JP2017018381A - Cleaning system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To further effectively clean an indoor space by effectively coordinating an air cleaner and a vacuum cleaner, while minimizing wasteful power consumption.SOLUTION: A cleaning system 1 includes an air cleaner (10-1) and a vacuum cleaner (10-2). A vacuum-cleaner operation state detection part detects an operation state of the vacuum cleaner (10-2), and a dust sensor detects an amount of floating particles included in the air. The air cleaner (10-1) determines whether a room in which the vacuum cleaner (10-2) is operated and a room in which the air cleaner (10-1) is disposed are a same room or not on the basis of the operation state of the vacuum cleaner (10-2) detected by the vacuum-cleaner operation state detection part and the amount of the floating particles detected by the dust sensor (15), and when determining that both are same, enhances an air cleaning performance.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a cleaning system in which an air cleaner and a vacuum cleaner cooperate to clean an indoor space.

  In recent years, air cleaners that purify airborne particles such as dust, viruses, and cigarette smoke contained in the air, and self-propelled cleaners that automatically run and clean the floor surface are becoming widespread.

  For example, Patent Literature 1 includes an air purifying unit that automatically cleans indoor air and a floor surface cleaning unit that automatically cleans the indoor floor surface, and operates in cooperation with each other. A dust collector is disclosed. When it is determined that the floor surface cleaning unit is cleaning, the indoor dust collector operates the air cleaning unit.

  The indoor dust collector is configured such that the floor cleaning unit is based on the connection state between the power transmission unit of the air cleaning unit and the power reception unit of the floor cleaning unit, or based on the operation state notified from the floor cleaning unit. Determine if you are cleaning.

JP 2013-13538 A (published January 24, 2013)

  However, in the technique of Patent Document 1, it is not confirmed whether the room where the air cleaning unit is installed and the room where the floor cleaning unit is cleaning, and the floor cleaning unit operates. The air purifier is operated simply by determining that it is working. Therefore, for example, even when the floor surface cleaning unit is cleaning a room different from the room where the air cleaning unit is installed, the air cleaning unit may operate, which is an effective cooperative operation. Absent.

  Unlike the air purifier (air purifier) that is installed and used in a room, the floor surface cleaner (vacuum cleaner) is used by the user by transporting it to another room or sharing it in each room. It is possible that the floor cleaning unit operates in a room different from the air cleaning unit.

  The present invention has been made in view of such a problem, and its purpose is to effectively link an air cleaner and a vacuum cleaner while minimizing wasteful power consumption as much as possible. It is providing the cleaning system which can aim at cleaning.

  In order to solve the above-mentioned problem, a cleaning system according to an aspect of the present invention is included in an air cleaner, a cleaner, a cleaner operating state detector that detects an operating state of the cleaner, and the air. Based on the dust sensor for detecting the amount of suspended particles, the operating state of the cleaner detected by the cleaner operating state detector and the amount of the suspended particles detected by the dust sensor. Control that determines whether the room in which the air cleaner is operating and the room in which the air purifier is installed are the same, and controls the air purifier so that the air purifying capacity is increased if it is determined that they are the same And a device.

  According to the cleaning system according to one aspect of the present invention, the air cleaner and the vacuum cleaner can be effectively linked while suppressing wasteful power consumption as much as possible, thereby more effectively cleaning the indoor space. There is an effect.

It is a figure which shows schematic structure of the remote control system containing the cleaning system concerning one Embodiment. It is a block diagram which shows schematic structure of the air cleaner which comprises the said cleaning system. It is a block diagram which shows schematic structure of the cleaner which comprises the said cleaning system. It is a block diagram which shows schematic structure of the server contained in the said remote control system. It is a flowchart which shows the process in the said air cleaner. It is a flowchart which shows the process in the said cleaner. It is a flowchart which shows the process in the said server. It is a block diagram which shows schematic structure of the cleaner in the cleaning system of other embodiment. It is a block diagram which shows schematic structure of the air cleaner in the cleaning system of said other embodiment. It is a flowchart which shows the process in the said air cleaner. It is a block diagram which shows schematic structure of the air cleaner in the cleaning system of other embodiment.

[Embodiment 1]
Hereinafter, it will be as follows if one Embodiment of this invention is described based on FIGS. In addition, in this Embodiment, the structure which the air cleaner and vacuum cleaner which comprise a cleaning system perform via the server contained in a remote control system is illustrated.

(Configuration of remote operation system 100)
FIG. 1 is a diagram showing a schematic configuration of a remote operation system 100 including a cleaning system 1 according to the present embodiment. As shown in FIG. 1, in the remote operation system 100, a home appliance 10 (10-1 to 10-4), a server 40, and a communication terminal device 30 (30-1 to 30-3) installed in a user home 70. Are connected via the communication network 60. FIG. 1 shows a portion related to one user home 70 in the remote operation system 100.

