JP2023106857A - Refrigerating device, refrigerant leakage detection device, and refrigerant leakage detection method - Google Patents

Abstract

To grasp performance degradation of a refrigerant sensor.SOLUTION: A refrigerating device comprises a refrigerant circuit (11) in which a refrigerant is circulated, a first sensor (51) for detecting the refrigerant in an object space (43), and a second sensor (52) arranged in the same object space (43) as the first sensor (51), and for detecting predetermined gas. When the first sensor (51) does not detect the refrigerant due to degradation associated with use of the first sensor (51) and the second sensor (52) in a predetermined period, the second sensor (52) detects the predetermined gas even if the predetermined gas does not exist.SELECTED DRAWING: Figure 5

Description

TECHNICAL FIELD The present disclosure relates to a refrigeration system, a refrigerant leakage detection device, and a refrigerant leakage detection method.

Patent Literature 1 discloses an air conditioner provided with two refrigerant sensors. In this air conditioner, the refrigerant can always be detected by alternately switching between energization and de-energization of each refrigerant sensor. By providing a period in which the refrigerant sensor is not energized, performance deterioration of the refrigerant sensor due to energization is suppressed.

JP 2017-180927 A

In an air conditioner such as that disclosed in Patent Document 1, even if performance deterioration of the refrigerant sensor can be suppressed, it is not possible to grasp how much the performance of the refrigerant sensor has deteriorated.

An object of the present disclosure is to grasp performance deterioration of a refrigerant sensor.

A first aspect of the present disclosure includes:
a refrigerant circuit (11) through which refrigerant circulates;
a first sensor (51) for detecting refrigerant in the target space (43);
a second sensor (52) arranged in the same target space (43) as the first sensor (51) and detecting a predetermined gas;
When the first sensor (51) does not detect the refrigerant due to deterioration due to use of the first sensor (51) and the second sensor (52) for a predetermined period of time, the second sensor (52) detects the The refrigerating apparatus is characterized in that the predetermined gas is detected even in the absence of the predetermined gas.

In the first aspect, some gas sensors become sensitive enough to respond to even trace amounts of gas due to deterioration in performance due to use for a predetermined period of time, and then become unresponsive to exposure to high-concentration gas ( sensitivity is reduced). Detects a second sensor (52) whose performance deteriorates faster than the first sensor (51), or a predetermined gas whose deterioration speed is the same and whose concentration is lower than that detected by the first sensor (51). A second sensor (52) is placed in the same object space as the first sensor (51). As the sensitivities of the first sensor (51) and the second sensor (52) become sharper as the performance deteriorates, the second sensor (52) becomes the first sensor even when there is no gas in the target space (43). react before (51). Thus, when the first sensor (51) does not detect, the performance of the first sensor (51) deteriorates similarly to the second sensor (52) because the second sensor (52) detects. I can understand. Moreover, by confirming the deterioration of the performance of the second sensor (52), the first sensor (51) can be replaced before the deterioration of the performance of the first sensor (51) progresses.

A second aspect is the first aspect,
the predetermined gas is a refrigerant,
The second sensor (52) detects refrigerant in the target space (43).

In the second aspect, both the first sensor (51) and the second sensor (52) sense refrigerant in the target space (43).

A third aspect is the first or second aspect,
The first sensor (51) detects refrigerant having a first concentration,
The second sensor (52) detects the predetermined gas having a concentration lower than the first concentration.

In the third aspect, due to deterioration with use of the first sensor (51) and the second sensor (52), the sensor sensitivity of the second sensor (52) sharpens faster than the first sensor (51). This makes it possible to grasp deterioration of the first sensor (51).

A fourth aspect is the first or second aspect,
The first sensor (51) detects refrigerant having a first concentration,
The second sensor (52) detects the predetermined gas having the same concentration as the first concentration,
The second sensor (52) deteriorates faster than the first sensor (51) after being used for a predetermined period of time.

In the fourth aspect, since the deterioration speed of the second sensor (52) is faster than the deterioration speed of the first sensor (51), the sensor sensitivity of the second sensor (52) is faster than that of the first sensor (51). sensitize. This makes it possible to grasp deterioration of the first sensor (51).

A fifth aspect, in any one of the first to fourth aspects,
A control section (C2) is provided for determining whether or not a first condition is established in which the first sensor (51) detects no refrigerant and the second sensor (52) detects the predetermined gas.

In the fifth mode, progress of deterioration of the first sensor (51) can be grasped by determining whether the first condition is established by the control section (C2).

A sixth aspect is the fifth aspect,
The control unit (C2) detects that the first sensor (51) does not detect the refrigerant and the second sensor (52) detects the predetermined gas for a predetermined period of time. , is determined as the first condition.

In the sixth aspect, by determining whether or not the first condition is satisfied, it is possible to determine whether the refrigerant is actually leaking or whether the first sensor (51) is deteriorated. As a result, erroneous detection of performance deterioration of the first sensor (51) can be suppressed.

A seventh aspect is the fifth or sixth aspect,
A notification section (42) is provided for notifying a person that the first sensor (51) is degraded when the first condition is satisfied.

