JPWO2019004218A1 - Heat source device, information terminal, and control program - Google Patents

Abstract

The heat source device includes a heat source unit that cools or heats a heat medium, a memory for storing data, and a controller that sequentially stores operation data of the heat source unit in the memory. The controller wirelessly transmits the operation data in the memory to the information terminal, and causes the information terminal to display a graph indicating a relationship between a temporal change of the operation data and time.

Description

  An embodiment of the present invention relates to a heat source device that cools or heats a heat medium, an information terminal, and a control program.

  There is known a heat source unit that cools or heats a heat medium (water, brine, or the like) by operating a heat pump refrigeration cycle and supplies the cooled or heated heat medium to a load (use side).

  An administrator or serviceman who manages this heat source unit needs to check the operation status of the heat source unit periodically or as needed.

  An object of the present embodiment is to provide a heat source device, an information terminal, and a control program that can easily and accurately notify a user of an operation state of a heat source unit.

  A heat source device according to a first aspect includes a heat source unit that cools or heats a heat medium, a memory for storing data, and a controller that sequentially stores operation data of the heat source unit in the memory. The controller wirelessly transmits the operation data in the memory to the information terminal, thereby causing the information terminal to display the relationship between the temporal change of the operation data and the time.

  The information terminal according to claim 10 is used for managing a heat source device including a heat source unit that cools or heats a heat medium, a memory for storing data, and a controller that sequentially stores operation data of the heat source unit in the memory. A display, a first control section, and a second control section. The first control section wirelessly transmits, to the controller, a data request signal for causing the controller to wirelessly transmit operation data in the memory when the operation status confirmation mode is designated. The second control section fetches operation data wirelessly transmitted from the controller in response to the data request signal, and displays a graph showing a relationship between a temporal change of the fetched operation data and time on the display.

  A control program according to claim 16 is used for managing a heat source device including a heat source unit that cools or heats a heat medium, a memory for storing data, and a controller that sequentially stores operation data of the heat source unit in the memory. The information terminal is caused to function as first control means and second control means. The first control means wirelessly transmits to the controller a data request signal for causing the controller to wirelessly transmit the operation data in the memory when the operation status confirmation mode is designated. The second control means captures operation data wirelessly transmitted from the controller in response to the data request signal, and displays a graph showing a relationship between a time change of the captured operation data and time on a display of the information terminal. I do.

FIG. 1 is a diagram showing an overall configuration of one embodiment. FIG. 2 is a diagram illustrating a configuration of a heat pump refrigeration cycle according to one embodiment. FIG. 3 is a block diagram showing a main part of one embodiment. FIG. 4 is a flowchart illustrating control of the module controller according to the embodiment. FIG. 5 is a flowchart illustrating control of the tablet terminal according to the embodiment. FIG. 6 is a diagram illustrating an initial screen according to one embodiment. FIG. 7 is a diagram showing a data display screen in one embodiment. FIG. 8 is a diagram showing a trend graph display screen according to one embodiment. FIG. 9 is a diagram illustrating a unit-specific data display screen according to one embodiment. FIG. 10 is a diagram illustrating a first report display screen according to one embodiment. FIG. 11 is a diagram showing a second report display screen in one embodiment. FIG. 12 is a diagram showing a business report according to the embodiment.

Hereinafter, an embodiment of a heat source device, an information terminal, and a control program will be described with reference to the drawings.
As shown in FIG. 1, a plurality (for example, eight) of heat source units UC1, UC2,... UCm are arranged. The heat source unit UC1 includes a plurality of, for example, four refrigeration cycle circuits UC1a, UC1b, UC1c, and UC1d. The heat source unit UC2 includes a plurality of, for example, four refrigeration cycle circuits UC2a, UC2b, UC2c, and UC2d. The heat source unit UC3 includes a plurality of, for example, four refrigeration cycle circuits UC3a, UC3b, UC3c, and UC3d. The heat source unit UC4 includes a plurality of, for example, four refrigeration cycle circuits UC4a, UC4b, UC4c, and UC4d.

  The refrigeration cycle circuit UC1a of the heat source unit UC1 includes a compressor 1, a four-way valve 2, air heat exchangers 3a and 3b, an expansion valve 4, a water heat exchanger 5, an outside air fan 6, an outside air temperature sensor 7, and the like. The compressor 1 sucks and compresses a refrigerant and discharges it.

  As shown in FIG. 2, one end of each of the air heat exchangers 3a and 3b is connected to the refrigerant discharge port of the compressor 1 via the four-way valve 2, and expanded to the other end of each of the air heat exchangers 3a and 3b. One end of a refrigerant flow path 5a of the water heat exchanger 5 is connected to the pipe via the valve 4, and the other end of the refrigerant flow path 5a is connected to the refrigerant suction port of the compressor 1 by pipe. These piping connections constitute a heat pump refrigeration cycle. The air heat exchangers 3a and 3b are arranged so as to be separated from each other and face each other. The outside air fan 6 is disposed between the upper portions of the air heat exchangers 3a and 3b in a state where the blowing direction is directed upward. When the outside air fan 6 operates, outside air is sucked into the inside of the refrigeration cycle circuit UC1a through the air heat exchangers 3a and 3b, and the sucked air is discharged through the outside air fan 6 above the refrigeration cycle circuit UC1a. . The outside air temperature sensor 7 detects an outside air temperature at a place where the refrigeration cycle circuit UC1a is installed.

