JP4225773B2 - Air conditioner and air conditioning system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a heat exchange unit that heats or cools air, a blower that discharges the air heat-exchanged by the heat exchange unit to the outside, and the blowerBe equippedThe present invention relates to an air conditioner and an air conditioner system including the air conditioner.
[0002]
[Prior art]
Since mold or bacteria are easy to propagate on heat exchangers, filters, drain pans, etc. inside air conditioners, conventionally, paint that has a bactericidal effect is applied to heat exchangers, etc., or heat exchangers etc. are antibacterial materials The growth of mold and bacteria was suppressed by the formation of the above. As a technique relating to these, Japanese Patent Application Laid-Open No. 62-288427 discloses an air conditioner in which a fungicide, a bactericidal agent, a deodorant or the like is mixed or applied to components such as a heat exchanger.
[0003]
Japanese Patent Application Laid-Open No. 11-63632 and Japanese Utility Model Laid-Open No. 5-10937 disclose a technique for heating the inside of an air conditioner or a heat exchanger to suppress generation of mold, bacteria, and the like. Japanese Patent Publication No. 5-73974 also discloses a technique for performing deodorization or the like by sealing the inside of an air conditioner and generating ozone.
[0004]
Furthermore, Japanese Patent Laid-Open No. 5-223325 discloses an air conditioner that suppresses the generation of bacteria by performing air blowing and heating operation after cooling operation, drying the heat exchanger to remove moisture, and so forth. ing. In addition, an air conditioner configured to facilitate removal and disassembly of a front panel and the like in order to facilitate cleaning of an air conditioner in which bacteria or the like are generated is also known.
[0005]
On the other hand, the applicant of the present application has identified H as positive ions in the air.⁺ (H₂ O)_n (Hereinafter, n represents a natural number) and O₂ ^- (H₂ O)_m (Hereinafter, m represents a natural number), the above ions are encased in airborne bacteria to cause a chemical reaction, and hydrogen peroxide (H₂ O₂) And / or a hydroxyl radical (.OH) decomposing action, an ion generator was developed to sterilize airborne bacteria. The ion generator is provided in the vicinity of the blower, and the generated negative ions and positive ions are diffused into the room, thereby succeeding in suppressing and killing mold and bacteria in the room.
[0006]
[Patent Document 1]
Japanese Patent Laid-Open No. 62-288427
[Patent Document 2]
Japanese Patent Laid-Open No. 11-63632
[Patent Document 3]
Japanese Utility Model Publication No. 5-10937
[Patent Document 4]
Japanese Patent Publication No. 5-73974
[Patent Document 5]
JP-A-5-223325
[0007]
[Problems to be solved by the invention]
However, the air conditioner disclosed in Japanese Patent Application Laid-Open No. 5-223325, etc. has an effect of suppressing the growth of mold or bacteria, but has not yet been killed effectively, and can exhibit a sufficient effect. It wasn't. In addition, the air conditioner disclosed in Japanese Patent Publication No. 5-73974 has a problem that ozone odor is generated because ozone is used, and the human body may be adversely affected depending on the concentration of ozone.
[0008]
In addition, an air conditioner that installs an ion generator near the blower inside the air conditioner and diffuses positive ions and negative ions in the room can remove mold and bacteria in the room, but mold and bacteria inside the air conditioner Has not been fully sterilized.
[0009]
This invention is made | formed in view of such a situation, The place made into the objective performs the operation | movement for the disinfection inside an air conditioner within the fixed time after completion | finish of operation | movement, such as air_conditioning | cooling, heating, and dehumidification. Accordingly, an object of the present invention is to provide an air conditioner capable of effectively sterilizing not only indoors but also mold and bacteria inside the air conditioner.
[0010]
Another object of the present invention is that mold and bacteria are easily killed in a dry state. Therefore, by appropriately operating the heating together with the operation of the ion generator, the mold and bacteria inside the air conditioner can be effectively removed. It is providing the air conditioner which can be sterilized.
[0011]
Another object of the present invention is to provide an air conditioner capable of sterilizing mold and bacteria inside the air conditioner in a shorter time by controlling the angle of the louver and shortening the exhaust and intake cycles. Is to provide.
[0012]
Another object of the present invention is to execute the sterilization operation of mold and bacteria inside the air conditioner without the user being particularly conscious by setting the setting of the sterilization operation inside the air conditioner as a default. The object is to provide a possible air conditioner.
