoors near the utilization heat exchanger (32). The utilization fan (33) of this example is a centrifugal fan. The utilization fan (33) conveys air passing through the utilization heat exchanger (32).

The utilization unit (30) has a second controller (C2). The second controller (C2) and the first controller (C1) of each utilization unit (30) are connected to each other via a first communication line (W1). The first communication line (W1) is wired or wireless.

(2-5) Remote Controller The air conditioner (10) has a remote controller (40). One remote controller (40) in this example is provided for each corresponding usage unit (30). The remote controller (40) is a device for operating the air conditioner (10). As shown in FIG. 2, the remote controller (40) has a first operating section (41) and a first display section (42) as functional sections. It should be noted that the term "functional unit" used here or described below includes a functional unit realized only by hardware, a functional unit realized only by software, and a functional unit realized by cooperation between hardware and software. Including function part.

The first operation section (41) is a functional section for a person to input various instructions to the air conditioner (10). The 1st operation part (41) contains a switch, a button, or a touch panel.

The first display section (42) is a functional section that displays settings for the air conditioner (10) and the state of the air conditioner (10). The first display (42) includes a display.

The remote controller (40) has a third control device (C3). The third control device (C3) and the second control device (C2) are connected to each other via a second communication line (W2). The second communication line (W2) is wired or wireless.

(2-6) The air conditioner (10) is provided with a safety device (5). The safety device (5) includes a refrigerant sensor (45) and countermeasure devices (50, 55, 60). The refrigerant sensor (45) detects refrigerant leakage. The countermeasure device (50, 55, 60) is a device that takes countermeasures against refrigerant leakage. The countermeasure device (50, 55, 60) includes at least one of a blocking device (50), a ventilation device (55), and an alarm device (60). The safety device (5) of this example is provided corresponding to the first usage unit (30A). In other words, the safety device (5) is provided corresponding to the first target space (S1). A safety device (5) may be provided corresponding to the second utilization unit (30B) and the second object space (S).

(2-7) Refrigerant Sensor The air conditioner (10) of the example shown in FIG. 1 has a refrigerant sensor (45). The refrigerant sensor (45) is provided corresponding to the target space (S) determined to require the safety device (5).

The refrigerant sensor (45) is a semiconductor type sensor. The refrigerant sensor (45) outputs a detection signal with a higher intensity (for example, a current value) as the concentration of the leaked refrigerant increases. The refrigerant sensor (45) is not limited to the semiconductor type, and may be of another type such as an infrared type.

The refrigerant sensor (45) and the second control device (C2) of the first usage unit (30A) are connected to each other by a third communication line (W3). The third communication line (W3) is wired or wireless. A detection signal output from the refrigerant sensor (45) is input to the second control device (C2) via the third communication line (W3).

(2-8) Shutoff Device The air conditioner (10) has a shutoff device (50) as a countermeasure device. The blocking device (50) is provided corresponding to the target space (S) determined to require the safety device (5). In this example, a blocking device (50) is provided corresponding to the first target space (S1) or the first usage unit (30A). The shutoff device (50) has a first shutoff valve (51) and a second shutoff valve (52).

The first shutoff valve (51) is a liquid side shutoff valve. The first shutoff valve (51) of this example is provided in the first branch pipe (13b) connected to the first utilization unit (30A). The first cutoff valve (51) is an on-off valve such as a solenoid valve or an electric valve.

The second shutoff valve (52) is a gas side shutoff valve. The second shutoff valve (52) of this example is provided in the second branch pipe (14b) connected to the first utilization unit (30A). The second cutoff valve (52) is an on-off valve such as an electromagnetic valve or an electric valve.

The shut-off device (50) has a fourth control device (C4). The fourth control device (C4) and the second control device (C2) of the first usage unit (30A) are connected to each other via a fourth communication line (W4). The fourth communication line (W4) is wired or wireless.

(2-9) Ventilation Device The air conditioner (10) has a ventilation device (55) as a countermeasure device. The ventilator (55) is provided corresponding to the target space (S) determined to require the safety device (5). In this example, a ventilator (55) is provided corresponding to the first target space (S1) or the first usage unit (30A). The shut-off device (50) has a ventilation fan (56). The ventilation fan (56) exhausts the air in the target space (S) to the outside through an exhaust path (not shown).

The ventilator (55) has a fifth controller (C5). The fifth control device (C5) and the second control device (C2) of the first usage unit (30A) are connected to each other via a fifth communication line (W5). The fifth communication line (W5) is wired or wireless.

