JP2022162432A - air conditioner - Google Patents

Abstract

To provide an air conditioner capable of detecting abnormality on shortage of refrigerant amount and suppressing dripping of condensate water to a floor surface, while suppressing power consumption and increase of noise in a normal operation free from the shortage of refrigerant amount.SOLUTION: An air conditioner includes a housing, an indoor fan, an indoor heat exchanger, a drain pan, a plurality of plate materials, and a control portion. The indoor heat exchanger is disposed in a manner of crossing an air channel formed inside of the housing and inclined to a horizontal face at its air inflow face. The drain pan is disposed at a lower end of the indoor heat exchanger and collects condensate water generated in the indoor heat exchanger. The plurality of plate materials is disposed along the air inflow face at a lower part of the indoor heat exchanger. The control portion controls a direction of the plurality of plate materials so that the plurality of plate materials does not become resistance of the air channel to the indoor heat exchanger when the shortage of the refrigerant amount is not found and controls the direction of the plurality of plate materials to a direction to receive dripping of the condensate water from the indoor heat exchanger when the shortage of the refrigerant amount is found.SELECTED DRAWING: Figure 5

Description

The present disclosure relates to an air conditioner that performs air conditioning control for a space to be air conditioned.

An air conditioner for cooling and heating is composed of an indoor unit and an outdoor unit, and a floor-standing indoor unit is sometimes used as the indoor unit. A floor-standing indoor unit has a housing. The housing is provided with an inlet and an outlet. A floor-standing indoor unit has an indoor heat exchanger, an indoor fan, and a drain pan inside a housing. The indoor heat exchanger and the indoor fan are arranged in the order of the indoor heat exchanger and the indoor fan in the air flow direction from the inlet to the outlet in the interior of the housing. The indoor heat exchanger is arranged obliquely so as to cross the air flow. The drain pan is arranged so as not to block the suction port and to receive condensed water generated in the indoor heat exchanger during cooling operation from the lower end of the indoor heat exchanger.

In Patent Document 1, in such a floor-standing indoor unit, condensed water does not drip into the drain pan at the lower end of the indoor heat exchanger at the end of the cooling operation, and from the surface facing the bottom side of the indoor heat exchanger, the floor-standing type An air conditioner is disclosed that prevents leakage to a floor surface where an indoor unit is installed. In the air conditioner described in Patent Document 1, control is performed to stop the indoor fan after rotating the indoor fan at a predetermined number of revolutions for a predetermined period of time from the end of the cooling operation.

Patent Literature 2 discloses a floor-standing indoor unit provided with a draining member that catches condensed water on the lower side of an indoor heat exchanger inside a housing and guides it to a drain pan. The draining member has a plurality of draining plates. A plurality of draining plates are arranged below the indoor heat exchanger along the inclination angle of the indoor heat exchanger. Adjacent draining plates are arranged at intervals in the vertical direction, but in plan view, the adjacent draining plates are arranged so as to overlap each other. As a result, it is possible to prevent the condensed water from dripping outside the housing while using the space in the vertical direction between the draining plates as an air flow passage, and to collect the condensed water with the drain pan.

JP 2017-110855 A Japanese Patent No. 3042329

By the way, in a floor-standing type indoor unit, refrigerant leakage may occur due to construction defects or aging corrosion due to chemical reaction of copper pipes for circulating the refrigerant. In the technique described in Patent Document 1, when a refrigerant leak occurs, the indoor heat exchanger may dry out during the cooling operation depending on the degree to which the refrigerant is reduced, causing the indoor heat exchanger to dry during the cooling operation. The condensed water does not flow to the lower end of the heat exchanger and may drop out of the drain pan. Further, the technology described in Patent Document 1 is based on the premise that the floor-standing indoor unit is in a normal state without refrigerant leakage, that is, the indoor heat exchanger is not dry. Therefore, when the amount of refrigerant decreases and the indoor heat exchanger dries, there is a problem that the condensed water cannot be collected in the drain pan regardless of whether the indoor fan is in operation.

Furthermore, in the technique described in Patent Document 2, the vertical space between each draining plate is used as an air flow path, but the installation of a plurality of draining plates is an arrangement that creates resistance in the direction of air flow. . For this reason, in order to ensure the air volume during normal operation, it is necessary to increase the output of the indoor fan, which causes the problem of increased power consumption and noise.

The present disclosure has been made in view of the above, and while suppressing an increase in power consumption and noise during normal operation when there is no shortage of refrigerant, detects an abnormality of the shortage of refrigerant, and An object of the present invention is to obtain an air conditioner capable of suppressing dripping of condensed water.

