JP7242017B2 - air conditioner - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner in which an evaporator is accommodated in a housing and condensed water condensed on the evaporator can be discharged to the outside of the housing.

As an air conditioner of this type, the following patent document discloses a cooling fan that can be installed indoors and used. In this cooler, each component of the refrigeration cycle is accommodated in a flat box-shaped main body (outer shell: hereinafter also referred to as the "casing"), and the condensed water condensed on the surface of the evaporator can be stored. A drain tank is configured and removably attached to the housing.

During cold air operation of the cooler, the first blower arranged in the first air passage together with the evaporator is operated, so that the air outside the housing flows into the first air passage from the first suction port. is sucked in and blown out of the housing from the first outlet after passing through the evaporator, and by operating the second blower disposed in the second air passage together with the condenser, the second Air outside the housing is sucked into the second air passage through the second intake port, passes through the condenser, and is then blown out of the housing through the second outlet. At this time, the air whose temperature has been lowered by heat exchange with the refrigerant in the evaporator is blown out from the first outlet, and the air whose temperature has been raised by heat exchange with the refrigerant in the condenser is blown out. It is blown out from the second outlet.

Also, during this cold air operation, the moisture contained in the air sucked from the first suction port condenses on the surface of the evaporator, and this condensed water flows down the evaporator and flows out of the first air passage from the drain port. (outside the housing) and flows into the drain tank via a connecting pipe. Therefore, by continuing to operate the cooling fan for a certain amount of time, a large amount of condensed water is stored in the drain tank. In this case, when the water level sensor detects that the drain tank is full of condensed water, the indicator lamp lights up and a warning sound is output to indicate that the condensed water should be discarded. is reported. Therefore, when the user recognizes that the drain tank is full, the user removes the drain tank from the housing, transports it to an arbitrary disposal site, disposes of the condensed water in the drain tank, and then removes the empty drain tank. is brought back to the installation location of the cooling fan and attached to the housing.

Although detailed description is omitted, in this cooler, the second air passage is communicated with the first air passage during drying operation for drying clothes, etc., so that when passing through the evaporator, The dehumidified low-temperature air and the high-temperature air whose temperature is raised when passing through the condenser are mixed and blown out from the first outlet toward the upper front of the cooler. Accordingly, it is possible to suitably dry the clothes or the like with the air blown out from the first outlet. Even during this drying operation, the condensed water that condenses on the surface of the evaporator flows into the drain tank and is stored there. done on purpose.

Japanese Patent Application Laid-Open No. 2008-190803 (pages 4-7, Figures 1-5)

However, the cooling fan disclosed in the above patent document has the following problems to be solved. Specifically, in the above cooler, the water that condensed on the surface of the evaporator during operation was stored in a drain tank attached to the housing, and it was detected that the drain tank was full. In some cases, a configuration is adopted in which the fact that the condensed water should be discarded is notified by lighting an indicator lamp or outputting a warning sound. In this case, the cooling fan is in a fixed installation state (it cannot be moved), as specified in the "Best Mode for Carrying Out the Invention", "In operation, it shall be placed on the floor in a suitable place in the room." A portable air conditioner that is not intended for use in a state where it is fixedly installed in one place without assuming that the is assumed). For this reason, the cooling fan requires a drain tank for preventing the condensed water on the surface of the evaporator from flowing out to the place where the cooling fan is installed.

On the other hand, among portable air conditioners, not only can they be used in a movable installation state, but also in a fixed installation state or a semi-fixed installation state (an installation state that can be moved if a certain amount of time and effort is required). There are also devices that are intended for use with In this case, it is difficult to dispose of the condensed water stored in the drain tank. It is preferable to discharge (dispose of) directly to an outdoor drainage site, etc. Large air conditioners, in particular, process a large amount of air per unit time, resulting in a large amount of condensed water per unit time. necessary. However, in a configuration with a large drain tank, not only is it difficult to transport the large and heavy drain tank containing a large amount of condensed water to the disposal site, but the size of the drain tank also reduces the size of the air conditioner. becomes difficult.

Therefore, for air conditioners that are expected to be used not only in a movable installation state but also in a semi-fixed installation state and a fixed installation state, it is necessary to install an evaporation tank without integrally providing a container body like the drain tank in the above-mentioned cooler. It is preferable to employ a configuration in which the condensed water condensed on the surface of the container is directly discharged to the outside of the housing. As a result, the size of the air conditioner can be reduced by the amount that the drain tank is not integrally provided, and when the air conditioner is used in a semi-fixed state or a fixed state, the condensed water discharge port in the housing can be used as a waste pipe. By connecting it and letting it flow directly to the disposal site, it is possible to eliminate the need to dispose of the condensed water itself. By storing the condensed water in the container, it is possible to avoid the work of transporting a large amount of condensed water, which is difficult to transport, to the disposal site.

However, in a usage pattern in which the condensed water discharged from the housing is stored in a separately prepared container, the container becomes full before the stored condensed water is discarded, and the condensed water overflowing from the container is may flow out. In this case, the amount of condensed water drained from the air conditioner per unit time varies greatly depending on the humidity and temperature of the air to be treated. is extremely difficult to predict accurately. For this reason, it is necessary to frequently check how much condensed water has accumulated in the container so that it does not overflow even if the amount of condensed water that exceeds predictions is discharged per unit time. Confirmation work becomes complicated. In addition, in order to lengthen the period of confirmation work, it becomes necessary to prepare a large container, and in that case, it becomes difficult to solve the above-mentioned problems in the configuration integrally provided with a large drain tank.

Further, the cooling fan disclosed in the above patent document adopts a configuration in which the dew condensation water condensed on the evaporator naturally flows down to the drain tank. For this reason, instead of the drain tank in the cooling fan disclosed in the above patent document, when adopting a configuration in which a waste pipe is directly connected to the condensed water discharge port provided below the evaporator to flow out to the disposal place. Secondly, when the disposal site is located higher than the condensed water outlet, the condensed water cannot be drained from the disposal pipe. In this case, when the air conditioner is operated with the tip of the pipe (the end on the disposal site side) positioned higher than the condensed water outlet, the condensed water that is not drained from the pipe will flow into the evaporator inside the housing. It overflows to the side and flows out to the installation place of the air conditioner. However, it is sometimes difficult to correctly determine which of the condensed water discharge port and the end of the pipe for disposal (disposal site) is located at a higher place, and the condensed water flows out to the installation location of the air conditioner. It is difficult to prevent the situation with certainty.

