JP3742926B2 - Air conditioning management device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an air conditioner management apparatus that manages a plurality of air conditioners connected to at least one outdoor unit.
[0002]
[Prior art]
  2. Description of the Related Art Conventionally, there is known an air conditioning management system that manages an air conditioning apparatus having a plurality of refrigerant systems having a plurality of indoor air conditioners and one outdoor unit. In such an air conditioning management system, parameters (coefficients) as eigenvalues depending on the type of air conditioner to be managed may be prepared for each model in advance, and air conditioner data setting processing may be performed.
[0003]
  For example, in the power apportioning process for obtaining the power cost of each air conditioner, a plurality of parameters for setting the power load as the data of each air conditioner is prepared in advance in a database for each model, for example, and the model retrieved from the database The power load of the model is set from the parameters. Then, the power consumption of the outdoor unit is apportioned with the set power load to calculate the electricity cost of each air conditioner.
[0004]
  In the process of preparing data according to the model in advance and setting the data, when the parameter is not prepared in advance for a new model or the like, the parameter of the existing model with similar performance is corrected and used.
[0005]
[Problems to be solved by the invention]
  When the parameters of an existing model are modified and used, there is no problem if the parameters are modified appropriately. However, if the parameters are corrected by mistake, problems may occur during the trial run of the new model used. For example, if the power load is set with incorrect parameters in the power apportioning process, the calculated electricity bill will be inaccurate and may cause problems that may cause complaints from customers. There is.
[0006]
  Therefore, when a malfunction occurs during the trial run, the cause is pursued, but it is difficult to determine whether the malfunction is caused by a parameter correction error or due to another cause. Also, if there is an error in parameter correction, the problem cannot be resolved unless the parameter before correction and the parameter after correction are compared one by one. For this reason, when the parameters of an existing model are corrected and used, it may take a long time to investigate the cause of the malfunction.
[0007]
  An object of the present invention is to provide an air conditioning management device that facilitates investigation of the cause of a failure when data setting processing is performed by correcting parameters for air conditioner management.
[0008]
[Means for Solving the Problems]
  An air conditioning management apparatus according to claim 1 is an air conditioning management apparatus that manages a plurality of air conditioners connected to at least one outdoor unit, and includes first information holding means, correction means, and second information holding means. WhenAnd display meansIt has. The first information holding means is means for holding information on the power load coefficient for each air conditioner. The “power load coefficient” here is a coefficient for calculating the power load of each air conditioner. The correcting means is means for correcting the power load coefficient information held in the first information holding means. The second information holding means is means for holding correction information indicating that the correction is made when the content held in the first information holding means is corrected by the correction means.The display means displays the name of the air conditioner, information on the power load coefficient, and correction information. When the information on the power load coefficient is corrected by the correction means, the display means displays the correction information in the display column for the name of the air conditioner, and displays the name of the air conditioner in another field.
[0009]
  In this air conditioning management device, the information on the power load coefficient is held in the first holding means. When the information on the power load coefficient held in the first holding unit is corrected by the correcting unit, the correction information is held in the second information holding unit.Then, when the information on the power load coefficient is corrected by the correcting means, the display means displays the correction information in the display column for the name of the air conditioner, and displays the name of the air conditioner in another field. For this reason, the operator can instantly determine that the information on the power load coefficient has been corrected. In addition, since the information of the name of the original air conditioner is also displayed in another place, it is possible to instantly determine which air conditioner has been corrected based on the power load coefficient, making it easier to investigate the cause of the malfunction.
[0010]
  Claim2The air conditioning management device according to claim1The air conditioning management device according to claim 1, wherein the measured power measured by the power load calculating means for calculating the power load based on the power load coefficient and the power measuring means for measuring the power consumption of the outdoor unit is the power of each outdoor unit. It further comprises power apportioning means that apportions according to the load. In this case, even if the power load coefficient is erroneously corrected and the power load is set incorrectly, the problem can be solved in a short time.
