JP3675424B2 - air conditioner - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an air conditioner capable of operating a plurality of indoor units in the same operation or simultaneously with one outdoor unit.
[0002]
The present invention also relates to automatic setting of the number of outdoor units connected to the outdoor unit and the identification number of the unit set for each indoor unit, particularly the identification number between the outdoor unit and the indoor unit, in the air conditioner.
[0003]
[Prior art]
As this type of conventional air conditioner, for example, a technique described in JP-A-1-208647 can be cited.
FIG. 38 is a schematic diagram of a conventional air conditioner described in JP-A-1-208647.
38, 91 is a remote control switch, 92, 100, 101 are indoor units, 93 is an outdoor unit, 94 is an indoor control device, 95 is an outdoor control device, 96 is a remote control-indoor transmission line, and 97 is an indoor-outdoor transmission line. 98, 99 are transmission lines between indoor units.
[0004]
In the conventional air conditioner configured as described above, when the operation input from the remote controller 91 is input to the control device 94 of the indoor unit 92 through the remote control-indoor transmission line 96, the operation input from the remote controller 91 simultaneously passes through the indoor unit transmission line 98. Are transmitted to the control devices of the indoor units 100 and 101. Transmission to the outdoor unit communicates with the control unit 95 of the outdoor unit 93 through the indoor-outdoor transmission line 97 and the indoor unit transmission line 99 in the order set by the DIP switch on the indoor control unit. The control device of the outdoor unit 93 operates the compressor and the like only when the operation command is continued for the number of indoor units that can be connected to the outdoor unit.
Further, when connecting a conventional multi-type air conditioner to a higher management system, it is common to connect each indoor unit to a controller of the higher management system.
[0005]
Another example of a conventional air conditioner is shown in FIG.
FIG. 39 is a block diagram showing a conventional centralized control system for an air conditioner disclosed in, for example, Japanese Patent Laid-Open No. 4-288440. In the figure, 101a and 101b are remote controllers, 102a and 102b are air conditioning units, 103 is a centralized controller that centrally controls the air conditioning units by connecting the air conditioning units 102a and 102b with a communication cable 116, and 104 is an address automatic control for the remote controllers 101a and 101b. Setting switch 107 is an address setting start command unit of remote controllers 101a and 101b, 115 is an indoor unit control unit of the air conditioning unit, 114 is a response unit of the indoor unit, 111 is a duplicate setting detection unit of the indoor unit, and 112 is an address of the indoor unit It is a registration setting part.
[0006]
In such a conventional centralized control system for air conditioners, the remote controllers 101a and 101b are connected to air conditioning units 102a and 102b to which a plurality of indoor unit controllers 115 are connected, and these air conditioning units 102a and 102b are connected to a communication cable 116. In this way, the bus is connected, and the address is controlled by the bus controller via the communication cable 116 by the central controller 103 that centrally controls the air conditioning unit. When the address automatic setting switch 104 of the remote controller 101a is input, an address automatic setting command a is output to all the indoor units, and the indoor unit temporarily stops the bus communication d or cancels the suspension to the centralized controller 103 and other indoor units. On the other hand, the remote controller 101a outputs an automatic setting command a by the address automatic setting switch 104, and then outputs a setting start command b to each indoor unit in order by the address setting start command unit 107. The indoor unit control unit 115 sets a temporary address and individually transmits it to another indoor unit, and the duplication setting detection unit 111 detects an answer back of the individual transmission from the response unit 114 of the other indoor unit, and there is no answer back. Until the temporary address is changed, the address registration and setting unit 112 registers and sets the temporary address without answerback as a self address.
Another example is JP-A-6-58602.
[0007]
[Problems to be solved by the invention]
Since the conventional air conditioner described in Japanese Patent Laid-Open No. 1-208647 is configured as described above, it is possible to simultaneously operate in the same state with a plurality of indoor units. It is necessary to connect all of the transmission lines and the transmission lines that connect each indoor period in series, and there is a drawback that the local wiring work is difficult and the wiring cost is high.
In addition, when connecting a conventional air conditioner to a higher management system, each indoor unit is connected to a controller of a higher management system or each indoor unit is connected to a transmission conversion device with a higher management system controller. Generally, it is necessary to connect, but in the former case, it is necessary to mount communication H / W and S / W corresponding to a higher management system in all indoor units, and there is a disadvantage that the cost increases. In the latter case, there are disadvantages such as poor workability when connecting to a higher management system later, and no space for installing the transmission conversion device in the indoor unit.
[0008]
In the conventional centralized control system for an air conditioner disclosed in Japanese Patent Laid-Open No. 4-288440, when a setting start command is input to each indoor unit, a temporary address is set and individually transmitted to other indoor units. If there is a setting unit, a response unit that answers when there is an individual transmission of the same address, and an answerback from another indoor unit, it is determined that the temporary address is duplicated with another indoor unit, and there is no answerback Until the temporary address is set, the duplication determining means for instructing the setting means to change the temporary address and the temporary address without answer back are registered as the self-address, so that the indoor unit transmits a signal transmitted by another indoor unit. There is a problem that a communication circuit capable of receiving the signal is necessary and expensive.
[0009]
The present invention has been made to solve the above-mentioned problems, and the first object is to easily carry out on-site wiring work. Moreover, the workability when connecting to a higher management system is good and inexpensive. An air conditioner is provided.
[0010]
The second object is to provide an air conditioner that automatically sets indoor unit identification numbers set between a plurality of indoor units and outdoor units even when an inexpensive communication circuit that cannot transmit and receive between indoor units is used. To get.
The third object is to obtain an air conditioner that automatically sets the number of connected indoor units and the unit identification number without having any setting means such as a switch in either the indoor unit or the outdoor unit.
[0011]
[Means for Solving the Problems]
An air conditioner according to a first aspect of the invention is connected to at least one of the outdoor unit, the outdoor unit, the transmission unit for transmitting information between the outdoor unit and the indoor unit connected to the outdoor unit, and the content of operation. The operation command means for setting and the facility function information of the indoor unit provided and connected to the outdoor unit are collected and connected from the facility function information of the indoor unit. all The operation content that can be set for the operation of the indoor unit is determined, provided to at least one of the indoor unit or the operation command means, a control means that transmits the determined operation content to each indoor unit via the transmission means, The operation details that can be set by the operation transmitted from the control means. Without being limited to facility function information of a specific indoor unit And an operation function setting unit that automatically sets operation contents that can be operated by the indoor unit or the operation command unit.
[0028]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
Hereinafter, an example of an embodiment of the present invention will be described.
FIG. 1 shows a block diagram of an embodiment of an air conditioner that performs the same operation. In the figure, 1 is an outdoor unit, 2 to 4 are indoor units (A) to (C), 5 is a wired remote controller, and 6 to 8 are outdoor unit 1 and indoor unit (A ) 2 to (C) 4, 9 is a transmission line between the local remote controller 5 and the indoor unit (A) 1, and 10 is a wireless type remote controller.
FIG. 2 is a block diagram of the configuration of the control unit in the outdoor unit 1, FIG. 3 is a block diagram of the configuration of the control unit of the indoor units (A) 2 to (C) 4, and FIG. Indicates.
In FIG. 2, 20 is a control unit in the outdoor unit 1, 21 is an indoor / outdoor communication receiving means for receiving operation information from the indoor unit, 22 is an indoor / outdoor communication transmitting means for transmitting operation settings to the indoor unit, 23 Is an air conditioning unit operation setting means for setting the contents of simultaneous operation of the indoor units based on the operation information of each indoor unit received by the indoor / outdoor communication receiving means 21, and 24 is an outdoor unit processing section for controlling the outdoor unit.
[0029]
In FIG. 3, 30 is a control unit in the indoor units (A) 2 to (C) 4, 31 is an indoor / outdoor communication receiving means for receiving the operation setting from the outdoor unit, and 32 is the operation information transmitted to the outdoor unit. Indoor / outdoor communication transmitting means 33, remote control communication receiving means 33 for receiving the operation setting from the local remote controller, 34 remote control communication transmitting means for transmitting the operation state to the local remote controller, 35 indoor / outdoor communication receiving means 31 or remote control communication reception Operation setting means for setting the operation content of the indoor unit according to the operation setting received by the means 33, 36 is an indoor unit processing unit that controls the indoor unit, and 37 is a wireless that receives a signal from the wireless remote controller 10. It is a signal receiving means.
In FIG. 4, 40 is a control unit in the local remote controller 5, 41 is remote control communication receiving means for receiving the operation state from the indoor unit, 42 is remote control communication transmitting means for transmitting the operation setting to the indoor unit, and 43 is at hand. This is a local remote controller processing unit for controlling the remote controller.
[0030]
Next, the operation of the embodiment of the multi-type air conditioner that simultaneously performs the same operation configured as described above will be described.
For example, as shown in FIG. 1, an indoor unit (A) 2, an indoor unit (B) 3, and an indoor unit (C) 4 are connected to the outdoor unit 1. The indoor unit (A) 2 to the indoor unit (C) 4 have their operation details set by the local remote controller 5 or the wireless type local remote controller 10, and perform simultaneous operation with the same settings.
[0031]
First, the operation will be described by taking as an example a case where operation setting is performed by the local remote controller 5. The control unit of the local remote controller is configured as shown in FIG. 4. When the operation content is set by an operation setting switch (not shown) or the like, the remote control processing unit 43 transmits the set operation setting content to the remote control communication transmitting means. At 42, the data is transmitted to the indoor unit (A) 2. The control unit of the indoor unit (A) 2 has the configuration shown in FIG. 5. When the operation setting content transmitted from the remote control is received by the remote control communication receiving means 33, the operation setting means 35 determines the operation content. The indoor unit processing unit 36 controls the indoor unit according to the determined operation content, and the operation content and operation status data are transmitted to the outdoor unit 1 and the local remote controller 5 by the indoor / outdoor communication transmitting unit 32 and the remote control communication transmitting unit 34. . The control unit of the outdoor unit 1 is configured as shown in FIG. 2. When the operation content is received by the indoor / outdoor communication receiving means 21, the air conditioner unit operation setting means 23 determines the simultaneous operation content of all the indoor units, In accordance with the determined operation content, the outdoor unit processing unit 24 controls the outdoor unit, and the indoor / outdoor communication transmitting means 22 converts the operation content into the indoor unit (A) 2, the indoor unit (B) 3, the indoor unit (C ) Send to 4. When the indoor units (A) 2 to (C) 4 receive the operation content by the indoor / outdoor communication receiving means 31, the operation setting means 35 determines the operation content, and the indoor unit processing unit 36 determines the operation content according to the determined operation content. Control indoor units.