  The water heat exchanger 5 has a water flow path 5b in addition to the refrigerant flow path 5a. Water circulation pipes 11 and 12 are provided between the water flow path 5b and the load-side device 10, and a water circulation pump 8 is provided in the pipe 12. The load-side device 10 is, for example, a fan coil for air conditioning. In the cooling mode in which the air heat exchangers 3a and 3b function as condensers and the refrigerant flow path 5a of the water heat exchanger 5 functions as an evaporator, the refrigerant flows from the load-side device 10 into the water flow path 5b of the water heat exchanger 5. The generated water is deprived of heat by the refrigerant in the refrigerant flow path 5 a to become cold water, and the cold water is sent to the load-side device 10. In the heating mode in which the air heat exchangers 3a and 3b function as evaporators and the refrigerant flow path 5a of the water heat exchanger 5 functions as a condenser, the heat flows from the load-side device 10 into the water flow path 5b of the water heat exchanger 5. The generated water takes heat from the refrigerant in the refrigerant flow path 5a to become hot water, and the hot water is sent to the load-side device 10.

  The remaining three refrigeration cycle circuits UC1b to UC1d in the heat source unit UC1 also have a heat pump refrigeration cycle (compressor 1, four-way valve 2, air heat exchangers 3a and 3b, expansion valve 4, water It has a heat exchanger 5), an outside air fan 6, an outside air temperature sensor 7, and a pump 8.

  Note that one water heat exchanger 5 may be shared by two refrigeration cycle circuits UC1a and UC1b, and another water heat exchanger 5 may be shared by two refrigeration cycle circuits UC1c and UC1d. For example, one plate type heat exchanger including two refrigerant channels and one water channel is shared by the refrigeration cycle circuits UC1a and UC1b, and another one including two refrigerant channels and one water channel is also used. The plate heat exchanger is shared by the refrigeration cycle circuits UC1c and UC1d.

  The refrigeration cycle circuits of the heat source units UC2 to UCm other than the heat source unit UC1 also have the same configuration as the refrigeration cycle circuits UC1a to UC1d of the heat source unit UC1.

  A unit controller 30a for controlling the operation of the refrigeration cycle circuits UC1a to UC1d of the heat source unit UC1 is mounted on the refrigeration cycle circuit UC1a of the heat source unit UC1. A unit controller 30b for controlling the operation of the refrigeration cycle circuits UC2a to UC2d of the heat source unit UC2 is mounted on the refrigeration cycle circuit UC2a of the heat source unit UC2. Similarly, unit controllers 30c to 30m that control the operation of each of the refrigeration cycle circuits of the heat source units UC3 to UCm are mounted on the refrigeration cycle circuits UC3a to UCma of the heat source units UC3 to UCm, respectively.

  One module MC1 is configured by the heat source units UC1 to UCm. A module controller 20 that controls the heat source units UC1 to UCm of the module MC1 in a comprehensive manner is mounted on the refrigeration cycle circuit UC1a of the heat source unit UC1. A unit controller 30a is connected to the module controller 20 via a signal line. A signal cable 31 for transmitting and receiving data is connected between the module controller 20 and the unit controllers 30b to 30m. The unit controllers 30a to 30m respectively control the operation of the heat source units UC1 to UCm in accordance with instructions from the module controller 20, and sequentially notify the module controller 20 of the operation data of the heat source units UC1 to UCm.

  The operation data of the heat source units UC1 to UCm are the operation data of the heat source units UC1 to UCm itself, and the operation data of all the refrigeration cycle circuits UC1a to UC1d, UC2a to UC2d, UCma to UCmd in the heat source units UC1 to UCm. And the operating conditions of the heat source units UC1 to UCm that change from moment to moment (for example, “operation state”, “operation mode”, “set temperature”, “outside air temperature”, “inlet water temperature”, “outlet water temperature”, etc. ), And the operating conditions of the refrigeration cycle circuits UC1a to UC1d, UC2a to UC2d,... UCma to UCmd in the heat source units UC1 to UCm that change every moment (for example, “high pressure”, “low pressure”). Pressure, “condensation temperature,” “compressor operating state,” “fan operating state”).

  When the capacity of the load-side device 10 is large, the module MC10 including the heat source units UC1 to UCm as components as in the module MC1 is added. The number of modules MC1, MC10,... Is appropriately selected according to the load situation.

  At least the modules MC1, MC10,... And the module controller 20 constitute the heat source device of the present embodiment.

  In the module controller 20 of the refrigeration cycle circuit UC1a in the heat source unit UC1, an SD (Secure digital) memory card 21 having a wireless communication function with an information terminal such as a tablet terminal 40 is mounted as a memory for storing data. The tablet terminal 40 is a portable type that a user such as an administrator or a service person can hold with one hand.

  FIG. 3 shows the main parts of the module controller 20, the SD memory card 21, and the tablet terminal 40.

  The SD memory card 21 is, for example, a FlashAir SD memory card (registered trademark) that operates by receiving power from the module controller 20, and includes a storage section 21a, a reception section 21b, and a transmission section 21c. The receiving section 21b constructs a wireless LAN (Wireless Local Area Network) for wirelessly transmitting and receiving data to and from an information terminal such as the tablet terminal 40, and transmits a signal wirelessly transmitted from the tablet terminal 40 via the wireless LAN. And supplies the received signal to the module controller 20. The transmission section 21c wirelessly transmits a signal issued from the module controller 20 and operation data in the storage section 21a to the tablet terminal 40 via the wireless LAN. In the wireless LAN, the SD memory card 21 is a so-called master unit, and the tablet terminal 40 is a so-called slave unit.

  The module controller 20 sequentially collects the operation data of all the heat source units UC1 to UCm in the modules MC1, MC10,... And stores them in the SD memory card 21, and the operation data in the SD memory card 21 from the tablet terminal 40. In response to the request, the SD memory card 21 performs wireless transmission control to the tablet terminal 40, and includes a clock section 20a, a storage control section 20b, a communication control section 20c, and a transmission control section 20d as main functions. .

  The clock section 20a emits time data of the current time.