[0011]
  Claim3The air conditioning management device according to claim2The power load calculating means calculates the power load by multiplying the difference between the suction temperature and the set temperature of each air conditioner by the power load coefficient. In this case, even if each air conditioner is located at a different customer, it is possible to rationally collect power charges.
  Claim4The air conditioning management device according to claimAny one of 1 to 3The correction information is a character that is not related to the name of the air conditioner. In this case, since characters that are not related to the air conditioner are displayed in the display field of the air conditioner, it can be further instantaneously determined that the information on the power load coefficient has been corrected.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
  <System configuration>
  FIG. 1 shows an air conditioning management system according to an embodiment of the present invention. This air-conditioning management system is a system that monitors and controls the air-conditioning system 3 installed in a building or the like. It is a system that executes by such as. The air conditioning management system includes an information terminal 1 for trial operation, a station 2 connected to the information terminal 1 via, for example, a LAN and connected to an air conditioning system 3 via, for example, a two-core cable, and monitoring for monitoring the air conditioning system 3. The terminal 4 is configured.
[0013]
  The information terminal 1 is a terminal connected to the station 2 at the time of trial operation, and sets power apportioning processing of the air conditioning system 3 including a coefficient database 13 as first information holding means and a coefficient correction routine 15 as correction means. It has a power apportioning trial run program 11. By the power apportioning trial run program 11, the information terminal 1 requests the station 2 for trial run control of the air conditioning system 3, or the monitoring control program 21 and the correction information holding unit (an example of the second information holding unit) of the station 2. ) 14 is set. Further, the information terminal 1 displays a result of monitoring / control of the air conditioning system 3 obtained from the station 2 and a setting state of the monitoring control program 21 included in the station 2. The monitoring terminal 4 requests the station 2 for operation control of the air conditioning system 3 or sets the monitoring control program 21 included in the station 2. Here, the information terminal 1 and the monitoring terminal 4 are, for example, a personal computer, a portable computer, a panel computer, etc., and are computers having a display as a display means and input keys.
[0014]
  Here, the coefficient database 13 holds a model name of the air conditioner 31 and a plurality of types of coefficients (eigenvalues) for power distribution corresponding to the model name. Specifically, for example, as shown in the lower right column of the model information editing screen of FIG. 7, the cooling coefficient a1, the cooling coefficient a2, the heating coefficient b1, the heating coefficient b2, the cooling rated power consumption coefficient, the heating rated power consumption Nine types of coefficients are held for each model: a coefficient of power consumption, a coefficient of rated power consumption of the fan, a coefficient of rated power consumption of the heater, and a coefficient of power consumption when stopped.
[0015]
  The station 2 has a monitoring control program 21 for monitoring and controlling the air conditioning system 3 and a correction information holding unit 14. Monitoring of the refrigerant system identification information and operation state of each air conditioning system 3, start / stop control, operation Setting or the like is automatically executed according to a request from the information terminal 1 or according to an operation schedule or the like. In addition, the information terminal 1 is notified of the monitoring / control result.
[0016]
  When the coefficient obtained from the coefficient database 13 is corrected based on the searched air conditioner model, the correction information holding unit 14 holds correction information (for example, “manual input”) that means that. .
  The air conditioning system 3 includes a plurality of refrigerant systems 20 having one outdoor unit 30 and a plurality of indoor air conditioners (an example of equipment) 31. Each outdoor unit 30 includes a commercial power source 33. An integrating wattmeter 32 for measuring the power supplied from is connected. The integrated wattmeter 32 detects the power used by each outdoor unit 30. The integrated wattmeter 32 is connected to the station 2 via a pulse converter (not shown), and the detection result of the integrated wattmeter 32, that is, the integrated power of the outdoor unit 30 is sent to the station 2.