  The home appliance 10 is a network home appliance having a wireless communication function for connecting to the communication network 60 and communicating with the server 40. The wireless communication function may be incorporated in the home appliance 10 main body, or may be provided in a communication adapter externally attached to the home appliance 10 main body. The home appliance 10 receives a remote operation from the associated communication terminal device 30 via the server 40.

  An account for enabling communication with the server 40 and the like is attached to the home appliance 10, and basically the same account is attached to the home appliance 10 in the same user home 70. Further, information on the installation location in the user's home 70 (for example, a living room, a kitchen, an entrance, a child's room, a bedroom, etc.) is attached to the home appliance 10 as necessary.

  In the example of FIG. 1, as the home appliance 10, an air cleaner 10-1, a self-propelled cleaner 10-2, an air conditioner 10-3, and a refrigerator 10-4 are illustrated. Although details will be described later, among these home appliances 10, the air purifier 10-1 and the vacuum cleaner 10-2 having information on the same installation location cooperate to purify the indoor space (cleaning system 1).

  The server 40 associates the communication terminal device 30 that enables remote operation with the home appliance 10, and registers and manages the combination. By registering the combination in the server 40, the home terminal 10 can be remotely operated by the communication terminal device 30. The server 40 grasps the operating state (operation start, operation end, operation mode, etc.) of the home appliance 10 by communicating with the home appliance 10 mutually.

  In addition, the server 40 also acquires information on an installation location attached to the home appliance 10 when communicating with the home appliance 10. When the server 40 acquires information on the installation location of the home appliance 10, the home appliances 10 having the same account can share information on the installation location of each other via the server 40.

  The communication terminal device 30 is a smartphone or a tablet terminal in which an application for remote operation is downloaded.

  The user home 70 is provided with a wireless local area network (LAN) that forms part of the communication network 60. The wireless LAN relay station 50 is connected to a communication network 60 including the Internet. The relay station 50 is a communication device such as a WiFi (registered trademark) router or a WiFi (registered trademark) access point. In the present embodiment, a configuration including the Internet is exemplified as the communication network 60, but a telephone line network, a mobile communication network, a CATV (CAble TeleVision) communication network, a satellite communication network, or the like can also be used.

  The server 40 and the home appliance 10 can communicate with each other via the communication network 60 and the wireless LAN relay station 50. In addition, the server 40 and the communication terminal device 30 can communicate with each other via the communication network 60. The communication terminal device 30 and the Internet in the communication network 60 are connected using 3G (3rd Generation), LTE (Long Term Evolution), a home or public WiFi (registered trademark) access point, and the like.

(Configuration of air cleaner 10-1)
FIG. 2 is a block diagram illustrating a schematic configuration of the air purifier 10-1. As shown in FIG. 2, the air cleaner 10-1 includes a clean control unit 11, a clean storage unit 12, a clean communication unit 13, an air clean unit 14, and a dust sensor 15. The cleaning control unit 11 includes an operation control unit 16, a cleaner operating state detection unit 17, and a room determination unit (control device) 18.

  The clean control unit 11 is composed of, for example, a computer device including an arithmetic processing unit such as a CPU (Central Processing Unit) or a dedicated processor, and controls the operation of each unit of the air purifier 10-1.

  The clean memory | storage part 12 memorize | stores the various information used with the air cleaner 10-1. The clean storage unit 12 also stores account information used for connection with the server 40, installation location information, and the like. Since the air cleaner 10-1 is normally installed and used in a room, information such as “living room” and “bedroom” is set as information on the installation location. The clean storage unit 12 also stores data and information that the operation control unit 16 operates the air cleaning unit 14 and the room determination unit 18 uses for room determination based on the detection result of the dust sensor 15. ing.

  The clean communication unit 13 performs mutual communication with the server 40 via the wireless LAN relay station 50 and the communication network 60 under the control of the clean control unit 11.

  The dust sensor 15 detects the amount of suspended particles contained in the air. The dust sensor 15 is generally of a type in which the sensor output value increases or decreases one-dimensionally according to the amount of suspended particles. Airborne particles include tick feces and carcasses, pollen, dust, tobacco smoke, and viruses. In the present embodiment, the dust sensor 15 sets the dust level to “0: non-detection”, “1: low”, “2: medium”, and “3: high” based on the detection result of the amount of suspended particles. The structure judged in a step is illustrated.

  Under the control of the cleaning control unit 11, the air cleaning unit 14 rotates the fan to suck in air and cleans the air. The cleaning control unit 11 includes various types such as a type that captures suspended particles in the air by passing the sucked air through a filter, and a type that discharges ions or the like that can render the suspended particles harmless or suppress harmfulness, etc. Available types.

  In the present embodiment, a configuration in which the air cleaning unit 14 performs a switching operation between a strong operation having a large air cleaning effect and a weak operation having a small cleaning effect is illustrated. In addition, the structure which has a middle driving | operation between a strong driving | operation and a weak driving | running | working may be sufficient, or the structure etc. which switch the air cleaning part 14 on and off may be sufficient.