  The storage control section 20b collects operation data of all the heat source units UC1 to UCm in the modules MC1, MC10,... Via the unit controllers 30a to 30m, and sequentially corresponds the collected operation data and the time data of the clock section 20a. While attaching, the associated operation data and time data are stored in the SD memory card 21. When the storage amount of the operation data and the time data reaches the storage capacity of the SD memory card 21, the storage control section 20a deletes the oldest operation data and the time data in the SD memory card 21, and deletes the latest operation data and the time. The data is stored in the SD memory card 21.

  The communication control section 20b always turns on the operation of the receiving section 21b of the SD memory card 21, and when a data request signal wirelessly transmitted from the tablet terminal 40 is received by the receiving section 21b, the source of the data request signal is transmitted. It is determined whether or not the tablet terminal 40 is a pre-registered information terminal based on the identification data included in the data request signal, and provided that the tablet terminal 40 is a pre-registered information terminal. The operation of the transmission section 21c of 21 is turned on (activated), and a communication link for data transmission and reception is formed between the module controller 20 and the tablet terminal 40 of the transmission source by turning on the operation of the transmission section 21c.

  The transmission control section 20c wirelessly transmits the operation data and the time data in the storage section 21a of the SD memory card 21 to the tablet terminal 40 by the transmission section 21c of the SD memory card 21 with the formation of the communication link by the communication control section 20b. .

  The module controller 20 and the SD memory card 21 are mounted on the heat source unit UC1 in a state where the module controller 20 and the SD memory card 21 are accommodated in a metal protective housing 22. The protection housing 22 protects the module controller 20 and the SD memory card 21 from wind, rain and dust in consideration of the case where the heat source unit UC1 is installed outdoors. However, the protective housing 22 has a shape that does not hinder the transmission and reception of wireless communication radio waves between the SD memory card 21 and the tablet terminal 40, and has a length longer than 1/4 of the wavelength of radio waves used in the wireless LAN. It has an antenna part and a slit part. The length of the antenna section or the slit section is 6 cm or more or 2 cm or more when the wireless LAN uses, for example, 2.4 GHz or 5 GHz radio waves.

  On the other hand, the tablet terminal 40 includes a CPU 41, a ROM 42, a RAM (storage means) 43, a touch-panel display 44, a transmission / reception unit 45, and the like, and transmits operation data and time data wirelessly transmitted from the SD memory card 21 to the transmission / reception unit 45. Then, the data is taken into the RAM 43, a graph showing a relationship between a time change (transition) of the taken operation data and time is generated based on the reference of the taken time data, and a generated trend graph is displayed. Display at 44.

  The ROM 42 stores control programs such as an operating system and application programs necessary for the processing of the CPU 41. The RAM 43 stores various data necessary for the processing of the CPU 41, and also stores the operation data and the time data. The display 44 has, for example, a color liquid crystal type screen 44a and a transparent touch panel 44b disposed on the screen 44a, and displays images and characters in color on the screen 44a, and there is a touch operation of a finger on the touch panel 44b. In this case, the display content of the screen 44a corresponding to the position of the touch operation is taken in as an operation input. The transmission / reception unit 45 performs wireless data transmission / reception with the SD memory card 21.

The CPU 41 includes first to fourth control sections 41a to 41d as main functions for collecting operation data of all the heat source units UC1 to UCm in the modules MC1, MC10,.
The first control section 41a wirelessly transmits a data request signal to the module controller 20 from the transmission / reception unit 45 when the operation status confirmation mode is designated by a touch operation on the display 44.

  The second control section 41b receives the operation data and time data wirelessly transmitted from the SD memory card 21 by the instruction of the module controller 20 in response to the data request signal in the transmission / reception unit 45, fetches the operation data and the fetched operation data, A graph (a trend graph 300 described later) indicating the relationship between the temporal change (transition) and the time is generated based on the imported time data, and the generated graph is displayed on the display 44.

  When an arbitrary time is specified by a user's touch operation on the graph displayed on the display 44, the third control section 41c fetches the driving data associated with the time data of the specified time. The contents (values, etc.) of the extracted operation data are lined up by item (“operation state”, “operation mode”, “set temperature”, “outside air temperature”, “inlet temperature”, “outlet temperature”, etc.) A list (lists 401 and 402 to be described later) is displayed on the display 44, and the display form of the contents of the operation data (“display color”, “character type”, “character size”, “character”) in the displayed list is displayed. Thickness, “light emission”, “background”, etc.) depending on whether or not the content of each operation data is included in a predetermined reference range.

  The fourth control section 41d generates a report file for business report in which the contents of the operation data extracted in the second control section 41c are represented by characters or images, displays the generated report file on the display 44 and connects to the network. It is output to a state that the user can view by printing from the external printer.

  One or a plurality of the tablet terminals 40 are arranged, for example, in a management room or the like for managing the heat source device, and can be taken out by a user such as an administrator or a service person when necessary. The tablet terminal 40 may be a tablet terminal prepared exclusively for management of the heat source device, or a general-purpose tablet terminal that is individually owned by the user and used in daily life. Instead of the tablet terminal 40, a so-called smartphone type information terminal may be used. General-purpose information terminals owned by users are widely used as phones and personal computers, including smartphones, so they are very easy to handle for users and dedicated information for manufacturers and retailers. Since there is no need to prepare a terminal, the cost is reduced. In this case, it is conceivable that a user downloads a dedicated application program from a website of a maker or a store to a user's own information terminal.

  Next, control executed by the module controller 20 will be described with reference to the flowchart of FIG. Steps S1, S2,... In the flowchart are simply abbreviated as S1, S2,.

  The module controller 20 turns on the operation of the receiving section 21b of the SD memory card 21 (S1), and sequentially collects the operation data of all the heat source units UC1 to UCm in the modules MC1, MC10,. (And time data) are stored in the SD memory card 21 (S2). Then, the module controller 20 monitors whether or not the data request signal wirelessly transmitted from the tablet terminal 40 is received by the receiving section 21b (S3). When a data request signal has not been received (NO in S3), the module controller 20 repeats collection and storage of operation data (S2).