The present invention has been made in view of such problems to be solved, and provides an air conditioner that can reliably and easily dispose of condensed water generated in the housing at a disposal site while reducing the size of the entire apparatus. The main purpose is to provide

In order to achieve the above object, the air conditioner according to claim 1 has an evaporator in a refrigeration cycle accommodated in a housing, and heat exchange between the air introduced into the housing and the refrigerant in the evaporator. an air conditioner configured to be able to discharge condensed water condensed on the evaporator to the outside of the housing by a first sensor for detecting, a pump for pumping the condensed water stored in the storage unit, a first guiding pipe for guiding the condensed water pumped by the pump to the outside of the housing , and flowing down from the evaporator a water collecting portion formed separately from the storage portion so as to be able to collect the condensed water and arranged below the evaporator; a guide pipe, a second sensor for detecting the amount of the condensed water collected in the water collecting portion, and a control portion for controlling pumping of the condensed water by the pump, and at least the storage portion , the first sensor and the pump are accommodated in the housing, and the control unit controls the amount of the condensed water that is predetermined in the storage unit based on the detection result of the first sensor. a pumping process for pumping the condensed water from the reservoir to the first guide pipe by controlling the pump when it is determined that the condensed water is stored; a pumping amount specifying process for specifying based on an operating state, and when the amount specified in the pumping amount specifying process reaches a predetermined second amount, the amount of the condensed water pumped by the pump is determined. and a first notification process for notifying that the second amount has been reached, and a third amount predetermined in the water collecting portion based on the detection result of the second sensor. a second notification process for notifying that the third amount of the condensed water is retained in the water collecting portion when it is determined that the condensed water is retained in the second sensor; When it is determined that the third amount of the condensed water does not stay in the water collecting part based on the detection result of It is configured to be able to execute both the third notification process for notifying that the

In the air conditioner according to claim 2, the evaporator in the refrigerating cycle is accommodated in the housing, and heat exchange between the air introduced into the housing and the refrigerant in the evaporator causes condensation on the evaporator. An air conditioner configured to be able to discharge condensed water to the outside of the housing, comprising: a storage section capable of storing the condensed water; a first sensor that detects the amount of the condensed water stored in the storage section; a pump for pumping the condensed water stored in the reservoir, a first guide pipe for guiding the condensed water pressure-fed by the pump to the outside of the housing, and collecting the condensed water flowing down from the evaporator a water collecting portion formed separately from the reservoir and disposed below the evaporator ; a second guiding pipe for guiding the condensed water from the water collecting portion to the reservoir ; A second sensor for detecting the amount of the condensed water collected in the water section, a power supply section for supplying power to components of the air conditioning apparatus, and pressure feeding of the condensed water by the pump and power supply by the power supply section. and at least the reservoir, the first sensor and the pump are accommodated in the housing, and the power supply unit converts commercial alternating current to AC/DC to convert the air conditioner to Power is supplied to the components of the air conditioner, and power is supplied from the battery to the components of the air conditioner according to the control of the control unit, and the control unit supplies power to the components of the air conditioner based on the detection result of the first sensor . A pressure-feeding process of controlling the pump to force-feed the condensed water from the storage section to the first guide pipe when it is determined that a predetermined first amount of the condensed water has been stored in the storage section. a pumping amount specifying process for specifying the amount of the condensed water pressure-fed by the pump based on the operating state of the pump; and a pumping amount specifying process in which the specified amount reaches a predetermined second amount. a first notification process for notifying that the amount of the condensed water pressure-fed by the pump has reached the second amount when the dew condensation water has reached the second amount, and detection by the second sensor; When it is determined based on the result that a predetermined third amount of the condensed water remains in the water collecting section, the third amount of the condensed water remains in the water collecting section. a second notification process for notifying that the condensed water is present in the water collecting portion; A third for notifying that the third amount of the condensed water is not retained in the water part a notification process, and determining that the third amount of the condensed water remains in the water collecting portion; and the first amount of the condensed water. is stored in the storage unit, the power supply unit is controlled and the A battery provides continuous power to the pump .

The air conditioner according to claim 3 is the air conditioner according to claim 1 or 2, wherein the amount of the condensed water specified by the control unit as pumped by the pump based on the operating state of the pump is An operation unit capable of performing a reset operation for resetting an integrated value is provided, and the control unit resets the integrated value of the amount of the dew condensation water specified as pumped by the pump when the reset operation is performed. do.

The air conditioner according to claim 4 is the air conditioner according to any one of claims 1 to 3, wherein the condenser in the refrigeration cycle is accommodated in the housing, and the condensed water pumped by the pump to the condenser, and a switching valve for switching the destination of the condensed water by the pump to either the first guide pipe or the third guide pipe. ing.

The air conditioner according to claim 5 is the air conditioner according to claim 4, wherein the control unit controls the switching valve after execution of the first notification process to determine the destination of the condensed water by the pump. is switched to the third guide pipe.

In the air conditioner according to claims 1 and 2 , the pump is operated when the control unit determines that a predetermined first amount of condensed water is stored in the storage unit based on the detection result of the first sensor. A pumping process for controlling and pumping the condensed water from the reservoir to the first guide pipe, a pumped amount specifying process for specifying the amount of the condensed water pumped by the pump based on the operating state of the pump, and a pumped amount specifying and a first notification process for notifying that the amount of dew condensed water pumped has reached the second amount when the amount specified in the process reaches the second amount specified in advance. It is

Therefore, according to the air conditioner of claims 1 and 2 , when the condensed water condensed on the evaporator is directly discharged to the disposal site through a guide pipe or the like, the disposal site is at a higher place than the air conditioner. Even so, the condensed water discharged to the outside of the housing by the pressure-feeding process by the pump can be reliably moved to the disposal site. As a result, it is possible to preferably avoid a situation in which the condensed water flows out to the installation location of the air conditioner. In addition, by connecting a guide pipe that reaches the disposal site and allowing the condensed water discharged from the housing to flow directly to the disposal site, it is possible to eliminate the need to dispose of the condensed water and guide it to a container prepared separately. In the mode of use in which the condensed water flows out from the water pipe, the amount of the condensed water discharged from the housing and stored in the container is determined according to the capacity of the prepared container. Even without monitoring the first notification process, it is possible to reliably and easily recognize that the condensed water in the container body should be discarded based on the notification by the first notification process, and the condensed water overflows from the container body. Disposal operations can be carried out prior to release. As a result, it is possible to reliably avoid the situation where the condensed water overflows from the container body and flows into the installation location of the air conditioner. Furthermore, by not integrally providing an unnecessary container for storing condensed water in the fixed installation state or the semi-fixed installation state, the overall size of the air conditioner can be sufficiently reduced.

Further, in the air conditioner according to claims 1 and 2, the control unit detects a state in which a predetermined third amount of condensed water is retained in the water collection unit based on the detection result of the second sensor. a second notification process for notifying that a third amount of condensed water remains in the water collecting section when the determination is made; It is possible to execute both (or at least one of ) a third notification process for notifying that the third amount of condensed water does not remain in the water collecting portion when it is determined that the condensed water does not remain. is configured to Therefore, according to the air conditioners of claims 1 and 2, the power supply is cut off when there is a risk that the condensed water may flow out from the water collecting part or the storage part when the power is cut off and the pump does not operate. It is possible to suitably avoid a situation in which the air conditioner is moved when there is a risk that condensed water may flow out from the water collecting portion or the storage portion when the air conditioner is moved.
Further, in the air conditioner according to claim 2, the control unit determines that the third amount of condensed water is retained in the water collecting unit, and the state in which the first amount of condensed water is retained in the storage unit When the power supply is cut off or the power supply is cut off from the commercial AC, the power supply is controlled to continue supplying power from the battery to the pump. to supply Therefore, a person who does not know that the third amount of condensed water is retained in the water collecting portion or that the first amount of condensed water is retained in the reservoir cuts off the power supply. Even if commercial alternating current is cut off due to a power failure or the like against the will of the user, the state in which the condensed water in the water collecting part is pressure-fed to a separately prepared container can be maintained.