  The cleaner operating state detector 17 detects the operating state of the cleaner 10-2 associated with the air cleaner 10-1. The cleaner 10-2 associated with the air cleaner 10-1 is a cleaner having the same account as the air cleaner 10-1, and is installed in the same user house 70, and A vacuum cleaner with the same installation location information. That is, even if it has the same account as the air cleaner 10-1, the information on the installation location of the air cleaner 10-1 is “living”, and the information on the installation location of the cleaner 10-2 is “living room”. "Is not included, it does not correspond to the associated vacuum cleaner.

  In this Embodiment, the cleaner operating state detection part 17 receives the information of the operation state of the associated cleaner 10-2 via the server 40, and detects an operating state. Specifically, the operation start information and the operation end information are received as the operation state information, and the operation start and the operation end are detected.

  The room determination unit 18 is the same as the room where the air cleaner 10-1 is installed in the room in which the vacuum cleaner 10-2 that the vacuum cleaner operating state detection unit 17 detects the start of operation performs cleaning. Whether or not. The room determination unit 18 has a higher dust level than the normal control before the change within the first predetermined time after the start of operation of the cleaner 10-2 is detected by the cleaner operating state detector 17. When this is detected, it is determined that the room in which the cleaner 10-2 is cleaning and the room in which the air cleaner 10-1 is installed are the same room. The first predetermined time is determined according to the time required for cleaning and is, for example, 10 minutes.

  The operation control unit 16 controls the drive of the air cleaning unit 14 to operate. The operation control unit 16 performs normal control for operating the air cleaning unit 14 based on the dust level determined by the dust sensor 15 until the cleaner operating state detection unit 17 detects the start of operation of the cleaner 10-2. Run. And if the operation start of the cleaner 10-2 is detected, normal control and cooperation control will be performed in parallel.

  In the normal control, the operation control unit 16 operates the air cleaning unit 14 based on the dust level determined by the dust sensor 15. In the present embodiment, in normal control, the air cleaning unit 14 is always operated in a weak operation, and when the dust level becomes “2: medium” or higher, the operation is switched to a strong operation, and the dust level decreases to “0: non-detection”. The structure which returns to weak driving | running is illustrated. The operation content during normal control is not limited to this.

  In the cooperative control, when the room determination unit 18 determines that the room is the same room, after the operation of the cleaner 10-2 ends (when the cleaner operation state detection unit 17 detects the operation end of the cleaner 10-2). The air purifier 14 is caused to execute a strong operation for a second predetermined time. The second predetermined time is preferably a time set according to the size of the room in which the air cleaner 10-1 is installed.

  Here, the room determination unit 18 determines whether or not the room is in the same room based on the operation start timing and the dust level of the vacuum cleaner 10-2. It is set as the structure which carries out the strong operation of the air cleaning part 14 for the 2nd predetermined time after the operation | movement completion of 10-2. In other words, based on the operation start timing of the vacuum cleaner 10-2 and the dust level, it is determined whether the amount of airborne particles in the air has increased due to the operation of the vacuum cleaner 10-2. When it can be determined that the increase is due to the operation of 10-2, the operation control unit 16 causes the air cleaning unit 14 to perform a strong operation for a second predetermined time after the operation of the cleaner 10-2 is completed.

  When the operation control unit 16 finishes the strong operation for the second predetermined time in the cooperative control, the operation control unit 16 returns the drive control of the air cleaning unit 14 from the parallel processing to the single processing of the normal control. If the room determination unit 18 does not determine that the room is the same room, when the cleaner operating state detector 17 detects the end of the operation of the cleaner 10-2, the drive control of the air cleaner 14 is performed in parallel processing. To return to normal control single processing.

(Configuration of vacuum cleaner 10-2)
FIG. 3 is a block diagram illustrating a schematic configuration of the cleaner 10-2. As shown in FIG. 3, the cleaner 10-2 includes a cleaning control unit 31, a cleaning storage unit 32, a cleaning communication unit 33, a floor surface cleaning unit 34, and a traveling mechanism unit 35. In addition, a cleaner operation state notifying unit 36 is constructed in the cleaning control unit 31.

  The cleaning control unit 31 includes, for example, a computer device that includes an arithmetic processing unit such as a CPU (Central Processing Unit) or a dedicated processor, and controls the operation of each unit of the cleaner 10-2.

  The cleaning control unit 31 stores various information used in the cleaner 10-2. The cleaning storage unit 32 also stores account information used for connection with the server 40, installation location information, and the like. Unlike the air cleaner 10-1, the vacuum cleaner is usually shared in each room, and therefore, multiple information such as “living room, bedroom, entrance,.

  The cleaning communication unit 33 performs mutual communication with the server 40 via the wireless LAN relay station 50 and the communication network 60 under the control of the cleaning control unit 31.

  Under the control of the cleaning control unit 31, the floor surface cleaning unit 34 rotates the fan and sucks dust existing on the floor surface together with air to clean the floor surface. The traveling mechanism unit 35 causes the cleaner 10-2 to self-travel.