(2-10) Alarm Device The air conditioner (10) has an alarm device (60) as a countermeasure device. The alarm device (60) is provided corresponding to the target space (S) determined to require the safety device (5). In this example, an alarm device (60) is provided corresponding to the first object space (S1) or the first usage unit (30A). The alarm device (60) has a light emitter (61) and a sound generator (62) as an alarm. The light emitting part (61) notifies a person of refrigerant leakage with light. The light emitting part (61) is, for example, an LED. The sound generator (62) notifies a person of refrigerant leakage by sound. The sound generator (62) is, for example, a speaker.

The alarm device (60) has a sixth controller (C6). The sixth control device (C6) and the second control device (C2) of the first usage unit (30A) are connected to each other via a sixth communication line (W6). The sixth communication line (W6) is wired or wireless.

(2-11) Notification Device As shown in FIG. 2, the air conditioner (10) includes a notification device (70). The notification device (70) is a device that notifies a person (strictly speaking, an administrator) that the refrigerant has leaked. The notification device (70) includes a seventh control device (C7) and a notification section (71). The seventh control device (C6) and the second control device (C2) of the first usage unit (30A) are connected to each other via a seventh communication line (W7). The seventh communication line (W6) is wired or wireless.

The reporting section (71) reports information indicating that the refrigerant has leaked. The reporting section (71) of this example outputs information indicating that the refrigerant has leaked to the central monitoring device (65). This allows the administrator to know that the refrigerant is leaking (details will be described later). The term "notification" as used herein includes notifications such as e-mail and FAX notifications, sound (including voice) notifications, screen displays, and the like.

The notification device (70) may be provided in the utilization unit (30) or may be provided in the heat source unit (20).

(2-12) Control Unit The control unit (AC) controls the operation of the air conditioner (10). The control unit (AC) comprises a first control device (C1), a second control device (C2), a third control device (C3), a fourth control device (C4), a fifth control device (C5), a sixth control device Device (C6), seventh control device (C7), first communication line (W1), second communication line (W2), third communication line (W3), fourth communication line (W4), fifth communication line ( W5), a sixth communication line (W6), and a seventh communication line (W7). A first controller (C1), a second controller (C2), a third controller (C3), a fourth controller (C4), a fifth controller (C5), a sixth controller (C6), and a Each of the 7 controllers (C7) includes an MCU (Micro Control Unit, microcontroller unit), an electrical circuit, and an electronic circuit. The MCU includes a CPU (Central Processing Unit), a memory, and a communication interface. Various programs for the CPU to execute are stored in the memory.

The first controller (C1) is a heat source controller. The first control device (C1) controls the compressor (21), the heat source expansion valve (25), and the heat source fan (23).

The second control device (C2) is a usage control unit. The second control device (C2) controls the utilization expansion valve (31) and the utilization fan (33). The second control device (C2) receives the detection signal of the refrigerant sensor (45). The second control device (C2) determines whether the detected value of the refrigerant sensor (45) exceeds the first value. The second control device (C2) determines whether the detected value of the refrigerant sensor (45) exceeds a second value. Here, the detected value of the refrigerant sensor (45) is, for example, an output current value. The detected value of the refrigerant sensor (45) increases according to the surrounding refrigerant concentration. The second value is greater than the first value. For example, the first value is a few percent of the second value.

The second control device (C2) activates the notification device (70) when the detected value of the refrigerant sensor (45) exceeds the first value. Specifically, the second control device (C2) outputs a first signal to the notification device (70) when the detected value of the refrigerant sensor (45) exceeds the first value.

The second control device (C2) activates the countermeasure devices (50, 55, 60) when the detected value of the refrigerant sensor (45) exceeds the second value. Specifically, the second control device (C2) outputs a second signal to the countermeasure device (50, 55, 60) when the detected value of the refrigerant sensor (45) exceeds the second value. In addition, the second control device (C2) outputs a third signal to the notification device (70) when the detected value of the refrigerant sensor (45) exceeds the second value.

The third control device (C3) outputs an instruction based on the input of the first operation section (41) to the second control device (C2). The third control device (C3) causes the first display section (42) to display predetermined information according to the input of the first operation section (41).

The fourth control device (C4) controls the open/close states of the first shutoff valve (51) and the second shutoff valve (52). When the second signal output from the second control device (C2) is input to the fourth control device (C4), the fourth control device (C4) switches between the first shutoff valve (51) and the second shutoff valve (52). ).

A fifth controller (C5) controls the ventilation fan (56). When the second signal output from the second control device (C2) is input to the fifth control device (C5), the fifth control device (C5) operates the ventilation fan (56).

A sixth controller (C6) controls an alarm device (60). When the second signal output from the second control device (C2) is input to the sixth control device (C6), the sixth control device (C6) controls the light emitting section (61) and the sound generating section (62). activate.

The seventh control device (C7) controls the notification section (71). When the first signal output from the second control device (C2) is input to the seventh control device (C7), the seventh control device (C7) causes the reporting section (71) to report the first information. . When the third signal output from the second control device (C2) is input to the seventh control device (C7), the seventh control device (C7) sends the second information different from the first information from the reporting unit (71). inform information.