[0013]
Another object of the present invention is to display information on the remaining time, elapsed time, etc. on the air conditioner main body or the controller when the sterilization operation inside the air conditioner is being executed, thereby making it easy for the user. Furthermore, it is providing the air conditioner and air conditioning system which can grasp | ascertain the time when a driving | operation complete | finishes.
[0014]
[Means for Solving the Problems]
  An air conditioner according to the present invention is an air conditioner provided with a heat exchanger that heats or cools air, a blower that draws air into the machine through an inlet and discharges the heat exchanged through the heat exchanger, An ion generating device that generates ions for sterilizing bacteria in the vicinity of (in the vicinity of) the outlet of the air path for discharging the heat-exchanged air to the outside of the apparatus, and during operation for heating or cooling the air conditioner, The ions generated by the ion generating means are discharged outside the apparatus, the discharged ions are sucked into the apparatus again, and the heat exchange unit is stopped by an instruction to stop the operation of the air conditioner. A control unit that operates the ion generator for a predetermined time; and a louver that is positioned at the discharge port and changes the direction of the discharged air. The louver is controlled to a direction that can reduce the inhalation cycle of the generated ions ejected, a display unit for displaying the state of operation, operation stop command of the air conditionerWhen a signal is receivedAnd determining whether a predetermined time has elapsed after operating the blower and the ion generator while stopping the heat exchange unit,Receiving an operation stop instruction signal of the air conditioner; andWhen it is determined that the predetermined time has not elapsed, the remaining time of operation of the blower and the ion generator and information indicating that the operation setting by the blower and the ion generator after the operation stop is made to the display unit And a means for outputting.
[0018]
  The air conditioner according to the present invention is characterized in that a filter is disposed between an air inlet of the air conditioner and the heat exchange unit. The air conditioner according to the present invention discharges heat-exchanged air from the discharge port through the air path.PassingIt is characterized by including a path and a path passing through the ion generating means. Moreover, the air conditioner according to the present invention is characterized in that the ion generator is disposed in the vicinity of the discharge port.
[0020]
  An air conditioning system according to the present invention includes a heat exchanging unit that heats or cools air, a blower that draws air into the apparatus from an inlet and discharges the heat exchanged through the heat exchanging unit, and air that has undergone heat exchange An ion generating device for generating ions for sterilizing bacteria in the vicinity (near) of the discharge port of the air path for discharging the air to the outside of the apparatus, and during the operation for heating or cooling the air conditioner, the ion generating means In addition to discharging the ions generated in step 1 to the outside of the apparatus, the discharged ions are sucked into the apparatus again, and the heat exchange unit is stopped by the operation stop instruction of the air conditioner, and the blower and the ion generator are A control unit that operates for a predetermined time; and a louver that is positioned at the discharge port and that changes the direction of the discharged air. The control unit generates and discharges the ion generation device according to an operation stop instruction. An air conditioner that controls the louver in a direction that can shorten the ion suction cycle, and an operation device that outputs a control signal to the air conditioner. A display unit for indicating a state, and an instruction to stop the operation of the air conditionerWhen a signal is receivedAnd determining whether a predetermined time has elapsed after operating the blower and the ion generator while stopping the heat exchange unit,Receiving an operation stop instruction signal of the air conditioner; andWhen it is determined that the predetermined time has not elapsed, the remaining time of operation of the blower and the ion generator and information indicating that the operation setting by the blower and the ion generator after the operation stop is made to the display unit And means for outputting.
[0021]
  In the present invention,IGenerated from the on generatorTaOn is exhausted to the outside by the blower, sterilizing mold and bacteria floating in the air, while being exhausted to the outsideTaSince ON is sucked by the blower again, mold and bacteria around each part are sterilized, so that generation of mold and bacteria can be effectively prevented.
[0022]
  In the present invention,According to the operation stop instruction, the blower and the ion generator are operated for a predetermined time (for example, 3 minutes after the stop) for a predetermined time. Thereby, the ions generated from the ion generator are discharged to the outside by the blower, and again sucked by the blower.Effectively, it becomes possible to effectively sterilize mold, bacteria, and the like inside the air conditioner.
[0024]
  In the present invention, the loopBaBecause we controlled,IThe exhaust and intake cycle of air including ON can be shortened, and mold and bacteria in the air conditioner can be sterilized in a shorter time.