  The cleaner operating state notifying unit 36 notifies the server 40 of the operating state of the cleaner 10-2 via the cleaning communication unit 33. Specifically, at least information on operation start and operation end is notified as the operation state.

(Configuration of server 40)
FIG. 4 is a block diagram illustrating a schematic configuration of the server 40. The server 40 is a server that manages each home appliance 10, and includes a server control unit 41, a server storage unit 42, and a server communication unit 43, as shown in FIG.

  The server control unit 41 is composed of, for example, a computer device including an arithmetic processing unit such as a CPU (Central Processing Unit) or a dedicated processor, and controls the operation of each unit of the server 40. Further, when the operation state (operation start, operation end) is notified from the cleaner 10-2, the server control unit 41 sends the notified operation information to the air cleaner 10- of the same account via the server communication unit 43. 1 to send.

  The server storage unit 42 stores various information used in the server 40. The server communication unit 43 performs mutual communication with the home appliance 10 and the communication terminal device 30 via the communication network 60 under the control of the server control unit 41.

(Processing of air cleaner 10-1)
The process in the air cleaner 10-1 is demonstrated using the flowchart of FIG. The clean control unit 11 always determines whether or not an operation start is instructed (S1). If YES is determined in S1, monitoring of the amount of suspended particles by the dust sensor 15 and operation of the air cleaning unit 14 by normal control are started (S2).

  After the start of the operation of the air cleaning unit 14, the cleaning control unit 11 determines whether or not the start of operation of the cleaner 10-2 is notified from the server 40 (S3), and whether the operation of the air cleaner 10-1 is instructed. (S4) is always determined.

If YES is determined in S <b> 3, the process proceeds to S <b> 6 to start cooperative control and proceeds in parallel with the normal control. On the other hand, if YES is determined in S4, the monitoring of the amount of suspended particles by the dust sensor 15 and the operation of the air cleaning unit 14 by the normal control are ended (S5).
In the cooperative control, the cleaning control unit 11 always determines whether the dust level has increased compared to before the shift to the cooperative control (S6), and whether the operation end of the cleaner 10-2 has been notified from the server 40 (S7). Deciding.

  If YES is determined in S6, the process proceeds to S8, and it is determined whether the dust level increase detection in S6 is within a predetermined time (for example, 10 minutes) after the start of operation of the cleaner 10-2 in S3 is notified. For example, when the dust level rises within a predetermined time of about 10 minutes after the operation of the cleaner 10-2, the room in which the cleaner 10-2 is cleaning and the air cleaner 10- It is possible to determine that the amount of suspended particles in the air has increased due to the operation of the cleaner 10-2.

  If YES is determined in S <b> 8, the process proceeds to S <b> 9, and it is always determined whether or not the operation end of the cleaner 10-2 is notified again from the server 40. If YES is determined in S6, strong operation is executed for a second predetermined time set according to the room size (S10), and then the cooperative control is terminated and the process proceeds to S4.

  Moreover, the case where it is judged as YES in S7, and the case where it is judged as NO in S8, complete | finish cooperation control without performing the strong driving | operation after the completion | finish of operation of the cleaner 10-2 in S10, and transfer to S4. .

(Processing of the vacuum cleaner 10-2)
The process in the cleaner 10-2 will be described with reference to the flowchart of FIG. The cleaning control unit 31 always determines whether or not an operation start is instructed (S21). If YES is determined in S21, the server 40 is notified of the start of its own operation (S22), and the traveling mechanism unit 35 and the floor surface cleaning unit 34 are driven to start floor surface cleaning (S23).

  After the start of cleaning, the cleaning control unit 31 always determines whether or not the end of the operation of the cleaner 10-2 has been instructed (S24). If YES is determined in S24, the driving of the floor surface cleaning unit 34 and the traveling mechanism unit 35 is stopped, the floor surface cleaning is ended (S25), and the server 40 is notified of the end of earning (S26). The operation start instruction in S21 is, for example, a case where the operation is automatically started at the registration time in addition to the start button operation by the user. In addition, the operation end instruction in S24 is, for example, when the user automatically determines to end the operation (cleaning is completed, breakdown, battery is exhausted), in addition to the stop button operation by the user.

(Processing of server 40)
Processing in the server 40 will be described with reference to the flowchart of FIG. The server control unit 41 always determines whether the operation start is notified from the cleaner 10-2 (S31). If it is judged as YES in S31, server control part 41 will notify start of operation of cleaner 10-2 to air cleaner 10-1 of the same account as cleaner 10-2 (S32). Thereafter, the server control unit 41 always determines whether or not the operation end is notified from the cleaner 10-2 (S33). If it is judged as YES in S33, server control part 41 will notify the end of operation of cleaner 10-2 to air cleaner 10-1 of the same account as cleaner 10-2 (S34). Thereafter, the process returns to S31.