  When receiving the data request signal (YES in S3), the module controller 20 includes in the data request signal whether or not the tablet terminal 40 that has transmitted the data request signal is an information terminal registered in advance. The determination is made based on the identification data (S4). When the tablet terminal 40 of the transmission source is not an information terminal registered in advance (NO in S4), the module controller 20 repeats collection and storage of the operation data (S2).

  If the tablet terminal 40 of the transmission source is an information terminal registered in advance (YES in S4), the module controller 20 turns on (starts) the operation of the transmission section 21c of the SD memory card 21, and thereby, the operation of the transmission source A communication link for data transmission / reception is formed with the tablet terminal 40 (S5). With the formation of the communication link, the module controller 20 wirelessly transmits all operation data stored in the SD memory card 21 to the tablet terminal 40 of the transmission source via the SD memory card 21 (S6), Wait for the completion of the transmission (S7). When the transmission is completed (YES in S7), the module controller 20 turns off the operation of the transmission section 21c of the SD memory card 21, thereby releasing the communication link with the tablet terminal 40 (S8).

The control executed by the CPU 41 of the tablet terminal 40 will be described with reference to the flowchart of FIG.
The user who wants to check the operation data of the heat source units UC1 to UCm in the module MC1 approaches the heat source unit UC1 of the module MC1 with the tablet terminal 40 and touches the display 44 of the tablet terminal 40 to specify the check mode.

  The CPU 41 determines whether or not the confirmation mode is specified (S11). When the confirmation mode is not specified (NO in S11), the CPU 41 repeats the determination in S11. When the confirmation mode is specified (YES in S11), the CPU 41 activates a built-in application program for an operation status confirmation process (S12). Then, based on the activated application program, the CPU 41 causes the user to specify which of the heat source units UC1 to UCm of the modules MC1 and MC10 to start the operation status confirmation processing for the heat source unit in FIG. The screen 100 is displayed on the display 44 (S13). The initial screen 100 includes a display of a start button 101 for the module MC1, a display of a start button 102 for the module MC10, and a display of a cancel button 103.

  When the cancel button 103 on the initial screen 100 is touched (NO in S14), the CPU 210 shuts down the running application program and ends the operation status check processing (S21). After this, the CPU 210 returns to the determination in S11.

  When the start button 101 on the initial screen 100 is touched (YES in S14), the CPU 41 wirelessly transmits a data request signal (S15). After this transmission, the CPU 41 monitors whether a communication link with the module controller 20 has been formed based on a notification from the module controller 20 (S16). If there is no communication link formation notification (NO in S16), the CPU 41 starts a time count t (S17), and compares the time count t with a predetermined set time t1 (S18).

  When the time count t is less than the set time t1 (NO in S18), the CPU 41 repeats the monitoring in S16 and the time count t in S17. If the time count t has reached the set time t1 (YES in S18) without the notification of the communication link formation (S16: NO), the CPU 41 shuts down the running application program and ends the operation status confirmation processing. (S21). After this, the CPU 210 returns to the determination in S11.

  If the communication link formation notification has been received before the time count t has not reached the set time t1 (NO in S18), the CPU 41 executes an operation status confirmation process (S19). That is, the CPU 41 takes in the operation data transmitted from the SD memory card 21 and stores it in the RAM 43.

  Therefore, the operation data of the heat source units UC1 to UCm in the module MC1 can be easily and quickly transmitted to the tablet terminal 40 without any troublesome operation such as connecting an information terminal such as a personal computer to the module controller 20 with a cable as in the related art. Can be collected.

  Along with the execution of the driving status confirmation processing, the CPU 41 monitors a user's processing end operation on the tablet terminal 40 (S20). If there is no operation to end the process (NO in S20), the CPU 41 continues to execute the operation status confirmation process in S19. When there is a processing end operation (YES in S20), the CPU 41 ends the operation status confirmation processing (S21). After this, the CPU 210 returns to the determination in S11.

[Data Display Screen 200]
In the operation status confirmation processing, the CPU 41 generates a data display screen 200 shown in FIG. 7 based on the operation data taken from the SD memory card 21, and displays the generated data display screen 200 on the display 44. The data display screen 200 includes a list 201, a trend graph designation button 202, a failure history designation button 203, a consumables designation button 204, a date / time display 205, a clip button 206, an operation data tab 211, an inspection tab 212, a report tab 213, and the like. Including display.

  The list 201 displays the current operation data of the heat source units UC1 to UCm in the module MC1 among the operation data imported from the SD memory card 21 by various items and displays the characters. The items include, for example, “operation state”, “operation mode”, “set temperature”, “outside air temperature”, “inlet water temperature”, and “outlet water temperature”.

  The trend graph designation button 202 is for designating a trend graph display screen 300 described later. The failure history designation button 203 is for designating a failure history display screen. The consumable item designation button 204 is for designating a consumable item display screen. The date and time display 205 displays the current date and time. The operation data tab 211 is for designating the data display screen 200. The inspection tab 212 is for designating an inspection display screen. The report tab 213 is for specifying a report display screen 500 described later.

[Trend graph display screen 300]
When the trend graph designation button 202 on the data display screen 200 is touched, the CPU 41 displays a trend graph display screen 300 showing the relationship between the time change of the operation data of the heat source unit UC1 and the time as shown in FIG. The generated trend graph display screen 300 is displayed on the display 44.

  The trend graph display screen 300 includes a trend graph 301, a plurality of heat source unit designation buttons 302, a plurality of time designation buttons 303, a plurality of scale size designation buttons 304, and the same trend graph designation button 202 as the data display screen 200. , A failure history designation button 203, a consumables designation button 204, a date / time display 205, a clip button 206, an operation data tab 211, an inspection tab 212, a report tab 213, and the like.