[0026]
Furthermore, in the present invention, when the ion generator and the blower are operated for a predetermined time, information such as the remaining time is output to the display unit of the air conditioner or the operation unit, so that the user It is possible to easily grasp how long these operations will be completed.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail with reference to the drawings illustrating embodiments.
Embodiment 1
FIG. 1 is a schematic cross-sectional view showing a cross section of an air conditioner, and FIG. 2 is a block diagram showing a configuration of a control unit inside the air conditioner. In FIG. 1, a filter 33 provided at the front portion of the air conditioner 30 removes dust, fine particles, and the like contained in the air sucked into the air conditioner 30 through the suction port 34. The room air is sucked into the air conditioner 30 through the suction port 34 and the filter 33 by the rotation operation of the blower 32 disposed in the longitudinal direction at a substantially central portion of the air conditioner 30.
[0028]
The sucked air is heated or cooled by the heat exchanger 31, and the heated or cooled air is again discharged into the room via the discharge port 35 by the rotation operation of the blower 32. In the present embodiment, the case where the air conditioner 30 uses a refrigeration cycle will be described. However, the present invention is not limited to this, and the air conditioner 30 may be applied to electric heating, hot water heating, or cooling / heating using a Beltier element. Here, in the case of the refrigeration cycle in the present embodiment, the heat exchange unit that heats or cools the air includes the heat exchanger 31 described above, the compressor 310 of the outdoor unit shown in FIG. In the case of electric heating, the heat exchanging part is a ceramic heater or the like to which a voltage is applied, and in the case of hot water heating, the heat exchanging part is a pipe or the like in which hot water is enclosed, and a heat sink joined to the Beltier element In the case of the air conditioning used, a heat exchange part becomes a Beltier element.
Water generated by cooling the air is accumulated in a drain pan 31 a provided at the lower part of the heat exchanger 31. Further, the discharged air is discharged in an appropriate direction by a rectangular louver 33b installed over the longitudinal direction of the air conditioner 30. A rotation shaft 33a is rotatably provided at a substantially central portion of each louver 33b, and rotates following the rotation operation of the louver drive motor 33M shown in FIG. It is comprised so that it may incline to. The blower 32 sucks and discharges indoor air. However, the indoor air may be sucked by another blower (not shown), and the sucked indoor air may be sent out toward the heat exchanger 31. Further, in addition to the blower 32 in the present embodiment, another blower (not shown) is provided, or a special wind direction plate (not shown) is separately provided so that the air blown from the blower 32 is easily circulated inside the air conditioner 30. Air passing through the generator 20 and containing positive ions and negative ions may diffuse into the air conditioner 30.
[0029]
Furthermore, an ion generator 20 that generates positive ions and negative ions is provided in the vicinity of the blower 32 and the discharge port 35. Positive ions and negative ions generated by the ion generator 20 are diffused into the room by the blowing function of the blower 32. In the present embodiment, the ion generator 20 is provided in the vicinity of the discharge port 35. However, as long as positive ions and negative ions are efficiently diffused by the air blowing function of the blower 32, the present invention is not limited to this location. You may install in the place of. The ion generation principle of the ion generator will be described in detail later.
[0030]
Then, the content of the control part 50 which controls operation | movement of the air conditioner 30 concerning this invention is demonstrated using FIG. A CPU (Central Processing Unit) 51 in the control unit 50 is connected via a bus 57 to a clock unit 58 that outputs time information, a RAM (Random Access Memory) 52 that temporarily stores information to be processed, and the present invention. It is connected to a ROM (Read Only Memory) 55 or the like in which a control program for performing such control processing is stored. Further, the control unit 50 includes an input unit 53 that receives an operation or stop instruction for the air conditioner 30. The input unit 53 includes, for example, a plurality of push buttons, and an input signal is output to the control unit 50. In addition, information indicating the driving situation is output to a display unit 54 including a liquid crystal or an LED (Light Emitting Diode) that emits a plurality of colors, and predetermined information is displayed.
[0031]
In addition, the control unit 50 is provided indoors or outdoors according to the control program in the ROM 55, and based on the output of the temperature sensor 50T that outputs the detected indoor temperature or outdoor temperature, the heat exchanger 31, the compressor 310, and the louver drive The motor 33M, the blower drive motor 32M, and the ion generator 20 are controlled.