  As described above, according to the configuration of the home appliance 10 according to the present embodiment, the cleaning control unit 11 of the air cleaner 10-1 is cleaned based on the operating state of the cleaner 10-2 and the dust level of the dust lance 15. It is determined whether the room in which the machine 10-2 is operating and the room in which the air purifier 10-1 is installed are the same (same room). The air purifier 10-1 (air purifier 14) is controlled.

  Thus, the room where the cleaner 10-2 is operating and the air cleaner 10-1 are installed by using not only the operating state of the cleaner 10-2 but also the dust level by the dust sensor 15. It can be determined whether the room is the same.

  Therefore, even though the vacuum cleaner 10-2 is cleaning a room different from the room where the air purifier 10-1 is installed, the air purifier 10-1 operates strongly and wastefully. It can be avoided. As a result, the air cleaner 10-1 and the vacuum cleaner 10-2 can be effectively linked while suppressing wasteful power consumption as much as possible, so that the indoor space can be more effectively cleaned.

  Moreover, in addition to the operating state of the vacuum cleaner 10-2, it is determined whether or not there is the same room by using a function originally provided such as using the dust level by the dust sensor 15, so that a dedicated sensor or the like is separately provided. In comparison, the number of parts and the cost can be reduced.

  Moreover, in the said structure, when it judges that it is the same room and raises an air cleaning capability, after driving | operation completion | finish of the vacuum cleaner 10-2, strong operation is implemented for the 2nd predetermined time decided according to the area of a room. It is a configuration.

  If the normal control is immediately resumed after the operation of the vacuum cleaner 10-2 is finished, the operation will be shifted to a weak operation when the air around the air cleaner 10-1 on which the dust sensor 15 is mounted is purified. Unable to purify the air in the whole room. On the other hand, with the above configuration, strong operation is performed until the suspended particles wound up by cleaning are removed from the entire room, so the dust rolled up in the air by the cleaning operation can be more reliably Can be removed.

  In the cleaning system 1 according to the present embodiment, the cleaner 10-2 is not limited to the self-propelled type, and may be a cleaner that is manually moved by the user.

  Moreover, in the normal control that performs parallel processing with the cooperative control, the dust level for performing strong driving may be set lower than when the parallel processing is not performed. This is because there is a high possibility of dust being rolled up because the cleaner 10-2 is in operation. By setting the dust level for strong driving low, the purification of the air in the room being cleaned can be started more quickly.

  By the way, in this Embodiment, although the cleaner operating state detection part 17 and the room determination part 18 were provided in the air cleaner 10-1, you may provide in the server 40. FIG. The server 40 is notified of account information, installation location information, and the like from each of the cleaner 10-2 and the air cleaner 10-1, and the cleaner 10-2 is notified of information on its operating state. . The server 40 detects the operating state of the cleaner 10-2 associated with the air cleaner 10-1 using these pieces of information. In this case, dust level information from the dust sensor 15 is transmitted from the air cleaner 10-1 to the server 40.

  Moreover, in this Embodiment, although the structure which the air cleaner 10-1 and the cleaner 10-2 cooperate via the server 40 was illustrated, it cooperates not via the server 40 but via the relay station 50 of wireless LAN. The air cleaner 10-1 and the cleaner 10-2 may communicate with each other directly and cooperate with each other without using the relay station 50 (see FIG. 1).

  Or it replaces with the server 40 on the communication network 60, and the structure which provides a home server in the local network in the user's house 70, and cooperates via a home server may be sufficient. When going through a home server, you may provide the cleaner operating state detection part 17 and the room determination part 18 in a home server.

[Embodiment 2]
Another embodiment of the present invention will be described. For convenience of explanation, members having the same functions as those described in the embodiment are given the same reference numerals, and descriptions thereof are omitted.

  FIG. 8 is a block diagram showing a schematic configuration of the cleaner 10-2A in the cleaning system 1A according to the present embodiment. The vacuum cleaner 10-2A has a configuration in which a room size recognition unit 37 and a room size information notification unit 38 are added to the vacuum cleaner 10-2 shown in FIG. The room size recognition unit 37 and the room size information notification unit 38 are constructed in the cleaning control unit 31A. In the present embodiment, cleaner 10-2A is limited to a self-propelled type.

  The room size recognizing unit 37 recognizes the size of the room from information obtained in the process in which the cleaner 10-2A moves in the room during the cleaning operation. For example, start from the charging stand at the start of cleaning, run along the wall, find the shape and size of the room from the time and distance traveled around the room and returning to the charging stand, the direction and number of turns Can do.

  The room size information notification unit 38 notifies the server 40 of information on the room size recognized by the room size recognition unit 37 via the cleaning communication unit 33.

  FIG. 9 is a block diagram illustrating a schematic configuration of the air cleaner 10-1A in the cleaning system 1A according to the present embodiment. The air purifier 10-1A has a configuration in which a second predetermined time determination unit 19 is added to the air purifier 10-1 illustrated in FIG. The second predetermined time determination unit 19 is constructed in the cleaning control unit 11A.