The first information includes information regarding refrigerant leakage. The second information includes information about refrigerant leakage, information about the operation of the countermeasure device (50, 55, 60), and information about the inoperability of the air conditioner (10). The degree of the refrigerant leakage level for the information about the refrigerant leakage in the first information is lower than the degree of the refrigerant leakage level for the information about the refrigerant leakage in the second information.

(2-13) Sensors As shown in FIG. 1, the air conditioner (10) has a plurality of sensors. These sensors are high pressure sensor (90), low pressure sensor (91), discharge temperature sensor (92), suction temperature sensor (93), first refrigerant temperature sensor (94), second refrigerant temperature sensor (95). , a third refrigerant temperature sensor (96), an outside air temperature sensor (97), and a suction temperature sensor (98).

The high pressure sensor (90) detects the pressure of high pressure refrigerant (discharged refrigerant) discharged from the compressor (21). The low-pressure sensor (91) detects the pressure of low-pressure refrigerant (intake refrigerant) sucked into the compressor (21). The discharge temperature sensor (92) detects the temperature of high-pressure refrigerant discharged from the compressor (21). The first refrigerant temperature sensor (94) detects the temperature of the refrigerant at the liquid side end of the heat source heat exchanger (22). The second refrigerant temperature sensor (95) detects the temperature of the refrigerant at the liquid side end of the heat utilization heat exchanger (32). The third refrigerant temperature sensor (96) detects the temperature of refrigerant at the gas-side end of the heat utilization heat exchanger (32). The outside air temperature sensor (97) detects the temperature of outside air. The intake temperature sensor (98) detects the temperature of indoor air blown into the utilization unit (30).

(3) Air Conditioning System As shown in FIG. 3, the air conditioner (10) described above is a system of equipment having one refrigerant circuit (11). In a building or the like, an air conditioning system (1) including a plurality of systems of air conditioners (10) is configured. An air conditioning system (1) has a plurality of air conditioners (10) and a central monitoring device (65).

The central monitoring device (65) has a second operating section (66) and a second display section (67) as functional sections.

The second operation section (66) is a functional section for a person (administrator, etc.) to input various instructions to each air conditioner (10). The second operation unit (66) includes switches, buttons, or a touch panel.

The second display section (67) is a functional section that displays settings for each air conditioner (10) and the state of each air conditioner (10). The second display (67) includes a display.

The central monitoring device (65) has an eighth controller (C8). The eighth controller (C8) and the controller (AC) of each air conditioner (10) are connected to each other via an eighth communication line (W8). The eighth communication line (W8) is wired or wireless.

The eighth controller (C8) includes an MCU (Micro Control Unit), an electric circuit, and an electronic circuit. The MCU includes a CPU (Central Processing Unit), a memory, and a communication interface. Various programs for the CPU to execute are stored in the memory.

Information from the reporting section (71) is input to the centralized monitoring device (65) via the eighth communication line (W8). When the central monitoring device (65) receives the notification, the information from the notification section (71) is displayed on the second display section (67). Specifically, when the first information is input to the central monitoring device (65), the second display section (67), for example, displays information (low level) regarding refrigerant leakage. When the second information is input to the central monitoring device (65), for example, the second display section (67) displays information about refrigerant leakage (high level), indicating that the countermeasure devices (50, 55, 60) are operating. and at least one of information indicating that the air conditioner (10) cannot be operated. The displayed information includes characters, symbols, icons, graphics, and the like. The centralized monitoring device (65) may notify the administrator of these information by voice.

(4) Operating Behavior The operating behavior of the air conditioner (10) will be described with reference to FIG. The air conditioner (10) switches between cooling operation and heating operation. In FIG. 1, the flow of refrigerant during cooling operation is indicated by solid arrows, and the flow of refrigerant during heating operation is indicated by dashed arrows.

(4-1) Cooling operation In the cooling operation, the first control device (C1) operates the compressor (21) and the heat source fan (23), sets the switching mechanism (24) to the first state, and heat source expansion valve (25). ) is fully open. The second control device (C2) operates the utilization fan (33) and adjusts the utilization expansion valve (31) to a predetermined degree of opening. During normal cooling operation, the first shutoff valve (51) and the second shutoff valve (52) are open.

During the cooling operation, the refrigerant circuit (11) performs the first refrigerating cycle. In the first refrigerating cycle, the heat source heat exchanger (22) functions as a radiator (strictly speaking, a condenser), and the utilization heat exchanger (32) functions as an evaporator.