According to the air conditioner of claim 3, when the reset operation is performed, the control unit resets the integrated value of the amount of condensed water that is specified to have been pressure-fed by the pump. When the condensed water discharged outside the body and stored in the container is discarded before the first notification process is executed (that is, before a sufficient amount of condensed water is stored in the container) , the amount of condensed water newly stored in the empty container can be specified correctly, and the first notification process can be executed at a suitable timing. As a result, it is possible to more reliably avoid the situation where the condensed water overflows from the container body and flows into the installation location of the air conditioner.

According to the air conditioner of claim 4, the third guide pipe for guiding the condensed water pressure-fed by the pump to the condenser, and the destination of the pressure-fed condensed water by the pump are the first guide pipe and the third guide pipe. By providing a switching valve for switching to one of the guide pipes, the condensation efficiency of the refrigerant in the condenser can be improved by spraying the condensed water from the third guide pipe to the condenser. In a mode of use in which the condensed water discharged from the body is stored in the container and transported together with the container to a disposal site for disposal, the amount of water injected from the third guide pipe to the condenser is stored in the container. Since the amount of condensed water can be reduced, the burden of disposal work can be sufficiently reduced.

According to the air conditioner of claim 5, the controller controls the switching valve after executing the first notification process to switch the destination of the condensed water pumped by the pump to the third guide pipe. Since the condensed water pressure-fed by the pump after the execution of the notification process of 1 is sprayed from the third guide pipe to the condenser, the container body that stores the condensed water discharged from the housing has more condensation. It is possible to suitably avoid a situation in which water flows in and condensed water overflows from the container body.

1 is a configuration diagram showing the configuration of an air conditioner 1 according to an embodiment of the present invention; FIG. 2 is an explanatory diagram for explaining the internal structure of the air conditioner 1. FIG.

Hereinafter, embodiments of an air conditioner will be described with reference to the accompanying drawings.

First, the configuration of the air conditioner 1 will be described with reference to the accompanying drawings.

The air conditioner 1 shown in FIGS. 1 and 2 is an example of an "air conditioner" and is a portable integrated cooling fan. It is configured so that it can be installed and used in relatively large buildings such as outdoor event venues and sports venues. As shown in FIG. 1, the air conditioner 1 includes a refrigerating cycle 2, blowing fans 3a and 3b, a pump 4, a switching valve 5, an operation section 6, a display section 7, a control section 8, a storage section 9, and a power supply section. 10 are housed in a rectangular parallelepiped housing 20 (see FIG. 2) (an example of a configuration in which both the "evaporator" and the "condenser" are housed in the "housing").

The refrigerating cycle 2 includes a compressor 21, a condenser 22, an expansion valve 23, and an evaporator 24. The refrigerant pressure-fed by the compressor 21 and condensed in the condenser 22 passes through the expansion valve 23 to the evaporator 24. By supplying the coolant to the inside, the temperature of the air is lowered by heat exchange between the air passing through the evaporator 24 and the refrigerant, as will be described later. In practice, a pressure sensor for specifying the refrigerant pressure in the refrigerating cycle 2 and a temperature sensor for specifying the refrigerant temperature are provided, but illustration and description of these sensors are omitted. In this case, in the air conditioner 1 of this example, as shown in FIG. is arranged (an example of a configuration in which a “condenser” and an “evaporator” are arranged vertically in a “casing”). Alternatively, the condenser 22 and the evaporator 24 can be arranged side by side within the "housing".

In addition, as will be described later, below the evaporator 24, condensation flows down from the evaporator 24 due to heat exchange between the air introduced into the housing 20 and the refrigerant in the evaporator 24. A drain pan 31 (an example of a “water collecting portion”) is provided to collect water (condensed water flowing down the evaporator 24). Further, the drain pan 31 is provided with a water level sensor 31s (an example of a “second sensor”) that detects the amount of condensed water collected (the amount of condensed water remaining in the drain pan 31). there is Further, as an example, a drain pan 32 (an example of a “reservoir”) is disposed on the side of the condenser 22 (on the bottom plate of the housing 20), and condensation that has flowed down from the evaporator 24 into the drain pan 31 A guide pipe 33 (an example of a “second guide pipe”) for guiding water to the drain pan 32 is laid from the bottom of the drain pan 31 to the inside of the drain pan 32 . In this case, in the air conditioner 1 of this example, the guide pipe 33 is connected to the deepest portion of the drain pan 31 when the air conditioner 1 is installed on the horizontal ground plane, and the guide pipe 33 is connected A water level sensor 31s is installed near the site.

As an example, the blowing fan 3a blows out the air heat-exchanged in the evaporator 24 to the outside of the housing 20, thereby introducing new air into the housing 20 (air heat-exchanged in the evaporator 24). It is arranged downstream of the evaporator 24 in the flow path. As an example, the blower fan 3b blows out the air heat-exchanged in the condenser 22 to the outside of the housing 20, thereby introducing new air into the housing 20 (air heat-exchanged in the condenser 22). It is arranged downstream of the condenser 22 in the flow path.

The pump (drain pump) 4 is an example of a “pump” and is configured to pump the condensed water stored in the drain pan 32 toward the outside of the housing 20 and the condenser 22 . As an example, the pump 4 includes a mechanical portion 4p that operates by power supplied from the power supply portion 10, and a water level sensor 4s (an example of a “first sensor”) that detects the amount of dew condensation water stored in the drain pan 32. and a control section 4c for controlling the operation of the mechanism section 4p according to the sensor signal from the water level sensor 4s. In this case, in the air conditioning apparatus 1 of this example, the pump 4 (mechanism part 4p) is configured by a pump with a fixed pumping capacity (a pump that pumps a constant amount of liquid per unit time).

In addition, in the air conditioner 1 of the present example, the switching valve 5 (an example of a "switching valve") is connected to the mechanical portion 4p of the pump 4, and the pump 4 (mechanical portion 4p) pumps air to the switching valve 5. A guide pipe 34 (an example of a “third guide pipe”) that guides the condensed water to the condenser 22 (injects the condensed water onto the surface of the condenser 22) and guides it outside the housing 20. A guide pipe 35 (an example of a "first guide pipe") is connected. In this case, as an example, the switching valve 5 directs the dew condensation water to be pressure-fed by the pump 4 to either the guide pipe 34 (condenser 22) or the guide pipe 35 (outside the housing 20) under the control of the control unit 8. switch. A nozzle capable of injecting condensed water pressure-fed by the pump 4 is attached to the tip of the guide pipe 34 (the end on the condenser 22 side), and the tip of the guide pipe 35 (the end of the housing 20) is attached. A connector to which an arbitrary length of guiding pipe Px can be connected is attached to the end portion that is pulled out to the outside.

In addition, in the air conditioner 1 of the present example, the controller 4c and the controller 8 of the pump 4 together constitute a "controller". Specifically, the control unit 4c controls the operation of the mechanism unit 4p under the control of the control unit 8 as will be described later, and determines the amount of condensed water in the drain pan 32 based on the sensor signal from the water level sensor 4s. Identify. Further, when the control unit 4c determines that a specified amount (an example of a “predetermined first amount”) of condensed water is stored in the drain pan 32 based on the detection result of the water level sensor 4s, the mechanism unit 4p is activated. A "pumping process" is executed to control and force the condensed water from the drain pan 32 toward the switching valve 5 (the guide pipe 34 or the guide pipe 35). Furthermore, the control unit 4c outputs data indicating the operating state of the mechanism unit 4p to the control unit 8. FIG.

