JP4106941B2 - Air conditioning apparatus control system, remote centralized management apparatus, and control system control method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to control of an air conditioner, and more particularly to a technique for optimizing operation control parameters in accordance with installation conditions after installation of the air conditioner to save energy.
[0002]
[Prior art]
  The characteristics of the air conditioner to be used vary depending on the temperature of the place where it is installed and the state of installation, but in general, after specifying a certain usage environment, it is anywhere within that range. A control algorithm has been constructed and embedded at the time of manufacture so that performance and reliability exceeding a predetermined level can be demonstrated.
  However, when actually used, various problems occur, and it may be necessary to change the setting of the control algorithm.
  For example, Japanese Patent Laid-Open No. 10-122631 discloses a method in which an operator operates a call button, first and second setting buttons according to a predetermined procedure while looking at a controller panel of an outdoor unit. And the type of operation control parameter, press the first setting button and the second setting button, change the setting value, and send this setting value to each indoor unit, the time interval for issuing the filter cleaning sign A method of making changes is disclosed.
[0003]
  Japanese Patent Laid-Open No. 2001-85475 discloses that control parameters for controlling the operation of the compressor and the blower are recorded in the ROM when the control board is manufactured. A method is disclosed in which an external device is connected, an alternative parameter is set from the external device to the EEPROM, and operation control of the compressor or the like is performed using the alternative parameter.
[0004]
[Problems to be solved by the invention]
  However, in the case of a conventional air conditioner, in order to deal with a problem, the user only has to reset the parameter with the problem. Therefore, it was not possible to reconfigure automatically, and it was not necessarily optimal for the usage environment.
[0005]
  In particular, recently, there has been an increasing demand for energy saving while ensuring comfort. For example, as disclosed in Japanese Patent No. 3078280, a dehumidification rotor and a sensible heat exchange rotor are provided, and intake air in ventilation air is reduced. Although dehumidification reduces the load on the refrigerated showcase and saves energy, this energy-saving setting varies depending on the temperature of the installation location and the installation conditions. Therefore, it is not necessarily the optimum one, and it cannot be said that a sufficient energy saving effect is achieved.
[0006]
  The present invention has been made to solve the above-mentioned problems, and it is possible to easily perform optimum parameter setting according to the installation location and use environment, and to perform the optimum operation for the use environment. And it aims at providing the control system and control method of the air conditioning apparatus which can aim at the energy saving effect sufficiently.
[0007]
[Means for Solving the Problems]
  A control system for an air conditioner according to the present invention includes a heat source unit including a compressor and a heat source side heat exchanger, a heat source unit controller that controls the heat source unit, an indoor unit including a throttling device and a use side heat exchanger, and An air conditioner equipped with an indoor unit controller for controlling the indoor unit, a remote control device connected to the air conditioner via a transmission line and controlling the operation of the air conditioner, and a pipe length of the air conditioner, or The setting condition information indicating the vertical relationship between the heat source unit and the indoor unit is input, and the input means for outputting the setting condition information to the remote control device, and from the site where the air conditioner and the remote control device are installed via the public line A remote centralized management device provided at a remote location and connected to the remote control device via a public line, and the remote centralized control device provides air conditioning based on setting condition information received from the remote control device. A control parameter such machine is energy-saving operationTo the value at which the high pressure side pressure of the heat source machine decreases according to the pipe length or the vertical relationshipA control parameter determining means for determining, and a remote operation transmitting means for transmitting the determined control parameter to the remote control device via a public line. The remote control device transmits the control parameter transmitted from the remote centralized management device to the public line. And the received control parameter is set in an air conditioner connected by a transmission line.