Specifically, the refrigerant compressed by the compressor (21) flows through the heat source heat exchanger (22). In the heat source heat exchanger (22), the refrigerant releases heat to the outdoor air and condenses. The refrigerant condensed in the heat source heat exchanger (22) flows through the first communication pipe (13) and is branched to each utilization circuit (30a). In each utilization circuit (30a), the refrigerant is decompressed by the utilization expansion valve (31) and then flows through the utilization heat exchanger (32). In the heat utilization heat exchanger (32), the refrigerant absorbs heat from the indoor air and evaporates. The refrigerant evaporated in each utilization heat exchanger (32) joins in the second communication pipe (14) and is sucked into the compressor (21).

(4-2) Heating operation In the heating operation, the first control device (C1) operates the compressor (21) and the heat source fan (23), sets the switching mechanism (24) to the second state, and heats the heat source expansion valve (25). ) is adjusted to a predetermined opening. The second control device (C2) operates the utilization fan (33) and adjusts the utilization expansion valve (31) to a predetermined degree of opening. During normal heating operation, the first shutoff valve (51) and the second shutoff valve (52) are open.

During the heating operation, the refrigerant circuit (11) performs the second refrigerating cycle. In the second refrigerating cycle, the utilization heat exchanger (32) functions as a radiator (strictly speaking, a condenser), and the heat source heat exchanger (22) functions as an evaporator.

Specifically, the refrigerant compressed by the compressor (21) flows through the second communication pipe (14) and is branched to each utilization circuit (30a). In each utilization circuit (30a), refrigerant flows through a utilization heat exchanger (32). In the utilization heat exchanger (32), the refrigerant releases heat to the room air and condenses. The refrigerant condensed in each utilization heat exchanger (32) is decompressed in each utilization expansion valve (31) and then joins in the first communication pipe (13). The refrigerant in the first communication pipe (13) is decompressed by the heat source expansion valve (25) and then flows through the heat source heat exchanger (22). In the heat source heat exchanger (22), the refrigerant absorbs heat from outdoor air and evaporates. The refrigerant evaporated in the heat source heat exchanger (22) is sucked into the compressor (21).

(5) Operation at Refrigerant Leakage The operation of the air conditioner (10) at the time of refrigerant leakage will be described with reference to FIG. The following operations are performed during operation of the air conditioner (10).

When refrigerant leaks from the first usage unit (30A), the leaked refrigerant flows into the first target space (S1). Specifically, since the density of the refrigerant is higher than that of air, the refrigerant flows downward in the first target space (S1). As a result, the concentration of the refrigerant in the first target space (S1) gradually increases.

In step S11, the refrigerant sensor (45) detects refrigerant leakage. The detected value of the refrigerant sensor (45) is input to the second control device (C2) of the first usage unit (30A) via the third communication line (W3).

In step S12, the second control device (C2) determines whether or not the detected value of the refrigerant sensor (45) exceeds the first value. When the detected value of the refrigerant sensor (45) exceeds the first value, the second controller (C2) outputs a first signal to the seventh controller (C7) in step S13. In step S13, the seventh control device (C7) causes the reporting section (71) to report. Specifically, the reporting section (71) outputs the first information to the central monitoring device (65).

The second display section (67) of the central monitoring device (65) displays the first information. Specifically, the second display section (67) displays, for example, "refrigerant is beginning to leak", "refrigerant is leaking slowly", "needs some sort of countermeasure against refrigerant leakage", and the like. Displayed as 1 information. This allows the administrator to take some countermeasures when the level of refrigerant leakage is low.

In step S14, the second control device (C2) determines whether or not the detected value of the refrigerant sensor (45) exceeds a second value. When the detected value of the refrigerant sensor (45) exceeds the second value, in step S15 the second control device (C2) outputs a second signal for activating the countermeasure devices (50, 55, 60). At step S15, the countermeasure device (50, 55, 60) operates. Specifically, in step S15, when the second signal output from the second control device (C2) is input to the fourth control device (C4), the fourth control device (C4) controls the cutoff device (50 ) are closed. In step S15, when the second signal output from the second control device (C2) is input to the fifth control device (C5), the fifth control device (C5) operates the ventilation fan (56). In step S15, when the second signal output from the second control device (C2) is input to the sixth control device (C6), the sixth control device (C6) emits light from the light emitting section (61). Let In addition, the sixth control device (C6) causes the sound generator (62) to generate a sound such as a warning sound.

By activating the countermeasure device (50, 55, 60) in this way, refrigerant leakage can be reliably suppressed when countermeasures against refrigerant leakage based on the first information are not in time.

When the detected value of the refrigerant sensor (45) exceeds the second value in step S14, the second controller (C2) outputs a second signal to the seventh controller (C7) in step S16. In step S16, the seventh control device (C7) causes the reporting section (71) to report. Specifically, the reporting section (71) outputs the second information to the central monitoring device (65).