[0017]
  The air conditioner 31 has a remote controller 40 for temperature setting and a temperature sensor 41 for detecting the suction temperature. The air conditioner 31 constantly transmits signals including control information such as temperature setting information and suction temperature information, refrigerant system identification information, and model identification information to the station 2. With this refrigerant system identification information, the information terminal 1 recognizes the refrigerant system 20 and model information of each air conditioner 31 via the station 2.
[0018]
  <Operation of test run program>
  During the trial operation, the power apportioning test operation program can be used to confirm the power apportioning process of the air conditioner 31 of the air conditioning system 3 connected to the air conditioning management system from the information terminal 1. 2 to 4 are control flowcharts, and FIGS. 5 to 8 are screens displayed on the information terminal 1 during the power apportioning test operation of the air conditioner. The operation of the trial run program for the air conditioner 31 will be described with reference to these drawings.
[0019]
  The test run program is a program that can be operated with a graphic user interface (GUI), and when the test run program starts operation, a main screen shown in FIG. 5 is displayed. FIG. 5 shows a state where the initialization process is selected on the main screen.
  The main screen in FIG. 5 is a screen that is displayed when the power apportioning test run program is executed. An initialization button 51, a time setting button 52, a device setting button 53, a power group button 54, an operation check button 55, a monitor are displayed at the top of the screen. A button 56 and an end button 57 are displayed. FIG. 3 shows a state where the initialization button 51 is selected. The initialization button 51 is a button for initializing the refrigerant system 20, and by this operation, detection processing as to which refrigerant system each air conditioner 31 belongs to is performed. The time setting button 52 is a button for setting the time at the time of trial operation. The device setting button 53 is a button for performing device setting processing such as setting a coefficient of each air conditioner 31 for apportioning electric power. The power group button 54 is used for group editing or the like of which refrigerant system 20 each air conditioner 31 belongs to. The operation confirmation button 55 is for confirming the power apportioning operation being executed in the station 2. The monitor button 56 is for monitoring the current operating state of the air conditioner 31. The end button 57 is a button for ending the power apportioning test run program. Each button can be operated by moving the cursor on the screen with a mouse or cursor keys to select these buttons, and left-clicking or pressing the enter key in the selected state.
[0020]
  Then, in step S10 to step S16 of FIG. 2, it is determined which button arranged on the upper part of the main screen has been operated.
  In step S10, it is determined whether or not the device setting button 53 has been operated. In step S12, it is determined whether or not the power group button 54 has been operated. In step S14, it is determined whether or not another operation such as operation of other buttons such as the initialization button 51, the time setting button 52, and the monitor button 56 has been selected. In step S16, it is determined whether or not the end button 57 has been operated. When another operation is performed, the process proceeds from step S16 to step S36, and other processes such as an operation based on the selected button are executed. Further, when the end button 57 is operated, the processing is ended.
[0021]
  When the device setting button 53 is operated, the process proceeds from step S10 to step S20. In step S20, a device setting list screen as shown in FIG. 6 is displayed. In the device setting list screen, a setting state display field 70 indicating the setting state of the air conditioner 31 is arranged on the most part of the screen, and a setting change button 71, a copy button 72, a paste button 73, a clear button 74, and an automatic are displayed on the right side. Setting buttons 75 are arranged side by side.
[0022]
  In the setting state display column 70, the number of the air conditioner 31 (air conditioner No .: information for identifying the air conditioner 31: device identification information), the group name of the refrigerant system, the model name (model identification information), and , Comment, apportionment calculation method, and other setting conditions are displayed. Thereby, the setting state for every apparatus can be grasped instantaneously. The operator can change the setting by setting the cursor to a specific device.