  The 2nd predetermined time determination part 19 determines the 2nd predetermined time which performs strong driving | operation after completion | finish of operation of the cleaner 10-2A according to the information of the room size acquired from the cleaner 10-2A.

  Although a block diagram is not shown about the server 40, if it demonstrates with reference to FIG. 4, the server control part 41 will transmit the information of the room size received from the cleaner 10-2A to the air cleaner 10-1A.

  FIG. 10 is a flowchart showing processing in the air purifier 10-1A. As can be seen from a comparison with the flowchart of FIG. 5 described above, S100 is added between S9 and S10, and S101 that is advanced when YES is determined in S100 is added.

  In S100, it is determined whether or not room size information has been received from the server 40. If NO is determined, the process proceeds to S10. If YES is determined in S100, the process proceeds to S101, where the second predetermined time is determined based on the room size information received from the server 40, and the strong operation is executed. Then, cooperation control is complete | finished and it returns to S4.

  Thereby, the effort which registers the information of the installed room size with respect to the air cleaner 10-1 becomes unnecessary.

  Further, the second predetermined time determination unit 19 may be provided in the server 40 or the home server. In this case, the server 40 transmits the determined second predetermined time to the air purifier 10-1A.

[Embodiment 3]
Another embodiment of the present invention will be described. For convenience of explanation, members having the same functions as those described in the embodiment are given the same reference numerals, and descriptions thereof are omitted.

  FIG. 11 is a block diagram showing a schematic configuration of the air cleaner 10-1B in the cleaning system 1B according to the present embodiment. The air cleaner 10-1B has a configuration in which an air cleaner operating state detecting unit 20 and a cleaner operating instruction unit 21 are added to the air cleaner 10-1A shown in FIG. The air cleaner operating state detecting unit 20 and the cleaner operating instruction unit 21 are constructed in the cleaning control unit 11B. In the present embodiment, cleaner 10-2B (see FIG. 1) is limited to a self-propelled type.

  The air purifier operating state detection unit 20 detects the operating state of the air purifier 10-1B. Specifically, the information and the number of times when the strong operation is performed in the normal control, and the strong in the cooperative control. If the strong operation automatic control mode for automatically performing the strong operation is not set, the time and the number of manual strong operations are detected.

  The cleaner operation instructing unit 21 is based on the air cleaner operating state detected by the air cleaner operating state detecting unit 20 and the dust level information detected by the dust sensor 15. If it is determined that the amount of dust level is not reduced only by the cleaning operation by 1B, the cleaner is instructed to perform cleaning. The operation instruction from the cleaner operation instruction unit 21 is sent to the cleaner 10-2B via the server 40, and the cleaner 10-2B starts cleaning.

  For example, the cleaner operation instructing unit 21 determines that the normal control strong operation with the dust level “2: medium” or higher is performed for three consecutive days, and that the cleaner 10-2B is not operated during that time. Then, the operation is instructed. Further, when the strong operation automatic control mode is not selected and the strong operation is manually performed, for example, after the strong operation of the air cleaner 10-1B is performed (by manual operation), the dust level “2: medium” is obtained within 24 hours. When the above is detected three times or more, the operation is instructed. Alternatively, the operation is instructed when the dust level “2: medium” or higher is counted three times or more within 24 hours regardless of the execution of the strong driving.

  As described above, when a large amount of dust is accumulated on the floor or the like in the room and the amount of suspended particles does not decrease even if the air cleaner 10-1B continues to be driven with a strong operation, the air cleaner 10- By instructing the cleaner 10-2B from 1B to perform cleaning, the air cleaner 10-1B and the cleaner 10-2B are effectively linked together to further effectively clean the indoor space. be able to.

  Based on the operating state of the air cleaner 10-1B and the dust level information from the dust sensor 15, it is determined that the amount of suspended particles is not reduced by only the cleaning by the air cleaner 10-1B. The control device that instructs the cleaner 10-2B to perform cleaning includes the cleaning control unit 11B and the cleaning control unit 31, or these and the server control unit 41.

  It should be noted that such a configuration instructing cleaning from the air cleaner 10-1B side to the cleaner 10-2B side is not necessarily combined with the first and second embodiments.

  Moreover, you may provide the air cleaner operating state detection part 20 and the cleaner operation instruction | indication part 21 in the server 40 or a home server. In this case, the air cleaner 10-1B transmits information necessary for the server 40 to detect the operating state of the air cleaner 10-1B to the server 40.

[Embodiment 4]
The air cleaners 10-1, 10-1A, 10-1B, the cleaners 10-2, 10-2A, 10-2B, and the server 40 in the server 40 described in the first to third embodiments, the cleaner An operation state detection unit 17, a room determination unit 18, a cleaner operation state notification unit 36, a room size recognition unit 37 and a room size information notification unit 38, a second predetermined time determination unit 19, an air cleaner operation state detection unit 20, and The vacuum cleaner operation instruction unit 21 may be realized in hardware by a logic circuit formed on an integrated circuit (IC chip), or may be realized in software using a CPU (Central Processing Unit). Good.