In the seventh aspect, the reporting section (42) reports to the user, thereby suppressing the delay in discovering the deterioration of the performance of the first sensor (51).

An eighth aspect, in any one of the first to seventh aspects,
Equipped with an indoor unit (30) that conditions the air in the air-conditioned space,
The first sensor (51) and the second sensor (52) are arranged inside the indoor unit (30).

In the eighth aspect, refrigerant leakage inside the indoor unit (30) can be detected.

A ninth aspect is
a first sensor (51) for detecting refrigerant in the target space (43);
a second sensor (52) arranged in the same target space (43) as the first sensor (51) and detecting a predetermined gas;
When the first sensor (51) does not detect the refrigerant due to deterioration due to use of the first sensor (51) and the second sensor (52) for a predetermined period of time, the second sensor (52) detects the The refrigerant leakage detection device is characterized by detecting the predetermined gas even in the absence of the predetermined gas.

A tenth aspect is
a first sensor (51) for detecting refrigerant in the target space (43);
a second sensor (52) arranged in the same target space (43) as the first sensor (51) and detecting a predetermined gas;
When the first sensor (51) does not detect the refrigerant due to deterioration due to use of the first sensor (51) and the second sensor (52) for a predetermined period of time, the second sensor (52) detects the A refrigerant leakage detection method characterized in that the predetermined gas is detected even in the absence of the predetermined gas.

FIG. 1 is a piping system diagram of an air conditioner of an embodiment. FIG. 2 is a block diagram showing the relationship between the controller of the air conditioner and each device. FIG. 3 is a diagram showing the configuration of the indoor unit of the air conditioner. FIG. 4 is a graph schematically showing the characteristics of the refrigerant sensor. FIG. 5 is a diagram for explaining a method of detecting deterioration of a refrigerant sensor. FIG. 6 is a flow chart showing control of refrigerant leakage detection. FIG. 7 is a diagram for explaining a method of detecting deterioration of a refrigerant sensor according to Modification 1. FIG. FIG. 8 is a diagram for explaining a method of detecting deterioration of a refrigerant sensor according to Modification 2. FIG. FIG. 9 is a flow chart showing control of refrigerant leakage detection. FIG. 10 is a block diagram showing the configuration of the refrigerant leakage detection device.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its applications, or its uses. In addition, each configuration such as each embodiment, modified examples, and other examples described below can be combined or partially replaced within the scope in which the present invention can be implemented.

(1) Overall Configuration of Air Conditioner As shown in FIGS. 1 to 3, an air conditioner (10) adjusts the temperature of air in an indoor space (S) such as a building. The air conditioner (10) is an example of the refrigeration system (10) of the present disclosure. The indoor space (S) is an example of the air-conditioned space (S) of the present disclosure.

The air conditioner (10) cools or heats the indoor space (S). The air conditioner (10) is of a multi-type having a plurality of indoor units (30). An air conditioner (10) has an outdoor unit (20), a plurality of indoor units (30), a connecting pipe (12), and a controller (AC). The plurality of indoor units (30) and the outdoor 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 an outdoor circuit (20a) provided in the outdoor unit (20) and an indoor circuit (30a) provided in each indoor 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 indoor space (S), and when the refrigerant concentration in the indoor space (S) increases, the refrigerant may burn. The density of refrigerant is greater than that of air. Therefore, when the refrigerant leaks into the indoor space (S), the refrigerant flows to the lower part of the indoor space (S).

(2-2) Communication Pipe The communication pipe (12) includes a liquid communication pipe (13) and a gas communication pipe (14).

The liquid 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 outdoor circuit (20a) via 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 indoor circuit (30a).

The gas 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 outdoor 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 end of each of the plurality of second branch pipes (14b) is connected to the corresponding indoor unit (30).

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

The outdoor unit (20) has a compressor (21), an outdoor heat exchanger (22), an outdoor fan (23), a switching mechanism (24), an outdoor expansion valve (25) and a first controller (C1).

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

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

The outdoor fan (23) is arranged outdoors near the outdoor heat exchanger (22). The outdoor fan (23) of this example is a propeller fan. The outdoor fan (23) conveys air passing through the outdoor 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 gas 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 outdoor 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 outdoor expansion valve (25) reduces the pressure of the refrigerant. The outdoor expansion valve (25) is arranged between the first closing valve (15) and the outdoor heat exchanger (22) in the outdoor circuit (20a). The outdoor expansion valve (25) is an electronic expansion valve whose degree of opening is adjustable.

(2-4) Indoor Unit As shown in FIG. 3, the indoor unit (30) of this example is a ceiling-embedded type. The indoor unit (30) has a casing (34), an indoor fan (33), an indoor heat exchanger (32), a bellmouth (49), a drain pan (44) and a flap (38). The indoor unit (30) air-conditions the indoor space (S).

The casing (34) has a casing body (35) and a panel (36). The casing body (35) is shaped like a rectangular box with an open surface on the lower side. The panel (36) is detachably provided on the opening surface of the casing body (35). The panel (36) has a rectangular frame-shaped panel body (37) in plan view, and an intake grille (45) provided in the center of the panel body (37). A suction port (46) is formed in the center of the panel body (37). The suction grille (45) is attached to the suction port (46). Each of the four side edges of the panel body (37) is formed with one outlet (47). Inside the casing (34), an air passageway (48) is formed from the inlet (46) to the outlet (47).