A second display section (67) of the central monitoring device (65) displays the second information. Specifically, the second display section (67) indicates that "the refrigerant is leaking significantly", "the refrigerant is leaking rapidly", "the countermeasure device has been activated due to the refrigerant leakage", The second information such as "the air conditioner (10) cannot be operated due to refrigerant leakage" is displayed. This allows the administrator to know when the level of refrigerant leakage is high and to take countermeasures accordingly.

(6) Features (6-1)
The air conditioner (10) includes a countermeasure device (50, 55, 60) against refrigerant leakage in the target space (S), a reporting unit (71), a countermeasure device (50, 55, 60) and the reporting unit (71). ) and a control unit (AC) for controlling the The control section (AC) causes the notification section (71) to issue predetermined information when the detected value of the refrigerant sensor (45) exceeds the first value. The control unit (AC) activates the countermeasure device (50, 55, 60) when the detected value of the refrigerant sensor (45) exceeds a second value that is larger than the first value.

As a result, for example, even if the refrigerant leaks slowly and the concentration of the refrigerant in the target space (S) is at a relatively low level, the notification unit (71) issues a notification so that the administrator or the like can promptly notify the situation. can know. Therefore, before the level of leakage of the refrigerant becomes large, the manager or the like can take some countermeasures.

When the refrigerant concentration in the target space (S) reaches a relatively high level, the countermeasure device (50, 55, 60) is activated. Therefore, the countermeasure device (50, 55, 60) reliably suppresses the refrigerant leakage even if the manager or the like fails to take countermeasures in time. Therefore, sufficient safety measures can be taken for the target space (S).

(6-2)
The notification section (71) causes the notification section (71) to issue first information when the detected value of the refrigerant sensor (45) exceeds the first value, and the detected value of the refrigerant sensor (45) exceeds the second value. When crossing, the notification section (71) issues second information different from the first information. As a result, a manager or the like can know necessary information according to the level of refrigerant concentration in the target space (S).

Specifically, the reporting section (71) outputs first information indicating that there is a low-level refrigerant leak from the reporting section (71) when the detected value of the refrigerant sensor (45) exceeds the first value. report. The reporting section (71) issues second information indicating that there is a high level of refrigerant leakage from the reporting section (71) when the detected value of the refrigerant sensor (45) exceeds the second value. Therefore, the administrator can take appropriate measures according to the level of refrigerant leakage.

(6-3)
The second information includes information on refrigerant leakage, information on the operation of the countermeasure device (50, 55, 60), and information on the inoperability of the air conditioner (10). contains at least one

For this reason, when the refrigerant concentration in the target space (S) is at a relatively high level, the administrator must confirm that the refrigerant is leaking, that the countermeasure device (50, 55, 60) is operating, or It is possible to quickly know that the air conditioner (10) cannot be operated.

(7) Modifications The above embodiment may be modified as follows. Differences from the embodiment will be described below.

(7-1) Modification 1
The air conditioner (10) according to Modification 1 acquires information on refrigerant leakage based on its operating data. As shown in FIG. 5, the control section (AC) of the air conditioner (10) of Modification 1 includes a storage section (81) and an information acquisition section (82) as a functional section. In this example, the storage section (81) and the information acquisition section (82) are provided in the first control device (C1) of the heat source unit (20). The storage section (81) and the information acquisition section (82) may be provided in the second control device (C2) of the usage unit (30).

The storage unit (81) includes a HDD (Hard Disk Drive), a RAM (Random Access Memory), an SSD (Solid State Drive), and the like. The storage section (81) stores the detected values of the plurality of sensors (90 to 97) as operation data. In addition, the storage unit (81) stores, as operation data of the air conditioner (10), the rotational speed (operating frequency) of the compressor (21), the opening of the utilization expansion valve (31), the heat source expansion valve (25) opening, target evaporating temperature, target condensing temperature, indoor set temperature, air volume of heat source fan (23), air volume of utilization fan (33), and other control parameters are stored.

The information acquisition section (82) acquires information on refrigerant leakage based on the operating data stored in the storage section (81). Specifically, the information acquiring section (82) of the present example identifies the location of refrigerant leakage based on the operating data.

For example, when the pressure detected by the high-pressure sensor (90) drops rapidly compared to the pressure detected by the low-pressure sensor (91), it can be determined that refrigerant has leaked from the high-pressure line of the refrigerant circuit (11). Alternatively, when the pressure detected by the low-pressure sensor (91) drops sharply compared to the pressure detected by the high-pressure sensor (90), it can be determined that refrigerant has leaked from the low-pressure line of the refrigerant circuit (11). Further, by providing pressure sensors for the first communication pipe (13), which is a liquid pipe, and the second communication pipe (14), which is a gas pipe, refrigerant leakage in these communication pipes (13, 14) can be identified. Furthermore, from the detected values of various sensors (90 to 97), the theoretical amount of refrigerant in the high-pressure line, low-pressure line, connecting pipe (12), etc. is estimated, and by judging the decrease in these refrigerant amounts, refrigerant leakage is detected. can be identified. In this case, based on the internal volumes of the utilization heat exchanger (32), the heat source heat exchanger (22), the connecting pipe (12), etc., and the density of the refrigerant flowing through them, each predetermined portion of the refrigerant circuit (11) A theoretical refrigerant amount can be estimated.