  In the latter case, the air cleaners 10-1, 10-1A, 10-1B, the cleaners 10-2, 10-2A, 10-2B, and the server 40 are respectively program commands that are software that implements the respective functions. , A ROM (Read Only Memory) or a storage device (these are referred to as “recording media”) in which the program and various data are recorded so as to be readable by a computer (or CPU), and a RAM ( Random Access Memory). And the objective of this invention is achieved when a computer (or CPU) reads the said program from the said recording medium and runs it. As the recording medium, a “non-temporary tangible medium” such as a tape, a disk, a card, a semiconductor memory, a programmable logic circuit, or the like can be used. The program may be supplied to the computer via an arbitrary transmission medium (such as a communication network or a broadcast wave) that can transmit the program. The present invention can also be realized in the form of a data signal embedded in a carrier wave in which the program is embodied by electronic transmission.

  The present invention is not limited to the above-described embodiments, and various modifications are possible, and the present invention also relates to embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is included in the technical scope. Furthermore, a new technical feature can be formed by combining the technical means disclosed in each embodiment.

[Summary]
The cleaning system 1, 1A, 1B according to the first aspect of the present invention includes an air cleaner 10-1, a cleaner 10-2, and a cleaner operating state detector 17 that detects an operating state of the cleaner 10-2. The dust sensor 15 for detecting the amount of suspended particles contained in the air, the operating state of the cleaner 10-2 detected by the cleaner operating state detector 17 and the dust sensor 15 Based on the amount of suspended particles, it is determined whether the room in which the cleaner 10-2 is operating and the room in which the air cleaner 10-1 is installed are the same. If it judges that, the control apparatus (cleaning control part 11) which controls the said air cleaner 10-1 so that air-cleaning capability may increase is provided.

  According to the said structure, a control apparatus is based on the operating state of the cleaner 10-2, and the quantity of the suspended particle by the dust sensor 15, The room where the said cleaner 10-2 is operating, The said air cleaner 10 It is determined whether or not the room in which -1 is installed is the same, and if it is determined that the room is the same, the air purifier 10-1 is controlled so as to enhance the air cleaning capability, and the indoor air is purified.

  During the cleaning, dust accumulated on the floor surface rises due to the influence of the moving air flow accompanying the movement of the cleaner 10-2 and the exhaust air flow accompanying the intake air during cleaning, and the amount of suspended particles in the air increases. To increase. Therefore, whether the room in which the cleaner 10-2 is operating and the room in which the air cleaner is installed is the same based on the operating state of the cleaner 10-2 and the amount of suspended particles in the air. I can judge.

  Thereby, even though the vacuum cleaner 10-2 is cleaning a room different from the room where the air cleaner 10-1 is installed, the air cleaner 10-1 operates unnecessarily strongly. The trouble can be avoided. As a result, the air cleaner 10-1 and the vacuum cleaner 10-2 can be effectively linked while suppressing wasteful power consumption as much as possible, so that the indoor space can be more effectively cleaned.

  Moreover, in addition to the operating state of the vacuum cleaner 10-2, a function provided from the start, such as using the detection output of the dust sensor 15, is used to determine whether they are the same, so a dedicated sensor or the like is separately provided. Compared to the above, the number of parts and the cost can be reduced.

  In the cleaning systems 1, 1 </ b> A, 1 </ b> B according to the second aspect of the present invention, the control device (cleaning control unit 11) further detects the start of operation of the cleaner 10-2 by the cleaner operating state detector 17. When the amount of the suspended particles detected by the dust sensor 15 increases within a first predetermined time from the start of operation of the cleaner 10-2, the cleaner 10-2 operates. And the room where the air purifier 10-1 is installed are the same, and the first predetermined time depends on the time required for cleaning the room where the air purifier is installed. It is also possible to adopt a configuration determined by the above.

  According to the above configuration, when the vacuum cleaner 10-2 starts operating and the amount of airborne particles in the room air increases within a first predetermined time from the start of operation, the room in which the vacuum cleaner 10-2 is operating. And whether the room in which the air purifier 10-1 is installed is the same. The first predetermined time is determined according to the time required for cleaning the room in which the air purifier is installed.

  Thus, by taking in the elements of the time required for cleaning the room in which the air cleaner is installed, the room in which the cleaner 10-2 is operating and the room in which the air cleaner 10-1 is installed Can be determined with higher accuracy.

  In the cleaning system 1, 1A, 1B according to the third aspect of the present invention, the control device further detects the end of the operation of the cleaner 10-2 by the cleaner operating state detection unit 17. The air cleaner 10-1 is controlled so as to maintain a high air cleaning capacity for a second predetermined time after the operation of the air cleaner 10-2 ends, and the second predetermined time is determined by the air cleaner 10. -1 may be determined according to the size of the room in which the -1 is installed.