The indoor fan (33) is arranged upstream of the indoor heat exchanger (32) in the air passageway (48). The indoor fan (33) is of a centrifugal type. The indoor fan (33) supplies air passing through the indoor heat exchanger (32) to the indoor space (S). The indoor fan (33) is configured such that its air volume can be switched in a plurality of stages.

The indoor heat exchanger (32) is arranged in the air passageway (48). The indoor heat exchanger (32) is arranged around the indoor fan (33). In the indoor heat exchanger (32), heat is exchanged between the air carried by the indoor fan (33) and the refrigerant.

A bellmouth (49) is arranged in the air passageway (48). Specifically, the bell mouth (49) is arranged above the suction port (46). A bellmouth (49) rectifies the intake air.

The drain pan (44) is arranged in the air passageway (48). Specifically, the drain pan (44) is arranged above the bellmouth (49) and below the indoor heat exchanger (32). The drain pan (44) is concavely formed. Water generated when the indoor heat exchanger (32) functions as an evaporator is stored in the drain pan (44). Water stored in the drain pan (44) is discharged to the outside through a drain pipe (not shown).

The flap (38) adjusts the direction of blown air that is blown out from the outlet (47). The flap (38) is provided along the side edge of the panel body (37) or along the longitudinal direction of the outlet (47).

The indoor unit (30) has a second controller (C2). The second controller (C2) and the first controller (C1) of each indoor 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) is provided for each indoor 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. 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 first display section (42) is an example of the notification section (42) of the present disclosure.

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) First Sensor and Second Sensor The air conditioner (10) of the present embodiment includes a first sensor (51) and a second sensor (52). The first sensor (51) and the second sensor (52) are arranged in the same partitioned space inside the indoor unit (30). A first sensor (51) and a second sensor (52) are positioned close to each other. The first sensor (51) and the second sensor (52) detect refrigerant. A refrigerant is an example of a predetermined gas in this disclosure. Hereinafter, the first sensor (51) and the second sensor (52) may be collectively referred to simply as refrigerant sensors (51, 52).

Specifically, the first sensor (51) and the second sensor (52) of the present embodiment are arranged in the first space (43), which is the space inside the drain pan (44). The first space (43) is an example of the target space (43) of this example. Thus, the second sensor (52) is arranged in the same first space (43) as the first sensor (51). The first sensor (51) and the second sensor (52) detect refrigerant in the first space (43).

Since the first space (43) has a recessed shape, refrigerant having a higher density than air tends to accumulate in the first space (43). Therefore, the first sensor (51) in the first space (43) can relatively easily detect refrigerant leaking into the indoor unit (30).

The refrigerant sensors (51, 52) are semiconductor sensors. The refrigerant sensor (51, 52) outputs a detection signal with a higher intensity (for example, a current value) as the concentration of the leaked refrigerant increases. For example, the refrigerant sensors (51, 52) have tin oxide, a ceramic substrate such as alumina, and a heater.

The refrigerant sensors (51, 52) become ready to detect refrigerant gas when energized. Specifically, when the heaters of the refrigerant sensors (51, 52) are energized, the tin oxide is heated through the ceramic substrate. Heating the tin oxide to a predetermined temperature enables the refrigerant sensors (51, 52) to detect the refrigerant. The refrigerant sensors (51, 52) transmit detection signals to the second control device (C2) according to the concentration of the refrigerant contacting the refrigerant sensors (51, 52).

A first sensor (51) detects a first concentration of refrigerant. The first concentration is, for example, 5,000 ppm. Specifically, when the detection signal transmitted from the first sensor (51) to the second control device (C2) indicates 5,000 rpm, the notification device (60), which will be described later, is activated. A second sensor (52) detects a second concentration of refrigerant. The second concentration is lower than the first concentration. The second concentration is, for example, 3,000 rpm. Specifically, the second sensor (52) sends a detection signal indicating 3,000 rpm to the second controller (C2).

The first sensor (51) is connected to each other by the second controller (C2) of the indoor unit (30) and the third communication line (W3). The third communication line (W3) is wired or wireless. A detection signal output from the first sensor (51) is input to the second control device (C2) via the third communication line (W3).

The second sensor (52) is connected to each other by the second controller (C2) of the indoor unit (30) and the fourth communication line (W4). The fourth communication line (W4) is wired or wireless. A detection signal output from the second sensor (52) is input to the second control device (C2) via the fourth communication line (W4).

(2-7) Notification Device The air conditioner (10) has a notification device (60). The notification device (60) is provided in the indoor unit (30). The notification device (60) is a device that notifies a person of refrigerant leakage. Specifically, the notification device (60) notifies the user in the indoor space (S) that the first sensor (51) has detected the first concentration.

The notification device (60) has a light emitting section (61) and a sound generating section (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 notification device (60) has a fourth control device (C4). The fourth controller (C4) is connected to the second controller (C2) of the indoor unit (30) via a fifth communication line (W5). The fifth communication line (W5) is wired or wireless.