The operation of the air conditioner (10) of Modification 1 will be described with reference to FIG.

In step S21, the storage section (81) of the information acquisition section (82) stores the detection values and control parameters of the sensors (90 to 97) as operation data. The storage section (81) stores the operating data at predetermined time intervals. In step S22, the refrigerant sensor (45) detects refrigerant leakage.

In step S23, the control section (AC) determines whether or not the detected value of the refrigerant sensor (45) exceeds the first value. When the detected value of the refrigerant sensor (45) exceeds the first value, in step S24, the information acquisition section (82) stores the information in the storage section (81) in synchronism with the fact that the detected value exceeds the first value. Obtain information on refrigerant leakage based on the obtained operating data.

Here, the operating data referred to by the information acquiring section (82) of this example is data for a predetermined first period including time t1 when the detection value of the refrigerant sensor (45) exceeds the first value. The start time of the first period is a time point a predetermined time before time t1. The end point of the first period is a certain point after a predetermined time after the point t1. When the detected value of the refrigerant sensor (45) exceeds the first value, the operating data also shows signs of refrigerant leakage. Therefore, in Modified Example 1, the information obtaining section (82) obtains information about refrigerant leakage based on the operating data in the first period.

The information about refrigerant leakage includes the location of refrigerant leakage identified based on the operating data. That is, in step S24, the information obtaining section (82) identifies the refrigerant leak location based on the operation data in the first period.

In step S25, the reporting section (71) reports the first information and the third information. Here, the third information is information including the leakage location of the refrigerant. The reporting section (71) outputs the first information and the third information to the central monitoring device (65).

The second display section (67) of the central monitoring device (65) displays the third information in addition to the first information. Specifically, the second display section (67) displays the location of refrigerant leakage identified based on the operating data. Therefore, the administrator can not only know from the refrigerant sensor (45) that the refrigerant is leaking, but also know at which point in the refrigerant circuit (11) the refrigerant is leaking.

Steps S26 to S28 according to Modification 1 are the same as steps S14 to S16 of the embodiment.

As described above, in Modification 1, when the detected value of the refrigerant sensor (45) exceeds the first value, the notification section (71) issues the first information for notifying the leakage of the refrigerant. The detection accuracy of refrigerant leakage by the refrigerant sensor (45) is higher than the accuracy of determination of refrigerant leakage based on operation data. Therefore, even when the refrigerant is slowly leaking into the target space (S), it is possible to reliably notify the manager or the like of the refrigerant leakage.

On the other hand, detection of refrigerant leakage by the refrigerant sensor (45) alone cannot identify the portion of the refrigerant circuit (11) where the refrigerant is leaking. In contrast, in Modification 1, the information acquisition section (82) provides information (strictly speaking, acquires information on the location of leakage of the refrigerant). Therefore, based on the data acquired by the information acquiring section (82), the administrator or the like can determine in which part of the refrigerant circuit (11) the refrigerant is leaking.

More specifically, since the notification unit (71) notifies the first information as well as the third information specifying the location of the refrigerant leakage, the operator can detect not only the leakage of the refrigerant but also the location of the refrigerant leakage. can be known to

(7-1-1) Another form 1 of modification 1
After the reporting section (71) reports the first information, the information acquisition section (82) may identify the refrigerant leak location. In this case, the notification section (71) immediately issues the third information after the location of the refrigerant leak is identified.

(7-1-2) Another form 2 of modification 1
The reporting unit (71) may report the operating data itself for the first period. By referring to the operation data of the first period, the administrator can determine the location of refrigerant leakage by himself/herself.

(7-1-3) Another form 3 of modification 1
The information acquiring section (82) of Modification 1 acquires information about refrigerant leakage based on the operating data for the first period including time t1 when the detected value exceeds the first value. However, the information acquiring section (82) obtains information about refrigerant leakage based on the operating data for the second period from time t1 when the detection value of the refrigerant sensor (45) exceeds the first value until a predetermined time has elapsed. may be obtained. The reporting section (71) reports the first information and the third information after the second period has elapsed.