[0032]
Further, the air conditioner 30 includes an operating device 40 that transmits various control signals such as start / stop of operation, setting of an operation mode, and temperature setting to the air conditioner 30. The transmission of information from the operation device 40 is performed, for example, between the communication unit 56 on the air conditioner 30 side including an infrared receiving unit (not shown) and the communication unit 46 on the operation device 40 side. In the present embodiment, the case where the controller 40 transmits information wirelessly will be described. However, the information may be transmitted / received by wire or wirelessly. The operation device 40 has the same configuration as a known operation device. The CPU 41 is connected to a CPU 41 via a bus 47, a RAM 42, an input unit 43 including a plurality of push buttons, a display unit 44 such as a liquid crystal, the communication unit 46 described above, and the like. The clock unit 48 outputs time information.
[0033]
Next, details of the ion generator 20 will be described below. 3 is a schematic perspective view showing the configuration of the ion generating element according to the present invention, FIG. 4 is a plan view of the ion generating element, FIG. 5 is a sectional view taken along line VV of FIG. 3, and FIG. It is sectional drawing by a -VI line.
[0034]
The ion generating element 1 constituting the ion generating apparatus 20 includes a surface electrode 5 formed in a lattice shape on the surface of a flat dielectric 4 and a lower surface of the dielectric 4 for supplying power to the surface electrode 5. Provided on the lower surface of the dielectric electrode 4 for supplying power to the internal electrode 6, the surface electrode contact 8 provided, the strip-shaped internal electrode 6 embedded in the dielectric 4 and provided substantially parallel to the surface electrode 5 The internal electrode contact 7 is provided. The dielectric 4 is composed of an upper dielectric 2 and a lower dielectric 3.
[0035]
The following is a detailed description of each configuration. As the material of the dielectric 4, a material excellent in oxidation resistance is suitable as the organic substance, and for example, a resin such as polyimide or glass epoxy is used. In the case of inorganic materials, ceramics such as high-purity alumina, crystallized glass, forsterite, and steatite can be used, but in view of corrosion resistance, inorganic materials are preferred, and moldability, In view of the ease of the configuration of the electrode described later, it is preferable to mold using ceramic.
[0036]
The shape of the dielectric 4 may be a circle, an ellipse, or other shapes including a polygon, and may be a cylindrical shape. It is preferable to do this. The surface electrode 5 can be used without particular limitation as long as it has conductivity. However, the condition is that the surface electrode 5 does not cause deformation such as melting by discharge. In the present embodiment, the surface electrode 5 is made of tungsten on the surface of the dielectric 4 by screen printing.
[0037]
The internal electrode 6 may be any conductive material such as tungsten, and is formed in a band shape on the surface of the upper dielectric 2 or the lower dielectric 3. The surface electrode contact 8 shown in FIG. 5 is a contact that is electrically connected to the surface electrode 5, and is connected to the contact by, for example, contacting one end of a lead wire made of copper or aluminum, and the other end of the other configuration. It connects with a contact and makes another structure and the surface electrode 5 conduct | electrically_connect.
[0038]
The internal electrode contact 7 is a contact that is electrically connected to the internal electrode 6, and one end of a lead wire made of copper or aluminum is connected to this contact, and the other end of the lead wire is connected to a contact of another configuration. The other structure is electrically connected to the internal electrode 6.
[0039]
Next, a method for manufacturing the ion generating element 1 will be described. First, a high-purity alumina sheet having a thickness of 0.45 nm is cut into a predetermined size (width 15 mm × length 37 mm) to form two alumina substrates having substantially the same size. The purity of alumina may be 90% or more, but here 92% purity alumina is used.
[0040]
Then, tungsten is screen-printed on one upper surface of the two alumina base materials, and the surface electrode 5 and the upper surface conductive portion 10 are integrally formed on the surface of the alumina base material to form the upper dielectric 2. create. Then, tungsten is screen-printed on the upper surface of another alumina substrate to form the internal electrode 6 integrally on the surface of the alumina substrate, and the surface electrode contact 8 and the internal electrode contact 7 are formed on the lower surface of the alumina substrate. Is formed by screen printing to form the lower dielectric 3.
[0041]
Further, an alumina coating layer 9 (shown only in FIG. 5) is formed on the surface of the upper dielectric 2 to insulate the surface electrode 5. Then, after the lower surface of the upper dielectric 2 and the upper surface of the lower dielectric 3 are superposed, pressure bonding and evacuation are performed, and these are placed in a furnace and fired in a non-oxidizing atmosphere at 1400 ° C. to 1600 ° C. . By manufacturing in this way, the ion generating element 1 as shown in the present invention can be easily manufactured.