The notification device (60) operates by receiving a notification signal transmitted from the second control device (C2). The notification signal is transmitted when the second control device (C2) receives the detection signal transmitted from the first sensor (51). When the notification device (60) is activated, the light emitter (61) emits light and the sound generator (62) emits an alarm sound.

(2-8) Controller The controller (AC) controls the operation of the air conditioner (10). The control device (AC) includes a first control device (C1), a second control device (C2), a third control device (C3), a fourth control device (C4), a first communication line (W1), a second communication It includes a line (W2), a third communication line (W3), a fourth communication line (W4) and a fifth communication line (W5). Each of the first controller (C1), the second controller (C2), the third controller (C3), and the fourth controller (C4) includes an MCU (Micro Control Unit), an electric circuit, Contains electronic circuits. 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 control device (C1) controls the compressor (21), the switching mechanism (24), the outdoor expansion valve (25), and the outdoor fan (23).

The second controller (C2) is the controller (C2) of the present disclosure. The second control device (C2) controls the indoor expansion valve (31) and the indoor fan (33). The second control device (C2) receives detection signals from the refrigerant sensors (51, 52). The second control device (C2) determines whether or not the detection signals from the refrigerant sensors (51, 52) indicate a first concentration or higher. When the second control device (C2) determines that the detection signals from the refrigerant sensors (51, 52) indicate the first concentration, it transmits a notification signal to the fourth control device (C4).

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 controller (C4) controls the notification device (60). Specifically, when the notification signal output from the second control device (C2) is input to the fourth control device (C4), the fourth control device (C4) controls the light emitting section (61) and the sound generating section ( 62).

(3) 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.

(3-1) Cooling operation In the cooling operation, the first control device (C1) operates the compressor (21) and the outdoor fan (23), sets the switching mechanism (24) to the first state, and sets the outdoor expansion valve (25) to the first state. ) is fully open. The second control device (C2) operates the indoor fan (33) and adjusts the indoor expansion valve (31) to a predetermined degree of opening.

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

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

(3-2) Heating operation In the heating operation, the first control device (C1) operates the compressor (21) and the outdoor fan (23), sets the switching mechanism (24) to the second state, and switches the outdoor expansion valve (25). ) is adjusted to a predetermined opening. The second control device (C2) operates the indoor fan (33) and adjusts the indoor expansion valve (31) to a predetermined degree of opening.

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

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

(4) Problems related to performance deterioration of refrigerant sensors Semiconductor-type refrigerant sensors are relatively accurate and inexpensive, so they are suitable for installation in air conditioners such as the present embodiment. Due to the influence of gases such as siloxane floating in the air, the sensitivity to detect the refrigerant gradually decreases. Therefore, it is necessary to repair or replace the refrigerant sensor before the performance deterioration of the refrigerant sensor progresses. However, when the refrigerant sensor does not detect the refrigerant, it is difficult to determine whether the refrigerant cannot be detected due to a decrease in sensitivity or whether the refrigerant cannot be detected because there is no refrigerant around the refrigerant sensor. Thus, it is not easy to grasp the degree of performance deterioration of the refrigerant.

A possible solution to this problem is to set the service life of the refrigerant sensor. Specifically, the service life period is set to a period during which the refrigerant detection accuracy of the refrigerant sensor is estimated to fall below a reference value when the refrigerant sensor continues to be used in a normal environment. Then, the refrigerant sensor is repaired or replaced when the life period has passed. However, since the progress of performance deterioration of the refrigerant sensor differs depending on the air environment around the refrigerant sensor, there is a possibility that the performance of the refrigerant sensor has deteriorated before the set life period elapses. Further, there is a possibility that the performance of the refrigerant sensor has not deteriorated even after the set life period has passed, and in such a case, repairing or replacing the refrigerant sensor is not preferable in terms of cost. Therefore, with such a method, it cannot be said that repair or replacement can be performed before performance deterioration of the refrigerant sensor progresses.

Also, for example, a method of arranging two sensors for detecting the amount of leaked refrigerant can be considered. Specifically, by arranging such sensors close to each other, if the values detected by the two sensors do not match, it is determined that the performance of the refrigerant sensor has deteriorated. However, if the values detected by the two sensors do not match, it cannot be determined which value is correct, so it cannot be said that performance deterioration of the refrigerant sensor can be grasped by this method.

Here, it is known that the performance of the semiconductor-type refrigerant sensor deteriorates in two stages. Specifically, as shown in FIG. 4, first, in stage 1 (period up to T1), the response of the refrigerant sensor becomes sharper.

"Sensitization" is a phenomenon in which a refrigerant sensor detects, as the target concentration, a refrigerant with a concentration lower than the target concentration that should be detected. For example, when the target concentration is 5,000 ppm, the refrigerant sensor detects the concentration as 5,000 ppm even if the actual concentration of the refrigerant is 3,000 ppm due to the sensitivity of the refrigerant sensor. As the sensitization progresses further, even if the actual refrigerant concentration is 1,000 ppm, the refrigerant sensor will detect it as 5,000 ppm. In this case, even if the actual concentration of refrigerant is 1,000 rpm, the refrigerant sensor outputs a detection signal of 5,000 rpm, so the notification device (60) is activated.