The operation unit 6 is an example of an "operation unit", and includes an operation switch for setting operating conditions of the air conditioner 1, an operation switch for instructing start/stop of operation of the air conditioner 1, and an operation switch which will be described later. The value integrated by the control unit 8 for the condensed water pressure-fed by the pump 4 (the integrated value of the condensed water specified by the control unit 8 as being injected toward the condenser 22, A reset button or the like for resetting the amount of condensed water specified as being discharged) is provided, and an operation signal corresponding to the operation thereof is output to the control unit 8 . The display unit 7 displays various information such as operating conditions and operating states of the air conditioner 1 under the control of the control unit 8 .

The control unit 8 comprehensively controls the air conditioner 1 . Specifically, the control unit 8 controls the compressor 21 of the refrigeration cycle 2 to compress the refrigerant, and controls the expansion valve 23 to discharge the required amount of refrigerant into the evaporator 24 . Further, the control unit 8 controls the blowing fans 3 a and 3 b to blow air, and causes the display unit 7 to display the operating state of the air conditioner 1 . Further, the control unit 8 controls the pump 4 (control unit 4c) to execute the process of pumping the condensed water, and data transmitted from the pump 4 (control unit 4c) (the operation state of the mechanism unit 4p can be specified). data) to specify the amount of condensed water pressure-fed by the pump 4 (mechanism part 4p).

In addition, the control unit 8 connects the pump 4 (mechanism unit 4p) to the guide pipe 35 by controlling the switching valve 5, and the amount specified in the above-described "pumping amount specifying process", that is, the guide pipe The amount of condensed water discharged out of the housing 20 when the amount of condensed water discharged out of the housing 20 from 35 reaches a preset amount (an example of the “second amount”). Executes a "first notification process" for notifying that has reached a set amount. In this case, in the air conditioner 1 of this example, as an example of the "first notification processing", a message "The amount of waste water has reached the set amount. Please operate the reset button after the disposal is completed." is displayed. Display on the unit 7, light up an indicator (not shown) indicating that the amount of condensed water drained from the air conditioner 1 (housing 20) has reached a set amount, and output a warning sound from a speaker (not shown) do.

Furthermore, the control unit 8 connects the pump 4 (mechanism unit 4p) to the guide pipe 34 by controlling the switching valve 5 after executing the “first notification process” (“Destination of condensed water pumped by the pump An example of the process of "switching to the third guide pipe"), and the amount specified in the "pumping amount specifying process" executed after the "first notification process", that is, from the guide pipe 34 to the condenser 22 When the amount of condensed water injected toward the surface of the condenser 22 reaches a preset amount, it is identifiably notified that the amount of condensed water injected toward the condenser 22 has reached the set amount. . In this case, in the air conditioning apparatus 1 of this example, as an example, the message "Condensed water may flow out. Please operate the reset button after disposal is completed." is displayed on the display unit 7, and An indicator (not shown) is turned on to indicate that the amount of condensed water jetted toward the condenser 22 has reached a set amount, and a warning sound is output from a speaker (not shown).

The controller 8 also specifies the amount of condensed water detected by the water level sensor 31 s, that is, the amount of condensed water remaining in the drain pan 31 . Further, when the control unit 8 determines that a predetermined amount (an example of the “third amount”) of condensed water remains in the drain pan 31, for example, an indicator (not shown) lights up in red. By doing so, a “second notification process” for notifying that the amount of condensed water exceeding a specified amount is stagnant in the drain pan 31, and a predetermined amount (“third amount”) of condensed water is added to the drain pan 31. a "third notification process" for notifying that dew condensation water exceeding a specified amount does not remain in the drain pan 31 by lighting an indicator (not shown) in green when it is determined that the condensed water does not remain in the drain pan 31; Execute (an example of a configuration for executing both the "second notification process" and the "third notification process").

The storage unit 9 stores an operation program of the control unit 8, data of operating conditions of the air conditioner 1, and the like. A power supply unit 10 supplies power to each of the components 2 to 9 described above. In this case, as shown in FIG. 1, in a normal state, the power supply unit 10 in the air conditioning apparatus 1 of the present embodiment converts commercial alternating current into AC/DC and steps it down, and then supplies it to each unit. When the control unit 8 determines that a specified amount of condensed water has accumulated in the drain pans 31 and 32, when the connection with the commercial alternating current is cut off, the pump 4, the display unit 7, and the control unit A battery 10a for supplying power to the unit 8 and the like is provided.

The housing 20 is an example of a "housing", and as shown in FIG. 2, is formed in a rectangular parallelepiped shape as a whole. In this case, in the air conditioner 1 of this example, the space accommodating the condenser 22, the space accommodating the evaporator 24, the space accommodating the compressor 21, the power supply unit 10, and the like, and the control unit 8 and the like are provided in the housing 20 independently of each other. In addition, the housing 20 has an inlet for introducing air to exchange heat with the condenser 22, an outlet for blowing out the air heat-exchanged with the condenser 22, an inlet for introducing air for heat-exchanging with the evaporator 24, and air outlets for blowing out the air heat-exchanged with the evaporator 24 (not shown).

When using the air conditioner 1, the air conditioner 1 is installed in a place where the air (cold air) whose temperature has been lowered by the evaporator 24 is to be supplied, and the power supply section 10 is connected to the commercial alternating current. At this time, when the air conditioner 1 is used in a semi-fixed installation state or a fixed installation state, as indicated by the broken line in FIG. Have them guide you to the disposal site for disposal. As a result, the condensed water discharged from the air conditioner 1 is directly guided to the disposal site by the guide pipe Px. Next, the air conditioner 1 is powered on, and the operation section 6 is operated to set the operating conditions. At this time, in this example used in the semi-fixed installation state or the fixed installation state, an operation mode is selected in which the above-described warning regarding the amount of condensed water discharged from the guide pipe 35 to the outside of the housing 20 is not issued.

Next, when the operation start is instructed by the switch operation on the operation unit 6, the control unit 8 controls the switching valve 5 to connect the pump 4 (mechanism unit 4p) to the guide pipe 34, and the refrigeration cycle 2 , the air blowing fans 3a and 3b are started to operate, and the operation state is displayed on the display unit 7. At this time, the blower fan 3a starts blowing with the electric power supplied from the power supply unit 10, so that the air in the housing space of the evaporator 24 is blown out of the housing 20 from the blowout port. Air outside the housing 20 is introduced into the housing space of the evaporator 24 through the inlet. In addition, when the blower fan 3b starts blowing with electric power supplied from the power supply unit 10, the air in the accommodation space of the condenser 22 is blown out of the housing 20 from the blowout port. Outside air is introduced into the housing space of the condenser 22 through the inlet. Furthermore, the refrigerant condensed in the condenser 22 is supplied to the evaporator 24 via the expansion valve 23 by compressing (pumping) the refrigerant in the refrigerating cycle 2 with the electric power supplied from the power supply unit 10 by the compressor 21 . be done.