[0042]
Next, a case where a voltage is applied to the ion generating element 1 formed by the above-described method will be described. In order to apply a voltage between the surface electrode 5 and the internal electrode 6 of the ion generating element 1, the voltage application circuit V and the surface electrode 5 are connected by a lead wire, and the internal electrode contact 7 and the voltage application circuit are connected. The ion generator 20 is configured by connecting V to the lead wire. Then, by operating the voltage application circuit V and applying an alternating high voltage between the surface electrode 5 and the internal electrode 6, positive ions and negative ions are generated.
[0043]
In the above configuration, a processing procedure when operating the air conditioner 30 of the present invention will be described using a flowchart. FIG. 7 is a flowchart showing the procedure of the first operation. When each operation such as cooling, heating, dehumidification is performed (step S71), the control unit 50 inputs an operation stop instruction from the input unit 53 of the air conditioner 30 main body or the input unit 43 of the operating device 40. Then, it is determined whether or not the input signal indicating the stop instruction has been received (step S72). Here, when the stop instruction is not received (NO in step S72), the operation is continued.
[0044]
On the other hand, when the operation stop instruction is received, the refrigeration cycle to the heat exchanger 31, that is, the compressor 310 is stopped, and the blower 32 and the ion generator 20 are operated (step S73). That is, when various operations such as cooling and heating are stopped by a user stop instruction or a stop instruction set in advance by a timer, all the operations such as the heat exchanger 31 and the compressor 310 are temporarily stopped, and the blower In order to sterilize the mold and bacteria inside the air conditioner 30 by operating only 32 and the ion generator 20, internal cleaning is performed. Hereinafter, the internal cleaning process in step S73 is referred to as a first operation.
[0045]
Thereby, after completion | finish of driving | operations, such as air_conditioning | cooling, the positive ion diffused from the ion generator 20 and the negative ion are taken in in the air conditioner 30, and it becomes possible to make bacteria etc. in the air conditioner 30 effective. Become. Even during normal heating and cooling operations, negative ions and positive ions are taken into the air conditioner 30 to sterilize bacteria. However, the refrigeration cycle to the heat exchanger 31, that is, the compressor 310, etc. By stopping and operating only the blower 32 and the ion generator 20 independently for internal cleaning, the inside of the air conditioner 30 can be effectively cleaned.
[0046]
When the first operation is started, the control unit 50 operates the louver drive motor 33M to control the angle of the louver 33b (step S74). Specifically, the control is performed so that the maximum angle within the use angle range of the louver 33b is equal to or larger. For example, the use angle range of the louver 33b is about 0 degree (substantially below as shown in FIG. 1, the louver 33b adjusts the vertical angle, and the suction port (suction port 34) is at the front or upper part of the air conditioner 30. When the angle is about 85 degrees (nearly horizontal), the maximum angle is controlled to about 85 degrees to guide the air discharged from the discharge port 35 toward the suction port 34.
Note that the “usage angle range of the louver 33b” is added as a precaution. The use angle range here is an angle used in normal air conditioner operations such as cooling and heating, and does not include an angle at which the louver 33b closes the outlet (exhaust port 35) when the operation is stopped. The closing angle is further upward than horizontal, but no air is discharged.
Here, the control unit 50 receives time information output from the clock unit 58 (step S75), and determines whether or not a first predetermined time (for example, 3 minutes) stored in advance in the ROM 55 has elapsed (step S76). ). If the first predetermined time has not elapsed (NO in step S76), the CPU 51 determines the remaining time until the first operation ends based on the time information output from the clock unit 53 and the first predetermined time. Time information is calculated, and the time information related to the first predetermined time is output to the display unit 44 of the operation unit 40 in the case of the display unit 54 or the operation unit connected by wire (step S78). Even in the case of wireless operation, it can be transmitted from the communication unit 56 on the air conditioner 30 side to the communication unit 46 of the operating device 40 and displayed on the display unit 44, but the communication unit 56 has a transmission function and the communication unit 46 receives it. Requires functionality. Therefore, on the operation device 40 side, when the first operation start is instructed to be transmitted to the communication unit 56, the clock unit 48 measures the time, the CPU 41 calculates the remaining time, and the display unit 44 displays the remaining time. The transmission function of the communication unit 56 and the reception function of the communication unit 46 are unnecessary and inexpensive.