In this way, first, the indoor unit (A) 2 connected to the remote controller starts operation according to the received operation setting content by receiving the operation setting from the local remote controller 5, and the indoor unit (A) 2 becomes the outdoor unit 1. When the outdoor unit 1 transmits the operation setting content to each indoor unit (A) 2 to (C) 4, all the indoor units perform simultaneous operation.
[0032]
Next, a case where operation setting is performed with the wireless remote controller 10 will be described. When the indoor unit (C) 4 receives the operation setting by the wireless signal receiving unit 37, the operation setting unit 35 determines the operation content, and the indoor unit processing unit 36 controls the indoor unit according to the determined operation content. At the same time, the operation content and operation status data are transmitted to the outdoor unit 1 by the indoor / outdoor communication transmitting means 32. When the outdoor unit 1 receives the operation content by the indoor / outdoor communication receiving means 21, the air conditioning unit operation setting means 23 determines the simultaneous operation content of all the indoor units, and the outdoor unit processing unit 24 according to the determined operation content. While controlling the outdoor unit, the indoor / outdoor communication transmitting means 22 transmits the operation content to the indoor unit (A) 2, the indoor unit (B) 3, and the indoor unit (C) 4. When the indoor units (A) 2 to (C) 4 receive the operation content by the indoor / outdoor communication receiving means 31, the operation setting means 35 determines the operation content, and the indoor unit processing unit 36 determines the operation content according to the determined operation content. Control indoor units. At this time, the indoor unit (A) 2 transmits the operation contents and operation status data to the local remote controller 5 by the remote control communication transmitting means 34, and the local remote controller 5 operates from the indoor unit (A) 2 by the remote control communication receiving means 42. When the contents and the driving situation are received, the remote control processing unit 43 notifies them by a display unit (not shown).
[0033]
In addition, with respect to the operation when the operation setting is simultaneously performed with different contents by the local remote controller 5 and the wireless remote controller 10, the cooling setting is performed by the local remote controller 5 and the dry setting is performed by the wireless remote controller 10 as an example. explain.
First, the indoor unit (A) 2 to which the remote control is connected by receiving the operation setting, that is, the cooling setting from the local remote controller 5 starts the cooling operation, and by receiving the operation setting, that is, the dry setting, from the wireless type remote controller 10, The indoor unit (C) 4 starts dry operation. When the outdoor unit 1 receives different operation setting contents from the indoor unit (A) 2 and the indoor unit (C) 4, that is, cooling setting and dry setting, by the indoor / outdoor communication receiving means 21, the air conditioning unit operation setting means 23 According to a predetermined priority order, the operation content is determined as one of the operation settings from the indoor units (A) 2 and (C) 4. For example, when the setting of the indoor unit with a large unit number is followed, the dry setting received from the indoor unit (C) 4 is determined. When the operation content is determined, the outdoor unit processing unit 24 controls the outdoor unit, and the indoor / outdoor communication transmitting unit 22 sets the operation content, that is, the dry setting to the indoor unit (A) 2, the indoor unit (B) 3, The data is transmitted to the indoor unit (C) 4, and each of the indoor units (A) 2 to (C) 4 performs simultaneous operation with the same setting contents, that is, dry setting. The indoor unit (A) 2 starts the cooling operation by receiving the cooling setting from the local remote controller 5, but by newly receiving the operation setting from the outdoor unit, the indoor unit (A) 2 performs the dry operation content determined by the outdoor unit. Operation will be carried out, and all indoor units will operate simultaneously with the same setting.
[0034]
In this way, first, the indoor unit (A) 2 and the wireless signal receiving indoor unit (C) 4 to which the remote controller is connected by receiving the operation setting from the local remote controller 5 and the wireless type local remote controller 10 have the reception operation setting contents. In response, the indoor unit (A) 2 and the indoor unit (C) 4 transmit the operation setting contents to the outdoor unit 1, and the outdoor unit 1 determines the simultaneous operation contents according to a predetermined priority order. By transmitting the operation setting contents to each indoor unit (A) 2 to (C) 4, all the indoor units simultaneously operate with the same setting contents.
As described above, the indoor units (A) 2 to (C) 4 transmit / receive operating information to / from the outdoor unit 1 and the local remote controller 5, so that the indoor units (B) 3, (C) 4 and the local remote controller 5 are connected. Simultaneous operation control can be performed with the same setting without any wiring work and when any unit receives different operation settings of multiple remote controllers at any time.
In this example, the local remote controller 5 is connected to the indoor unit (A) 2 and the signal of the wireless-type local remote controller 10 is input from the indoor unit (C) 4. Similarly, simultaneous operation control is possible. Further, the number of remote controllers that can be operated is not limited to two.
[0035]
Next, the operation of the indoor unit will be described based on the flowchart of FIG. In step S10, normal operation is started. When the operation setting from the local remote controller 5 is received in step S11, the air conditioning unit is controlled with the operation setting content from the local remote control in step S12, and the operation setting content is transmitted to the outdoor unit 1 in step S13. . Next, when the operation setting from the outdoor unit 1 is received in step S14, the operation setting content from the outdoor unit 1 is transmitted to the local remote controller 5 in step S15. If the operation setting is not received from the local remote controller 5 in step S11, the previous operation control is continued and step S14 is performed. If the operation setting from the outdoor unit 1 is not performed in step S14, the previous operation control is continued and step S11 is performed.
Thus, even if the control is performed according to the operation setting from the local remote controller at steps S11 and S12, when another operation setting is newly received from the outdoor unit at step S14, the indoor unit is controlled according to the contents. Therefore, even if a plurality of indoor units receive different operation settings, the outdoor unit 1 determines and transmits the operation settings, so that each air conditioning unit operates with the same settings.
[0036]
Next, operation | movement of an outdoor unit is demonstrated based on the flowchart of FIG. In step S20, normal operation is started. When the operation setting from any of the indoor units (A) 2 to (C) 4 is received in step S21, it is determined in step S22 whether the operation settings from a plurality of air conditioning units have been received.
If it is determined in step S22 that operation settings from a plurality of air conditioning units have been received, the operation setting contents are determined in accordance with the priority order set in advance in step S23, and control of the own unit is performed in step S24. In step S25, the operation setting content is transmitted to all indoor units (A) 2 to (C) 4. If it is determined in step S22 that operation settings have not been received from a plurality of air conditioning units, that is, if it is determined that operation settings have been received from one air conditioning unit, control of the own unit is performed in step S24 with the operation setting contents. In step S25, the operation setting content is transmitted to all indoor units (A) 2 to (C) 4. If the operation setting from the indoor unit is not received in step S21, the previous operation control is continued.
[0037]
Thus, the operation setting is received from a single or a plurality of indoor units, the outdoor unit 1 determines the content of simultaneous operation of all the air conditioning units, and each air conditioning unit operates with the same setting. As for the above priority order, priority is given to the order of No. 4, No. 3, and so on from the large unit of the No. unit, or priority may be given to, for example, heating, cooling, drying, and blowing in accordance with the operation mode. .
[0038]
In this air conditioner, the remote controller communication receiving means and remote control communication transmitting means of the local remote controller, the remote controller communication receiving means and the remote control communication transmitting means of the indoor unit perform transmission / reception of operation information between the local remote controller and the indoor unit, and Operation information is transmitted and received between the outdoor unit and the indoor unit by the indoor / outdoor communication receiving means, the indoor / outdoor communication transmitting means, the indoor / outdoor communication receiving means and the indoor / outdoor communication transmitting means of the indoor unit, and the air conditioning unit operation setting of the outdoor unit is set. The contents of simultaneous operation of all the indoor units are determined by the means, and the indoor units are operated by the operation setting means of the indoor units.
[0039]
As described above, this air conditioner includes the remote control communication receiving means and the remote control communication transmitting means in the local remote controller, the remote control communication receiving means and the remote control communication transmitting means in the indoor unit, and operating information between the local remote controller and the indoor unit. The outdoor unit is equipped with an indoor / outdoor communication receiving means and an indoor / outdoor communication transmitting means, and the indoor unit is equipped with an indoor / outdoor communication receiving means and an indoor / outdoor communication transmitting means, and transmits / receives operation information between the outdoor unit and the indoor unit. The air conditioning unit operation setting means provided in the outdoor unit determines the simultaneous operation contents of all the indoor units, and the indoor unit is operated by the operation setting means provided in the indoor unit. Wiring can be reduced, and there are no restrictions on the indoor unit to which the remote control is connected, making it easy to install for many indoor units. There is an effect that the simultaneous operation multi-type air conditioner can be achieved that was. In the first embodiment described above, the operation of the embodiment of the multi-type air conditioner in which each indoor unit performs the same operation at the same time has been described. However, the operation of each indoor unit is a different operation with different setting contents, or not simultaneously. Non-simultaneous driving may be used.
[0040]
Embodiment 2.
FIG. 7 shows a configuration block diagram of an example of another embodiment of an air conditioner. In the figure, 1 and 12 are outdoor units, 2 to 4, 13 and 14 are indoor units, 5 and 15 are wired remote controllers, and 6 to 8 are outdoor unit 1 and indoor unit ( A) a transmission line between 2 and (C) 4, 9 is a transmission line between the local remote controller 5 and the indoor unit (A) 1, and 10 is a wireless type local remote controller. 11 is a transmission conversion device that transmits and receives control information to and from the controller of the air conditioning management system, and 16 is an air conditioning management device that centrally manages a plurality of air conditioners.
FIG. 8 shows a block diagram of the configuration of the control unit of the outdoor unit 1 of another example.
[0041]
FIG. 9 shows an example of another control unit configuration block diagram of the outdoor unit 1 of the multi-type air conditioner, and FIG. 10 shows a control unit configuration block diagram of a remote control of the multi-type air conditioner.
In FIG. 9, reference numeral 71 denotes remote control function setting means for setting functions that can be operated by the local remote controllers 5 and 15 or the air conditioning management device 16 based on the operation information of each indoor unit received by the indoor / outdoor communication receiving means 21.
In FIG. 10, reference numeral 81 denotes function setting means for setting a function that can be operated by remote control function information received by the remote control communication receiving means 41. In this example, it is provided in the control unit 40 in the remote controller, but the same unit can be provided in the indoor unit.
[0042]
Next, the operation | movement about embodiment of this multi type air conditioner is demonstrated.