In order to solve the above-described problems and achieve the object, the air conditioner of the present disclosure includes a housing, an indoor fan, an indoor heat exchanger, a drain pan, a plurality of plate members, and a control unit. . The housing has an inlet and an outlet. The indoor fan is provided inside the housing that causes air to flow from the suction port toward the blowout port. The indoor heat exchanger is arranged inside the housing so that the air inflow surface into which the air flows is inclined with respect to the horizontal plane while crossing the air passage that is the flow of air generated inside the housing by the indoor fan. , heat exchange is performed between the air passing through the air passage and the refrigerant. The drain pan is provided at the lower end of the indoor heat exchanger inside the housing, and collects condensed water generated in the indoor heat exchanger. A plurality of plate members are arranged below the indoor heat exchanger inside the housing along the air inflow surface and are movable. The controller controls operations of the indoor fan, the indoor heat exchanger, and the plurality of plates. During cooling operation, if there is no shortage of refrigerant, the control unit controls the orientation of the plurality of plates so that the plurality of plates do not act as resistance to the air path to the indoor heat exchanger, thereby preventing the shortage of refrigerant. is generated, the orientation of the plurality of plate members is controlled so as to receive dripping of condensed water from the indoor heat exchanger.

According to the present disclosure, while suppressing an increase in power consumption and noise during normal operation when there is no shortage of refrigerant, it is possible to detect an abnormality due to an insufficient amount of refrigerant and suppress dripping of condensed water on the floor surface. It has the effect of being able to

1 is a cross-sectional view schematically showing an example of the configuration of a floor-standing indoor unit of an air conditioner according to Embodiment 1. FIG. FIG. 2 is a block diagram showing an example of the functional configuration of the control unit of the air conditioner according to Embodiment 1; FIG. 2 is a block diagram showing an example of a hardware configuration of a controller provided in the air conditioner according to Embodiment 1; FIG. 4 is a flow chart showing an example of the operation procedure of the controller in the floor-standing indoor unit of the air conditioner according to Embodiment 1. Sectional view schematically showing an example of the state of the plate material in the air conditioner according to Embodiment 1

Air conditioners according to embodiments of the present disclosure will be described in detail below with reference to the drawings.

The air conditioner described in the following embodiments includes a floor-standing indoor unit installed indoors and an outdoor unit installed outdoors. The ratio between the number of floor-standing indoor units and the number of outdoor units is arbitrary. For example, one floor-standing indoor unit may be connected to a plurality of outdoor units. A configuration in which one outdoor unit is connected to a single floor-standing indoor unit may also be used. For example, when an air conditioner is composed of one floor-standing indoor unit and a plurality of outdoor units, piping is provided so that the refrigerant circulates between each outdoor unit and the floor-standing indoor units. Refrigerant circuits connected with are formed by the number of outdoor units.

Embodiment 1.
1 is a cross-sectional view schematically showing an example of the configuration of a floor-standing indoor unit of an air conditioner according to Embodiment 1. FIG. The floor-standing indoor unit 1 includes a housing 10 that serves as an indoor unit main body. The housing 10 has an air inlet 10a provided for taking in air, and an air outlet 10b for supplying cooling/heating air heat-exchanged inside the room. The floor-standing indoor unit 1 includes an indoor fan 11 , an indoor heat exchanger 12 , a drain pan 13 , a plurality of movable plate members 14 , and a controller 15 inside a housing 10 .

The indoor fan 11 is provided inside the housing 10 and causes air to flow inside the housing 10 from the suction port 10a toward the blowout port 10b. An example of the indoor fan 11 is a multi-blade fan. By driving the indoor fan 11, air outside the housing 10, for example, indoor air, is taken in through the inlet 10a and blown out through the outlet 10b. A blowout duct 21 is connected to the blowout port 10b, and the blown air is carried through the blowout duct 21. - 特許庁The blow-out duct 21 is connected to, for example, an underfloor space, a space above the ceiling, a space between an inner wall and an outer wall, or a dedicated duct, and supplies conditioned air, which is the air conditioned by the floor-standing indoor unit 1, to a plurality of living rooms. Distribute. A path along which air flows from the suction port 10a to the blowout port 10b created inside the housing 10 by the indoor fan 11 is hereinafter also referred to as an air path.