[0047]
FIG. 8 is an explanatory diagram illustrating a display form of the display unit 44 of the operation device 40. In FIG. 8, the remaining time information until the first operation is completed is displayed on the display unit 44. This time information may indicate the elapsed time in addition to the remaining time. The remaining time information is obtained by causing the CPU 41 of the operating device 40 to calculate the remaining time and displaying the remaining time on the display unit 44 based on an output from the clock unit 48 provided in the operating device 40. Of course, you may make it output sequentially from the communication part 56 of the air conditioner 30 to the operation device 40. FIG.
[0048]
On the other hand, if the first predetermined time has elapsed (YES in step S76), all operations are terminated (step S77). Specifically, the refrigeration cycle to the heat exchanger 31, that is, the operation of the blower 32 and the ion generator 20, including the compressor 310, is terminated.
[0049]
FIG. 9 is a flowchart showing the procedure of the setting process for the first operation or non-operation. The user can set whether or not to perform the first operation after the operation is stopped. In this case, the user sets the operation by the first operation or the non-operation from the input unit 43 of the operation device 40. When such setting information is input, the control unit 50 accepts the setting of operation or non-operation by the first operation via the communication unit 56 (step S91), and sets the operation or non-operation flag in the RAM 52. Further, when a flag indicating the operation setting is set in the RAM 52, the information is output to the display unit 54. In that case, as shown in FIG. 8, a display of “internal clean” indicating that the operation setting by the first operation is made may be output.
[0050]
After the operation such as cooling or heating ends, the CPU 51 determines whether or not the operation setting by the first operation is made (step S92). Specifically, it is determined whether or not the flag indicating the operation by the first operation is set in the RAM 52. When the operation setting by the first operation is made (YES in step S92), the first operation is performed as described above (step S93). That is, the heat exchanger 31, the compressor 310, and the like are stopped to stop operations such as cooling and heating, and only the blower 32 and the ion generator 20 are operated. If the operation setting by the first operation is not made (NO in step S92), the process proceeds without skipping the process of step S93 and executing the operation process by the first operation.
[0051]
In this case, the refrigeration cycle to the heat exchanger 31, that is, all the operations of the compressor 310, the blower 32, and the ion generator 20 are stopped. In this way, by enabling the setting of the operation or the non-operation by the first operation, the user does not bother to operate the operation unit 40 with an instruction to sterilize the inside of the air conditioner 30 after stopping the operation such as cooling. Since the internal sterilization process by the first operation is performed after the stop, it is convenient for the user, and since the internal sterilization is performed every time after the operation is stopped, the inside of the air conditioner 30 can be extremely clean. it can.
[0052]
Embodiment 2
In the second embodiment, the process of operating the ion generator 20 and the blower 32 is performed within a predetermined time after the operation is stopped, such as cooling, in the first operation. In the meantime, the generator 20 and the blower 32 are operated, and the refrigeration cycle to the heat exchanger 31, that is, the compressor 310 is operated in consideration of the temperature condition, and the sterilizing effect is enhanced by drying the air. 2 related to driving.
[0053]
FIG. 10 is a flowchart showing a procedure of processing in the second operation. First, when the user desires sterilization processing inside the air conditioner 30, an instruction signal for starting the second operation processing is input from the input unit 43 of the operation device 40. When this instruction signal is input, the control unit 50 receives the instruction signal (step S101), and the temperature output from the temperature sensor 50T that measures the outdoor outdoor temperature is a threshold value (for example, 24) stored in advance in the ROM 55. It is determined whether the temperature is equal to or higher than (° C.) (step S102). The temperature sensor 50T may be a sensor that detects an indoor temperature in addition to a sensor that detects an outdoor outdoor temperature. Hereinafter, the temperature sensor 50T will be described as a sensor that detects the outside air temperature. When the outside air temperature is not equal to or higher than the threshold value (NO in step S102), the control unit 50 operates the refrigeration cycle to the heat exchanger 31, that is, the compressor 310 to heat the air (step S103). This heating (heating operation) is performed with the room temperature set to 27 ° C. Furthermore, the blower 32 and the ion generator 20 are operated (step S104). By the way, it is known that the mold and bacteria in a dry state can suppress the generation and can be easily killed. Therefore, in the present invention, bacteria and the like are sterilized by diffusing positive ions and negative ions by the blower 32 in a state where the air is heated and dried by the heat exchange unit such as the heat exchanger 31 and the compressor 310. To do.