For example, as shown in FIG. 7, indoor units (A) 2, (B) 3, (C) 4 are connected to the outdoor unit 1, and indoor units (D) 13, (E) 14 are connected to the outdoor unit 12. Yes. The local remote controllers 5 and 15 are connected to the indoor units (A) 2 and (D) 13, respectively, and the outdoor units 1 and 12 are connected to the air conditioning management device 16 via the transmission conversion device 11. The operation is controlled by the air conditioning management device 16. First, the operation will be described by taking as an example the case where the operation settings of the indoor units (A) 2 to (C) 4 are performed by the air conditioning management device 16. The control unit of the outdoor unit 1 has the configuration shown in FIG. 8. When the outdoor unit 1 receives the operation setting content from the air conditioning management device 16 by the transmission conversion device 11, the air conditioning unit operation setting means 23 performs all the operations. The content of the simultaneous operation of the indoor units is determined, and the outdoor unit is controlled by the outdoor unit processing unit 24 according to the determined operation content. Transmit to unit (B) 3 and indoor unit (C) 4. When the indoor units (A) 2 to (C) 4 receive the operation contents by the indoor / outdoor communication receiving means 31 as shown in FIG. 3, the operation contents are determined by the operation setting means 35, and the indoor units are determined according to the determined operation contents. The processing unit 36 controls the indoor unit. At this time, the indoor unit (A) 2 transmits the operation content and operation status data to the local remote controller 5 by the remote control communication transmitting means, and the local remote controller 5 receives the indoor unit (A) 2 by the remote control communication receiving means 41 as shown in FIG. When the driving content and driving status are received, the remote control processing unit 43 notifies the display unit (not shown) and the like.
[0043]
Next, the operation will be described by taking as an example a case where operation setting is performed by the local remote controller 5. When the indoor unit (A) 2 receives the operation setting content transmitted from the local remote controller 5 by the remote control communication receiving means 33, the operation setting means 35 determines the operation content, and the indoor unit processing unit according to the determined operation content The indoor unit is controlled at 36, and the operation content and operation status data are transmitted to the outdoor unit 1 and the local remote controller 5 by the indoor / outdoor communication transmitting means 32 and the remote control communication transmitting means 34. When the outdoor unit 1 receives the operation content by the indoor / outdoor communication receiving means 21, the air conditioning unit operation setting means 23 determines the simultaneous operation content of all the indoor units, and the outdoor unit processing unit 24 according to the determined operation content. The outdoor unit is controlled, and the operation content is transmitted to the indoor unit (A) 2, the indoor unit (B) 3, and the indoor unit (C) 4 by the indoor / outdoor communication transmission means 22, and at the transmission conversion device 11 The operation details and operation status are transmitted to the air conditioning management device 16. When the indoor units (A) 2 to (C) 4 receive the operation content by the indoor / outdoor communication receiving means 31, the operation setting means 35 determines the operation content, and the indoor unit processing unit 36 determines the operation content according to the determined operation content. Control indoor units.
In this way, centralized management and operation control of the air conditioner by the air conditioning management device 16 can be performed by simply providing the outdoor unit with the transmission conversion device without complicated construction. Such a transmission conversion device that performs signal conversion between indoor / outdoor communication and outdoor / higher-level controller communication may be incorporated in the control device in advance as shown in FIGS. It may be added as an adapter.
[0044]
Moreover, operation | movement of embodiment of this multi-type air conditioner is demonstrated. The indoor unit (A) 2 to the indoor unit (C) 4 transmit the functions (for example, louver function, vanes wing function, etc.) of the self unit set in advance to the outdoor unit 1 by the indoor / outdoor communication transmitting means 32. When the outdoor unit 1 receives the function information of each of the indoor units (A) 2 to (C) 4 by the indoor / outdoor communication receiving means 21, the remote control function setting means 71 sets the operation by the local remote controller or the controller of the air conditioning management system. The possible items are determined, and the function information is transmitted to the indoor unit (A) 2 by the indoor / outdoor communication transmitting means 22. The indoor unit (A) 2 transmits the function information received by the indoor / outdoor communication receiving means 31 to the local remote controller 5 by the remote control communication transmitting means 34, and the local remote controller 5 receives the indoor unit (A) by the remote control communication receiving means 42. When the function information from 2 is received, the function setting means 81 sets an item that can be operated by itself. For example, when the outdoor unit 1 sets vane as the remote control function information and sets no swing, the local remote controller 5 uses the function setting means 81 to set the vanes wing by the setting switch (not shown), that is, the up-and-down wind direction. Process to disable the continuous operation setting. Similarly, in the case of the air conditioning management device, the outdoor unit 1 can set the operable items by transmitting the function information via the transmission conversion device 11.
As described above, it is possible to set items operable with the remote controller without being limited to the functions of the indoor units connected to the remote controller.
Note that the function setting means 81 may be provided in the indoor unit instead of being provided in the remote controller, and function information obtained by remote control operation may be converted and operated by the indoor unit.
[0045]
Furthermore, the operation of this embodiment of the multi-type air conditioner will be described. The indoor unit (A) 2 to the indoor unit (C) 4 transmit the functions (for example, louver function, vanes wing function, etc.) of the self unit set in advance to the outdoor unit 1 by the indoor / outdoor communication transmitting means 32. When the outdoor unit 1 receives the function information of each of the indoor units (A) 2 to (C) 4 by the indoor / outdoor communication receiving means 21, the remote control function setting means 71 sets the operation by the local remote controller or the controller of the air conditioning management system. Possible items are determined by the logical sum of the functions of the indoor units, and the indoor / outdoor communication transmitting means 22 transmits the function information to the indoor unit (A) 2. The indoor unit (A) 2 transmits the function information received by the indoor / outdoor communication receiving means 31 to the local remote controller 5 by the remote control communication transmitting means 34, and the local remote controller 5 receives the indoor unit (A) by the remote control communication receiving means 42. When the function information from 2 is received, an item that can be operated by the function setting means is set.
[0046]
For example, if the indoor unit (A) 2 is set to “with louver and without swing” and the indoor units (B) 3 and (C) 4 are set to “without louver and with swing”, the outdoor unit 1 Is set as a logical sum “with louver, with swing”, and the set content is transmitted to the local remote controller 5 via the indoor unit (A) 2. The local remote controller 5 includes the remote control communication receiving means 41 and the function setting means 81. Through the remote control processing unit 43, the louver setting by a setting switch (not shown), that is, the continuous operation setting of the left and right wind direction, and the vane wing setting, that is, the continuous operation setting of the up and down wind direction are both valid, and when both are set, the louver setting = ” “ON” signal and vane setting = “swing” signal are transmitted simultaneously. The indoor unit (A) 2 to which the local remote controller 5 is connected simultaneously receives a signal of louver setting = “ON” and a signal of vane setting = “swing” together with other operation setting information by the remote control communication receiving means 33. . Since the function information of the indoor unit (A) 2 is “with louver, without swing”, the louver = “ON”, which is the content controllable by the own unit, that is, the continuous operation in the left and right wind directions is performed. Since the indoor unit (A) 2 does not have a swing function, continuous operation in the up and down direction is not performed. However, the louver setting = “ON” signal and vane setting together with other operation setting information by the indoor / outdoor communication transmitting means 32. = A signal “swing” is transmitted to the outdoor unit 1.
[0047]
When the outdoor unit 1 receives the operation setting by the indoor / outdoor communication receiving means 21, the indoor / outdoor communication transmitting means 22 sends a signal of louver setting = “ON” and a signal of vane setting = “swing” together with other operation setting information. It transmits to indoor unit (A) 2-indoor unit (C) 4 simultaneously.
Since the indoor units (B) 3 and (C) 4 have a function of “no louver, with swing”, when the operation setting is received by the indoor / outdoor communication receiving means 31, the left and right wind directions are not continuously operated, and the vanes wing is not performed. That is, continuous operation in the up and down direction is performed.
In this way, in the conventional simultaneous operation multi-air conditioner, if the model to which the remote controller is connected is a model without the swing function, the vane setting must be made even if the other indoor units connected to the same outdoor unit are swing models. If it is impossible to make a swing, and the model to which the remote control is connected is a model without a louver function, it is impossible to turn on the louver setting even if the other indoor unit is a louver model. However, the simultaneous operation multi-air conditioner of the present embodiment is possible.
[0048]
In addition, the above example is an example of a mixture of louver / swing models. However, the same applies to the case where the wind speed switching function is mixed with two-stage models, four-stage models, and non-switched models. The unit 1 sets “wind speed switching 4 steps” which is a logical sum as remote control function information, and transmits the set contents to the local remote controller 5 via the indoor unit (A) 2. The local remote controller 5 receives the remote control communication receiving means 41, The remote controller 43 operates via the function setting means 81 so as to validate each setting of weak wind, medium weak wind, medium strong wind, and strong wind with a setting switch (not shown). For example, the indoor unit (A) 2 is a model with no wind speed switching, the indoor unit (B) 3 is a model with two stages of wind speed switching, and the indoor unit (C) 4 is a model with four stages of wind speed switching. Is set to “medium strong wind”, the indoor unit (A) 2 does not switch the wind speed, so it operates with strong wind, for example, while the wind speed is fixed, and the indoor / outdoor communication transmission means 32 sends wind speed = “medium strong wind”. To do. Since indoor unit (B) 3 has two stages of wind speed switching, for example, it is decided to control in advance if the wind is set to weak wind, medium weak wind, medium strong wind, etc. It operates in a weak wind by receiving “medium strong wind”. Since the indoor unit (C) 4 has four stages of wind speed switching, it operates with the received “medium strong wind”.
[0049]
Thus, in the conventional multi-air conditioner, when the model to which the remote controller is connected is a model without wind speed switching, even if the other indoor units connected to the same outdoor unit are models with two or four stages of wind speed switching. When the wind speed switching control is impossible and the model to which the remote controller is connected is a wind speed switching two-stage model, even if the other indoor unit is a wind speed switching four-stage model, What was impossible to implement the wind speed switching control is possible with the multi-air conditioner of the present embodiment.
That is, it is possible to set all the functions originally provided in the installed indoor unit without limiting the items that can be operated by the remote controller to the functions of the specific indoor unit.
Similarly, in the case of the air conditioning management device, the outdoor unit 1 can set the operable items by transmitting the function information via the transmission conversion device 11.
[0050]
As described above, in this multi-type air conditioner, control information is transmitted and received between the transmission conversion device of the outdoor unit and the controller of the air-conditioning management system that centrally manages a plurality of air-conditioners. Set up and manage the operation of the air conditioner.
That is, the multi-type air conditioner has a transmission conversion device in the outdoor unit, transmits and receives control information to and from the controller of the air-conditioning management system that centrally manages a plurality of air-conditioners, Since the operation setting and management are performed, the air conditioning management device 16 can be inexpensively provided with a transmission conversion device in the outdoor unit, and not in a complicated construction, and not in a large number of indoor units that are difficult to perform post-installation. There is an effect that centralized management and operation control of the air conditioner can be performed. Further, even in an indoor unit where there is no space for installing the transmission conversion device, there is an effect that centralized management and operation control of the air conditioner by the air conditioning management device 16 can be performed.