The indoor heat exchanger 12 is arranged across the air passage inside the housing 10, and performs heat exchange between the air passing through the air passage and the refrigerant circulating between the outdoor unit. The indoor heat exchanger 12 has a rectangular parallelepiped shape or a flat plate shape. has an air discharge surface 12b facing the . In one example, the air inlet surface 12a and the air outlet surface 12b are parallel to each other. The air inflow surface 12a is arranged inside the housing 10 so as to be inclined at a predetermined angle that is not 90° with respect to the horizontal plane. In one example, the ground plane of the floor on which the floor-standing indoor unit 1 is installed is a horizontal plane. Further, the indoor heat exchanger 12 is arranged inside the housing 10 so that the air inflow surface 12a is 55° with respect to the horizontal plane. It should be noted that this angle is appropriately changed depending on the size of the housing 10 . The indoor heat exchanger 12 exchanges heat between the air taken into the housing 10 through the suction port 10 a by the rotation of the indoor fan 11 and the refrigerant.

The drain pan 13 is provided at the lower end portion 12c of the indoor heat exchanger 12 inside the housing 10, and collects drain water. An example of drain water is condensed water generated in the indoor heat exchanger 12 during cooling operation. In one example, the drain pan 13 has a rectangular bottom surface, side surfaces extending upward from the four sides of the bottom surface, and an open top box shape. The drain pan 13 is arranged below the lower end portion 12c of the indoor heat exchanger 12 so as not to block the suction port 10a.

A plurality of plate members 14 are provided inside the housing 10 at positions that do not interfere with the drain pan 13 below the air inflow surface 12 a of the indoor heat exchanger 12 . The plurality of plate members 14 are configured to rotate within a plane parallel to the air inflow surface 12a of the indoor heat exchanger 12 around a rotation axis that is an axis perpendicular to the tilt direction. By rotating the plate member 14 about the rotation axis, the orientation of the plate member 14 with respect to the air inflow surface 12a of the indoor heat exchanger 12 can be changed. The rotation axis of each plate member 14 is along the air inflow surface 12a of the indoor heat exchanger 12. In one example, a virtual plane connecting the rotation shafts of the respective plate members 14 is the air inflow surface of the indoor heat exchanger 12. A plurality of plate members 14 are arranged so as to be parallel to 12a. In the normal state where there is no shortage of refrigerant, each plate member 14 is arranged so as not to create resistance in the air path to the indoor heat exchanger 12 . An example of the direction in which the air path to the indoor heat exchanger 12 does not create resistance is a direction parallel or nearly parallel to the air flow in the vicinity of the indoor heat exchanger 12 . The orientation of the plurality of plate members 14 can be changed by instructions from the control unit 15, which will be described later. A driving system (not shown) is connected to the rotating shaft, and rotates the plate member 14 according to an instruction from the control unit 15 . Although the thickness of the plate member 14 can be set arbitrarily, it can be set within 1 mm as an example.

In order to prevent the resistance of the air passage, all of the plate members 14 may be inclined in the same direction in a horizontal direction with respect to the air passage. There is also a method of changing the orientation of each of the plurality of plate members 14 so as to be uniform with respect to the air inflow surface 12a. In this case, the inclination of each of the plurality of plate members 14 is changed instead of all of the plurality of plate members 14 having the same inclination. As a result, the air flowing into the air inflow surface 12a of the indoor heat exchanger 12 is made uniform, so that the amount of air flowing into the surface near the drain pan 13, in particular, where air is difficult to flow, increases, and the heat exchange of the indoor heat exchanger 12 increases. Efficiency can be improved.

The control unit 15 controls the operation of the floor-standing indoor unit 1 . Here, the controller 15 controls the operation of the indoor fan 11, the operation of the indoor heat exchanger 12, and the directions of the plurality of plate members 14. FIG.

2 is a block diagram showing an example of a functional configuration of a control unit of the air conditioner according to Embodiment 1. FIG. Note that FIG. 2 also shows components provided in the floor-standing indoor unit 1 connected to the control unit 15 . The control unit 15 includes an integrated control unit 151 , a refrigerant shortage determination unit 152 , and a cooling operation stop determination unit 153 .

The integrated control unit 151 controls the air conditioning operation by sending operation instructions to the indoor fan 11, the indoor heat exchanger 12, and the plurality of plate members 14 based on operation request information from a room controller (not shown). The room controller has a user interface that can set the operation type of the air conditioner, the indoor target temperature, the target air volume, and the like. Information set by the user in the room via the user interface becomes the operation request information.