[0054]
On the other hand, when the temperature output from the temperature sensor 50T is equal to or higher than the threshold value stored in advance in the ROM 55 (YES in step S102), the process of step S103 is skipped and only the blower 32 and the ion generator 20 are operated ( Step S104). Thus, the user does not feel uncomfortable due to an increase in the room temperature due to the heating of air.
[0055]
When the second operation described above is started, the control unit 50 operates the louver drive motor 33M to control the louver angle (step S105). Here, the control unit 50 receives time information output from the clock unit 58 (step S106), and determines whether or not a second predetermined time (for example, 40 minutes) stored in advance in the ROM 55 has elapsed (step S107). ). If the second predetermined time has not elapsed (NO in step S107), the CPU 51 determines the remaining time until the second operation ends based on the time information output from the clock unit 58 and the second predetermined time. Time information is calculated, and time information related to the second predetermined time is output to the display unit 54 (step S109). Alternatively, as described above, the time information may be calculated by the CPU 41 of the controller 40 based on the output from the clock unit 48 provided in the controller 40 and output to the display unit 44.
[0056]
As described in the first embodiment, the remaining time information until the second operation ends is displayed on the display unit 44 (see FIG. 8). This time information may indicate the elapsed time in addition to the remaining time. The remaining time information is obtained by causing the CPU 41 of the operating device 40 to calculate the remaining time and displaying the remaining time on the display unit 44 based on an output from the clock unit 48 provided in the operating device 40. Of course, you may make it output sequentially from the communication part 56 of the air conditioner 30 to the operation device 40. FIG.
[0057]
On the other hand, when the second predetermined time has elapsed (YES in step S107), the second operation is terminated (step S108). Specifically, the refrigeration cycle to the heat exchanger 31, that is, the operation of the blower 32 and the ion generator 20, including the compressor 310, is terminated.
When the second operation described above is completed, the blower 32 and the ion generator 20 may be further operated for a predetermined time. Specifically, after step S108, the process proceeds to step S73 to execute the first operation. In other words, in addition to the second operation with the heating operation, the first operation without the heating operation is further performed, so that it is possible to achieve energy saving accompanying the reduction in the heating operation time.
[0058]
The second embodiment is configured as described above, and the other configurations and operations are the same as those of the first embodiment. Therefore, corresponding parts are denoted by the same reference numerals, and detailed description thereof is omitted.
[0059]
【The invention's effect】
  As detailed above, in the present invention,,IGenerated from the on generatorTaOn is discharged to the outside by the blower, while it is discharged to the outsideTaSince ON is sucked by the blower again, mold and bacteria around each part are sterilized, so that generation of mold and bacteria can be effectively prevented.
[0060]
  In the present invention,Predetermined time by stop instruction,The blower and the ion generator are operated.Thereby, the ions generated from the ion generator are discharged to the outside by the blower and are again sucked by the blower.Effectively, it becomes possible to effectively sterilize mold, bacteria, and the like inside the air conditioner.
[0062]
In the present invention, since the louver is controlled so that the maximum angle within the use angle range of the louver or more is exceeded, the exhaust and intake cycle of air containing negative ions and positive ions can be shortened and shortened. It becomes possible to sterilize mold and bacteria in the air conditioner over time.
[0063]
Further, in the present invention, after the operation is stopped, the setting of whether or not to execute the first operation for operating the ion generator and the blower to sterilize mold, bacteria, and the like in the air conditioner is accepted. When such a setting is accepted, the first operation is performed without any particular awareness or operation by the user, so that the internal sterilization is performed each time the air conditioner is used, and the inside of the air conditioner is always clean. It becomes possible to keep it. Further, if the first operation is not set by setting, the first operation is not started, so that it is possible to meet a request from a user who does not want to use such a function.
[0064]
Furthermore, in the present invention, when the ion generator and the blower are operated for a predetermined time, information such as the remaining time is output to the display unit of the air conditioner or the operating device. The user can easily grasp how long the operation will be completed, and the present invention can provide excellent effects.
[Brief description of the drawings]
FIG. 1 is a schematic cross-sectional view showing a cross section of an air conditioner.
FIG. 2 is a block diagram showing a configuration of a control unit inside the air conditioner.