[0023]
  The setting change button 71 is a button for changing the setting state of the selected air conditioner 31. In the setting change process by the setting change button 71, if a model is manually selected from the coefficient database 13 to set the coefficient of the device, or there is no data of the corresponding model in the coefficient database 13, but there is similar product data, It is possible to set the coefficient of the device using the data, or to manually input all the coefficients when there is no similar data in the coefficient database 13. The copy button 72 is a button for copying the settings of the other air conditioners 31 at the time of setting. The paste button 73 is a button for pasting the copied setting to another air conditioner 31. The clear button 74 is a button for clearing the setting. The automatic setting button 75 is a button for performing automatic setting processing for automatically setting coefficients and the like. In the automatic setting process, when the model based on the model identification information sent from the air conditioner 31 can be automatically retrieved from the coefficient database 13, the setting of the air conditioner 31 is performed. Therefore, when the model cannot be retrieved from the coefficient database 13, the coefficient cannot be set by this automatic setting process.
[0024]
  In step S21, it is determined whether or not the automatic setting button 75 has been operated. In step S22, it is determined whether or not the setting change button has been operated. In step S23, it is determined whether another button operation such as the copy button 72 has been performed. In step S24, it is determined whether or not the end button 57 has been operated. If another button is operated, the process proceeds to step S27, and another process corresponding to the button is performed. When the end button 57 is not operated, the process returns from step S24 to step S21, and when the end button 57 is operated, the process proceeds to step S12.
[0025]
  When the automatic setting button 75 is operated, the process proceeds from step S21 to step S25, and the automatic setting process shown in FIG. 3 is executed. This automatic setting process is a process for automatically setting each device (air conditioner 31) when the model identification information sent from the air conditioner 31 can be automatically retrieved from the coefficient database 13 as described above. In step S40 of FIG. 3, the device to be set is specified. For example, the air conditioner 31 of the first address (air conditioner No.) of the refrigerant system 20 is specified. In step S42, it is determined whether or not the model identification information of the specified air conditioner 31 is in the coefficient database 13. If the model identification information is not in the coefficient database 13, the process proceeds to step S <b> 44 and it is determined whether or not the air conditioner 31 that has not been set remains in the refrigerant system 20. If the air conditioner 31 still remains, the process returns to step S40 to identify the next air conditioner 31.
[0026]
  When the model identification information is in the coefficient database 13, the process proceeds from step S42 to step S46. In step S46, setting information including the coefficient information is searched from the coefficient database 13 using the model identification information as a key. In step S48, it is determined whether the setting information is found from the coefficient database 13. If not found, the process proceeds to step S44. If found, the process proceeds to step S50.
[0027]
  In step S50, the searched model is set as a model name and displayed in the model name display portion of the setting status display field 70. In step S52, the coefficient data of the model stored and searched in the coefficient database 13 is set. In step S54, the coefficient is disabled. In step S56, the characters “automatically set” are displayed in the comment display portion of the setting state display field 70, and the process proceeds to step S44. Thus, the operator can easily recognize that the retrieved device data is automatically set.
[0028]
  When all the devices have been identified, the process proceeds from step S44 to step S58. In step S58, the set data is set in the station 2, for example, the automatic setting process is terminated, and the process returns to the main routine.
  When the setting change button 71 is operated, the process proceeds from step S24 in FIG. 2 to step S32. In step S32, the setting change process shown in FIG. 4 is executed. In the setting change process, first, in step S60, it is determined whether or not the device selected by the cursor has already been set with a coefficient. If already set, the process proceeds to step S62 to disable the coefficient input.
[0029]
  On the other hand, when the setting of the coefficient of the device has not been completed yet, the process proceeds from step S60 to step S74. In step S 74, “manual input” (correction information) is set as model name data, and is displayed in the model name display portion of the setting status display field 70. As a result, the operator can recognize that the coefficient of this model has been manually corrected. In step S76, an appropriate default value is set as the coefficient data. In step S78, the coefficient input is enabled. Then, the process proceeds to step S64. The operator copies the model name in the comment display field 63 before the setting change operation. Thereby, the corrected model name can be understood later.