[0051]
In addition, in this multi-type air conditioner, the function information of each indoor unit is collected by the indoor / outdoor communication receiving means of the outdoor unit, and the remote control function setting means determines the items that can be set for operation by the local remote controller or the controller of the air conditioning management system. The information is transmitted to the local remote controller via the indoor unit, and the local remote controller automatically sets the functions operable by the function setting means according to the information received by the remote control communication receiving means.
[0052]
That is, this multi-type air conditioner collects the function information of each indoor unit by the indoor / outdoor communication receiving means provided in the outdoor unit, and determines the items that can be set for operation by the remote controller or the controller of the air conditioning management system by the remote control function setting means. The function that can be operated by the remote control function setting means is automatically set according to the information transmitted to the local remote control through the indoor unit and received by the local remote control communication reception means provided in the local remote control, so that the remote control can be operated. There is an effect that the item can be set without being limited to the function of the indoor unit connected by remote control.
[0053]
In this multi-type air conditioner, the function information of each indoor unit is collected by the indoor / outdoor communication receiving means of the outdoor unit, and the remote control function is set by the logical sum of the function information of each indoor unit by the remote control function setting means.
[0054]
That is, this multi-type air conditioner collects the function information of each indoor unit by the indoor / outdoor communication receiving means provided in the outdoor unit, and the remote control function setting means performs the remote control function by the logical sum of the function information of each indoor unit. Since the setting is performed, the functions that can be operated by the remote controller are not limited to a specific indoor unit, and all the functions originally provided in the installed indoor unit can be set.
[0055]
Embodiment 3 FIG.
Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
FIG. 11 shows another embodiment.
FIG. 12 is a flowchart showing the operation of the control unit for the indoor unit and the outdoor unit.
11, reference numeral 311 denotes a unit control unit for controlling each of the indoor unit or the outdoor unit, 312 denotes own unit model setting means for setting the model of the indoor unit or the outdoor unit by, for example, a switch or a jumper, and 313 denotes the own unit model setting. The own unit model storage means for storing the model data of the own unit set by the means 312 in a nonvolatile memory or the like, 314 is the all model function storage for storing all the function information related to the model that can be selected by the own unit model setting means 312. Means 315 are own unit function setting means for setting the function of the own unit from the model set by the own unit model setting means 312 and the function for each model stored in the all model function storage means 314.
[0056]
Next, the operation will be described based on the flowchart of FIG.
Each unit (indoor unit, outdoor unit) sets the model of its own unit (self unit model setting means 312) by inputting switch and jumper settings, etc., at step S101 when the power is turned on, and non-volatile at step S102. The model data of the own unit stored in the own unit model storage means 313 such as a memory is compared with the model data newly set in step S101. As a result of the comparison, if it is determined that the model data is different in step S103, the model data newly set in step S101 is stored in the own unit model storage means 313 in step S104, and in step S105. The function data for each model stored in all model function storage means 314 is read out, and the function corresponding to the model data newly set in step S101 is selected from the function data for each model in step S106. The unit function is set (own unit function setting means 315). If the model data match as a result of comparing the model data in step S103, the previous set value is made the function of the own unit in step S106.
In addition, as an example of the switch, a plurality of DIP switches that can be turned on, off, and slid provided on the board are provided, and the microcomputer (unit control unit 311) reads a combination of 0 and 1 signals depending on the sliding state. The setting can be determined.
[0057]
Next, another embodiment will be described with reference to FIGS.
13 shows an indoor unit control apparatus using an embodiment of the air conditioner according to claim 11, FIG. 14 shows an outdoor unit control apparatus, FIG. 15 shows a configuration of the remote control apparatus, and FIG. 16 shows an indoor unit control apparatus. FIG. 17 is a flowchart showing the operation of the indoor unit control device.
In FIG. 13, 121 is an indoor unit controller for controlling each indoor unit, 122 is a local unit model setting means for setting the model of the indoor unit by, for example, a switch, a jumper, etc., and 123 is set by the local unit model setting means 122. Self-unit model storage means for storing the model data of the self-unit stored in a nonvolatile memory or the like, and 124 is an all-model function initial value storage means for storing initial values of all functions related to the models that can be selected by the self-unit model setting means 122 , 125 is a self unit function setting means for setting the function of the self unit from the model set by the self unit model setting means 122 and the function for each model stored in the all model function initial value storage means 124, and 126 is a self unit function. Own unit function storage means for storing the function information of the own unit set by the setting means 125; 7 remote control and operation information, the remote controller communication means for transmitting and receiving function information 128 are indoor-outdoor communication means for the outdoor unit and the operation information, the transmission and reception of function information.
[0058]
In FIG. 14, 131 is an outdoor unit control unit that performs each control of the outdoor unit, 132 is a self unit model setting unit that sets the model of the outdoor unit by a switch, a jumper, etc., and 133 is set by the self unit model setting unit 132. Self-unit model storage means for storing the model data of the self-unit stored in a nonvolatile memory or the like, and 134 is an all-model function initial value storage means for storing initial values of all functions related to the models that can be selected by the self-unit model setting means 132 135, own unit function setting means for setting the function of the own unit from the model set by the own unit model setting means 132 and the function for each model stored in the all model function initial value storage means 134, and 136 is the own unit function. Own unit function storage means for storing the function information of the own unit set by the setting means 135; 7 is a compartment outside communication means for the indoor unit and operation information, the transmission and reception of function information.
[0059]
In FIG. 15, 141 is a remote control unit for performing each control of the remote control, 142 is remote control communication means for transmitting / receiving operating information and function information to / from the indoor unit, and 143 is a unit function display means for displaying the functions of each indoor unit and outdoor unit. Reference numeral 144 denotes unit function setting change means for changing the setting of the unit function displayed on the unit function display means 143.
[0060]
Next, the operation will be described with reference to the flowcharts of FIGS.
First, the operation of the indoor unit will be described based on the flowchart of FIG. When the power is turned on, the indoor unit sets the model of its own unit by inputting switch and jumper settings in step S111 (own unit model setting means 122), and stores its own unit model such as a nonvolatile memory in step S112. The model data of the own unit stored in the means 123 is compared with the model data newly set in step S111. As a result of the comparison, if it is determined that the model data is different in step S113, the model data newly set in step S111 is stored in the own unit model storage means 123 in step S114, and in step S115. The function data initial setting value for each model stored in all model function initial value storage means 124 is read, and in step S116, the function data initial value corresponding to each model is newly set. After setting the function to the function of the own unit (own unit function setting means 125), the function information of the own unit is stored in the own unit function storage means 126 such as a nonvolatile memory in step S117. If the model data match as a result of comparing the model data in step S113, the previous set value is set as the function of the own unit in step S116.
This setting is performed, for example, by changing the setting of the storage means (RAM) provided in the control device 121 of FIG. 13 that controls the operation of the indoor unit if it is data necessary for the operation of the indoor unit. Further, the setting is changed in the same manner in the own unit function storage means 126 which is a nonvolatile memory.
In step S118, it is determined that the function information data has been received from the remote control by the remote control communication means 127. If it is determined in step S119 that the received data is the function information data for the own unit, in step S120 according to the received content, The function information is newly set (updated), the function information is stored in the own unit function storage means 126 in step S121, and the function information is transmitted to the outdoor unit by the indoor / outdoor communication means 128 in step S122. If it is determined in step S119 that the received data is not function information data related to the own unit, steps S120 and S121 are not performed, and the received data is transmitted to the outdoor unit in step S122.
After step S122 is completed, or in step S118, the function information data is not received from the remote controller, and in step S123, it is determined that the function information data is received from the outdoor unit by the indoor / outdoor communication means 128. In step S125, the function information is newly set (updated) in step S125, and the function information is stored in the own unit function storage means 126 in step S126. In step S127, the function information is transmitted to the remote controller by the remote control communication means 127, and the process returns to the reception waiting state in step S118. If it is determined in step S124 that the received data is not function information data related to the unit, steps S125 and S126 are not performed, and the received data is transmitted to the remote controller in step S127.
When function information data is not received from the outdoor unit in step S123 and operation control data is received by the remote control communication unit 127 or indoor / outdoor communication unit 128 in step S128, operation control is performed according to the received content in step S129, The process returns to the reception waiting state in step S118. If the operation control data from the remote controller or the outdoor unit is not received in step S128, the process returns to the reception waiting state in step S118.
[0061]
As described above, when the function information data transmitted after changing the setting from the remote controller is the content for the own unit, the function setting changing process of the own unit is performed, and the data for the other unit (outdoor unit or other indoor unit) is used. If there is, the remote control connection position may be arbitrary because each unit transmits the information to the outdoor unit or other indoor units via the indoor / outdoor communication means 128, and each unit changes its own function when receiving the information of its own unit. There is no need to redo.
[0062]
Next, operation | movement of an outdoor unit is demonstrated based on the flowchart of FIG. When the outdoor unit is turned on, in step S131, the model of its own unit is set by inputting switch and jumper settings, etc. (own unit model setting means 132), and in step S132, its own unit model storage such as a nonvolatile memory is stored. The model data of the own unit stored in the means 133 is compared with the model data newly set in step S131. As a result of the comparison, if it is determined that the model data is different in step S133, the model data newly set in step S131 is stored in the own unit model storage means 133 in step S134, and in step S135. The function data initial setting value for each model stored in all model function initial value storage means 134 is read out, and in step S136, the function data initial value for each model is corresponded to the newly set model data. After setting the function to the function of the own unit (own unit function setting means 135), in step S137, the function information of the own unit is stored in the own unit function storage means 136 such as a nonvolatile memory. If the model data match as a result of comparing the model data in step S133, the previous set value is set as the function of the own unit in step S136.
In step S138, it is determined that the function information data is received from the indoor unit by the indoor / outdoor communication means 137. If it is determined in step S139 that the received data is the function information data for the own unit, the process proceeds to step S140 according to the received content. Then, the function information is newly set (updated), the function information is stored in the own unit function storage unit 136 in step S141, and the function information is transmitted to all indoor units by the indoor / outdoor communication unit 137 in step S142. Then, the process returns to the reception waiting state in step S138.
If the function information data is not received from the indoor unit in step S138 and the operation control data is received by the indoor / outdoor communication means 137 in step S143, the operation control is performed according to the received content in step S144, and the reception of step S138 is awaited. Return to state. If the operation control data from the indoor unit is not received in step S143, the process returns to the reception waiting state in step S138.