FIG. 3 is a schematic perspective view showing a configuration of an ion generating element according to the present invention.
FIG. 4 is a plan view of an ion generating element.
5 is a cross-sectional view taken along line VV in FIG.
6 is a cross-sectional view taken along line VI-VI in FIG.
FIG. 7 is a flowchart showing a processing procedure of a first operation.
FIG. 8 is an explanatory diagram showing a display form of a display unit of the operation device.
FIG. 9 is a flowchart illustrating a procedure of setting processing for operation or non-operation of the first operation.
FIG. 10 is a flowchart showing a processing procedure in a second operation.
[Explanation of symbols]
1 Ion generator
2 Upper derivative
3 Lower derivatives
4 Dielectric
5 Surface electrode
6 Internal electrodes
7 Internal electrode contacts
8 Surface electrode contacts
9 Coating layer
10 Upper surface conduction part
11 Conductive part for surface electrode
12 Internal electrode conduction part
V voltage application circuit
30 Air conditioner
31 Heat exchanger (Heat exchange part)
310 Compressor (Heat Exchanger)
32 Blower
33 Filter
34 Suction port
35 outlet
33a Rotating shaft
33b louver
50 Control unit
58 Clock part
53 Input section
54 Display
33M louver drive motor
56 Communication Department
32M blower drive motor
20 Ion generator
50T temperature sensor
40 Controller
48 Clock part
46 Communication Department
44 Display
43 Input section

Claims (4)

In an air conditioner equipped with a heat exchanger that heats or cools air, a blower that sucks air into the machine through an inlet and discharges the heat exchanged through the heat exchanger,
It is equipped with an ion generator that generates ions that disinfect bacteria near the vicinity of the outlet of the air path that discharges the heat-exchanged air outside the machine,
During operation for heating or cooling the air conditioner, the ions generated by the ion generating means are discharged out of the apparatus, and the discharged ions are again sucked into the apparatus,
In accordance with the operation stop instruction of the air conditioner, the heat exchanging unit is stopped, and a control unit for operating the blower and the ion generator for a predetermined time;
A louver positioned at the outlet and changing the direction of the discharged air;
The control unit controls the louver in a direction capable of shortening a suction cycle of ions generated and discharged by the ion generator according to an operation stop instruction.
A display for displaying the operation status;
When the operation stop instruction signal of the air conditioner is received , the heat exchange unit is stopped, and it is determined whether or not a predetermined time has elapsed after operating the blower and the ion generator, and the air When the operation stop instruction signal of the harmonic machine is received and it is determined that the predetermined time has not elapsed, the remaining time of the operation of the blower and the ion generator and the operation setting by the blower and the ion generator after the operation stop The air conditioner further comprising: means for outputting information indicating that the information has been made to the display unit.   The air conditioner according to claim 1, wherein a filter is disposed between the air inlet of the air conditioner and the heat exchange unit. The air path is a path for discharging heat-exchanged air from an outlet,
The air conditioner according to claim 1 or 2, further comprising a path that passes through the ion generation means. A heat exchanging unit that heats or cools the air, and a blower that sucks air from the suction port into the apparatus and discharges the heat exchanged through the heat exchanging part,
An ion generator that generates ions for sterilizing bacteria near the discharge port of the air path for discharging the heat-exchanged air outside the machine,
During operation for heating or cooling the air conditioner, the ions generated by the ion generating means are discharged out of the apparatus, and the discharged ions are again sucked into the apparatus,
In accordance with the operation stop instruction of the air conditioner, the heat exchanging unit is stopped, and a control unit for operating the blower and the ion generator for a predetermined time;
A louver positioned at the outlet and changing the direction of the discharged air;
In response to an operation stop instruction, the control unit controls the louver in a direction that can shorten the suction cycle of ions generated and discharged by the ion generator, and outputs a control signal to the air conditioner. Equipped with an operating device,
The operating device includes a display unit that indicates a state of an operation instruction of the air conditioner;
When the operation stop instruction signal of the air conditioner is received , the heat exchange unit is stopped, and it is determined whether or not a predetermined time has elapsed after operating the blower and the ion generator, and the air When the operation stop instruction signal of the harmonic machine is received and it is determined that the predetermined time has not elapsed, the remaining time of the operation of the blower and the ion generator and the operation setting by the blower and the ion generator after the operation stop An air conditioning system comprising: means for outputting information indicating that the information has been made to the display unit.

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