  When the display on the display 44 is switched from the data display screen 200 to the trend graph display screen 300, the CPU 41 displays the display form (display color, character type, character size, character thickness, (Emission, etc.) is set to a state different from the display mode of the other buttons. The display points of the trend graph designation button 202 are different from the display forms of the other buttons, as indicated by dots in the drawing.

  In the trend graph 301, a time scale is assigned to the horizontal axis, a numerical scale, for example, a temperature scale “-60 to + 140 ° C.” is assigned to the vertical axis rising from the left end of the horizontal axis, and the vertical axis rises from the right end of the horizontal axis. Is assigned a numerical scale, for example, a percentage scale "0 to 100", and one or more data lines 301a for displaying numerical values and one cursor line 301b for specifying time are movable between these two vertical axes. Among the operation data of one heat source unit designated by a touch operation of each heat source unit designation button 302, and a temporal change of one or a plurality of operation data corresponding to one of a temperature scale and a percentage scale. The relationship with the time is displayed in an analog manner so that the user can see it.

  The one or more data lines 301a indicate the values of the operation data of one or more items by the height position in the direction along each vertical axis. The cursor line 301b is a straight line extending upward, and can be freely moved in the horizontal axis direction according to the touch & slide operation of the user, and can designate an arbitrary time scale on the horizontal axis.

  That is, among the operation data of “operation state”, “operation mode”, “set temperature”, “outside air temperature”, “inlet water temperature”, and “outlet water temperature” displayed in the list 201 of the data display screen 200, “operation state” “ The relationship between the temporal change and the time of the operation data of “set temperature”, “outside air temperature”, “inlet water temperature”, and “outlet water temperature” excluding the “operation mode” is the height position of the plurality of data lines 301 a in the trend graph 301. Is displayed at a glance.

  In the time scale of the horizontal axis of the trend graph 301 in FIG. 8, the left end indicates the time “12:37:00” which is 10 minutes before the current time “12:47:00”, and the right end indicates the current time “12:00”. 47 minutes 00 seconds ". The time specified by the cursor line 301b is approximately 12:46:25, which is slightly before the current time of 12:47:00.

  By looking at the trend graph 301, the user can accurately recognize the change in the operation state of the heat source unit UC1 for 10 minutes from the time “12:37:00” to the current time “12:47:00”. Can be.

  Each heat source unit designation button 302 is for designating any one of the heat source units UC1 to UCm according to a touch operation of the user, and the same m (eight) as the heat source units UC1 to UCm are prepared. I have.

  When the display on the display 44 is switched from the data display screen 200 to the trend graph display screen 300, the CPU 41 automatically designates the first heat source unit UC1 without touching each heat source unit designation button 302. In accordance with this designation, the display form of the heat source unit designating button 302 corresponding to the heat source unit UC1 is set to a state different from the display form of the other heat source unit designating buttons 302, as indicated by dots in the drawing. Then, the CPU 41 displays the relationship between the time change of the operation data of the heat source unit UC1 and the time on the trend graph 301. When, for example, the heat source unit specification button 302 corresponding to the heat source unit UC2 is touched from this display state, the CPU 41 specifies the second heat source unit UC2, and with this specification, the heat source unit specification corresponding to the heat source unit UC2. The display mode of the button 302 is set to a state different from the display mode of the other heat source unit designation buttons 302. Then, the CPU 41 displays the relationship between the time change of the operation data of the heat source unit UC2 and the time on the trend graph 301.

  Each time designation button 303 selects one of “10 minutes”, “30 minutes”, “1 hour”, “6 hours”, and “24 hours” according to a touch operation of the user by assigning a time scale range to be assigned to the horizontal axis of the trend graph 301. Is to be specified.

  When the display on the display 44 is switched from the data display screen 200 to the trend graph display screen 300, the CPU 41 automatically sets the minimum time range “10 minutes” as a time scale range without touching each time designation button 303. Specify With this designation, the time scale for 10 minutes is assigned to the horizontal axis of the trend graph 301. Along with the designation, the CPU 41 sets the display form of the time designation button 303 corresponding to “10 minutes” to a state different from the display form of the other time designation buttons 303 as indicated by dots in the figure. By looking at the trend graph 301, the user can accurately recognize a change in the operating state of the heat source unit UC1 for 10 minutes before the current time.

  When the time designation button 303 corresponding to “30 minutes” is touched, the CPU 41 designates “30 minutes” as the time scale range. With this designation, the time scale for 30 minutes is assigned to the horizontal axis of the trend graph 301. With this designation, the CPU 41 sets the display form of the time designation button 303 corresponding to “30 minutes” to a state different from the display form of the other time designation buttons 303. By looking at the trend graph 301, the user can accurately recognize a change in the operation status of the heat source unit UC1 for 30 minutes before the current time.

  Each scale size designation button 304 is for designating the scale interval on the vertical axis of the trend graph 301 to one of “large”, “medium”, and “small” in accordance with a touch operation by the user. When the “small” scale size designation button 304 is touched, the CPU 41 designates a scale interval “small”. With this designation, the CPU 41 sets the scale interval on the vertical axis of the trend graph 301 to the minimum, and changes the display mode of the scale size specifying button 304 corresponding to “small” to the display mode of the other scale size specifying buttons 304. Set to a different state. Each scale size designation button 304 is for designating the scale interval on the vertical axis of the trend graph 301 to one of “large”, “medium”, and “small” in accordance with a touch operation by the user. When the “large” scale size designation button 304 is touched, the CPU 41 designates a scale interval “large”. With this designation, the CPU 41 enlarges the scale interval on the vertical axis of the trend graph 301 to the maximum, and changes the display mode of the scale size specifying button 304 corresponding to “large” from the display mode of the other scale size specifying buttons 304. Set to state. For example, when the plurality of data lines 301a are in a state close to each other and it is difficult to distinguish the numerical values, it is easier to distinguish the numerical values by increasing the scale interval on the vertical axis.