[0063]
Next, the operation of the remote controller will be described with reference to FIG.
When the remote controller shifts to the unit function setting change mode by, for example, a switch operation in the unit function setting change means 144, the remote control communication means 142 collects the function information of all indoor units and outdoor units from the indoor unit, and by the switch operation. The unit setting display unit 143 displays the current setting data for the selected unit and setting change item. Further, when there is a setting change input by a switch operation, it is transmitted to the indoor unit by the remote control communication means 142 and displayed by the unit function display means 143.
[0064]
Next, another embodiment will be described with reference to FIG.
In FIG. 18, reference numeral 141 denotes a remote control unit for performing each control of the remote control, 142 is a remote control communication means for transmitting / receiving operation information and function information to / from the indoor unit, and 143 is a unit function display means for displaying the functions of each indoor unit and outdoor unit. Reference numerals 144 to 146 denote unit function setting change means 1 to n for changing the settings of the units displayed on the unit function display means 143. The unit function setting change means 1 to n, for example, for each item to be changed. Are provided with different input means.
For example, a case will be described in which there are two types: items set by the installation worker at the time of initial installation and items set by the service provider according to a request from the customer. At the time of initial installation, the items set by the installation operator are transferred to the setting mode by pressing the unit function setting changing means 1, for example, the switch A, and the items set by the service provider according to the request from the customer are the unit function setting change. By pressing the means 2, for example, the switch B, the mode is shifted to the setting mode.
The installation contractor changes the amount of blown air depending on the height of the installation location and the dirt condition, or changes the filter clogging detection timing in response to the dirt.
On the other hand, the service provider changes the function according to the customer's request, such as setting of the anti-freezing temperature and the presence / absence of a swing.
That is, when the switch A (unit function setting changing means 144) shifts to the setting mode in the remote controller of this embodiment shown in FIG. 20, only the items set by the installation operator, for example, item numbers 1 to 10, are displayed as unit functions. Displayed by means 143. For example, when an item is selected with the up and down keys 151 and 152, the item numbers 1 to 10 are sequentially displayed on the item display unit 153 every time the up and down key is input, and the item selected from the items 1 to 10 is displayed. Settings can be changed. When the switch B (unit function setting changing means 145) is used to shift to the setting mode, only the items set by the service provider, for example, item numbers 11 to 20 are displayed on the unit function display means 143. Similarly, when selecting an item with the up and down keys 151 and 152, the item numbers 11 to 20 are sequentially displayed on the item display unit 153 every time the up and down key is input, and the item selected from the items of 11 to 20 is displayed. Settings can be changed. By dividing the operation for shifting to the mode in this way, the items whose settings can be changed can be classified according to the type of the item whose settings are changed.
[0065]
Next, another embodiment will be described with reference to FIGS.
FIG. 20 is a block diagram showing an indoor unit controller using one embodiment of the multi-type air conditioner, and FIG. 21 is a flowchart showing the operation of the indoor unit controller.
In FIG. 20, reference numeral 129 denotes wireless signal receiving means for receiving an inspection signal including an address code from the wireless remote controller.
The operation will be described with reference to the flowchart of FIG. When the indoor unit receives an inspection request signal including an address code from the wireless remote controller in step S151, the indoor unit determines whether the received address code matches a predetermined address in step S152. If the received address code matches a predetermined address, for example 50, the function information setting change mode is entered in step S153. After shifting to the function information setting change mode, when the inspection request signal including the address code from the wireless remote controller is received again in step S154, the item whose setting is changed is determined in step S155 corresponding to the received address code. For example, when address 3 is received, the flow shifts to the air volume UP setting change mode. When the inspection request signal including the address code from the wireless remote controller is received again at step S156, the contents to be changed are determined at step S157 corresponding to the received address code. For example, when the address 2 is received, the air volume UP setting 2 is set.
In step S158, the function of the own unit is changed in accordance with the determined setting change item and setting change contents.
In step S152, if the received address code does not match a predetermined address, for example, 50, it is recognized as a normal inspection request signal, and a past abnormal code is output by a buzzer or LED in step S160. After performing the self-diagnosis, the process returns to the reception waiting state in step S151. If the inspection request signal including the address code is not received from the wireless remote controller in step S151 and the operation data is received in step S161, the operation is controlled in step S162 according to the received data, and the reception of step S151 is performed. Return to the waiting state. Even when the operation data is not received in step S161, the process returns to the reception waiting state in step S151.
[0066]
In the present embodiment, an example of changing the function of a unit that has received a wireless signal has been shown. However, as in the present embodiment, when an inspection request signal including an address code from a wireless remote controller is further received, the target unit is selected. May be performed. In this case, if the content is other than the own unit, the other unit is set by transmitting to the outdoor unit or another indoor unit by the indoor / outdoor communication means 128.
[0067]
Embodiment 4 FIG.
An embodiment of the present invention will be described below with reference to FIGS.
FIG. 22 shows a configuration of a control device using an embodiment of the multi-type air conditioner of the present invention. In the figure, 1 is an outdoor unit, 2 is an indoor unit (A) connected to the outdoor unit 1, 3 is an indoor unit (B) connected to the outdoor unit 1, and 4 is connected to the outdoor unit 1. The indoor units (C) and 6 to 8 are indoor / outdoor connection lines that share the power line and the communication line between the outdoor unit 1 and the indoor units (A) 2 to (C) 4.
Reference numeral 20 denotes an outdoor unit control unit that transmits and receives control information to and from each indoor unit via the communication circuit 213, and 22 denotes an indoor unit (A) 2 to (C) 4 and an unillustrated unit. A transmission circuit for transmitting each control information to the indoor unit, 21 a reception circuit for receiving control information from the indoor units (A) 2 to (C) 4 and an indoor unit (not shown), and 213 a transmission circuit 22 and reception The outdoor unit communication circuit 30 constituted by the circuit 21 is provided in the indoor units (A) 2 to (C) 4 and an indoor unit (not shown), and transmits / receives control information to / from the outdoor unit via the communication circuit 223. , An indoor unit control unit for controlling the operation of each indoor unit, 32 a transmission circuit for transmitting each control information to the outdoor unit 1, 31 for a reception circuit for receiving control information from the outdoor unit 1, and 223 for a transmission circuit Indicating the indoor unit communication circuit constituted by 2 and the receiving circuit 31.
[0068]
FIG. 23 shows an example of normal communication operation when operating control information is transmitted and received between the indoor unit and the outdoor unit when there are three indoor units (A) 2 to (C) 4 connected to the outdoor unit 1. It is a timing chart which shows an example.
When the indoor units (A) 2 to (C) 4 receive the control information (data 10) from the outdoor unit, the indoor units (A) 2 to (C) 4 sequentially transmit response data (data 11 to 13) according to the set own unit identification number. At this time, for example, if the indoor unit (C) 4 is set to the identification number 1, the indoor unit (A) 2 is set to the identification number 2, and the indoor unit (B) 3 is set to the identification number 3,
The indoor unit (C) 4 receives the response data (data 11) when T1 elapses after receiving the data 10, the indoor unit (A) 2 receives the response data (data 12) when T2 elapses after the data 10 is received, and the indoor unit (B) 3 Response data (data 13) is transmitted in order when T3 elapses after data 10 is received. In addition, when T0 elapses after data 10 is received, all indoor units end the transmission process and shift to the reception process.
The outdoor unit transmits the next control data (data 20) when T0 elapses after the data 10 is transmitted. The transmission timing T0 of the outdoor unit at this time is set based on the transmission time per indoor unit according to the number of indoor units connected by the connected number setting means.
The communication operation described above is an example in which an inexpensive communication circuit that cannot transmit / receive between indoor units is used, and is not limited thereto.
[0069]
Next, the operation will be described with reference to the flowcharts of FIGS. 24 and 25 and the timing chart of FIG. In this embodiment, the case where the predetermined logical code is “1” will be described. However, the predetermined logical code may be “0” or a combination of “1” and “0”.
FIG. 24 is a flowchart showing the operation of the indoor unit connected number setting means in the outdoor unit.
In the figure, the outdoor unit 1 is connected to the indoor unit ((A) 2 to (C) 4 and an indoor unit not shown) in the indoor / outdoor connection by the transmission circuit 22 in step S101 after the power is turned on. Transmit via lines 6-8. Wait until the identification code from the indoor unit is received in step S102, and when the identification code is received by the receiving circuit 21 via the indoor / outdoor connection lines 6 to 8, a predetermined logical code of the identification code received in step S103 (In the present embodiment, the number of logic “1”) is counted. Steps S101 to S103 are repeated until it is determined in step S104 that the identification code has been received a predetermined number of times n1, and if it is determined that the identification code has been received a predetermined number of times n1, the process proceeds to step S105. Of the number of logic “1” counted in S103, the maximum value among n1 executions is calculated. The maximum value of the number of logic “1” is divided by the constant value m1 in step S106, and the divided quotient is set to the number of connected indoor units connected to the own unit in step S107.
[0070]
Here, the logic “1” is set so that the outdoor unit 1 receives the logic “1” at the receiving circuit 21 when a plurality of indoor units transmit the logic “1” and the logic “0” at the same time. It means that the code is made.
[0071]
FIG. 25 is a flowchart showing the operations of the identification code setting means and the identification code transmission means in the indoor unit. Steps S111 and S112 show the operation of the identification code setting means, and steps S113 and S114 show the operation of the identification code transmission means.
In the figure, the indoor units (A) 2 to (C) 4 and the indoor unit (not shown) wait for an identification code request from the outdoor unit 1 in step S111 after the power is turned on. When the receiving circuit 31 receives the identification code request via .about.8, in step S112, the identification code is set so that the number of logic "1" of the code string to be transmitted becomes a constant value m1. This constant value m1 is the same as the constant value m1 in step S106 of the outdoor unit shown in FIG. The identification code is arbitrarily set by, for example, a random number, a calculation from a timer count value of the microcomputer, etc. every time an identification code request is received from the outdoor unit 1 in step S111. In step S113, the system waits until the transmission timing of the identification code is reached. When the transmission timing of the identification code is reached, in step S114, the transmission unit 22 transmits the identification code through the indoor / outdoor connection lines 6 to 8 to the outdoor unit 1. Send to. Here, the transmission timing of the identification code in step S113 is, for example, when a certain period of time has elapsed after receiving a signal from the outdoor unit 1 so that the transmission timings of all the indoor units are the same.
[0072]
FIG. 26 shows the operation when the number (m1) of the identification code logic “1” is 2 and the number of indoor units (A) 2 to (C) 4 connected to the outdoor unit 1 is three. It is a timing chart which shows.