[0008]
  The remote centralized management apparatus of the present invention includes a heat source unit, a heat source unit controller that controls the heat source unit, an indoor unit, a plurality of air conditioners including an indoor unit controller that controls the indoor unit, and an air conditioner A remote centralized management device for remotely managing a control system via a public line, which is connected via a transmission line and controls a plurality of remote control devices for controlling the operation of the air conditioner. Or interface means for receiving setting condition information indicating the vertical relationship between the heat source unit and the indoor unit, and control of the air conditioner so that the air conditioner is in energy saving operation based on the setting condition information received by the interface means. ParameterTo the value at which the high pressure side pressure of the heat source machine decreases according to the pipe length or the vertical relationshipControl parameter determining means for determining and transmitting the determined control parameter to the air conditioner via the remote control device.
[0009]
  The control method of the control system of the present invention includes a heat source unit, a heat source unit controller that controls the heat source unit, an indoor unit, an air conditioner including the indoor unit controller that controls the indoor unit, and an operation of the air conditioner In a control method of a control system comprising a remote control device for controlling the remote control device and a remote centralized management device connected to the remote control device, the input means connected to the remote control device is the pipe length of the air conditioner or the heat source device Receiving setting condition information indicating a vertical relationship between the remote control device and the indoor unit, a step in which the remote control device transmits setting condition information to the remote centralized management device via a line, Based on the information, control parameters of the air conditioner so that the air conditioner operates in energy saving mode.To the value at which the high pressure side pressure of the heat source machine decreases according to the pipe length or the vertical relationshipDetermining and returning the control parameter determined via the line to the remote control device; the air conditioner receives the control parameter from the remote control device; and the contents of the control parameter storage means of the heat source controller with the received control parameter And a step of rewriting.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
  1 is a configuration diagram of a refrigerant circuit of an air-conditioning apparatus according to Embodiment 1. FIG.
  In FIG. 1, the refrigerant circuit of the air conditioner includes a compressor 1, a four-way valve 2, a heat source side heat exchanger 3, a heat source side heat exchanger blower fan 4, a compressor output high pressure detection device 5, and a compressor input low pressure. A heat source unit 7 having a detection device 6, an expansion valve 100, an indoor side heat exchanger 101, an indoor unit 103 having an indoor side heat exchanger blower fan 102, and a first source that connects the heat source unit 5 and the indoor unit 103. It is mainly composed of a pipe 201 and a second pipe 202.
[0011]
  Next, the connection configuration of each control device for controlling the operation of the air conditioner will be described based on the configuration diagram of the control system in FIG.
  In FIG. 2, the control system for the air conditioner is mainly configured by connecting a heat source device controller 50, an indoor unit controller 150, a remote operation device 300, and a remote centralized management device 400. The heat source device controller 50, the indoor unit controller 150, and the remote operation device 300 are connected by a transmission line 500, and the remote operation device 300 and the remote centralized management device 400 are a public line connection device (modem) 501 and Connection is made via a public line 502.
[0012]
  The heat source controller 50 includes a heat source controller 51, a heat source sensor input means 52, a heat source actuator output means 53, a heat source transmission means 54, a control parameter storage means (nonvolatile memory) 55, and a parameter rewriting means 56. Have. The indoor unit controller 150 includes an indoor unit control unit 151, an indoor unit sensor input unit 152, an indoor unit actuator output unit 153, an indoor unit transmission unit 154, a control parameter storage unit (nonvolatile memory) 155, and a parameter rewriting unit 156. ing. The remote operation device 300 includes a remote operation control unit 301, a remote operation transmission unit 302, an I / F (interface) unit 303, a control parameter storage unit (non-volatile memory) 304, and a parameter rewrite unit 305. The modem 501, the input unit 306, and the display unit 307 are connected via the F unit 303. The remote centralized management device 400 includes a remote centralized management control unit 401, an I / F unit 402, a control parameter storage unit (nonvolatile memory) 403, a parameter rewriting unit 404, a remote information determination unit 405, and parameter option D / B (database). 406. The remote central management control unit 401, the remote information determination unit 405, and the parameter option D / B 406 mainly constitute a control parameter determination unit.
[0013]
  Next, what kind of processing is performed in the control system shown in FIG. 2 when changing the control parameters of the air conditioner will be described based on the flowchart of FIG.