When the integrated control unit 151 receives information indicating that the refrigerant amount is insufficient from the refrigerant amount shortage determination unit 152, the direction of the plate member 14 is controlled so that the condensed water dripping from the indoor heat exchanger 12 can be received. do. Further, when the integrated control unit 151 receives the information indicating that the amount of refrigerant is insufficient, the error notification unit 31 notifies error information indicating that the amount of refrigerant is insufficient. The error notification unit 31 may be provided in the floor-standing indoor unit 1 or may be provided in the room controller. For example, when the error notification unit 31 is the display unit of the room controller, the integrated control unit 151 displays error information on the display unit. The error information in this case is displayed in text, for example. Further, when the error notification unit 31 is the speaker of the room controller or the floor-standing indoor unit 1, the integrated control unit 151 outputs the error information from the speaker. The error information in this case is, for example, voice. In addition to these, the integrated control unit 151 may display a predetermined error code on the display unit.

Further, upon receiving information from the cooling operation stop determination unit 153 instructing to stop operation due to insufficient refrigerant, the integrated control unit 151 stops the operation of the indoor fan 11 and the indoor heat exchanger 12 . The integrated control unit 151 may notify the error information even when the cooling operation of the air conditioner is stopped due to insufficient amount of refrigerant.

It is possible that the user has a contract with a housing management company or a maintenance company that specializes in equipment or housing maintenance. In this case, the integrated control unit 151 may directly notify the housing management company or the maintenance company of maintenance information including error information about the air conditioner via a communication unit (not shown). Then, the housing management company or the maintenance company may announce the maintenance time to the user.

The refrigerant amount shortage determination unit 152 calculates a refrigerant amount determination value indicating the amount of circulating refrigerant from the detection result of the refrigerant amount shortage detection unit 32 provided in the indoor heat exchanger 12 or the outdoor unit. , is within the reference range for determining that the amount of refrigerant is insufficient. The refrigerant amount shortage determination unit 152 determines that the refrigerant amount is insufficient when the refrigerant amount determination value is within the reference range, and determines that the refrigerant amount is not insufficient when the refrigerant amount determination value is outside the reference range. I judge. The refrigerant amount shortage determination unit 152 determines whether or not all the refrigerant circuits in the floor-standing indoor unit 1 are in a refrigerant amount shortage. When the refrigerant amount determination value is within the reference range, the refrigerant amount shortage determination unit 152 notifies the integrated control unit 151 of refrigerant amount shortage information indicating that the refrigerant amount is insufficient. In addition, the refrigerant amount shortage determination unit 152 notifies the cooling operation stop determination unit 153 of the determination result.

The refrigerant amount shortage detection unit 32 detects the shortage of the refrigerant amount of the refrigerant circulating in the indoor heat exchanger 12 . The refrigerant shortage detection unit 32 is provided in the indoor heat exchanger 12 and detects a parameter of the indoor heat exchanger 12 that can estimate the refrigerant shortage. Methods for estimating the refrigerant shortage include a method using the temperature difference between the refrigerant inlet temperature and the refrigerant outlet temperature of the indoor heat exchanger 12, a method using the refrigerant pressure, a method using the circulation amount of the refrigerant, and the like.

In the case of the method using the temperature difference between the refrigerant inlet temperature and the refrigerant outlet temperature of the indoor heat exchanger 12, in one example, the refrigerant shortage detection unit 32 detects the refrigerant inlet temperature of the indoor heat exchanger 12. A temperature detection unit 321 and a refrigerant outlet temperature detection unit 322 that detects the refrigerant outlet temperature of the indoor heat exchanger 12 are provided. The refrigerant inlet temperature is the temperature of the refrigerant flowing into the indoor heat exchanger 12 , and the refrigerant outlet temperature is the temperature of the refrigerant flowing out of the indoor heat exchanger 12 . The refrigerant inlet temperature detector 321 is provided at the refrigerant inlet pipe portion of the indoor heat exchanger 12 , and the refrigerant outlet temperature detector 322 is provided at the refrigerant outlet pipe portion of the indoor heat exchanger 12 . An example of the refrigerant inlet temperature detector 321 and the refrigerant outlet temperature detector 322 is a temperature sensor such as a resistance temperature detector.

In this case, the refrigerant quantity shortage determination unit 152 obtains the temperature difference, which is the difference between the refrigerant outlet temperature detected by the refrigerant outlet temperature detection unit 322 and the refrigerant inlet temperature detected by the refrigerant inlet temperature detection unit 321 . Then, the refrigerant amount shortage determination unit 152 determines whether the temperature difference is larger than a reference value for determining that the refrigerant amount is insufficient. That is, the temperature difference becomes the refrigerant amount determination value. When the temperature difference is less than the reference value, the coolant amount shortage determination unit 152 determines that the coolant amount is not insufficient. Further, when the temperature difference is larger than the reference value, the refrigerant amount shortage determination unit 152 determines that the refrigerant amount is insufficient. Note that when the temperature difference is equal to the reference value, it may be determined that the amount of refrigerant is insufficient, or it may be determined that the amount of refrigerant is not insufficient.