(7-1-4) Another form 4 of modification 1
The information on refrigerant leakage acquired by the information acquiring section (82) may include a determination result as to whether or not the refrigerant is leaking based on the operating data. The notifying section (71) notifies the result of this determination as the fourth information, so that the manager or the like can know the refrigerant leakage more accurately. The information acquiring section (82) determines whether or not the refrigerant is leaking based on the operating data, for example, by the following method.

A) Decrease in High Pressure and Low Pressure in Refrigerating Cycle When the refrigerant in the refrigerant circuit (11) leaks, the high pressure and low pressure decrease. Therefore, the information obtaining section (82) determines whether the refrigerant is leaking based on the high pressure detected by the high pressure sensor (90) and the low pressure detected by the low pressure sensor (91).

B) Increase in Discharge Temperature When the refrigerant in the refrigerant circuit (11) leaks and runs out of gas, the temperature of the refrigerant discharged from the compressor (21) rises sharply. Therefore, the information obtaining section (82) determines whether the refrigerant is leaking based on the temperature of the discharged refrigerant detected by the discharge temperature sensor (92).

C) Increase in Degree of Suction Superheat When the refrigerant in the refrigerant circuit (11) leaks and runs out of gas, the degree of suction superheat of the refrigerant sucked into the compressor (21) rises sharply. Therefore, the information obtaining section (82) determines whether or not the refrigerant is leaking based on the degree of suction superheat. Here, for example, the degree of suction superheat can be obtained from the difference between the temperature of the suction refrigerant detected by the suction temperature sensor (93) and the saturation temperature corresponding to the low pressure detected by the low pressure sensor (91).

D) Decrease in Degree of Supercooling When the refrigerant in the refrigerant circuit (11) leaks and becomes gaseous, the degree of supercooling in the condenser (radiator) drops rapidly. Therefore, the information obtaining section (82) determines whether or not the refrigerant is leaking based on the degree of supercooling. Here, for example, the degree of subcooling can be obtained from the difference between the saturation temperature corresponding to the high pressure detected by the high pressure sensor (90) and the refrigerant temperature at the outlet of the heat exchanger serving as the condenser. Here, the refrigerant temperature at the outlet of the heat exchanger serving as the condenser is the temperature detected by the first refrigerant temperature sensor (94) in cooling operation. In the case of heating operation, the temperature is the temperature detected by the second refrigerant temperature sensor (95).

E) Reduction in temperature difference between air before and after passing through heat exchanger When the refrigerant in the refrigerant circuit (11) leaks and becomes gaseous, the temperature difference between air before and after passing through the heat exchanger decreases. Therefore, the information obtaining section (82) determines whether or not the refrigerant is leaking based on the air temperature difference. Here, for example, if it is a utilization unit (30), in addition to a suction temperature sensor (98), a blowing temperature sensor is provided. The blowout temperature sensor detects the temperature of the air that has passed through the utilization heat exchanger (32). The air temperature difference can be obtained from the difference between the temperature detected by the intake temperature sensor (98) and the temperature detected by the outlet temperature sensor.

The information acquiring section (82) similarly determines that the refrigerant is leaking when the temperature difference between the air before and after the heat source heat exchanger (22) becomes small.

The information obtaining section (82) determines whether or not the refrigerant is leaking by at least one of the above methods A) to E) or a combination of two or more of these methods.

(7-1-5) Another form 5 of modification 1
The information acquisition section (82) acquires information (the above-described third information and fourth information) on the refrigerant leakage based on the operation data in synchronization with the detection value of the refrigerant sensor (45) exceeding the second value. You may In this case, the reporting section (71) reports the third information and the fourth information together with the second information. In this case, a manager or the like can know the location of refrigerant leakage at the timing when the countermeasure device (50, 55, 60) is activated.

(7-2) Modification 2
The air conditioner (10) of the above embodiment performs the operations shown in FIG. 4 during its operation. However, the air conditioner (10) may perform the operations shown in FIG. 4 while it is not in the cooling operation or the heating operation.

Specifically, the refrigerant sensor (45) detects the concentration of refrigerant in the air-conditioned space (S) of the usage unit (30) while the air conditioner (10) is stopped. The control section (AC) causes the notification section (71) to issue predetermined information when the detection value of the refrigerant sensor (45) exceeds the first value while the air conditioner (10) is stopped. The control unit (AC) activates the countermeasure device (50, 55, 60) when the detected value of the refrigerant sensor (45) exceeds the second value.

As a result, even if the refrigerant slowly leaks while the air conditioner (10) is stopped, the manager or the like can be promptly notified of the fact. Even if the refrigerant concentration in the target space (S) becomes relatively high while the air conditioner (10) is stopped, the countermeasure device (50, 55, 60) can quickly suppress refrigerant leakage.