  First, the user inputs setting condition information to the remote control device 300 from the input means 301 (step (hereinafter referred to as “S”) 1).
  In the remote operation device 300, the setting condition information is received by the I / F means 303 and transmitted to the remote centralized management device 400 via the public line 502 (S2).
  In the remote centralized management device 400, the transmitted setting condition information is received by the I / F unit 402 and sent to the remote centralized management control unit 401. In the remote centralized management control unit 401,
Optimum using parameter option D / B 406 and remote information determination means 405
A control parameter is determined (S3).
[0014]
  Next, the remote centralized management control unit 401 determines the end of the control parameter determination process (S4), and if it does not end, executes S1 and subsequent steps again.
  If it is determined in S4 that the process is ended, the remote centralized management control unit 401 rewrites the contents of the control parameter storage unit 403 by associating the determined control parameter with the identification information (not described in detail) of the target air conditioner. (S5) Further, the control parameter is transmitted from the I / F unit 402 to the remote control device 300 via the modem 501 and the public line 502 (S6).
  In the remote operation device 300, the control parameter is received by the I / F unit 303, and the setting condition information and the control parameter are displayed on the display unit 307 (S7).
  Further, the remote operation control unit 301 uses the parameter rewriting unit 305 to rewrite the contents of the control parameter storage unit 304 with the sent control parameters (S8).
[0015]
  In the remote operation device 300, the remote operation transmission unit 302 transmits control parameters to the heat source device controller 50 and the indoor unit controller 150 via the transmission line 500 (S9).
  In the heat source device controller 50 and the indoor unit controller 150, the parameter rewriting means 56 and the parameter rewriting means 156 are used to rewrite the contents of the control parameter storage means 55 and 155 to the sent control parameters (S10).
  Thereby, the operation of the heat source device 7 and the indoor unit 103 is controlled by the control program that operates based on the rewritten control parameter.
[0016]
  FIG. 3 shows the case where the control parameter is changed in a state where the remote operation device 300 has already been installed and the operation is controlled. For example, the remote operation device itself may be replaced due to a failure or the like.
  Based on the flowchart of FIG. 4, a method for reflecting the already set control parameters in the remote operation device 300 when the content of the control parameter storage unit 304 of the remote operation device 300 becomes the initial value due to such exchange or the like. I will explain.
[0017]
  First, in the remote operation device 300, the remote operation control unit 301 determines whether or not the control parameter stored in the control parameter storage unit 304 is an initial value (S11). A command to transfer the control parameter stored in the control parameter storage unit 403 of the remote centralized management device 400 is issued via 502 to determine whether or not the control parameter transmitted from the remote centralized management device 400 is an initial value. (S12).
  If it is not the initial value in S11, the process proceeds to the normal operation as it is.
[0018]
  If the transferred control parameter is not the initial value in S12, the transferred control parameter is displayed on the display means 307, and the user waits for an input as to whether or not to use the control parameter (S13).
  In S13, when the user inputs from the input unit 306 that the control parameters of the remote centralized management device 400 are used as they are, the parameter rewriting unit 305 is used to change the contents of the control parameter storage unit 304 to the transmitted control parameters. Rewriting (S14), and further, this control parameter is transmitted to the heat source controller 50 and the indoor unit controller 150, and the contents of the control parameter storage means 55 and 155 are rewritten to the transmitted control parameters (S15). ). Further, when the control parameters of the remote centralized management device 400 are initial values in S12, and when the user inputs that the control parameters of the remote centralized management device 400 are not used in S13, the control shown in FIG. The process shifts to parameter change processing, and optimal control parameters are generated.
[0019]
  The flowchart shown in FIG. 3 is the one after the air conditioner has already started operation. However, conversion of the equipment configuration of the air conditioner, for example, replacement / addition of a heat source unit and an indoor unit has already been performed. The stored control parameters may be in a state where sufficient performance cannot be achieved, and an error occurs when transmitting the control parameters, and the consistency between the control devices is not achieved. A situation may occur.