[0030]
  In step S64, the model information editing screen shown in FIGS. 7 and 8 for the selected model is displayed on the display of the information terminal 1. This model information editing screen is a screen for editing the setting information of the selected model.
  In this model information editing screen, for example, the air conditioner No. A display column 60 and a calculation method display column 61 for setting a calculation method for power apportionment are arranged vertically, and a model name display column 62 and a comment display column 63 are arranged vertically above and to the right of the display column 60. . Below the calculation method display column 61, a condition setting column 64 for apportioning is arranged, and below the comment display column 63, a coefficient change button 65 and a database reference button 66 are arranged side by side. Further, a coefficient setting field 67 is arranged below both the buttons 65 and 66. The coefficient setting field 67 displays the above-described nine kinds of coefficients for apportioning the power of the selected model, and the coefficient can be set in the setting field 67. At the bottom of the model edit change screen, a setting button 68 for confirming the corrected setting and a cancel button 69 for canceling the setting are arranged side by side.
[0031]
  Here, the model name display field 62 is a field incapable of manual input. The coefficient change button 65 is a button for correcting a coefficient of a model that does not exist in the coefficient database 13 by using a coefficient of an existing model. The database reference button 66 is a button for searching for a coefficient of a model existing in the coefficient database 13 using, for example, a model name as a keyword and setting it in the coefficient setting field 67.
[0032]
  In step S66, it is determined whether or not the database reference button 66 has been operated. In step S68, it is determined whether or not the coefficient change button 65 has been operated. In step S70, it is determined whether or not the coefficient is ready for input. In step S72, it is determined whether or not the setting button 68 or the cancel button 69 has been operated.
  When the database reference button 66 is operated, the process proceeds from step S66 to step S80. In step S80, the coefficient database 13 is searched by the model name selected by the operator. In step S82, the searched model name is set as a model name, and is displayed in the model name display field 62. In step S84, the coefficient retrieved from the coefficient database 13 is set and displayed in the coefficient display field 67. In step S86, the coefficient is disabled and the process proceeds to step S68.
[0033]
  When the coefficient change button 65 is operated, the process proceeds from step S68 to step S88. In step S 88, “manual input” (correction information) is set as the model name and displayed in the model name display field 62. The manually input data is held in the correction information holding unit 14. In step S90, the coefficient is made ready for input, and the process proceeds to step S70.
[0034]
  If the coefficient is ready for input, the process proceeds from step S70 to step S92. In step S92, manual input of the coefficient by the operator is accepted. Thereby, a coefficient field city part can be changed manually or all can be changed. An example of this state is shown in FIG. In the example shown in FIG. 4, the heating coefficient b1, the cooling rated power consumption coefficient, and the heating rated power consumption are compared with the coefficients of the model (model name FXYCJ28XL) shown in FIG. The coefficient of the heater, the coefficient of the rated power consumption of the heater, and the coefficient at the time of stop are corrected by the operator. Thereby, it becomes possible to change using the coefficient of the existing model.
[0035]
  When the setting button 68 is operated, the process proceeds from step S72 to step S94, and the set data is set. This data is set, for example, in the power apportioning trial run program provided in the information terminal 1 and also in the power apportioning program provided in the station 2. When the cancel button 69 is operated, the process is terminated without setting data.
[0036]
  This setting change process corresponds to the coefficient correction routine 15. In the coefficient correction routine 15, when the operator is a new air conditioner 31 and no coefficient exists in the coefficient database 13, the coefficient of the model similar to the new model is corrected by using the coefficient change button 65 to newly It can be set as a coefficient of the air conditioner 31.
  As described above, when the coefficient is corrected, the correction information indicating that the coefficient has been corrected is held in the correction information holding unit 14, so that the correction information can be output by display or printing as necessary. By notifying with an alarm based on the information, the operator can recognize that the coefficient has been corrected. For this reason, even if a malfunction occurs during the trial operation of the air conditioning system 3, it can be easily determined whether the malfunction is caused by a mistake in correcting the coefficient or due to another cause. This makes it easier to investigate the cause of the malfunction.