  At the time when the operation of the cleaner 10-2 is completed, dust that has been rolled up by the cleaning operation of the cleaner 10-2 still remains in the indoor air. In the above configuration, since the air purifier 10-1 maintains a high air cleaning capability (strong operation) for the second predetermined time after the operation of the vacuum cleaner ends, the dust that has been rolled up into the air by the cleaning operation. Can be more effectively removed.

  Moreover, since the second predetermined time is determined according to the size of the room in which the air purifier 10-1 is installed, the dust that has been wound up in the air by the cleaning operation is effectively removed from the entire room. can do.

  In the cleaning system 1A according to aspect 4 of the present invention, the cleaner 10-2A is a self-propelled cleaner, and the self-propelled cleaner 10-2A is a self-propelled room for cleaning. A measurement unit (room size recognition unit 37) that measures the area; and a notification unit (room size information notification unit 38) that notifies the control device of the value measured by the measurement unit. May be configured to determine the second predetermined time based on information on the size of the room notified from the self-propelled cleaner 10-2A.

  According to the said structure, the effort which registers the information of the area of the room in which the air cleaner 10-1A is installed into a control apparatus becomes unnecessary, and the convenience improves.

  The cleaning system 1B according to the fifth aspect of the present invention further includes an air cleaner operating state detecting unit 20 that detects an operating state of the air cleaner 10-1B, and the cleaner 10-2B is a self-propelled cleaner. The control device (cleaning control unit sensor 11B, cleaning control unit 31) includes the operating state of the air purifier 10-1B detected by the air purifier operating state detecting unit 20, and the dust sensor 15. If it is determined that the amount of the suspended particles is not reduced only by the cleaning by the air purifier 10-1B based on the amount of the suspended particles detected by the self-propelled cleaning, the cleaning is performed. It can also be set as the structure which controls machine 10-2B.

  When a large amount of dust is accumulated on the indoor floor or the like, the amount of suspended particles does not decrease even if the air cleaner 10-1B continues to operate in a strong operation. According to the above configuration, in such a case, the control device causes the self-propelled cleaner 10-2B to perform cleaning, so that the room can be kept clean.

1, 1A, 1B Clean system 10-1, 10-1A, 10-1B Air cleaner 10-2, 10-2A, 10-2B Vacuum cleaner 11, 11A, 11B Clean control unit (control device)
14 Air Cleaner 15 Dust Sensor 16 Operation Control Unit (Control Device)
17 Vacuum cleaner operating state detection unit 18 Room determination unit (control device)
19 Second predetermined time determination unit (control device)
20 Air Cleaner Operation State Detection Unit 21 Vacuum Cleaner Operation Instruction Unit (Control Device)
31, 31A, cleaning control unit (control device)
36 Vacuum cleaner operating state notification unit 37 Room size recognition unit (measurement unit)
38 Room size information notification section (notification section)
40 server 43 server communication unit 60 communication network

Claims (5)

An air purifier,
Vacuum cleaner,
A vacuum cleaner operating state detecting unit for detecting an operating state of the vacuum cleaner;
A dust sensor for detecting the amount of suspended particles contained in the air;
Based on the operating state of the cleaner detected by the cleaner operating state detection unit and the amount of the suspended particles detected by the dust sensor, the room in which the cleaner is operating and the air cleaner And a control device that controls the air purifier so that the air purifying capacity is increased when it is determined that the room is the same as the room in which the air cleaner is installed. system. The control device detects the start of operation of the cleaner by the cleaner operating state detection unit, and the amount of the suspended particles detected by the dust sensor is the first from the start of operation of the cleaner. 1 When it increases within a predetermined time, it is determined that the room in which the vacuum cleaner is operating is the same as the room in which the air cleaner is installed;
The cleaning system according to claim 1, wherein the first predetermined time is determined according to a time required for cleaning a room in which the air cleaner is installed. When the operation end of the cleaner is detected by the cleaner operating state detection unit, the control device maintains a state in which the air cleaning capability is high for a second predetermined time from the operation end of the cleaner. Control the air purifier as
The cleaning system according to claim 1 or 2, wherein the second predetermined time is determined according to a size of a room in which the air cleaner is installed. The vacuum cleaner is a self-propelled vacuum cleaner;
The self-propelled cleaner is a measuring unit that measures the size of a room that is self-propelled and cleaned, and
A notification unit for notifying the control device of the value measured by the measurement unit,
The said control apparatus determines the said 2nd predetermined time based on the information of the area of the room notified from the said self-propelled cleaner, The cleaning system of Claim 3 characterized by the above-mentioned. An air cleaner operating state detection unit for detecting the operating state of the air cleaner;
The vacuum cleaner is a self-propelled vacuum cleaner;
The control device uses the air cleaner based on the operating state of the air cleaner detected by the air cleaner operating state detector and the amount of the suspended particles detected by the dust sensor. The cleaning according to any one of claims 1 to 3, wherein the self-propelled cleaner is controlled to perform cleaning when it is determined that the amount of the suspended particles is not reduced by cleaning alone. system.

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