At this time, the air introduced into the housing space of the evaporator 24 is blown out of the housing 20 after the temperature of the air is lowered by heat exchange with the refrigerant in the evaporator 24 when passing through the evaporator 24. be. Therefore, the temperature of the space ahead of the direction in which the air is blown out from the blow-out port is lowered. Also, when the air is passed through the evaporator 24 as described above, moisture contained in the air condenses on the surface of the evaporator 24 , and the condensed water flows down into the drain pan 31 . Condensed water collected by the drain pan 31 flows into the drain pan 32 via the guide pipe 33 and is stored therein. Therefore, the amount of condensed water stored in the drain pan 32 gradually increases according to the elapsed time after the operation of the air conditioner 1 is started.

Further, in the pump 4, when the controller 4c identifies the amount of condensed water stored in the drain pan 32 based on the sensor signal from the water level sensor 4s, and determines that a predetermined amount of drain water has been stored. Then, the mechanism part 4p is controlled to execute the "pumping process". At this time, the condensed water in the drain pan 32 is pressure-fed toward the condenser 22 via the switching valve 5 and the guide pipe 34, and is discharged from the tip of the guide pipe 34 (nozzle not shown) to the surface of the condenser 22. is injected into As a result, the temperature of the refrigerant in the condenser 22 is lowered by the heat of vaporization of the sprayed condensed water, and as a result, the efficiency of condensing the refrigerant is improved compared to when the condensed water is not sprayed. Further, the control unit 4c outputs to the control unit 8 data indicating that the “pumping process” has started.

In this case, although the condensation efficiency of the refrigerant is improved by spraying the condensed water as described above, if the amount sprayed per unit time is too large, part of the sprayed condensed water will not evaporate and the condenser 22 run down the surface of In such a case, the condensed water that has flowed down from the condenser 22 may flow out to the installation location of the air conditioner 1 .

On the other hand, in the air conditioner 1 of the present example, the amount of condensed water pressure-fed by the pump 4 (mechanism unit 4p) based on the data output from the pump 4 (control unit 4c) by the control unit 8, that is, the amount of condensed water pumped by the pump 4 In this example connected to the guide pipe 34 , the “pumping amount specifying process” for specifying the amount of condensed water sprayed from the guide pipe 34 to the condenser 22 is executed. Specifically, in the air conditioning apparatus 1 of this example that employs the pump 4 with a fixed pumping capacity, the pumping capacity of the pump 4 (pumping amount per unit time) and the pump 4 perform the "pumping process" It is possible to specify the amount of pumped dew condensation water based on the length of time that the dew condensation is present. Therefore, the control unit 8 specifies the amount of condensed water pressure-fed by the pump 4 (mechanism unit 4p) based on the elapsed time since the pump 4 output data indicating that the “pumping process” was started. In the air conditioner 1 (pump 4) of this example, when the control unit 4c specifies that the amount of condensed water in the drain pan 32 has fallen below a predetermined amount based on the sensor signal from the water level sensor 4s The mechanism part 4p is stopped immediately, and data indicating that the "pumping process" has been stopped is output to the control part 8. As shown in FIG.

Further, when the specified amount (the amount injected into the condenser 22) reaches a predetermined amount, the control unit 8 controls the switching valve 5 to switch the pump 4 from the guide pipe 34 to the guide pipe 35. to connect. As a result, the injection of condensed water from the guide pipe 34 to the condenser 22 is stopped, so that a situation in which excessive condensed water is injected and the condensed water flows down the surface of the condenser 22 can be avoided. Further, during the "pumping process" after connecting the pump 4 to the guide pipe 35, the condensed water in the drain pan 32 is guided to the disposal site via the guide pipe 34, the switching valve 5 and the guide pipe Px. As a result, the condensed water is discharged from the tip of the guide pipe Px to the disposal site.

Regarding the above-mentioned "predetermined amount" when the control unit 8 controls the switching valve 5 to connect the pump 4 to the guide pipe 35, the pumping capacity of the pump 4 and the size of the condenser 22 ( Although a fixed amount can be specified according to the surface area), for example, according to the time until the specified amount of condensed water is stored in the drain pan 32, the specified amount of condensed water is accumulated in a relatively short time. A specified amount of condensed water is stored in a somewhat longer time than the amount when it is stored (that is, when the humidity of the air passing through the evaporator 24 is high and the condensed water sprayed to the condenser 22 is difficult to evaporate). The variable amount can also be defined so that the amount is larger when the humidity of the air passing through the evaporator 24 is low and the condensed water sprayed to the condenser 22 is easy to evaporate. .

In addition, the control unit 8 measures the elapsed time from the time when the pump 4 is switched to the guide pipe 35 and connected, and even if the condensed water is sprayed to the condenser 22 again, there is no possibility that it will flow down from the condenser 22. When the time has passed (when the time required for the temperature of the refrigerant in the condenser 22 to rise sufficiently to vaporize the condensed water in the condenser 22 has passed), the switching valve 5 is controlled. The pump 4 is switched from the guide pipe 35 to the guide pipe 34 and connected. As a result, the condensed water pressure-fed by the pump 4 is jetted from the guide pipe 34 to the condenser 22, so that the efficiency of condensing the refrigerant in the condenser 22 is improved. Instead of restarting the injection of condensed water to the condenser 22 based on the elapsed time from when the injection of the condensed water to the condenser 22 was stopped as in the above example (or such a construction In addition), by monitoring the refrigerant temperature and refrigerant pressure in the refrigerating cycle 2, when it is determined that the condensed water injected to the condenser 22 is sufficiently vaporized, the injection of the condensed water is restarted. can also be adopted.

On the other hand, when the air conditioner 1 is used in a movable installation state, a container body having an arbitrary capacity capable of storing dew condensation water discharged from the air conditioner 1 is prepared, and as indicated by the solid line in FIG. A guide pipe Px is connected to the tip of the guide pipe 35 to guide the condensed water to the container body. Next, the air conditioner 1 is powered on, and the operation section 6 is operated to set the operating conditions. At this time, in this example used in the movable installation state, an operation mode is selected in which a warning is issued regarding the amount of condensed water discharged from the guide pipe 35 to the outside of the housing 20 . In addition, when using this operation mode, an arbitrary storage allowable amount (an amount determined to be transportable to a disposal site together with the container) is set within the range of the capacity of the prepared container.

Next, when an instruction to start operation is given by a switch operation on the operation unit 6, the control unit 8 controls the switching valve 5 to connect the pump 4 (mechanism unit 4p) to the guide pipe 35, and the refrigeration cycle 2 , the air blowing fans 3a and 3b are started to operate, and the operation state is displayed on the display unit 7. The flow of air heat-exchanged in the evaporator 24 and the condenser 22 is the same as in the above operation example in the semi-fixed installation state or the fixed installation state, so a detailed description thereof will be omitted. In this case, even when the air conditioner 1 is used in a movable installation state, condensed water condensed on the surface of the evaporator 24 during operation of the air conditioner 1 and collected by the drain pan 31 flows into the drain pan 32 via the guide pipe 33. flows into and is stored. Therefore, the amount of condensed water stored in the drain pan 32 gradually increases according to the elapsed time after the operation of the air conditioner 1 is started.