  However, when the display on the display 44 is switched from the data display screen 200 to the trend graph display screen 300, the CPU 41 automatically designates the scale interval “medium” without touching each time designation button 303. . Along with this designation, the CPU 41 sets the scale interval on the vertical axis of the trend graph 301 to an intermediate size between the maximum and the minimum, and changes the display form of the scale size designation button 304 corresponding to “medium” to another scale size. A state different from the display mode of the designation button 304 is set.

[Data display screen 400 for each unit]
In the operation data of the heat source unit UC1 displayed on the trend graph 301, when the user wants to confirm the contents (detailed values and the like) of the operation data at the time “12:46:25”, for example, By touching the cursor line 301b and sliding the touch position appropriately, the cursor line 301b is set to the time “12:46:25” of the trend graph 301 as shown in FIG. Then, the user performs a fixing operation such as separating the finger from the cursor line 301b. In response to this determination operation, the CPU 41 extracts the operation data at the time “12:46:25” designated by the cursor line 301b from the operation data of the heat source unit UC1 displayed on the trend graph 301. Then, a unit-specific data display screen 400 of FIG. 9 including the character display of the extracted operation data and the character display of the item name is generated and displayed on the display 44.

  The unit-specific data display screen 400 includes list tables 401 and 402, and has the same trend graph designation button 202, failure history designation button 203, consumables designation button 204, date and time display 205, clip button 206, and operation as the data display screen 200. The display includes a data tab 211, an inspection tab 212, a report tab 213, and the like. When the display on the display 44 is switched from the trend graph display screen 300 to the unit-specific data display screen 400, the display on the date / time display 205 changes from the current time display to the specified time “12:46:25” of the cursor line 301b. Change to display.

  The list 401 displays the contents of the operation data at the designated time of the cursor line 301b among the operation data of the heat source unit UC1 itself displayed on the trend graph display screen 300 together with the respective item names in text. The items include “operation state”, “operation mode”, “set temperature”, “outside air temperature”, “inlet water temperature”, “outlet water temperature”, and the like. Among these items, the items “set temperature”, “outside air temperature”, “inlet water temperature”, and “outlet water temperature” accompanied by numerical display correspond to the operation data items displayed on the trend graph display screen 300, and characters other than numerical values are displayed. The items “operation state” and “operation mode” accompanied by the display do not correspond to the items of the operation data displayed on the trend graph display screen 300. By viewing the list 401, the user can accurately recognize the operation status of the heat source unit UC1 itself at the time designated by the cursor line 301b.

  The list 402 shows the operation data of the refrigeration cycle circuits UC1a to UC1d at the time designated by the cursor 301b, among the operation data of the heat source unit UC1 displayed on the trend graph display screen 300, and the contents of these operation data. The reference range is displayed in characters along with each item name. Items include “high pressure”, “low pressure”, “condensing temperature”, “compressor operating state”, “fan operating state”, and the like. “High pressure”, “low pressure”, and “condensation temperature” are represented by numerical values, and “compressor operating state” and “fan operating state” are represented by ON / OFF characters and rotational speed numerical values.

  The reference range is a range suitable for operation (also referred to as an appropriate range), and serves as a reference for a user to make a prediction judgment of a device failure or to consider a timing of replacement of consumables. This reference range may be a fixed value that is determined in advance, or may be a variable value that fluctuates appropriately according to the driving situation. For example, the weight is increased for the driving state during a predetermined period from the start of the test operation, and the weight is gradually reduced for the driving state after the predetermined period has elapsed. The reference range may be variably set sequentially. In addition, for example, for the reference range of the high pressure and the reference range of the low pressure, the CPU 41 acquires the high pressure and the low pressure during the test operation after the installation of the heat source device as initial data, and acquires the acquired initial data thereafter. The data after the correction may be sequentially set as the reference range while the correction is sequentially performed according to the driving situation. The operating status includes, for example, the outside air temperature, the operating status of the load-side device 10 (water inlet temperature to the water heat exchanger 5 and water outlet temperature from the water heat exchanger 5), the rotation speed of the compressor 1, and the like.

  The high pressure of the refrigeration cycle gradually increases immediately after the start of the operation of the compressor 1, and reaches the highest pressure during a continuous operation after a predetermined time from the start of the operation. As the high pressure increases, the CPU 41 may variably set the high pressure reference range in the upward direction and may variably set the low pressure reference range in the downward direction. The high pressure of the refrigeration cycle drops immediately after the operation of the compressor 1 is stopped. The CPU 41 may variably set the reference range of the high-pressure pressure in the descending direction and variably set the reference range of the low-pressure pressure in the rising direction in accordance with the decrease in the high-pressure pressure.

  In the list 402, the reference range of "high pressure" is, for example, "1.0 to 1.5", and the reference range of "low pressure" is, for example, "1.0 to 1.5". Since the actual high pressure "1.53" of the refrigeration cycle circuit UC1a is out of the reference range "1.0 to 1.5", the display of the actual high pressure "1.53" of the refrigeration cycle circuit UC1a is different from the normal display mode (points shown). Become. The actual high pressures “1.16”, “1.16” and “1.16” of the refrigeration cycle circuits UC1b to UC1d are included in the reference range “1.0 to 1.5”, so the actual high pressures “1.16” and “1.16” of the refrigeration cycle circuits UC1b to UC1d. The display of “1.16” is the normal display mode. Since the low pressures “1.17”, “1.15”, “1.17”, and “1.14” of the refrigeration cycle circuits UC1a to UC1d are included in the reference range “1.0 to 1.5”, the actual low pressures “1.17” and “1.15” of the refrigeration cycle circuits UC1a to UC1d are included. The display of “1.17” and “1.14” is the normal display mode.

  Since the “high pressure” and the “low pressure” are related to each other, an alert may be displayed according to the relationship. For example, when the pressure difference between the actual “high pressure” and the actual “low pressure” is equal to or greater than a predetermined value, the display of the actual “high pressure” and the display of the actual “low pressure” blink, respectively. A display may be provided so that the user can easily recognize that the state is different from the normal operation.