The outdoor unit transmits an identification code request signal (signal 101) by the transmission circuit 22 via the indoor / outdoor connection lines 6-8. (FIG. 24, step S101)
The indoor units (A) 2 to (C) 4 set the identification code so that the number of logic “1” s of the code string to be transmitted becomes a constant value 2 by the identification code setting means (step S112 in FIG. 25). In the identification code transmission means (step S114 in FIG. 25), for example, the outdoor unit 1 transmits an “identification code request” as shown in FIG. Sometimes the identification code is transmitted from bit 1 at the same time. (Signals 102-104)
The outdoor unit receives the logical sum code / signal 105 of the identification code by the receiving circuit 21 via the indoor / outdoor connection lines 6 to 8 (step S102 in FIG. 24), and automatically sets the number of indoor unit connections (step S103 in FIG. 24). To S107), the number of connected indoor units is set.
In the present embodiment, the number of logic “1” s of the counted signal 105 is 6 (step S105), and the quotient is 3 when dividing by a constant value 2 (step S106), so that it is connected to its own unit. The number of indoor units connected is set to 3 (step S107).
[0073]
In this embodiment, the identification code is set so that the number of logical “1” s in the code string is a constant value m1 = 2 in step S112. However, when the constant value m1 = 1, the outdoor unit In step S106 in FIG. 24, the quotient obtained by dividing the maximum value of the number of received logic “1” s by 1 is set as the number of connected units, so the maximum value of the number of received logic “1” s is the number of connected units.
Moreover, although the identification code is repeatedly transmitted and received n1 times, it is possible to reduce the probability of erroneous setting of the number of connected devices by increasing n1. In addition, by increasing the number m1 of the identification code logic “1”, the probability that the identification codes arbitrarily set by all the indoor units by random numbers or the like are reduced, and the probability of erroneous setting of the number of connected units is further reduced. Is possible.
[0074]
Further, in this embodiment, after the outdoor unit 1 transmits the “identification code request”, when the predetermined time t has elapsed, the indoor unit transmits the identification code from bit 1 at the same time. Instead of receiving the “identification code request”, it may be transmitted simultaneously at regular intervals from the time of power-on.
[0075]
Next, another embodiment will be described with reference to FIGS. In this embodiment, as in the embodiment corresponding to claim 14, a case where the predetermined logical code is "1" will be described.
FIG. 27 is a flowchart showing the operations of the indoor unit connection number setting means, the indoor unit identification number setting means, the number of connected units, the identification number, and the identification code transmission means in the outdoor unit according to claim 15. Steps S201 to S206 indicate indoor unit connection number setting means, steps S207 to S211 indicate indoor unit identification number setting means, and step S212 indicates connection number, identification number, and identification code transmission means.
In the figure, after the power is turned on, the outdoor unit 1 sends an identification code request to the indoor units ((A) 2 to (C) 4 and an indoor unit not shown) in step S 201 by the transmission circuit 22. Transmit via 6-8. Wait until the identification code is received from the indoor unit in step S202, and when the reception circuit 21 receives the identification code via the indoor / outdoor connection lines 6-8, the logic "1" of the identification code received in step S203. Count the number of Steps S201 to S203 are repeatedly performed until it is determined in step S204 that the identification code has been received n1 times. If it is determined that the identification code has been received n1 times, step S205 is performed. The maximum value of the number of logic “1” counted in 203 is calculated. In step S206, the maximum value of the number of logic “1” is set to the number of connected indoor units connected to the own unit.
When the number of indoor units connected is set in step S206, an identification code request is sent to the indoor units ((A) 2 to (C) 4 and indoor units not shown) by the transmission circuit 22 in step S207. Transmit via connection lines 6-8. Wait until the identification code from the indoor unit is received in step S208, and when the reception circuit 21 receives the identification code via the indoor / outdoor connection lines 6 to 8, the logic "1" of the identification code received in step S209. Count the number of In step S210, the number of counted logical “1” and the number of connected indoor units set in step S206 are compared. If they match, an identification number is set in step S211. At this time, the identification number is set, for example, in ascending order of the identification code. In step S212, the number of indoor units connected and the identification number set in step S206 and step S211 and the identification code last received from each indoor unit are indicated in step S212. Send to indoor unit. As a result of comparing the number of logic “1” with the number of connected indoor units in step S210, if they do not match, the process repeats the identification code request transmission in step 207.
[0076]
FIG. 28 is a flowchart showing the operations of the identification code setting means, the identification code transmission means, the transmission identification code storage means, and the own unit identification number setting means in the indoor unit. Steps S221 and S222 indicate the operation of the identification code setting means, steps S223 and S224 indicate the identification code transmission means, step S225 indicates the transmission identification code storage means, and steps S226 to S229 indicate the operation of the own unit identification number setting means.
In the figure, the indoor units (A) 2 to (C) 4 and the indoor unit (not shown) receive the identification code request from the outdoor unit 1 by the receiving circuit 31 in step S221 after power-on, and then in step S222. The identification code is set so that the number of logic “1” s in the code string to be transmitted is 1. The identification code is arbitrarily set by, for example, a random number, a calculation from a timer count value of the microcomputer, etc. every time an identification code request is received from the outdoor unit 1 in step S221. In step S223, the process waits until the transmission timing of the identification code is reached. When the transmission timing of the identification code is reached, the identification code is transmitted to the outdoor unit 1 by the transmission circuit 32 in step S224, and the transmitted identification code is transmitted in step S225. And return to step S221. Steps S221 to S225 are repeated until it is determined in step S221 that the identification code request from the outdoor unit 1 has not been received and the number of connected units, the identification number, and the identification code from the outdoor unit 1 have been received in step S226. . At this time, the identification code stored in step S225 is updated every time the identification code is transmitted in step S224. If it is determined in step S226 that the number of connected units, the identification code, and the identification code are received from the outdoor unit 1, the received data is analyzed in step S227, and the identification code of the data received in step S228 is determined by the local unit. It is determined whether or not it matches the previously transmitted identification code (identification code stored in step S225), and if it matches, the identification number received from the outdoor unit 1 with the same data as the identification code in step S229 is Set to the identification number. If they do not match, the process returns to step S221.
Each indoor unit controls its own unit based on the number of connected indoor units and the identification number transmitted from the outdoor unit 1.
[0077]
FIG. 29 is a timing chart showing the operation when there are three indoor units (A) 2 to (C) 4 connected to the outdoor unit 1.
The outdoor unit 1 transmits an identification code request signal (signal 201) via the indoor / outdoor connection lines 6 to 8 by the transmission circuit 22. (FIG. 27, step S201 or step S207) The indoor units (A) 2 to (C) 4 are set to a constant value 1 by the identification code setting means (step S222 in FIG. 28). The identification code is set so that the transmission start timing of all the indoor units is synchronized with the identification code transmission means (step S224 in FIG. 28). When a certain time t has elapsed after transmitting the identification code, the identification code is transmitted from bit 1 at the same time. (Signals 202-204)
The outdoor unit receives the logical sum code (signal 205) of the identification code by the receiving circuit 21 via the indoor / outdoor connection lines 6 to 8, and the indoor unit connection number automatic setting means (steps S201 to S206 in FIG. 27) The number of indoor units connected is set, and the identification number of each indoor unit is set by the indoor unit identification number setting means (steps S207 to S211 in FIG. 27).
In this embodiment, assuming that the signal when the outdoor unit 1 calculates the maximum value of the number of logic “1” in step S205 of FIG. 27 is FIG. 29, the number of logic “1” of the counted signal 205 is Since it is 3 (step S205), the number of indoor units connected to its own unit is set to 3 (step S206). Assuming that the outdoor unit 1 receives the same signal as in FIG. 29 again in step S208 in FIG. 27 after setting the number of connected units, the count number of logic “1” of the signal 205 is 3 (step S209), and is obtained in step S206. Therefore, the identification number is set in step S211. For example, identification numbers 1, 2, and 3 are set in order from the unit with the lowest bit position number of the logic “1” of the transmitted identification code. In this embodiment, the identification number / signal 202 is transmitted with the identification number 1 of the indoor unit (C) 4 that has transmitted the identification code / signal 204 with bit number 3 as logic “1” and the bit number 11 as logic “1”. The identification number of the indoor unit (B) 3 that has transmitted the identification code / signal 203 is set to 3 with the identification number of the indoor unit (A) 2 set to 2 and the bit number 12 set to logic “1”.
[0078]
In this embodiment, the identification code is set so that the number of logic “1” s in the code string transmitted by the indoor unit is 1. However, when the outdoor unit sets the number of connected units (steps S201 to S206 in FIG. 27). ), The number of logic “1” s of the identification codes transmitted by the indoor units is set to be a constant value m1 (m1 ≧ 2), and the outdoor unit sets the identification number (steps S207 to S211 in FIG. 27). ) If the number of identification code logic “1” s transmitted by the indoor unit is set to 1 as in this embodiment, the number of identification code transmission / reception times when the outdoor unit sets the number of connected units. Without increasing n1, the probability of erroneous setting of the number of indoor units connected can be reduced, and the start-up time can be shortened. In this case, in the outdoor unit, the same processing as that in step S106 in FIG. 24 is added between the processing in steps S205 and S206 in FIG. In addition, the processing of the indoor units differs depending on whether the outdoor unit sets the number of indoor unit connections and when the indoor unit identification number is set.
When the constant value m1 = 1 is set as in the present embodiment, the processing of the indoor unit is common when the outdoor unit sets the number of indoor units connected and when the indoor unit identification number is set, thus simplifying. it can. In this case, it is possible to reduce the probability of erroneous setting of the number of connected indoor units by increasing the number n1 of transmission / reception of the identification code.
[0079]
Here, as in the embodiment of the air conditioner, the logic “1” means that when a plurality of indoor units transmit logic “1” and logic “0” at the same time, the outdoor unit 1 receives the logic “ It means a code set to receive 1 ″.
[0080]
Next, another embodiment will be described with reference to FIGS. In the present embodiment, as in the other embodiments, a case where a predetermined logical code is set to “1” will be described.
FIG. 30 is a flowchart showing the operations of the indoor unit connected number setting means, the indoor unit identification number setting means, the connected number, identification number and identification code transmission means, and the indoor unit identification number duplication detection means in the outdoor unit. Step S301 is an indoor unit connected number setting means, Step S302 is an indoor unit identification number setting means, Step S303 is a connected number, identification number and identification code transmitting means, and Steps S304 to S308 are indoor unit identification number duplication detecting means. Shows the operation.