Further, in the pump 4, when the controller 4c identifies the amount of condensed water stored in the drain pan 32 based on the sensor signal from the water level sensor 4s, and determines that a predetermined amount of drain water has been stored. Then, the mechanism part 4p is controlled to execute the "pumping process". At this time, the condensed water in the drain pan 32 is discharged to the outside of the housing 20 via the switching valve 5 and the guide pipe 35, and flows down into the container through the guide pipe Px. As a result, the amount of condensed water stored in the container body gradually increases according to the elapsed time after the start of the "pumping process". Further, the control unit 4c outputs to the control unit 8 data indicating that the “pumping process” has started.

In response to this, the control unit 8 controls the amount of condensed water pressure-fed by the pump 4 (mechanism unit 4p) based on the data output from the pump 4 (control unit 4c). In this example, the "pumping amount specifying process" for specifying the amount of condensed water pressure-fed from the guide pipe 35 to the container through the guide pipe Px (the amount of condensed water stored in the container) is specified. ”. Note that the specific processing procedure of the "pumping amount specifying process" is the same as the operation example in the usage pattern described above, so detailed description thereof will be omitted.

In addition, the control unit 8 controls the switching valve 5 when the specified amount (the amount discharged from the housing 20: that is, the amount stored in the prepared container body) reaches a predetermined amount. , the pump 4 is switched from the guide pipe 35 to the guide pipe 34 to be connected, and the amount of condensed water discharged from the guide pipe 35 to the outside of the housing 20 is a preset amount ("second amount ”) is executed. Specifically, as an example of the “first notification process”, the control unit 8 causes the display unit 7 to display the message “The amount of waste water has reached the set amount. , an indicator (not shown) that indicates that the amount of condensed water drained from the air conditioner 1 (housing 20) has reached a set amount is lit, and a warning sound is output from a speaker (not shown). It should be noted that the operation when the pump 4 is switched to the guide pipe 34 (injection of condensed water to the condenser 22) is the same as in the above-described operation example in the semi-fixed installation state or the fixed installation state. detailed description is omitted.

In addition, the user who recognizes that the amount of condensed water drained from the air conditioner 1 has reached the set amount by displaying the message, lighting the indicator, and outputting a warning sound as described above, is notified that the drained condensed water has reached the set amount. The stored container body is transported to a transport location and the condensed water is discarded. In this case, since the air conditioner 1 of this example employs a configuration in which the destination of the pump 4 is switched to the guide pipe 34 prior to the above-described notification processing, the drainage amount of the condensed water reaches the set amount. When the user recognizes this, the condensed water is not discharged from the guide pipe Px (guide pipe 35), but is sprayed from the guide pipe 34 to the condenser 22. As shown in FIG. Therefore, even if there is no container at the tip of the guide pipe Px, the condensed water does not flow out, so that the operation of transporting the container storing the condensed water to the disposal site can be started immediately.

On the other hand, when the disposal of the condensed water at the disposal site is completed, the empty container body is transported to the installation site of the air conditioner 1 and placed ahead of the guide pipe Px, and then the reset button of the operation unit 6 is operated. . In this case, the control unit 8 continues to display the message, light the indicator, and output the warning sound as described above until the user performs a reset operation. Therefore, it is possible to reliably make the user aware that the amount of condensed water discharged from the air conditioner 1 has reached the set amount. Further, when the reset button is operated, the control unit 8 controls the switching valve 5 to switch the pump 4 from the guide pipe 34 to the guide pipe 35 for connection, and displays the message and the indicator. The lighting and the output of the warning sound are stopped, and the integrated value of the amount of condensed water that is specified as having been discharged to the outside of the housing 20 by the "pumping amount specifying process" is reset. As a result, the condensed water in the drain pan 32 is discharged to the outside of the housing 20 through the switching valve 5 and the guide pipe 35 and stored in the container through the guide pipe Px in the same manner as when the operation is started. state, and the amount of discharged condensed water is newly integrated.

On the other hand, when it is determined that the amount discharged from the housing 20 (that is, the amount stored in the prepared container body) has reached a predetermined amount, and the pump 4 is switched to the guide pipe 34 , the control unit 8 executes a “pumping amount specifying process” for specifying the amount of condensed water pressure-fed from the drain pan 32 to the condenser 22 via the guide pipe 34 . At this time, after switching the dew condensation water destination to the guide pipe 34 (condenser 22), the user does not operate the reset button, and the amount specified by the "pumping amount specifying process" (condenser 22 When the amount of sprayed water reaches a predetermined amount, for example, the control unit 8 continues lighting the indicator and changes the message displayed on the operation unit 6 to "There is a risk that condensed water may flow out. Please complete the disposal operation immediately and press the reset button." and change the volume and type of warning sound. As a result, an excessive amount of condensed water is ejected to the condenser 22 and discharged from the housing 20 (stored in the container body) before the condensed water flows out to the installation location of the air conditioner 1. The user can be made aware that the amount of condensed water has reached the specified amount.

On the other hand, when used in a movable installation state, it may be necessary to move the air conditioner 1 in operation to another installation location. At this time, during the operation of the air conditioner 1, as described above, the condensed water condensed on the evaporator 24 flows down to the drain pan 31 and is collected. In this case, since the condensed water condensed on the surface of the evaporator 24 flows down into the drain pan 31 due to its own weight, it takes some time for the condensed water to flow down from the evaporator 24 into the drain pan 31 .

In addition, in the air conditioner 1 of this example, since the guide pipe 33 is connected to the deepest part of the drain pan 31, all of the condensed water flowing down from the evaporator 24 and collected by the drain pan 31 is is guided to the drain pan 32 via the However, the amount of condensed water generated per unit time is large due to the accumulation of foreign matter at the bottom of the drain pan 31 and the flow of condensed water being stagnant, or the high humidity of the air introduced into the air conditioner 1 . It takes a certain amount of time for the condensed water in the drain pan 31 to move to the drain pan 32 when such a state occurs.

Furthermore, in the air conditioner 1 of the present embodiment, the pump 4 does not constantly pressure-feed the condensed water in the drain pan 32, but when a predetermined amount of condensed water is stored in the drain pan 32, the pump 4 A configuration for executing a "pumping process" is adopted. Therefore, a certain amount of condensed water is stored in the drain pan 32 until the "pumping process" by the pump 4 is completed. Further, as described above, it takes a certain amount of time for the condensed water to flow down from the evaporator 24 to the drain pan 31, and it takes a certain amount of time for the condensed water to move from the drain pan 31 to the drain pan 32. Even after the "process" is completed, new condensed water flows into the drain pan 32 through the guide pipe 33, and a certain amount of condensed water is stored in the drain pan 32. - 特許庁

Therefore, when the air conditioner 1 in operation is stopped, a certain amount of condensed water exists inside the housing 20 (on the surface of the evaporator 24 and inside the drain pans 31 and 32). Therefore, when the power supply is cut off in order to move the operating air conditioner 1 to a new installation location (when the operation unit 6 is operated to shift to the OFF state, or when the power supply unit 10 is disconnected from the commercial AC) ), condensed water exceeding the storable amount may flow into the drain pan 32 and flow out from the drain pan 32 . Even if the amount of condensed water flowing into the drain pan 32 is within the range of the storable amount, the condensed water may flow out of the drain pan 32 when the air conditioner 1 is moved.