  By viewing the list 402, the user can accurately recognize the operation states of the refrigeration cycle circuits UC1a to UC1d at the time designated by the cursor 301b while comparing them with each other. In addition, the user views the list 402 to display whether or not the content (value) of the operation data of a predetermined item is included in the reference range in the operation status of the refrigeration cycle circuits UC1a to UC1d. It is easy to recognize from the form, and based on this recognition, it is possible to determine the location where the abnormality has occurred or the location where the abnormality is likely to occur. As a result, the user can accurately examine the prediction determination of the device failure and the timing of replacement of the consumables.

  When the trend graph designation button 202 is touched, the CPU 41 returns the display on the display 44 to the display on the trend graph display screen 300 immediately before the display on the unit-specific data display screen 400. By returning to the display of the trend graph display screen 300, the designated time of the cursor 301b can be changed.

  When the content (value) of any one of the operation data exceeds the reference range, the color display of the corresponding time zone portion of each data line 301a on the trend graph 301 may be changed. By looking at the trend graph 301, the user can determine the location where the abnormality has occurred or the location where the abnormality is likely to occur.

[Report display screen 500 and report display screen 600]
When the report tab 213 of the trend graph display screen 300 or the report tab 213 of the unit data display screen 400 is touched, the CPU 41 executes the operation data (the list of the unit data display screen 400) at the time designated by the cursor 301b. A report file for business report in which the contents of the operation data displayed in 401 and 402 are represented by characters and images is generated, and the generated report file is displayed on a report display screen (first report display screen) 500 shown in FIG. 11 and is sequentially displayed on the display 44 separately from the report display screen (second report display screen) 600 shown in FIG.

  The report display screen 500 corresponds to the top page of the report file, and includes a display of an operation record table 501, a preview button 502, an operation data tab 211, an inspection tab 212, a report tab 213, and the like.

  The operation record table 501 headlines various data (customer name / address) concerning the owner of the module MC1 and various data (work classification / work date / time) concerning the inspection work of the module MC1. The preview button 502 is for designating the second report display screen 600. When the preview button 502 is touched, the CPU 41 displays the report display screen 600 of FIG.

  The report display screen 600 includes an operation record table display 601 for displaying various data mainly including the contents of the operation record table 501 in a list form in a text format, and operation data at a designated time of the cursor 301b (a list of the unit-based data display screen 400). An operation data display 602 that displays the contents of the operation data displayed in the tables 401 and 402 in text form in a list format, and an item (inspection item) that has been inspected when the inspection of the module MC1 has been completed. X, Y) and an inspection item display 603 for displaying "OK" or "NG" as a result of the inspection, an output button 604 for designating a print output, and the like.

  Regarding the type and number of the inspection items X and Y, the inspection display screen is displayed on the display 44 by touching any one of the inspection tabs 212 of the trend graph display screen 300, the unit-specific data display screen 400, and the report display screen 500. , Can be appropriately selected by touch operation on the inspection display screen. Note that, among the inspection items described above, items of low importance and items that do not need to be changed are set to inherit the same descriptions as in the previous output. As a result, it is possible to create a report while shortening the report creation time of the inspection operator. Further, when confirming an unclear point or the like in the content of the check item, the item description or the help search function can be started by touching the item name portion.

  The CPU 41 stores the report display screen 500 and the report display screen 600 displayed on the display 44 in the RAM 43.

  When the output button 604 of the report display screen 600 is touched, the CPU 41 generates a business report 700 by combining the report display screen 500 and the report display screen 600 in the RAM 43 as shown in FIG. The report 700 is printed on one or more sheets by an external printer connected to the tablet terminal 40 via a network.

  For the user, the contents of the operation data at the time designated by the cursor 301b are automatically converted and displayed on the report display screen 500 and the report display screen 600 in a format suitable for the business report. Since the business report 700 combined with the display screen 600 can be printed out as needed, the business efficiency after the operation status confirmation processing is completed is greatly improved.

[Effects of SD Memory Card 21]
Since the SD memory card 21 having the wireless communication function is added to the module controller 20, it is not necessary to provide each heat source unit and the module controller 20 with the wireless communication function. Therefore, the manufacturing cost of each heat source unit and module controller 20 can be reduced. In the case where the device itself has a wireless communication function, authentication according to the radio law of each country is required, so the cost of acquiring the authentication for each device is required. By using the memory card 21, it is possible to reduce the cost of acquiring certification related to the Radio Law for each device.

[Operation of each outside air fan 6 and each pump 8 for inspection work]
The tablet terminal 40 can operate the operation / stop of the outside air fan 6 and the pump 8 in each heat source unit when performing the inspection work of each heat source unit as well as the designation of the operation status confirmation mode.

[Activation function]
From the viewpoint of security, when it is desired to divide the display screens 200, 300, 400, 500, and 600 into a form for the manager and a form for the serviceman, and the business report 700 is used for the form for the manager and the form for the serviceman. It is assumed that the user wants to generate the data separately from the style.

  In this case, a function for displaying the display screens 200, 300, 400, 500, and 600 for the administrator to generate the business report 700 for the administrator, and a display screen 200, 300, 400, 500, and An application program that has a function of displaying 600 and generating a business report report 700 for a serviceman is mounted on the CPU 41 of the tablet terminal 40. The administrator is provided with an activation command and password dedicated to the administrator, and the serviceman is provided with an activation command and password dedicated to the serviceman. When the activation command and the password for the administrator are input, the CPU 41 of the tablet terminal 40 displays the display screens 200, 300, 400, 500, and 600 for the administrator and displays the business report 700 for the administrator. Generate. When the activation command and the password for the serviceman are input, the CPU 41 of the tablet terminal 40 displays the display screens 200, 300, 400, 500, and 600 for the serviceman and the business report 700 for the serviceman. Generate

  The CPU 41 of the tablet terminal 40 changes the screen for inputting the activation command and the password in response to, for example, a continuous touch operation on one of the start buttons 101 and 102 on the initial screen 100 or a blank portion of the initial screen 100. Pop-up display on the initial screen 100 in response to a continuous touch operation on.