In the figure, the outdoor unit 1 sets the number of indoor units connected in step S301 after power is turned on, and in step S302, each indoor unit ((A) 2 to (C) 4 and indoor units not shown) is set. Set the identification number. The detailed contents of step S301 are the same as steps S101 to S107 or FIG. 27 steps S201 to S206 of FIG. 24, and the detailed contents of step S302 are the same as steps S207 to S211 of FIG. After setting the identification number of each indoor unit in step S302, the number of indoor units connected, the identification number, and the identification code received last from each indoor unit are determined in step S303. ) 4 and the indoor unit not shown. After transmitting the number of connected units and the identification number, in step S304, a duplicate detection code request is individually transmitted to the indoor unit with the identification number 1 through the indoor / outdoor connection lines 6 to 8 by the transmission circuit 22. It waits until it receives the duplication detection code from the indoor unit with the identification number 1 in step S305, and when the duplication detection code is received by the receiving circuit 21 via the indoor / outdoor connection lines 6-8, the duplication received in step S306. The number of logic “1” of the detection code is counted, and if it is determined in step S307 that the number of logic “1” exceeds a certain number m2, the process returns to step S301 and starts again from the setting of the number of connected units. If the number of logic "1" does not exceed the predetermined number m2, the steps S304 to S307 are repeated until it is determined in step S308 that the duplicate detection code has been received a predetermined number of times n2. Is determined to have been received a predetermined number of times n2, the duplication detection process for the indoor unit with identification number 1 is terminated. Steps S304 to S308 are repeated for the number of connected indoor units from the indoor unit with identification number 1. When steps S304 to S308 have been completed for all units, in step S309, the operation is shifted to normal operation control as completion of startup.
[0081]
FIG. 31 is a flowchart showing the operations of the identification code setting means, the identification code transmission means, the transmission identification code storage means, the own unit identification number setting means, and the duplicate detection code setting means in the indoor unit. Steps S321 and S322 are identification code setting means, Step S323 is identification code transmission means, Step S324 is transmission identification code storage means, Steps S325 to S326 are own unit identification number setting means, and Steps S327 and S328 are duplicate detection. The operation of the code setting means will be shown.
In the figure, after the power is turned on, the indoor unit receives an identification code request from the outdoor unit 1 in step S321, sets an identification code in step S322, and assigns an identification code to the outdoor unit 1 in step S323. In step S324, the transmitted identification code is stored, and the process returns to step S321. The identification code setting process in step S322 is the same as step S222 in FIG. 28, the identification code transmission process in step S323 is the same as steps 223 to S224 in FIG. 28, and the identification code storage process in step S324 is the same as step S225 in FIG. If the identification code request from the outdoor unit 1 is not received in step S321 and the number of connected units, the identification number, and the identification code are received from the outdoor unit 1 in step S325, the received identification number is determined in step S326. The own unit identification number is set, and the process returns to step S321. The own unit identification number setting process in step S326 is the same as that in steps S227 to S229 in FIG. If the number of connected units, the identification number, and the identification code are not received in step S325 and a duplicate detection code request is received from the outdoor unit 1 in step S327, the number of logical "1" is set as the duplicate detection code in step S328. For example, a random number or a calculation from a timer count value of the microcomputer is arbitrarily set so as to be a constant value m2, and the data is transmitted to the outdoor unit 1 in step S329, and the process returns to step S321. In the duplicate detection code setting process in step S328, the duplicate detection code is set every time a duplicate detection code request is received from the outdoor unit 1 in step S327. If the duplicate detection code request is not received in step S327 and the startup completion data is received in step S330, the startup process is completed in step S331, and normal operation control is performed. If startup completion data is not received in step S330, the process returns to step S321. The start-up completion data does not need to be special data, and may be normal operation control data.
[0082]
As described above, since the indoor unit arbitrarily sets the duplicate detection code so that the number of logic "1" becomes the constant value m2 and transmits it to the outdoor unit 1 in step S328, the indoor unit identification number is duplicated. Otherwise, the number of logical “1” s of the duplicate detection codes received by the outdoor unit 1 is m2, and if multiple indoor units are set to be duplicated in the same identification number, the duplicate detection code received by the outdoor unit 1 The number of logic “1” s of these is greater than m 2, and the outdoor unit can detect the duplicate setting in step S307.
[0083]
Also, by increasing the number m2 of the logic “1” of the duplication detection code, the probability that the duplication detection code arbitrarily set by all the indoor units by a random number or the like decreases, and the duplication detection probability of the indoor unit identification number is reduced. It is possible to raise.
Here, as in the embodiment of the multi-type air conditioner according to claims 1 and 2, the logic “1” means that when a plurality of indoor units transmit logic “1” and logic “0” simultaneously, It means a code that is set so that the unit 1 receives logic “1” in the receiving circuit 21.
[0084]
Next, another embodiment will be described with reference to FIGS.
FIG. 32 is a block diagram showing an outdoor unit control apparatus using an embodiment of an air conditioner. In the figure, 214 is a non-volatile memory for storing the set number of indoor unit connections.
FIG. 33 is a flowchart showing the operations of the indoor unit connected number setting means, the indoor unit identification number setting means, the connected number, identification number and identification code transmission means, and the indoor unit identification number duplication detection means in the outdoor unit.
In FIG. 33, after determining that the outdoor unit stores the number of indoor unit connections in the nonvolatile memory 214 after turning on the power, the indoor unit connection number setting process in step S402 is not performed. The indoor unit identification number setting process in S403, the number of connected units, the identification number and identification code transmission process in step S404, and the indoor unit identification number duplication detection process in step S405 are executed. If no duplication is detected, start-up is completed in step S406. To normal operation control. If duplication is detected, the process returns to step S402.
If it is determined in step S401 that the number of indoor unit connections is not stored in the nonvolatile memory 214, the processing is executed from the indoor unit connection number setting process in step S402 to the indoor unit identification number duplication detection process in step S405. As the start-up is completed, the operation shifts to normal operation control.
The indoor unit connected number setting process in step S402 is in step S301 in FIG. 30, the indoor unit identification number setting process in step S403 is in step S302 in FIG. 30, and the connected number, identification number and identification code transmission process in step S404 is in step S303 in FIG. Moreover, the indoor unit identification number duplication detection process in step S405 is the same as that in steps S304 to S308 in FIG.
[0085]
Next, in the air conditioner, the operation when the number of connected indoor units is once changed and the power is turned on again after changing the number of connected indoor units will be described.
First, a case where more indoor units are connected than the number of indoor units connected stored in the nonvolatile memory 214 will be described. Since the outdoor unit 1 determines that the number of indoor unit connections is stored in the nonvolatile memory 214 in step S401 after the power is turned on, the indoor unit connection number setting process in step S402 is not performed, and the indoor unit in step S403 is not executed. The unit identification number setting process is performed. However, since the number of indoor units is large, a larger number of logic “1” than the stored number of connected indoor units is received. In this case, the number of received logical “1” is set as the number of indoor unit connections, the indoor unit identification number setting process in step S403 is redone, and then the connected number, identification number and identification code transmission process in step S404, step The indoor unit identification number duplication detection process of S405 is performed, and if no duplication is detected, the start-up is completed in step S406 and the routine proceeds to normal operation control. If duplication is detected, the process returns to step S402.
[0086]
Next, the case where the number of indoor units connected is smaller than the number of indoor units connected stored in the nonvolatile memory 214 will be described. Since the outdoor unit 1 determines that the number of indoor unit connections is stored in the nonvolatile memory 214 in step S401 after the power is turned on, the indoor unit connection number setting process in step S402 is not performed, and the indoor unit in step S403 is not executed. The unit identification number setting process is performed, but since the number of indoor units is small, a smaller number of logic “1” is continuously received than the stored number of connected indoor units. If this state continues until the transmission / reception of the identification code is performed n3 times, the indoor unit connected number setting process in step S402 is performed, the indoor unit identification number setting process in step S403 is performed again, and then the connection in step S404 is performed. The number, identification number and identification code transmission processing, and the indoor unit identification number duplication detection processing in step S405 are performed. If no duplication is detected, the operation is shifted to normal operation control as completion of startup in step S406. If duplication is detected, the process returns to step S402.
Thus, even when the number of indoor units connected to a unit once installed is changed, the number of indoor unit connections can be set reliably.
[0087]
Next, another embodiment will be described with reference to FIGS.
FIG. 34 is a block diagram showing an indoor unit control apparatus using an embodiment of an air conditioner. In the figure, 224 is a non-volatile memory for storing the set indoor unit identification number.
FIG. 35 is a flowchart showing the operations of the identification code setting means, the identification code transmission means, the transmission identification code storage means, the own unit identification number setting means, and the duplicate detection code setting means in the indoor unit. Steps S501 to S504 are identification code setting means, steps S505 and S506 are identification code transmission means, step S507 is a transmission identification code storage means, steps S508 and S509 are own unit identification number setting means, and steps S510 and S511 are steps. The operation of the duplicate detection code setting means is shown.
In the figure, when the indoor unit receives the identification code request from the outdoor unit 1 in step S501 after power is turned on, if it is determined in step S502 that the identification number of the own unit is not stored in the nonvolatile memory 224, In step S503, an identification code is newly created, and in step S504, the identification code to be transmitted is set. If it is determined in step S502 that the identification number of the own unit is stored in the nonvolatile memory 224, the new identification code creation process in step S503 is not performed, and the identification number stored in the nonvolatile memory 224 is not stored. A uniquely determined identification code is set in step S504.
For example, if the stored identification number is 1, only the bit position 1 is logical “1”, if the identification number is 2, only the bit position 2 is logical “1”... The identification code is set so as to be logic “1”. In this case, in the new creation process of the identification code in step S503, the codes are created so that the bit positions 1 to i are logic “0” and the bit positions i + 1 and later are logic “1”.
When the identification code is set in step S504, when the transmission timing comes in step S505, the identification code is transmitted to the outdoor unit 1 in step S506, and the identification code transmitted in step S507 is stored. Return to.
In step S501, the processing (steps S508 to S514) when the identification code request from the outdoor unit 1 is not received is the same as steps S325 to S331 in FIG.
[0088]
Thus, when the indoor unit stores its own identification number in the nonvolatile memory 224, once the identification code is uniquely determined for the stored identification number and transmitted to the outdoor unit, If the outdoor unit performs the indoor unit identification number setting process again when the power is turned off and then turned on again, the identification number of each indoor unit is not changed.
[0089]
FIG. 36 shows the operation when the indoor unit does not store the identification number of its own unit in the nonvolatile memory 224 when there are three indoor units (A) 2 to (C) 4 connected to the outdoor unit 1. FIG. 37 is a timing chart showing the operation when the indoor unit stores the identification number of its own unit in the nonvolatile memory 224.