As the refrigerant sensor becomes more sensitive in this way, the refrigerant sensor will detect even a very small amount of refrigerant as the target concentration, and eventually even if there is no refrigerant (the refrigerant concentration becomes zero). ), the refrigerant sensor senses the refrigerant as the target concentration.

After that, in stage 2 (after T1 has elapsed), the reaction of the refrigerant sensor slows down. "Slowdown" is a phenomenon that the refrigerant sensor does not detect even when the actual refrigerant concentration exceeds the target concentration. When the refrigerant sensor becomes sluggish, it becomes insensitive to exposure to relatively high concentrations of refrigerant.

The air conditioner (10) of the present embodiment is constructed by utilizing such a property of the semiconductor type refrigerant sensor so that deterioration in performance of the first sensor (51) can be comprehended relatively quickly. A method for detecting performance deterioration of the refrigerant sensor of this embodiment will be described below.

(5) Refrigerant Sensor Performance Deterioration Detection Method In the refrigerant sensor performance deterioration detection method of the present embodiment, the second control device (C2) simultaneously energizes and supplies the first sensor (51) and the second sensor (52). De-energize. The second control device (C2) may always energize the first sensor (51) and the second sensor (52) regardless of whether the air conditioner (10) is ON or OFF.

As shown in FIG. 5, the first sensor (51) is sensitized after a period of use. Specifically, the first sensor (51) detects the refrigerant concentration as the first concentration even if the actual refrigerant concentration in the surroundings is lower than the first concentration. Similarly, the second sensor (52) also comes to detect the refrigerant concentration as the second concentration even if the actual refrigerant concentration in the surroundings is lower than the second concentration after being used for a predetermined period of time.

Here, the rate of deterioration with use of the first sensor (51) and the second sensor (52) is the same, so the first sensor (51) and the second sensor (52) are sensitized at the same pace. go. Since the second concentration is lower than the first concentration, when the first sensor (51) and the second sensor (52) are sensitized at the same speed, the second sensor (51) is sensitized before the first sensor (51). (52) reacts assuming that there is a refrigerant even if there is no refrigerant. In other words, when the first sensor (51) does not detect refrigerant, the second sensor (52) detects refrigerant even in the absence of refrigerant. In this case, a detection signal is sent from the second sensor (52) to the second control device (C2). The second control device (C2) determines that it has not received the detection signal from the first sensor (51) and has received the detection signal from the second sensor (52), and the third control device ( C3) to send the first information. The first information is information indicating that the performance deterioration of the first sensor (51) is progressing. Specifically, it is the information indicating that the sensitivity of the first sensor (51) is in a state just before it is lowered (stage 2). Thereby, performance degradation of the first sensor (51) can be grasped.

(6) Control Flow A control flow of the refrigerant leakage detection method by the air conditioner (10) of the present embodiment will be described with reference to FIG.

In step S11, the second control device (C2) energizes the first sensor (51) and the second sensor (52). The second control device (C2) may execute step S11 when the air conditioner (10) is connected to the external power supply.

In step S12, the second control device (C2) determines whether or not the first sensor (51) has detected the first concentration of refrigerant. When it is determined that the first sensor (51) has detected the first concentration refrigerant (YES in step S12), step S13 is executed. When it is determined that the first sensor (51) does not detect the first concentration refrigerant (YES in step S12), step S15 is executed.

In step S13, the second control device (C2) transmits a notification signal to the fourth control device (C4).

In step S14, the fourth control device (C4) activates the notification device (60). When the notification device (60) is activated, the light emitting section (61) emits light and the sound generating section (62) generates a warning sound. The notification device (60) may continue to operate the light emitting section (61) and the sound generating section (62) until the operation of the notification device (60) is canceled by the user's operation. When the concentration of the refrigerant detected by the first sensor (51) becomes less than the first concentration and the notification device (60) stops receiving the notification signal, the notification device (60) controls the light emitting section (61) and the sound generating section. (62) may be stopped.

In step S15, the second control device (C2) determines whether or not the second sensor (52) detects refrigerant having the second concentration. If it is determined that the second sensor (52) has detected the second concentration of refrigerant (YES in step S15), step S16 is executed. When it is determined that the second sensor (52) does not detect the second concentration refrigerant (NO in step S15), step S12 is executed. As the second sensor (52) becomes more sensitive, the second sensor (52) outputs a detection signal to the second controller ( C2).

In step S16, the second control device (C2) determines whether or not a predetermined period has passed. If it is determined that the predetermined period has passed (YES in step S16), step S17 is executed. If it is determined that the predetermined period has not passed (NO in step S16), step S16 is executed again.