On the other hand, in the air conditioner 1 of the present embodiment, as described above, the controller 8 always identifies the amount of condensed water remaining in the drain pan 31 based on the sensor signal from the water level sensor 31s, When it is determined that a certain amount (“third amount”) of condensed water remains in the drain pan 31, the indicator is lit in red (“second notification process”), and a predetermined amount ( "third amount") of the condensed water is not retained in the drain pan 31, the indicator is lit in green ("third notification process"). Further, in the air conditioner 1 of the present embodiment, the amount of condensed water stored in the drain pan 32 is always specified based on the operating state of the pump 4, and a predetermined amount of condensed water is stored in the drain pan 32. A configuration is adopted in which the indicator is lit in red even when it is determined that the state is

As a result, by checking the lighting color of the indicator when trying to cut off the power when moving the air conditioner 1 in operation, or when trying to move without cutting off the power, the indicator lights up in red. When the indicator is on, the condensed water may flow out from the drain pans 31, 32, and when the indicator is lit in green, it can be reliably and easily grasped that there is no risk of the condensed water flowing out from the drain pans 31, 32. It is possible. Therefore, when the indicator is lit in red, that is, when the amount of condensed water in the drain pan 31 or the amount of condensed water in the drain pan 32 exceeds the specified amount, the power supply is turned off. It is possible to prevent the condensed water from flowing out of the housing 20 by not blocking or moving the air conditioner 1 .

Further, in the air conditioner 1 of the present example, a state in which it is determined that a predetermined amount (“third amount”) of condensed water is retained in the drain pan 31, or a predetermined amount of condensed water In a state in which it is determined that water is stored in the drain pan 32, when an operation to turn off the power is performed on the operation unit 6, or when the power supply unit 10 is cut off from the commercial alternating current, the control unit 8 stops the power supply A configuration is adopted in which power is continuously supplied from the battery 10a to the pump 4 by controlling the unit 10, and when the pump 4 is switched to the guide pipe 34, the pump 4 is switched to the guide pipe 35 for connection. It is As a result, a person who does not recognize that the indicator is lit in red, or who does not understand the status notified by the lighting in red, cuts off the power supply, or unintentionally Even if the power supply is interrupted due to a power failure or the like, the state in which the condensed water in the drain pan 32 is pressure-fed to a separately prepared container body is maintained.

Thus, in the air conditioner 1, when the control unit 4c determines that the "predetermined first amount" of condensed water has been stored in the drain pan 32 based on the detection result of the water level sensor 4s, the mechanism The control unit 8 controls the unit 4p to perform a “pumping process” for pumping the condensed water from the drain pan 32 to the guide pipe 35, and the control unit 8 controls the amount of the condensed water pumped by the pump 4 (mechanism unit 4p). 4, and pumped by the pump 4 when the amount specified in the "pumping amount specifying process" reaches the "predetermined second" amount. A "first notification process" for notifying that the amount of dew condensation water has reached a "second amount" can be executed.

Therefore, according to the air conditioner 1, when the condensed water condensed on the evaporator 24 flows directly to the disposal site through the guide pipe Px or the like, even if the disposal site is higher than the air conditioner 1, Also, the condensed water discharged out of the housing 20 by the "pumping process" by the pump 4 can be reliably moved to the disposal site. As a result, it is possible to suitably avoid the situation where the condensed water flows out to the installation location of the air conditioner 1 . In addition, by connecting a guide pipe Px that reaches the disposal site and allowing the condensed water discharged from the housing 20 to flow directly to the disposal site, it is possible to eliminate the need to dispose of the condensed water. In the usage pattern in which the condensed water flows out from the guide pipe Px, the "first amount" is defined according to the capacity of the prepared container body, so that it is discharged from the housing 20 and stored in the container body. Even if the amount of condensed water collected is not monitored, it is possible to reliably and easily recognize that the condensed water in the container should be discarded based on the notification by the "first notification process". , the disposal operation can be carried out before the condensed water overflows from the container body. As a result, it is possible to reliably avoid the situation where the condensed water overflows from the container body and flows into the installation location of the air conditioner 1 . Furthermore, by integrally not providing an unnecessary container for storing condensed water in the fixed installation state or the semi-fixed installation state, the overall size of the air conditioner 1 can be sufficiently reduced.

Further, in the air conditioner 1, when the controller 8 determines that the "predetermined third amount" of condensed water remains in the drain pan 31 based on the detection result of the water level sensor 31s, A "second notification process" for notifying that a "third amount" of condensed water has accumulated in the drain pan 31, and a "third amount" of condensation on the drain pan 31 based on the detection result of the water level sensor 31s. At least one (in this example, both of them) of a "third notification process" for notifying that the "third amount" of condensed water does not remain in the drain pan 31 when it is determined that water does not remain ) is configured to be executable.

Therefore, according to the air conditioner 1, when the power is cut off and the pump 4 does not operate, the power is cut off when there is a risk that the condensed water may flow out from the drain pan 31 or the drain pan 32. It is possible to suitably avoid a situation in which the air conditioning apparatus 1 is moved when there is a risk that condensed water may flow out from the drain pan 31 or the drain pan 32 when the apparatus 1 is moved.

Furthermore, according to the air conditioner 1, when the reset operation is performed, the control unit 8 resets the integrated value of the amount of condensed water that is specified to have been pressure-fed by the pump 4. For example, Before the "first notification process" is executed for the condensed water discharged outside the housing 20 and stored in the container (that is, before a sufficient amount of condensed water is stored in the container) It is possible to correctly specify the amount of condensed water newly stored in the empty container body when the container body is discarded, and to execute the "first notification process" at a suitable timing. As a result, it is possible to more reliably avoid the situation where the condensed water overflows from the container body and flows into the installation location of the air conditioner 1 .

Further, according to the air conditioner 1, the guide pipe 34 for guiding the condensed water pressure-fed by the pump 4 to the condenser 22, and the guide pipe 34 or 35 for the destination of the condensed water pressure-fed by the pump 4. , the condensation efficiency of the refrigerant in the condenser 22 can be improved by spraying condensed water from the guide pipe 34 to the condenser 22, and the In a mode of use in which the condensed water is stored in the container body and transported to a disposal site together with the container body for disposal, the amount of condensed water stored in the container body is increased by the amount of the condensed water that is injected from the guide pipe 34 to the condenser 22. Since it can be reduced, the burden of disposal work can be sufficiently reduced.

Furthermore, according to the air conditioner 1, the control unit 8 controls the switching valve 5 after executing the "first notification process" to switch the destination of the condensed water pumped by the pump 4 to the guide pipe 34. , since the condensed water pressure-fed by the pump 4 after the execution of the "first notification process" is injected from the guide pipe 34 to the condenser 22, the container body storing the condensed water discharged from the housing 20 Therefore, it is possible to suitably avoid a situation in which a larger amount of condensed water flows in and the condensed water overflows from the container body.

In addition, the configuration of the “air conditioner” is not limited to the example of the configuration of the air conditioner 1 described above. For example, the configuration of the air conditioner 1 configured to be able to supply cool air (air whose temperature has been lowered by heat exchange with the refrigerant in the evaporator 24) to the supply target has been described as an example, but the supply target Also in the "air conditioner" configured to be able to supply hot air (air whose temperature has been raised by heat exchange with the refrigerant in the "condenser") to the "evaporator" as in the above air conditioner 1 By adopting a configuration that pumps the condensed water generated in the "pump" and specifies the amount of condensed water pumped based on the operating state of the "pump" and executes the "first notification process" etc. It is possible to achieve the same effects as those achieved by the harmonizing device 1 described above.