For example, if the maximum number of indoor units that can be connected is four, the identification code when the identification number is stored in the nonvolatile memory 224 is set to the logical “1” in the bit positions 1 to 4. When the identification number is not stored, the identification code after bit position 5 is used. When the nonvolatile memory 224 does not store the identification number, the signal is as shown in FIG.
Based on the signal 505 received by the outdoor unit 1, the identification number of the indoor unit (C) 4 that transmitted the identification code / signal 504 with bit number 5 as logic “1” is identified as 1, and the bit number 7 is identified as logic “1”. The identification number of the indoor unit (A) 2 that transmitted the code / signal 502 is set to 2 and the identification number of the indoor unit (B) 3 that transmitted the identification code / signal 503 is set to 3 with the bit number 10 set to logic “1”. If
The identification code transmission / reception when the power is turned on again is as shown in FIG. 37. Based on the signal 515 received by the outdoor unit 1, the indoor unit (C ) The identification number / signal of the indoor unit (A) 2 that transmitted the identification code / signal 512 with the identification number 4 as 1 and the bit number 2 as logic “1”, and the identification number / signal as 2 with the identification number 2 and bit number 3 as the logic “1” Since the identification number of the indoor unit (B) 3 that has transmitted 513 is set to 3, there is no change from the setting at the time of installation.
For this reason, for example, when an abnormality occurs in an indoor unit, the identification number of the unit in which the abnormality has occurred is displayed on the remote controller, etc., and the fan of the corresponding indoor unit is controlled during self-diagnosis, Even when the identification number set for an indoor unit is displayed to notify the unit with the abnormality, the identification number of that unit, and the content of the abnormality, the identification number of the indoor unit changes each time the power is reset. This will not cause confusion during service.
[0090]
A case where this embodiment is applied to an air conditioner in which the number of indoor units connected to the outdoor unit is known will be described with reference to FIG.
Since the number of indoor units is known, it is the same when it is determined in step S401 that the number of indoor unit connections is stored in the nonvolatile memory 214, and the indoor unit connection number setting process in step S402 is not performed.
For example, when two or more indoor units are mistakenly connected to an air conditioner in which the number of indoor units is set to one, the outdoor unit 1 performs the indoor unit identification number setting process in step S403 after turning on the power. The number of logical “1” s larger than the number of connected indoor units (1 unit) is received. In this case, since it is an erroneous setting, the start-up process is terminated, and it is possible to prompt correction by notifying the erroneous setting using a display unit such as a remote controller or an LED on the board. If the same number of logic “1” is received for the number of indoor unit connections (1 unit) in the indoor unit identification number setting process in step S403, the indoor unit identification number setting process in step S403 and the number of connected units in step S404. , The identification number and identification code transmission process, and the indoor unit identification number duplication detection process in step S405 are carried out, and if no duplication is detected, the start-up is completed in step S406 and the routine proceeds to normal operation control. If duplication is detected, the process returns to step S402.
If the known number of indoor unit connections is other than 1, the number of logical “1” greater than the number of indoor units connected or the number of logical “1” less than the number of indoor units connected in the indoor unit identification number setting process in step S403. When it is received, it is an incorrect setting, so it is possible to terminate the start-up process and notify the user of the incorrect setting by using a remote control, display means such as an LED on the board, etc. It becomes.
Here, the number of indoor unit connections stored in the outdoor unit is programmed in advance or stored in advance in a nonvolatile memory. Alternatively, it may be set by a switch or the like.
In this way, when applied to an air conditioner with a known number of indoor units, it can be reliably detected when the startup time is short and the number of connected indoor units is incorrect, and a notification is given by a display means or the like. Serviceability is improved by doing so.
[0091]
Also, even if the number of indoor units is unknown, if the maximum number of connected units is determined, if the indoor units are connected beyond the maximum number of connected units, an incorrect connection is detected and displayed on the display means, etc. Notification can be made, and serviceability can be improved.
[0092]
【The invention's effect】
As described above, the air conditioner according to the first aspect of the present invention is capable of multi-operation based on the same command even when many indoor units having different types of functions are used. Can provide a system.
[Brief description of the drawings]
FIG. 1 is an overall configuration block diagram of a multi-type air conditioner according to first to fifth embodiments of the present invention.
FIG. 2 is a block diagram showing a control unit of the outdoor unit of FIG.
FIG. 3 is a block diagram showing a control unit of the indoor unit of FIG. 1;
4 is a block diagram showing a control unit of the wired-type local remote controller of FIG. 1. FIG.
FIG. 5 is a flowchart showing the operation of the indoor unit of FIG.
FIG. 6 is a flowchart showing the outdoor unit operation of FIG.
FIG. 7 is an overall configuration block diagram of another multi-type air conditioner of the present invention.
FIG. 8 is a block diagram showing a control unit of the outdoor unit of FIG.
FIG. 9 is a block diagram showing a control unit of the outdoor unit of the multi-type air conditioner according to the present invention.
FIG. 10 is a block diagram showing a control unit of a wired remote controller of the multi-type air conditioner of the present invention.
FIG. 11 is a block diagram showing a control device for outdoor and indoor units of an air conditioner according to the present invention.
12 is a flowchart showing the operation of the control device shown in FIG.
FIG. 13 is a block diagram showing a control device for an indoor unit of an air conditioner according to the present invention.
FIG. 14 is a block diagram showing an outdoor unit control device corresponding to FIG. 13;
15 is a block diagram showing the configuration of a remote control device corresponding to FIG. 13; FIG.
FIG. 16 is a flowchart showing the operation of the indoor unit control apparatus corresponding to FIG. 13;
FIG. 17 is a flowchart showing the operation of the outdoor unit controller corresponding to FIG. 13;
FIG. 18 is a block diagram showing a remote controller of the present invention.
19 is an external view simulating the actual shape of the remote control of FIG.
FIG. 20 is a block diagram showing the configuration of the indoor unit controller according to the present invention.
FIG. 21 is a flowchart showing the operation of the indoor unit control device of FIG. 20;
FIG. 22 is a block diagram showing the configuration of a control device for an air conditioner according to the present invention.
FIG. 23 is a timing chart showing a normal communication operation between the control devices for the indoor and outdoor units shown in FIG. 22;
FIG. 24 is a flowchart showing the operation of the indoor unit connected number setting means in the outdoor unit of the air conditioner of the present invention.
FIG. 25 is a flowchart showing the operations of the identification code setting unit and the identification code transmission unit in the indoor unit of the air conditioner of the present invention.
FIG. 26 is a timing chart showing the operation of the outdoor unit and the indoor unit of the air conditioner according to the present invention.
FIG. 27 is a flowchart showing the operation of the outdoor unit of the air conditioner of the present invention.
FIG. 28 is a flowchart showing an operation in the outdoor unit of the air conditioner of the present invention.
FIG. 29 is a timing chart showing the operations of the outdoor unit and the indoor unit of the air conditioner.
FIG. 30 is a flowchart showing an operation in the outdoor unit of the air conditioner of the present invention.
FIG. 31 is a flowchart showing an operation in the indoor unit of the air conditioner of the present invention.
FIG. 32 is a structural block diagram showing a control device for an outdoor unit of an air conditioner according to the present invention.
FIG. 33 is a flowchart showing the operation of the outdoor unit of the air conditioner of the present invention.
FIG. 34 is a configuration block diagram showing a control device for an indoor unit of an air conditioner according to the present invention.
FIG. 35 is a flowchart showing an operation in the indoor unit of the air conditioner of the present invention.
FIG. 36 is a timing chart showing operations of the outdoor unit and the indoor unit of the air conditioner according to the present invention.
FIG. 37 is a timing chart showing operations of the outdoor unit and the indoor unit of the air conditioner according to the present invention.
FIG. 38 is a system diagram of a conventional operation multi-type air conditioner.
FIG. 39 is a block diagram showing a conventional centralized control system for an air conditioner.
[Explanation of symbols]
1 outdoor unit, 2 indoor unit (A), 3 indoor unit (B), 4 indoor unit (C), 5 remote controller, 6 transmission line between outdoor unit and indoor unit (A), 7 outdoor unit and indoor unit ( Transmission line between B), 8 Transmission line between outdoor unit and indoor unit (C), 9 Transmission line between remote control and indoor unit (A), 10 Wireless type local remote control, 11 Transmission converter, 12 Outdoor unit , 13, 14 indoor unit, 15 hand remote control, 16 air conditioning management device, 20 outdoor unit control unit, 21 indoor / outdoor communication receiving unit, 22 indoor / outdoor communication transmitting unit, 23 air conditioning unit operation setting unit, 24 outdoor unit processing unit, 30 indoor unit control unit, 31 indoor / outdoor communication receiving means, 32 indoor / outdoor communication transmitting means, 33 remote control communication receiving means, 34 remote control communication transmitting means, 35 36, indoor unit processing unit, 37 wireless signal receiving unit, 40 remote control unit, 41 remote control communication receiving unit, 42 remote control transmission unit, 43 remote control processing unit, 71 remote control function setting unit, 81 function setting unit 311 Unit control unit, 312 Self unit model setting means (outdoor unit), 313 Self unit model storage means, 314 All model function storage means, 315 Self unit model setting means, 121 Indoor unit control unit, 122 Self unit model setting means , 123 Self unit model storage means, 124 All model function initial value storage means, 125 Self unit function setting means, 126 Self unit function storage means, 127 Remote control communication means, 128 Indoor / outdoor communication means, 131 Outdoor unit control section, 132 Self Unit model setting means, 133 Model model storage means, 134 all model function initial value storage means, 135 all model function initial value storage means, 141 remote control control unit, 142 remote control communication means, 143 unit function display means, 144 unit function setting change means, 213 communication circuit (Outdoor unit), 214 non-volatile memory (outdoor unit), 223 communication circuit (indoor unit), 224 non-volatile memory (indoor unit).

Claims (1)

A transmission means for transmitting information between the outdoor unit, the outdoor unit and an indoor unit connected to the outdoor unit, an operation command means connected to at least one of the indoor units and setting operation details, and the outdoor unit Collecting facility function information of the indoor units provided and connected to the units, determining operation contents that can be set for operation of all connected indoor units from the facility function information of the indoor units, and transmitting the transmission means Via the control means for transmitting the determined operation content to each indoor unit via the at least one of the indoor unit or the operation command means, and the operation-setting operation content transmitted from the control means is transmitted to a specific indoor unit. the operable operation content of the indoor unit or the operation command means is not limited to the equipment function information of the unit itself Air conditioner characterized by comprising an operation function setting means for setting.

Images