In step S17, the second control device (C2) determines whether or not the first condition is satisfied. The first condition is that the first sensor (51) does not detect refrigerant and the second sensor (52) detects refrigerant for a predetermined period of time. If it is determined that the first condition is met (YES in step S17), step S18 is executed. If it is determined that the first condition is not satisfied (NO in step S17), step S12 is executed again. In this way, the first sensor (51) does not detect the first concentration of refrigerant and the second sensor (52) detects the second concentration of refrigerant. By doing so, erroneous determination that the first sensor (51) has deteriorated can be reliably suppressed. Specifically, when the refrigerant concentration around the refrigerant sensors (51, 52) becomes equal to or higher than the second concentration and lower than the first concentration due to the refrigerant actually leaking into the first space (43), the first sensor ( 51) does not detect the first concentration refrigerant, and the second sensor (52) detects the second concentration refrigerant. When the refrigerant concentration further increases and reaches the first concentration after a predetermined period of time elapses, the first sensor (51) detects refrigerant at the first concentration. In this way, the state in which the first sensor (51) does not detect the refrigerant having the first concentration and the second sensor (52) detects the refrigerant having the second concentration, even if the refrigerant is actually leaking. Since this may occur temporarily, it is possible to determine whether the refrigerant sensors (51, 52) are in a deteriorated state or whether the refrigerant is actually leaking by providing the predetermined period described above.

In step S18, the second control device (C2) transmits the first information to the third control device (C3).

In step S19, the third control device (C3) displays the first information on the first display section (42). The first display portion (42) displays a prompt to replace the first sensor (51). The first display portion (42) may display a prompt to replace the first sensor (51) and the second sensor (52).

(7) Features (7-1)
In the air conditioner (10) of the present embodiment, the first sensor (51) and the second sensor (52) are deteriorated due to use for a predetermined period of time, and when the first sensor (51) does not detect the refrigerant, the second The 2 sensors (52) detect a predetermined gas in the first space (43) (target space) even when there is no predetermined gas.

According to the present embodiment, when the first sensor (51) does not detect, the second sensor (52) detects that the performance of the first sensor (51) is degraded like the second sensor. can be grasped. As a result, the first sensor (51) can be replaced before performance deterioration of the first sensor (51) progresses. In addition, since the first sensor (51) can be replaced according to the degree of progress of performance deterioration, when a life period is set for the first sensor (51) and the first sensor (51) is replaced for each life period Compared to , it is possible to suppress deterioration in performance before replacement of the first sensor (51), or replacement of the first sensor (51) even though performance has not deteriorated.

(7-2)
In the air conditioner (10) of the present embodiment, the second sensor (52) detects refrigerant in the first space (43). Thus, both the first sensor (51) and the second sensor (52) are the same type of sensors that detect refrigerant.

(7-3)
In the air conditioner (10) of the present embodiment, the first sensor (51) detects refrigerant with a first concentration, and the second sensor (52) detects refrigerant with a concentration lower than the first concentration.

According to the present embodiment, since the first sensor (51) and the second sensor (52) react more sensitively to the refrigerant, the second sensor (52) can be detected even when there is no refrigerant in the first space (43). , the first sensor (51) detects that there is refrigerant earlier. This makes it possible to grasp deterioration of the first sensor (51).

(7-4)
In the air conditioner (10) of the present embodiment, the second control device (C2) (control unit) causes the first sensor (51) not to detect the refrigerant and the second sensor (52) to detect the refrigerant. It is determined as the first condition that the condition that the state continues for a predetermined time is satisfied.

According to this embodiment, it is possible to determine whether the refrigerant is actually leaking or whether the first sensor (51) is deteriorated by determining whether the first condition is satisfied. As a result, erroneous detection of performance deterioration of the first sensor (51) can be suppressed.

(7-5)
The air conditioner (10) of the present embodiment includes a first display section (42) (informing section) that informs a person that the first sensor (51) is degraded when the first condition is satisfied. .

According to the present embodiment, the fact that the first sensor (51) has deteriorated is displayed on the first display section (42) of the remote controller (40). This allows the user to replace the first sensor (51) before performance deterioration of the first sensor (51) progresses. Thus, if the first sensor (51) can be replaced according to the performance deterioration of the first sensor (51), the delay in discovering refrigerant leakage can be reliably suppressed.

(7-6)
An air conditioner (10) of the present embodiment includes an indoor unit (30) for conditioning air in a space to be air-conditioned, and a first sensor (51) and a second sensor (52) are located inside the indoor unit (30). placed in This allows the first sensor (51) to detect refrigerant leakage inside the indoor unit (30).

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

(8-1) Modification 1
In Modified Example 1, the second sensor (52) detects refrigerant having the same first concentration as the first sensor (51). The second sensor (52) is configured to deteriorate faster than the first sensor (51) with use for a predetermined period of time.

As shown in FIG. 7, deterioration due to use for a predetermined period of time causes the first sensor (51) and the second sensor (52) to react more sensitively to the refrigerant. In stage 1, the performance of the second sensor (52) deteriorates faster than that of the first sensor (51). If there is a refrigerant in the first space (43) even if there is no refrigerant, the refrigerant is detected as existing. Thus, in this example as well, it is possible to grasp the performance deterioration of the first sensor before moving to stage 2 (the reaction of the first sensor (51) to the refrigerant slows down).

(8-2) Modification 2
In Modified Example 2, the second sensor (52) detects a predetermined gas different from refrigerant. The predetermined gas is, for example, gas floating in the indoor space. The second sensor (52), like the first sensor (51), is configured such that it becomes more sensitive to gases due to deterioration due to use over a predetermined period of time.