In the case of the method using the pressure of the refrigerant, in one example, the refrigerant shortage detection unit 32 becomes the refrigerant pressure detection unit 323 that detects the refrigerant pressure in the indoor heat exchanger 12 . In one example, the refrigerant pressure detector 323 is provided in the refrigerant inlet pipe of the indoor heat exchanger 12 . An example of the refrigerant pressure detector 323 is a pressure sensor. In addition to the refrigerant inlet pipe of the indoor heat exchanger 12, the refrigerant pressure detection unit 323 may be provided in the refrigerant outlet pipe of the indoor heat exchanger 12, or the refrigerant inlet pipe or refrigerant outlet of the outdoor unit (not shown). It may be provided in piping.

In this case, the refrigerant amount shortage determination unit 152 determines whether the refrigerant pressure detected by the refrigerant pressure detection unit 323 is less than a reference value for determining that the refrigerant amount is insufficient. That is, the refrigerant pressure becomes the refrigerant amount determination value. When the refrigerant pressure is higher than the reference value, the refrigerant amount shortage determination unit 152 determines that the refrigerant amount is not insufficient. Further, when the refrigerant pressure is less than the reference value, the refrigerant amount shortage determination unit 152 determines that the refrigerant amount is insufficient. Note that when the refrigerant pressure is equal to the reference value, it may be determined that the refrigerant amount is insufficient, or that the refrigerant amount is not insufficient.

In the case of the method using the circulation amount of the refrigerant, in one example, the refrigerant amount shortage detection unit 32 becomes the refrigerant circulation amount detection unit 324 that detects the amount of refrigerant flowing through the indoor heat exchanger 12 . In one example, the refrigerant circulation amount detector 324 is provided in the refrigerant inlet pipe of the indoor heat exchanger 12 . An example of the refrigerant circulation amount detection unit 324 is a flow meter that measures the flow rate of the refrigerant. In addition, the refrigerant circulation amount detection unit 324 may be provided in the refrigerant outlet pipe of the indoor heat exchanger 12 in addition to the refrigerant inlet pipe of the indoor heat exchanger 12, or may be provided in the refrigerant pipe connected to the outdoor unit (not shown). It may be provided at the connecting portion. In addition, the amount of refrigerant circulating in the refrigerant circuit can be calculated from the flow rate from the flow meter installed in the pipe of the indoor heat exchanger 12 through which the refrigerant flows and the cross-sectional area of the pipe. . The refrigerant circulation amount may be calculated by the refrigerant amount shortage determination unit 152 .

In this case, the refrigerant amount shortage determination unit 152 determines whether or not the refrigerant circulation amount detected by the refrigerant circulation amount detection unit 324 is less than the reference value for determining that the refrigerant amount is insufficient. That is, the refrigerant circulation amount becomes the refrigerant amount determination value. When the refrigerant circulation amount is larger than the reference value, the refrigerant amount shortage determination unit 152 determines that the refrigerant amount is not insufficient. Further, when the refrigerant circulation amount is less than the reference value, the refrigerant amount shortage determination unit 152 determines that the refrigerant amount is insufficient. Note that when the refrigerant circulation amount is equal to the reference value, it may be determined that the refrigerant amount is insufficient, or that the refrigerant amount is not insufficient.

FIG. 2 shows the refrigerant inlet temperature detector 321, the refrigerant outlet temperature detector 322, the refrigerant pressure detector 323, and the refrigerant circulation amount detector 324 as the refrigerant shortage detector 32. A set of the temperature detection unit 321 and the refrigerant outlet temperature detection unit 322, the refrigerant pressure detection unit 323, or the refrigerant circulation amount detection unit 324 may be provided.

The cooling operation stop determination unit 153 determines whether the result of the refrigerant shortage determination from the refrigerant shortage determination unit 152 satisfies a stop determination condition for stopping the cooling operation of the floor-standing indoor unit 1 . Specifically, the cooling operation stop determination unit 153 determines that the stop determination condition is satisfied when all the refrigerant circuits formed in the floor-standing indoor unit 1 have insufficient refrigerant amounts, and the integrated control unit 151 sends the cooling operation stop determination unit 153 to the integrated control unit 151 . Operation stop instruction information, which is information instructing to stop operation, is notified. Further, if there is a refrigerant circuit that does not have a shortage of refrigerant, the cooling operation stop determination unit 153 does not satisfy the stop determination condition, and does not notify the integrated control unit 151 .