[0037]
  Moreover, since the correction information is displayed on the information terminal 1, it can be easily recognized whether or not the coefficient is corrected. For this reason, even if a problem occurs in the power apportioning process, it is possible to more easily determine whether the problem is caused by a correction error of the coefficient or due to another cause, and it is also possible to easily determine the correction location. For this reason, it becomes easier to investigate the cause of the malfunction.
[0038]
  Furthermore, by displaying the correction information in the model name display field 62, it can be instantaneously determined that the coefficient has been corrected. Further, by displaying the model name information in the comment display field 63, the model name information is also displayed in the comment display field 63, so that it is possible to instantly determine which model has been modified based on the factor, and the cause of the problem It becomes easier to pursue. Furthermore, since characters (for example, manual input) that are not related to the model name are displayed in the model name display field 62, it can be determined more instantly that the coefficient has been corrected.
[0039]
  When the power group button 54 is operated, the process proceeds from step S12 to step S28. In step S28, a power group list screen is displayed. In the power group list display screen, as shown in FIG. 9, a calculation start button 81 and a calculation end button 82 are arranged vertically on the left side of the screen, and a new button 83, a delete button 84, and a name change button are arranged on the right side of the screen. 85 and a group edit button 86 are arranged side by side. In the center of the screen, a power group display column 87 is arranged. Here, the calculation start button 81 is for starting the power apportioning calculation, and the calculation end button 82 is for finishing the power apportioning process. The new button 83 is for registering a new power group, the delete button 84 is for deleting the displayed power group, and the name change button 85 is for changing the name of the displayed power group. Is for. The group edit button is for registering or deleting the group of each air conditioner 31 in the power group.
[0040]
  When the power group list screen shown in FIG. 9 is displayed, in step S29, it is determined whether or not the calculation start button 81 has been operated. In step S30, it is determined whether or not the calculation end button 82 has been operated. In step S31, it is determined whether other buttons such as the group edit button 86, the new button 83, and the delete button 84 have been operated. In step S32, it is determined whether or not the end button 57 has been operated. If any other button is operated, the process proceeds to step S35, and processing corresponding to the other button is performed. If the end button 57 has been operated, the process proceeds to step S12. If not, the process returns to step S29.
[0041]
  When the calculation start button 81 is operated, the process proceeds from step S29 to step S33, and the power distribution calculation is started. In this power apportioning calculation process, each air conditioner 31 in each refrigerant system 20 uses the temperature difference between the set temperature set by the remote controller 40 and the suction temperature measured by the temperature sensor 41 and the set parameters. And the power accumulated by the integrating wattmeter 32 is apportioned based on the estimated power load.
[0042]
  Here, since the integrated power of the outdoor unit 30 is apportioned according to the power load of each air conditioner 31 grouped for each refrigerant system 20, the power consumption for each air conditioner 31 can be reasonably calculated. . Moreover, since the power load is estimated according to the difference between the suction temperature of each air conditioner 31 and the set temperature, the power load can be reasonably estimated according to the actual use state.
  When the calculation end button 82 is operated, the process proceeds from step S30 to step S34, and the power distribution calculation is ended.
[0043]
  <Other embodiments>
  (A) In the above embodiment, the present invention has been described by taking the coefficient for each air conditioner used during trial operation of power apportioning processing of the air conditioning system 3 as equipment, but the present invention is not limited to this. The present invention can be applied to all equipment management devices that correct information on the eigenvalues of equipment.
[0044]
  (B) In the above embodiment, the corrected coefficient is displayed. However, the present invention is not limited to this, and only correction information may be held. If the correction information is held in this way, the correction information can be output by display or printing, an alarm can be sounded based on the correction information, or only the correction portion can be displayed separately from other displays as necessary.