As shown in FIG. 8, the second sensor (52) senses a second concentration of the predetermined gas. The second concentration is a concentration obtained by converting a predetermined gas into refrigerant concentration. The second sensor (52) is configured to detect a gas of a second concentration, but as the sensitization to the given gas progresses in Stage 1, the second sensor (52) detects a gas of a concentration lower than the second concentration. It will be detected as concentration. In this example, when the second controller (C2) receives a detection signal indicating that the second sensor (52) has detected a third concentration gas lower than the second concentration as the second concentration gas, The progress of performance deterioration of the first sensor (51) is displayed on the first display section (42).

Thus, also in this example, when the reactions of the first sensor (51) and the second sensor (52) become more sensitive in stage 1, the second sensor (51) detects no refrigerant. The sensor (52) is adapted to detect a third concentration of gas. Thus, in this example, it is possible to ascertain that the first sensor (51) has deteriorated when the second sensor (52) detects the third concentration gas.

(9) Control Flow A control flow of the refrigerant leakage detection method for the air conditioner (10) of Modification 2 will be described with reference to FIG.

In step S21, the second control device (C2) energizes the first sensor (51) and the second sensor (52). The second control device (C2) may execute step S21 when the air conditioner (10) is connected to the external power supply.

In step S22, the second control device (C2) determines whether or not the first sensor (51) has detected the first concentration of refrigerant. If it is determined that the first sensor (51) has detected the first concentration refrigerant (YES in step S22), step S23 is executed. When it is determined that the first sensor (51) does not detect the first concentration refrigerant (YES in step S22), step S25 is executed.

In step S23, the second control device (C2) transmits a notification signal to the fourth control device (C4).

In step S24, the fourth control device (C4) activates the notification device (60). When the notification device (60) is activated, the light emitting section (61) emits light and the sound generating section (62) generates an alarm sound.

In step S25, the second control device (C2) determines whether the second sensor (52) detects the second concentration. In practice, it is determined whether the second sensor (52) detects the third concentration gas. If it is determined that the second sensor (52) has detected the third concentration gas (YES in step S25), step S26 is executed. If it is determined that the second sensor (52) does not detect the third concentration gas (NO in step S25), step S22 is executed.

In step S26, the second control device (C2) determines whether or not a predetermined period has passed. If it is determined that the predetermined period has passed (YES in step S26), step S27 is executed. If it is determined that the predetermined period has not elapsed (NO in step S26), step S26 is executed again.

In step S27, the second control device (C2) determines whether or not the first condition is satisfied. The first condition of the present example is a condition in which the first sensor (51) does not detect refrigerant and the second sensor (52) detects gas of the third concentration for a predetermined period of time. If it is determined that the first condition is satisfied (YES in step S27), step S28 is executed. If it is determined that the first condition is not satisfied (NO in step S27), step S22 is executed again.

In step S28, the second control device (C2) transmits the first information to the third control device (C3).

In step S29, the third control device (C3) displays the first information on the first display section (42). The first display portion (42) displays a prompt to replace the first sensor (51). The first display portion (42) may display a prompt to replace the first sensor (51) and the second sensor (52).

(10) Other Embodiments The above-described embodiment and modification may be configured as follows.

As shown in FIG. 10, the first sensor (51) and the second sensor (52) may constitute the refrigerant leakage detection device (50). The refrigerant leakage detector (50) is configured separately from the air conditioner (10). The refrigerant leakage detection device (50) may include a fifth control device (C5). The fifth controller (C5) is an example of the controller (C2) of the present disclosure. In this case, the refrigerant leakage detection device (50) may have a display (53). The display section (53) is an example of the notification section (42) of the present disclosure. When the first sensor (51) does not detect the refrigerant, the fifth control device (C5) determines that the second sensor (52) detects the refrigerant even when there is no refrigerant, and the display section (53) detects the refrigerant. ) to prompt replacement of the first sensor (51).

The first condition may be a state in which the first sensor (51) does not detect refrigerant and the second sensor (52) detects gas of the third concentration. In this case, it is not necessary to set the predetermined time as in the above embodiment and modification. In other words, it may be determined that the first condition is met when the first sensor (51) detects no refrigerant and the second sensor (52) detects gas of the third concentration.

The target space (43) of the present disclosure may be a specific partitioned space within the indoor unit (30). The specific space includes a space, such as the first space (43), in which leaked refrigerant is relatively likely to accumulate.

The target space (43) of the present disclosure may be in the vicinity of a potential source of refrigerant leakage. Portions that can be sources of refrigerant leakage include, for example, connecting portions between the refrigerant pipes such as the first branch pipe (13b) and the second branch pipe (14b) and the indoor heat exchanger (32), and between the refrigerant pipes and the indoor expansion pipe (32). It is a connection part with a valve (31).

The first sensor (51) and the second sensor (52) need only be placed in the target space (43) of the present disclosure, and need not be placed near each other.

The first sensor (51) and the second sensor (52) may be arranged near the drain pan (44).

The first sensor (51) and the second sensor (52) need only be placed close to each other inside the indoor unit (30) even if they are not placed in the target space (43) of the present disclosure.

The first sensor (51) and the second sensor (52) need not be semiconductor sensors as long as their response becomes more sensitive due to deterioration due to use for a predetermined period of time.