The control unit 15 is implemented as a processing circuit. The processing circuitry may be dedicated hardware, an integrated circuit, or a circuit with a processor. 3 is a block diagram showing an example of a hardware configuration of a controller provided in the air conditioner according to Embodiment 1. FIG. The control unit 15 has a processor 501 and a memory 502 . The processor 501 is a CPU (Central Processing Unit, central processing unit, processor, arithmetic unit, microprocessor, microcomputer, processor, DSP (Digital Signal Processor)), system LSI (Large Scale Integration), or the like. Memory 502 may be nonvolatile or Volatile semiconductor memory, magnetic disc, flexible disc, optical disc, compact disc, mini disc, DVD (Digital Versatile Disc), and the like. Processor 501 and memory 502 are connected via bus line 503 .

The control unit 15 is implemented by the processor 501 executing a program that reads from the memory 502 a program that describes the procedure for determining whether the amount of refrigerant is insufficient and controlling the orientation of the plate member 14 . Also, multiple processors and multiple memories may work together to achieve the above functions. Also, part of the functions of the control unit 15 may be implemented as an electronic circuit that is dedicated hardware, and other parts may be implemented using the processor 501 and the memory 502 . In one example, the controller 15 controls the rotation speed of the indoor fan 11 with an electric signal, controls the operation of the indoor heat exchanger 12 with an electric signal, and controls the orientation of the plate 14 with an electric signal.

Next, the operation of the floor-standing indoor unit 1 will be described. 4 is a flowchart showing an example of the procedure of the operation of the controller in the floor-standing indoor unit of the air conditioner according to Embodiment 1. FIG. First, when the integrated control unit 151 receives the operation request information instructing the start of the cooling operation from the room controller, it causes the air conditioner to perform the cooling operation (step S11). Specifically, the integrated control unit 151 starts the operation of the indoor fan 11 and the indoor heat exchanger 12 . The integrated control unit 151 also controls a drive system (not shown) so that the plurality of plate members 14 are oriented so as not to resist the wind.

Next, the integrated control unit 151 determines whether or not a predetermined time Ta has passed since the cooling operation was started (step S12). If the predetermined time Ta has not elapsed (No in step S12), the process enters a waiting state. When the predetermined time Ta has passed (Yes in step S12), the refrigerant amount shortage determination unit 152 determines that the refrigerant amount determination value obtained from the detection result of the refrigerant shortage detection unit 32 indicates that the refrigerant amount is insufficient. (step S13). Specifically, the refrigerant amount shortage determination unit 152 calculates the refrigerant amount determination value from the detection result of the refrigerant amount shortage detection unit 32 provided in the indoor heat exchanger 12 or the outdoor unit. It is determined whether or not the amount is within the reference range for determining that the amount is insufficient. If the refrigerant amount determination value does not satisfy the refrigerant amount shortage determination condition (No in step S13), the process returns to step S13.

When the refrigerant amount determination value satisfies the judgment condition of the refrigerant amount shortage (Yes in step S13), the refrigerant amount shortage determination unit 152 outputs the refrigerant amount shortage information indicating that the refrigerant amount is insufficient. is notified to the integrated control unit 151 . Upon receiving the refrigerant shortage information, the integrated control unit 151 controls the orientation of the plurality of plate members 14 so that the condensed water from the indoor heat exchanger 12 can be received (step S14). That is, the drive system is controlled so that the direction of the plate members 14 is such that the plurality of plate members 14 completely cover the area where the drain pan 13 is not present in the projection of the air inflow surface 12a of the indoor heat exchanger 12 onto the horizontal plane.