(7-3) Modification 3
The reporting unit (71) of the embodiment reports predetermined information to the central monitoring device (65). However, the reporting unit (71) may issue a report to a location (such as a control center) other than the location (such as a building) where the air conditioner (10) is installed. In this case, the notification section (71) notifies the manager of the management center of the predetermined information by, for example, e-mail, FAX, or voice call.

(7-4) Modification 4
The air conditioner (10) of the embodiment has a blocking device (50), a ventilator (55), and an alarm device (60) as countermeasure devices. However, the air conditioner (10) uses any two of the blocking device (50), the ventilation device (55), and the alarm device (60), or any one of them, as countermeasure devices. may have.

<<Other embodiments>>
The above-described embodiment and its modification may have the following configurations.

1) The air conditioner (10) may not be a multi-type, but may be a pair type having one utilization unit (30) and one heat source unit (20). The air conditioner (10) may have a plurality of heat source units (20).

2) The refrigerant filled in the refrigerant circuit (11) may be a refrigerant other than R32. The refrigerant is Class 3 (strongly flammable), Class 2 (weakly flammable), and Subclass 2L (slightly flammable) in the US ASHRAE34 Designation and Safety Classification of Refrigerant Standards or ISO817 Refrigerants- Designation and Safety Classification Standards. including.

For example, the refrigerant is a single refrigerant consisting of R1234yf, R1234ze(E), R516A, R445A, R444A, R454C, R444B, R454A, R455A, R457A, R459B, R452B, R454B, R447B, R32, R447A, R446A, and R459. .

Alternatively, the refrigerant is any two selected from R1234yf, R1234ze(E), R516A, R445A, R444A, R454C, R444B, R454A, R455A, R457A, R459B, R452B, R454B, R447B, R32, R447A, R446A, and R459. It is a mixed refrigerant composed of the above refrigerants.

3) The switching mechanism (24) does not have to be a four-way switching valve. The switching mechanism (24) may be configured by combining four flow paths and on-off valves for opening and closing these, or may be configured by combining two three-way valves.

4) The heat source expansion valve (25) and utilization expansion valve (31) may not be electronic expansion valves, but may be temperature sensitive expansion valves or rotary expansion mechanisms.

5) The utilization unit (30) does not have to be ceiling-mounted, but may be wall-mounted or floor-mounted.

Although embodiments and variations have been described above, it will be appreciated that various changes in form and detail may be made without departing from the spirit and scope of the claims. In addition, the above embodiments, modifications, and other embodiments may be appropriately combined or replaced as long as the functions of the object of the present disclosure are not impaired.

The descriptions of "first", "second", "third", etc. described above are used to distinguish the words and phrases to which these descriptions are given, and the number and order of the words and phrases are also limited. not something to do.

INDUSTRIAL APPLICABILITY As described above, the present disclosure is useful for air conditioners.

10 Air conditioner 30 Usage unit 45 Refrigerant sensor 50 Blocking device (countermeasure device)
55 Ventilation device (countermeasure device)
60 alarm device (countermeasure device)
71 reporting unit AC control unit

Claims (5)

a utilization unit (30);
a refrigerant sensor (45) for detecting the concentration of refrigerant in the air-conditioned space (S) of the usage unit (30);
a countermeasure device (50, 55, 60) against refrigerant leakage in the target space (S);
a reporting unit (71);
A control unit (AC) that controls the countermeasure device (50, 55, 60) and the reporting unit (71),
The control section (AC) causes the notification section (71) to issue predetermined information when the detection value of the refrigerant sensor (45) exceeds a first value, and the detection value of the refrigerant sensor (45) is An air conditioner that activates the countermeasure device (50, 55, 60) when a second value larger than the first value is exceeded. When the detected value of the refrigerant sensor (45) exceeds the first value, the control section (AC) causes the notification section (71) to issue first information, and the detected value of the refrigerant sensor (45) 2. The air conditioning apparatus according to claim 1, wherein the notification unit (71) issues second information different from the first information when V exceeds a second value. The second information includes information on refrigerant leakage, information on the operation of the countermeasure device (50, 55, 60), and information on the inoperability of the air conditioner (10). 3. The air conditioner according to claim 2, comprising at least one of The refrigerant sensor (45) detects a refrigerant concentration in a space (S) to be air-conditioned in the usage unit (30) while the air conditioner (10) is stopped, and
The control section (AC) issues predetermined information from the reporting section (71) when the detection value of the refrigerant sensor (45) exceeds a first value while the air conditioner (10) is stopped. 4. The air conditioner according to any one of claims 1 to 3, wherein the countermeasure device (50, 55, 60) is activated when the detected value of the refrigerant sensor (45) exceeds the second value. The control unit (AC) acquires information about refrigerant leakage based on operation data of the air conditioner (10) in synchronization with the detected value of the refrigerant sensor (45) exceeding the first value. The air conditioner according to any one of claims 1 to 4.

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