The second sensor (52) may not be a sensor that detects refrigerant, and may detect gas such as city gas. Even in this case, when the first sensor (51) does not detect the refrigerant due to deterioration due to use of the first sensor (51) and the second sensor (52) for a predetermined period, the second sensor (52) The presence of city gas in the first space (43) is detected even when there is no city gas.

The first sensor (51) and the second sensor (52) may be energized even when the air conditioner (10) is powered off. This makes it possible to detect the refrigerant even when the air conditioner (10) is not in operation.

The control unit (C2) of the present disclosure may not be provided in the second control device (C2), and may be provided in the first control device (C1) or the third control device (C3).

The first sensor (51) may determine that a first concentration of refrigerant has been detected. In this case, the first sensor (51) determines that the concentration of the refrigerant around the first sensor (51) is at the first concentration by reading the detection value indicating the refrigerant at the first concentration. The first sensor (51) that has detected the refrigerant of the first concentration transmits a detection signal to the second control device (C2).

A second sensor (52) may determine that a second concentration of refrigerant has been detected. In this case, the second sensor (52) determines that the concentration of the refrigerant around the second sensor (52) is at the second concentration by reading the detected value indicating the second concentration of refrigerant. The second sensor (52) that has detected the second concentration refrigerant transmits a detection signal to the second control device (C2).

The refrigerator (10) is not limited to the air conditioner (10). The refrigerating device (10) may be any device as long as it has a refrigerant circuit and performs a refrigerating cycle. For example, the refrigerating device of the present disclosure may be employed in a refrigerating device, a chiller unit, a water heater, or the like for a refrigerator/freezer that cools the inside of the refrigerator.

The control device (AC) of the embodiment may be arranged in a control center that centrally manages a plurality of indoor units (30). In this case, the notification device (60) may be configured to notify an administrator in the control center.

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 embodiments and modifications described above 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" and "third" mentioned above are used to distinguish the words and phrases to which these descriptions are given, and even limit the number and order of the words and phrases. not a thing

INDUSTRIAL APPLICABILITY As described above, the present disclosure is useful for refrigeration systems, refrigerant leakage detection devices, and refrigerant leakage detection methods.

10 Air conditioners (freezers)
11 Refrigerant circuit
30 indoor units
43 First space (target space)
51 First sensor
52 2nd sensor
42 First display unit (notification unit)
C2 Second control device (control section)
S Air-conditioned space (indoor space)

Claims (10)

a refrigerant circuit (11) through which refrigerant circulates;
a first sensor (51) for detecting refrigerant in the target space (43);
a second sensor (52) arranged in the same target space (43) as the first sensor (51) and detecting a predetermined gas;
When the first sensor (51) does not detect the refrigerant due to deterioration due to use of the first sensor (51) and the second sensor (52) for a predetermined period of time, the second sensor (52) detects the A refrigerating apparatus, wherein the predetermined gas is detected even in the absence of the predetermined gas. the predetermined gas is a refrigerant,
The refrigeration apparatus according to claim 1, wherein the second sensor (52) detects refrigerant in the target space (43). The first sensor (51) detects refrigerant having a first concentration,
3. The refrigerator according to claim 1, wherein said second sensor (52) detects said predetermined gas having a concentration lower than said first concentration. The first sensor (51) detects refrigerant having a first concentration,
The second sensor (52) detects the predetermined gas having the same concentration as the first concentration,
3. The refrigerating apparatus according to claim 1, wherein the second sensor (52) deteriorates faster than the first sensor (51) after being used for a predetermined period of time. A control unit (C2) for determining whether or not a first condition is established in which the first sensor (51) does not detect refrigerant and the second sensor (52) detects the predetermined gas. The refrigeration system according to any one of claims 1 to 4. The control unit (C2) detects that the first sensor (51) does not detect the refrigerant and the second sensor (52) detects the predetermined gas for a predetermined period of time. , is determined as the first condition. 7. The refrigerating apparatus according to claim 5, further comprising a notification section (42) that notifies a person that said first sensor (51) has deteriorated when said first condition is satisfied. Equipped with an indoor unit (30) that conditions the air in the air-conditioned space (S),
The refrigeration system according to any one of claims 1 to 7, wherein the first sensor (51) and the second sensor (52) are arranged inside the indoor unit (30). a first sensor (51) for detecting refrigerant in the target space (43);
a second sensor (52) arranged in the same target space (43) as the first sensor (51) and detecting a predetermined gas;
When the first sensor (51) does not detect the refrigerant due to deterioration due to use of the first sensor (51) and the second sensor (52) for a predetermined period of time, the second sensor (52) detects the A refrigerant leakage detection device, wherein the predetermined gas is detected even in the absence of the predetermined gas. a first sensor (51) for detecting refrigerant in the target space (43);
a second sensor (52) arranged in the same target space (43) as the first sensor (51) and detecting a predetermined gas;
When the first sensor (51) does not detect the refrigerant due to deterioration due to use of the first sensor (51) and the second sensor (52) for a predetermined period of time, the second sensor (52) detects the A refrigerant leakage detection method, wherein the predetermined gas is detected even when the predetermined gas is not present.

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