Further, in the "pumping amount specifying process", the configuration for specifying the pumping amount of the condensed water based on the pumping capability of the pump 4 and the length of time during which the "pumping process" is executed has been described as an example. , A "pump" that has a defined amount of pumping from the start of the "pumping process" to the end (a pump that automatically stops when a specified amount of liquid has been pumped after the start of the "pumping process") If it is adopted, it is possible to adopt a configuration that specifies the amount of condensed water pumped based on the number of times the “pump” executes the “pumping process” (“the amount of pumped condensed water Another example of the process of "specifying based on the state"). In addition, when a "pump" with variable pumping capacity is adopted, a configuration is adopted in which the amount of condensed water pumped is specified based on the operating speed of the "pump" and the length of time the "pumping process" is being executed. can do.

Further, the configuration includes a guide pipe 34 for guiding the condensed water pressure-fed by the pump 4 to the condenser 22, and a switching valve 5 for switching the destination of the condensed water under pressure to either of the guide pipes 34 and 35. Although the air conditioner 1 has been described as an example, the condensed water stored in the "storage section" is allowed to flow only outside the "casing" without the "third guide pipe" or the "switching valve". It is also possible to employ a configuration in which the condensed water is pumped (a configuration in which the condensed water is not injected into the "condenser").

Further, when it is determined that a "predetermined third amount" of condensed water remains in the drain pan 31 based on the detection result of the water level sensor 31s, a "second notification process" is performed to light the indicator in red. and a "third notification process" of lighting the indicator in blue when it is determined that the "third amount" of condensed water does not remain in the drain pan 31 based on the detection result of the water level sensor 31s. Although the air conditioner 1 having a configuration capable of executing is described as an example, only one of the "second notification process" and the "third notification process" can be configured to be executable. .

The present invention is an invention of an air conditioner that can be installed and used in relatively large buildings such as livestock barns, greenhouse cultivation buildings, gymnasiums, factories, warehouses, and theaters, as well as outdoor event venues, sports venues, and the like. is.

REFERENCE SIGNS LIST 1 air conditioner 2 refrigerating cycle 3a, 3b blower fan 4 pump 4p mechanism 4s, 31s water level sensor 4c, 8 control unit 5 switching valve 6 operation unit 7 display unit 9 storage unit 10 power supply unit 10a battery 20 housing 21 compression machine 22 condenser 23 expansion valve 24 evaporator 31, 32 drain pan 33-35, Px guide pipe

Claims (5)

An evaporator in a refrigeration cycle is accommodated in a housing, and heat exchange between air introduced into the housing and refrigerant in the evaporator allows condensed water condensed on the evaporator to be discharged outside the housing. A configured air conditioner,
a storage unit capable of storing the condensed water, a first sensor for detecting the amount of the condensed water stored in the storage unit, a pump for pumping the condensed water stored in the storage unit, and a pump pumped by the pump a first guiding pipe for guiding the condensed water to the outside of the housing, and a first guiding pipe formed separately from the reservoir so as to be able to collect the condensed water that has flowed down from the evaporator and disposed below the evaporator a water collecting portion, a second guiding pipe that guides the condensed water from the water collecting portion to the storage portion, a second sensor that detects the amount of the condensed water collected in the water collecting portion; and a control unit for controlling pumping of the condensed water by the pump, and at least the storage unit, the first sensor and the pump are accommodated in the housing,
The control unit controls the pump when it is determined that a predetermined first amount of the condensed water is stored in the storage unit based on the detection result of the first sensor, and the condensed water is discharged from the storage unit. A pumping process for pumping the condensed water to the first guide pipe, a pumped amount specifying process for specifying the amount of the condensed water pumped by the pump based on the operating state of the pump, and a pumped amount specifying a first notification process for notifying that the amount of the condensed water pressure-fed by the pump has reached the second amount when the amount specified in the process reaches the second amount specified in advance; and when it is determined that a predetermined third amount of the condensed water remains in the water collecting portion based on the detection result of the second sensor, the water collecting portion a second notification process for notifying that the third amount of the condensed water is stagnant in the water section; A third notification process for notifying that the third amount of the condensed water is not retained in the water collecting portion when it is determined that the condensed water is not retained. Air conditioner installed . An evaporator in a refrigeration cycle is accommodated in a housing, and heat exchange between air introduced into the housing and refrigerant in the evaporator allows condensed water condensed on the evaporator to be discharged outside the housing. A configured air conditioner,
a storage unit capable of storing the condensed water, a first sensor for detecting the amount of the condensed water stored in the storage unit, a pump for pumping the condensed water stored in the storage unit, and a pump pumped by the pump a first guiding pipe for guiding the condensed water to the outside of the housing, and a first guiding pipe formed separately from the reservoir so as to be able to collect the condensed water that has flowed down from the evaporator and disposed below the evaporator a water collecting portion, a second guiding pipe that guides the condensed water from the water collecting portion to the storage portion, a second sensor that detects the amount of the condensed water collected in the water collecting portion; a power supply unit that supplies power to components of the air conditioner; and a control unit that controls pumping of the condensed water by the pump and supply of power by the power supply unit , and at least the storage unit and the first and the pump are housed in the housing,
The power supply unit converts commercial alternating current into AC/DC to supply power to the components of the air conditioner, and is configured to be able to supply power from the battery to the components of the air conditioner under the control of the control unit. ,
The control unit controls the pump when it is determined that a predetermined first amount of the condensed water is stored in the storage unit based on the detection result of the first sensor, and the condensed water is discharged from the storage unit. A pumping process for pumping the condensed water to the first guide pipe, a pumped amount specifying process for specifying the amount of the condensed water pumped by the pump based on the operating state of the pump, and a pumped amount specifying a first notification process for notifying that the amount of the condensed water pressure-fed by the pump has reached the second amount when the amount specified in the process reaches the second amount specified in advance; and when it is determined that a predetermined third amount of the condensed water remains in the water collecting portion based on the detection result of the second sensor, the water collecting portion a second notification process for notifying that the third amount of the condensed water is stagnant in the water section; At least one of a third notification process for notifying that the third amount of the condensed water is not retained in the water collecting portion when it is determined that the condensed water is not retained. and a state in which it is determined that the third amount of the condensed water is retained in the water collecting portion; In the discriminated state, when an operation to cut off the power supply is performed and when the power supply section is cut off from the commercial alternating current, the power supply section is controlled to continue power supply from the battery to the pump. Air conditioner supplied . an operation unit capable of performing a reset operation for resetting an integrated value of the amount of the condensed water that the control unit specifies as having been pressure-fed by the pump based on the operating state of the pump;
3. The air conditioner according to claim 1, wherein the control unit resets an integrated value of the amount of the condensed water specified as pressure-fed by the pump when the reset operation is performed. A condenser in the refrigeration cycle is accommodated in the housing,
a third guiding pipe for guiding the condensed water pressure-fed by the pump to the condenser;
4. The air conditioner according to any one of claims 1 to 3, further comprising a switching valve for switching a destination of the condensed water pumped by the pump to either the first guide pipe or the third guide pipe. Device. 5. The air conditioner according to claim 4, wherein the control unit controls the switching valve to switch a destination of the condensed water by the pump to the third guide pipe after the execution of the first notification process.

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