[0045]
  (C) In the above-described embodiment, the text information of manual input is used as the correction information. However, the correction information is not limited to this. For example, only the corrected coefficient is highlighted in color or shape. Form may be sufficient.
  (D) Although the correction information holding unit 14 is provided in the station 2 in the embodiment, it may be provided in the information terminal 1 or the monitoring terminal 4. In addition, these may be provided in a distributed manner or may be provided in duplicate.
[0046]
  (E) In the above embodiment, the model name displayed in the model name display field 62 is manually copied to the comment display field 63. For example, correction information “manual input” is displayed in the model name display field 62. When displayed, the model name may be automatically displayed in the comment display field 63.
[0047]
【The invention's effect】
  In the air conditioning management device according to claim 1,When the information on the power load coefficient is corrected by the correction means, the display means displays the correction information in the display column for the name of the air conditioner, and displays the name of the air conditioner in another column. For this reason, the operator can instantly determine that the information on the power load coefficient has been corrected. In addition, the information on the name of the original air conditioner is also displayed in another place, so the power of any air conditioner It is possible to instantly determine whether the correction has been made based on the load coefficient, making it easier to investigate the cause of the failure.
[0048]
  Claim2In the air conditioning management device according to the above, even if the coefficient is corrected by mistake and the power load is set by mistake, the problem can be solved in a short time.
  Claim3In the air conditioning management apparatus according to the present invention, even if each air conditioner is located at a different customer, it is possible to collect a power charge reasonably.
  Claim4In the air conditioning management apparatus according to the above, since characters that are not related to the air conditioner are displayed in the display column of the air conditioner, it can be further instantaneously determined that the information on the power load coefficient has been corrected.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a system according to an embodiment of the present invention.
FIG. 2 is a schematic flowchart of a main routine of a power apportioning test run program.
FIG. 3 is a schematic flowchart of an automatic setting processing routine of a power apportioning test run program.
FIG. 4 is a schematic flowchart of a setting change processing routine of a power apportioning test run program.
FIG. 5 is a diagram showing a main screen of a power apportioning test run program.
FIG. 6 is a diagram showing a device setting list screen.
FIG. 7 is a diagram showing a model information editing screen before correction.
FIG. 8 is a diagram showing a model information editing screen after correction.
FIG. 9 is a diagram showing a power group list screen.
[Explanation of symbols]
    1 Information terminal
    2 stations
    3 Air conditioning system
  11 Power apportioning trial run program
  13 Coefficient database
  14 Correction information holding unit
  15 Coefficient correction routine

Claims (4)

An air conditioning management device (1, 2, 4) for managing a plurality of air conditioners (31) connected to at least one outdoor unit (30),
First information holding means (13) for holding information on the power load coefficient for each air conditioner;
Correction means (15) for correcting the information of the power load coefficient held in the first information holding means;
A second information holding unit (14) for holding correction information indicating that the correction has been made when the content held by the first holding unit is corrected by the correction unit;
Display means for displaying the name of the air conditioner (31), information on the power load coefficient, and the correction information;
Equipped with a,
When the information on the power load coefficient is corrected by the correction means (15), the display means displays the correction information in the display column (62) for the name of the air conditioner, and the name of the air conditioner is different. Displayed in the column (63),
Air conditioning management device. Power load calculating means for calculating the power load based on the power load coefficient;
It further comprises power apportioning means (11) that apportions the measured power measured by the power measuring means (32) that measures the power consumption of the outdoor unit (30) according to the power load of each outdoor unit (30). The air conditioning management device according to claim 1 . The air conditioning management device according to claim 2 , wherein the power load calculating unit calculates the power load by multiplying a difference between an intake temperature and a set temperature of each air conditioner by the power load coefficient. The air conditioning management device according to claim 1, wherein the correction information is a character that is not related to a name of the air conditioner.

Images