[Reception section 21b and transmission section 21c of SD memory card 21]
The SD memory card 21 operates with power supplied from the module controller 20. The operation of the receiving section 21b of the SD memory card 21 is always turned on when at least one of the heat source units is in the operating state. The operation of the transmission section 21c of the SD memory card 21 is turned on only when at least one of the heat source units is in operation and a communication link with the tablet terminal 40 is established. Since the operation of the transmission section 21c is turned on only when the communication link is established, unnecessary leakage of data can be avoided, and the power consumption of the SD memory card 21 can be reduced.

[Modification]
The above embodiments have been presented by way of example, and are not intended to limit the scope of the invention. These new embodiments can be implemented in other various forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and their equivalents.

  UC1a to UC1m: Refrigeration cycle circuit, 11, 12: Piping for water circulation, 20: Module controller, 30: Unit controller, 40: Tablet terminal (information terminal), 41: CPU, 44: Touch panel display, 44a: Screen , 44b ... Touch panel

Claims (16)

A heat source unit for cooling or heating the heat medium,
A memory for storing data,
A controller that sequentially stores the operation data of the heat source unit in the memory,
A heat source device comprising:
The controller, by wirelessly transmitting the operation data in the memory to the information terminal, causes the information terminal to display the relationship between the time change of the operation data and the time,
A heat source device characterized by the above-mentioned. A heat source unit for cooling or heating the heat medium,
A memory for storing data,
A controller that sequentially stores the operation data of the heat source unit in the memory,
An information terminal having a display,
A heat source device comprising:
The controller wirelessly transmits the operation data in the memory to the information terminal,
The information terminal captures the wirelessly transmitted driving data, and displays on the display a graph indicating a relationship between a temporal change of the captured driving data and time,
A heat source device characterized by the above-mentioned. 3. The heat source device according to claim 2, wherein the information terminal displays, on the display, the content of operation data at a time specified on a graph being displayed on the display. 4. The display is a touch panel display,
The information terminal extracts driving data at a time designated by a touch operation on a graph being displayed on the display from the captured driving data, and displays the content of the extracted driving data on the display. The heat source device according to claim 2, wherein The said information terminal makes the display form of the content of the driving data displayed on the display differ according to whether the content of the driving data is included in a reference range. The heat source device according to the above.   The heat source device according to claim 5, wherein the reference range is variable according to an operation state of the heat source unit. The memory is an SD memory card having a wireless communication function,
The controller according to claim 2, wherein the controller wirelessly transmits operation data in the SD memory card to the information terminal by the SD memory card in response to a data request signal wirelessly transmitted from the information terminal. Heat source equipment. The memory includes a storage section that stores the operation data, a reception section that receives a signal wirelessly transmitted from the information terminal and supplies the signal to the controller, a signal emitted from the controller, and operation data in the storage section. An SD memory card including a transmission section that wirelessly transmits to an information terminal, and operates by power supplied from the controller.
The controller always turns on the operation of the reception section, and when a data request signal wirelessly transmitted from the information terminal is received in the reception section, the information terminal of the source of the data request signal is registered in advance. It is determined whether or not the information terminal is an information terminal, and on the condition that this determination result is affirmative, the operation of the transmission section is turned on, and communication for data transmission and reception between the controller and the information terminal of the transmission source is performed. The heat source device according to claim 2, wherein a link is formed, and with the formation of the communication link, operation data in the storage section is wirelessly transmitted to the information terminal by the transmission section. 3. The heat source device according to claim 2, wherein the information terminal generates and outputs a report file for a business report in which the content of the extracted operation data is represented by characters or images. 4. A heat source unit for cooling or heating a heat medium, a memory for data storage, and an information terminal used for managing a heat source device including a controller for sequentially storing operation data of the heat source unit in the memory,
Display and
A first control section configured to wirelessly transmit a data request signal for causing the controller to wirelessly transmit operation data in the memory to the controller when a driving state confirmation mode is designated;
In response to the data request signal, captures the operation data wirelessly transmitted from the controller, a second control section that displays a graph showing a relationship between time and time of the acquired operation data on the display,
An information terminal comprising: A third control section for extracting operation data at a time specified on the graph being displayed on the display from the captured data, and displaying the content of the extracted operation data on the display;
The information terminal according to claim 10, further comprising: The display is a touch panel display,
The third control section extracts driving data at a time designated by a touch operation on the graph displayed on the display from the captured driving data, and displays the content of the extracted driving data on the display. The information terminal according to claim 11, wherein: The said 3rd control section makes the display form of the content of the driving data displayed on the said display differ according to whether the content of the driving data is contained in a reference | standard range. The Claim 11 or Claim 11 characterized by the above-mentioned. 13. The information terminal according to 12.   14. The information terminal according to claim 13, wherein the reference range is variable according to an operation state of the heat source unit. The information terminal according to claim 11, further comprising: a fourth control unit that displays a report file for a business report in which the content of the extracted operation data is represented by characters or images on the display. A heat source unit for cooling or heating the heat medium, a memory for data storage, and an information terminal used for managing a heat source device including a controller for sequentially storing operation data of the heat source unit in the memory,
A first control unit that wirelessly transmits a data request signal for causing the controller to wirelessly transmit the operation data in the memory to the controller when an operation status confirmation mode is designated;
Second control means for capturing operation data wirelessly transmitted from the controller in response to the data request signal, and displaying a graph showing a relationship between a temporal change and time of the captured operation data on a display of the information terminal;
Control program to function as

Images