FIG. 5 is a cross-sectional view schematically showing an example of the state of the plate material in the air conditioner according to Embodiment 1. FIG. The same reference numerals are given to the same components as in FIG. 1, and the description thereof is omitted. As described above, in FIG. 5 , the plurality of plate members 14 are oriented downward toward the drain pan 13 . At this time, the plurality of plate members 14 are arranged along the inclination angle of the indoor heat exchanger 12 . The arrangement state of the individual plate members 14 is a state in which there is a gap in the vertical direction between the lower end portion of the plate member 14 positioned above and the upper end portion of the plate member 14 positioned below the adjacent plate members 14, and is a plan view. are arranged so as to overlap each other. That is, the orientation of the plurality of plate members 14 is changed so as to cover the area where the drain pan 13 is not present in the projection of the air inflow surface 12a of the indoor heat exchanger 12 onto the horizontal plane. Between adjacent plate members 14 , the drain pan 13 side end of the upper plate member 14 is positioned on the lower plate member 14 . When the condensed water drips onto each of the plate members 14, the condensed water flows along the upper surface of the plate member 14, drops to the lower plate members 14 in order, and is recovered from the lowermost plate member 14 to the drain pan 13. At this time, the plate members 14 act as resistance to the flow of air in the housing 10, but the air passes through the gaps in the vertical direction between the adjacent plate members 14 and flows from the inlet 10a to the outlet 10b. flow. Also, dripping of condensed water to the bottom of the housing 10 is suppressed.

Returning to FIG. 4, the integrated control unit 151 notifies the error notification unit 31 of error information indicating that the amount of refrigerant is insufficient (step S15). With this, it is possible to let the user know that the amount of refrigerant is insufficient.

After that, the cooling operation stop determination unit 153 determines whether the stop determination condition is satisfied using the determination result of the refrigerant shortage determination unit 152 (step S16). Here, it is assumed that the stop determination condition is that the amount of refrigerant is insufficient for all refrigerant circuits.

If the determination result does not satisfy the stop determination condition (No in step S16), the process returns to step S13. In this case, the cooling operation of the air conditioner is not stopped. As shown in FIG. 5, even when the orientation of the plurality of plate members 14 is inclined downward toward the drain pan 13, the operation of the outdoor unit with the normal amount of refrigerant can be continued. At this time, the plurality of adjacent plate members 14 are arranged so as to provide resistance to the air passage, but from the vertical gap between the adjacent plate members 14, through the indoor heat exchanger 12, to the outlet 10b. An air passage for cooling operation is formed. As a result, it is possible to continue the cooling operation while receiving dripping of condensed water from the indoor heat exchanger 12 on each plate member 14 .

When the determination result satisfies the stop determination condition (Yes in step S16), the cooling operation stop determination unit 153 notifies the integrated control unit 151 of cooling operation stop instruction information. Upon receiving the operation stop instruction information, the integrated control unit 151 stops the cooling operation (step S17). Specifically, the integrated control unit 151 stops the operation of the indoor fan 11 and the indoor heat exchanger 12 . With this, the processing ends.

After stopping the cooling operation in step S17, the integrated control unit 151 may notify the error notification unit 31 of error information indicating that the cooling operation has been stopped.

In Embodiment 1, the floor-standing indoor unit 1 includes an indoor fan 11 for causing air to flow from the suction port 10a toward the discharge port 10b and a wind fan 11 in the housing 10 having the suction port 10a and the discharge port 10b. An indoor heat exchanger 12 that is arranged in a passage and exchanges heat between the air passing through the air passage and the refrigerant, a drain pan 13 that is provided at the lower end of the indoor heat exchanger 12 and collects condensed water, and indoor heat A plurality of movable plate members 14 provided below the exchanger 12 , and a control unit 15 that controls operations of the indoor fan 11 , the indoor heat exchanger 12 and the plurality of plate members 14 are provided. When the amount of refrigerant is not insufficient, the control unit 15 controls the air inflow surface 12a of the indoor heat exchanger 12 of the plate member 14 so as to be in a direction that does not cause resistance of the air path to the indoor heat exchanger 12 in the housing 10. Controls orientation with respect to In addition, when the amount of refrigerant is insufficient, the control unit 15 determines that the plurality of plate members 14 are projected on the horizontal plane of the air inflow surface 12a of the indoor heat exchanger 12 in the case where the amount of refrigerant is insufficient. The orientation of the plate member 14 is controlled so as to cover the . As a result, the plurality of plate members 14 are arranged so as not to block the air inflow surface 12a of the indoor heat exchanger 12 during normal operation when the amount of refrigerant is not insufficient. In comparison, the output and noise of the indoor fan 11 can be lowered. Therefore, it is possible to suppress an increase in power consumption and noise of the air conditioner during normal operation. Further, when the amount of refrigerant is insufficient, a plurality of plate members 14 are arranged so as to cover the area without the drain pan 13 in the projection of the air inflow surface 12a of the indoor heat exchanger 12 onto the horizontal plane. Condensed water generated at 12 can be received by each plate member 14 . The condensed water is then guided to the drain pan 13 . As a result, the condensed water of cooling when the amount of refrigerant is insufficient drips on the way without being guided by the drain pan 13, leaks to the outside of the housing 10 through the gap of the housing 10, and leaks to the floor surface. can be suppressed.

The configuration shown in the above embodiment is an example, and can be combined with another known technique, and part of the configuration can be omitted or changed without departing from the scope of the invention. It is possible.

1 Floor-standing indoor unit 10 Housing 10a Suction port 10b Air outlet 11 Indoor fan 12 Indoor heat exchanger 12a Air inflow surface 12b Air discharge surface 12c Lower end 13 Drain pan 14 Plate material 15 Control Part 21 Blow-out duct 31 Error reporting part 32 Refrigerant amount shortage detection part 151 Integrated control part 152 Refrigerant amount shortage determination part 153 Cooling operation stop determination part 321 Refrigerant inlet temperature detection part 322 Refrigerant outlet temperature detection part , 323 refrigerant pressure detector, 324 refrigerant circulation amount detector.

Claims (6)

a housing having an inlet and an outlet;
an indoor fan provided inside the housing for causing air to flow from the suction port toward the blowout port;
It is arranged inside the housing so that the air inflow surface into which the air flows is inclined with respect to the horizontal plane while crossing the air path that is the flow of the air created inside the housing by the indoor fan, an indoor heat exchanger that exchanges heat between the air passing through the air passage and the refrigerant;
a drain pan provided at the lower end of the indoor heat exchanger inside the housing for collecting condensed water generated in the indoor heat exchanger;
a plurality of movable plate members arranged along the air inflow surface below the indoor heat exchanger inside the housing;
a control unit that controls operations of the indoor fan, the indoor heat exchanger, and the plurality of plate members;
with
When there is no shortage of refrigerant during cooling operation, the control unit controls the orientation of the plurality of plate members so that the plurality of plate members do not act as resistance in the air passage to the indoor heat exchanger. and, when the amount of refrigerant is insufficient, the orientation of the plurality of plate members is controlled so as to receive dripping of condensed water from the indoor heat exchanger. Further comprising a refrigerant amount shortage detection unit that detects the refrigerant amount shortage,
2. The control unit according to claim 1, wherein the control unit determines whether or not a refrigerant amount judgment value indicating the amount of refrigerant obtained from the result of detection by the insufficient refrigerant amount detection unit satisfies the condition for judging the shortage of refrigerant amount. air conditioner. The refrigerant shortage detection unit includes a refrigerant inlet temperature detection unit that detects the refrigerant inlet temperature of the indoor heat exchanger and a refrigerant outlet temperature detection unit that detects the refrigerant outlet temperature of the indoor heat exchanger,
The control unit calculates a difference between the refrigerant outlet temperature detected by the refrigerant outlet temperature detection unit and the refrigerant inlet temperature detected by the refrigerant inlet temperature detection unit as the refrigerant amount determination value, When the refrigerant amount determination value is larger than the reference value for determining that the refrigerant amount is insufficient, it is determined that the refrigerant amount is insufficient, and when the refrigerant amount determination value is less than the reference value, the 3. The air conditioner according to claim 2, wherein it is determined that the amount of refrigerant is not insufficient. The refrigerant shortage detection unit is a refrigerant pressure detection unit that detects refrigerant pressure in the indoor heat exchanger,
The control unit uses the refrigerant pressure detected by the refrigerant pressure detection unit as the refrigerant amount judgment value, and when the refrigerant amount judgment value is less than a reference value for determining that the refrigerant amount is insufficient, 3. The air conditioner according to claim 2, wherein it is determined that the refrigerant amount is insufficient, and if the refrigerant amount determination value is greater than the reference value, it is determined that the refrigerant amount is not insufficient. The refrigerant amount shortage detection unit is a refrigerant circulation amount detection unit that detects a refrigerant circulation amount, which is the amount of refrigerant flowing through the indoor heat exchanger,
The control unit sets the refrigerant circulation amount detected by the refrigerant circulation amount detection unit as the refrigerant amount judgment value, and when the refrigerant amount judgment value is less than a reference value for judging that the refrigerant amount is insufficient. 3. The air conditioner according to claim 2, wherein it is determined that the refrigerant amount is insufficient, and when the refrigerant amount determination value is larger than the reference value, it is determined that the refrigerant amount is not insufficient. . When the plurality of plate members are oriented so as not to create resistance in the airflow path to the indoor heat exchanger, the controller controls the speed of the air flowing to the indoor heat exchanger so that the air in the indoor heat exchanger The air conditioner according to any one of claims 1 to 5, wherein the orientation of each of the plurality of plate members is changed so as to be uniform with respect to the inflow surface.

Images