  In order to cope with such a situation, the control system checks the validity of the control parameters periodically, particularly when the power is turned on.
  This check operation will be described based on the flowchart of FIG.
[0020]
  First, it is determined whether or not the remote control device 300 is powered on (S21). If it is determined in S21 that the power is turned on, the control parameter stored in the control parameter storage means 403 of the remote centralized management device 400 is transmitted to the remote operation device 300 via the public line 502 (S22). ).
  Next, the remote operation device 300 compares the control parameter transmitted from the remote centralized management device 400 with the control parameter stored in the control parameter storage unit 304 of the remote operation device 300, and determines whether or not they match. Is determined (S23).
  If it is determined in S23 that they do not match, the control parameter storage unit 304 of the remote operation device 300 displays on the display unit 307 whether or not to use the transmitted control parameter. (S24).
  In S24, when information indicating that the user uses the transmitted control parameter is input from the input unit 306, the contents of the control parameter storage unit 304 of the remote operation device 300 are rewritten to the transferred control parameter (S25). Further, this control parameter is transmitted to the heat source device controller 50 and the indoor unit controller 150, so that the contents of the control parameter storage means 55 and 155 are rewritten to the transmitted own control parameters (S30). In S24, when the user inputs information indicating that the transmitted control parameter is not used, the process proceeds to the control parameter changing process shown in FIG. 3, and an optimal control parameter is generated (S31).
[0021]
  If it is determined in S21 that the remote control device 300 is not turned on, or if it is determined in S23 that the control parameters do not match, then the heat source controller 50 and the indoor unit controller 150 It is determined whether the power is turned on (S26).
  If it is determined in S26 that the power has been turned on, the control parameters stored in the control parameter storage means 55 of the heat source controller 50 or the control parameter storage means 155 of the indoor unit controller 150 are transferred to the remote operation device 300. Send.
  The remote operation device 300 compares the transmitted control parameter with the control parameter stored in the control parameter storage unit 304, and determines whether or not they match (S28).
[0022]
  If it is determined in S28 that they do not match, whether or not to use the control parameters of the remote operation device 300 is displayed on the display means 307, waits for user information input (S29), and is used by the user. Is input from the input unit 306, the control parameter of the remote operation device 300 is transmitted to the heat source controller 50 or the indoor unit controller 150, and the contents of the control parameter storage unit 55 or the control parameter storage unit 155 are changed. Rewrite (S30).
  In addition, when information indicating that it is not used in S29 is input, an optimal control parameter is generated in S31.
  If the control parameters match in S28, the process ends.
[0023]
  In S1 to S3 in FIG. 3, the optimum control parameter is determined according to the setting condition information input by the user from the input unit 306. An example of the control parameter determination algorithm is shown in the flowchart of FIG. Based on
  First, a screen asking about the horizontally arranged refrigerant pipe length is displayed on the display means 307. The user inputs the refrigerant pipe length (l1) using the input means 306, and this information is transmitted to the remote centralized management device 400. (S41).
  In the remote centralized management control means 401 of the remote centralized management device 400,
ΔP1 = (first predetermined length−l1) / first predetermined value (1)
ΔP1 is obtained (S42). Note that the first predetermined length is assumed to be the maximum possible pipe length, for example, 50 m, and the first predetermined value may be about 1000. If it does in this way, the target high voltage | pressure at the time of 0.01 Mpa cooling can be reduced for every 10 m short with respect to the 1st predetermined length.
[0024]
  Next, on the display means 307, a screen asking whether the extension pipe length in the vertical direction and the heat source unit is above or below the indoor unit is displayed, and the user uses the input means 306 to extend the screen. The pipe length (12) and the vertical relationship are input, and this information is transmitted to the remote centralized management device 400 (S43).
  The remote centralized management control means 401 of the remote centralized management apparatus 400 first determines whether the heat source unit is above or below the indoor unit (S44), and if it is determined that the heat source unit is above. , L2 = 0 (S45).
  After setting l2 = 0 in S45, or if it is determined in S44 that the heat source unit is down,
    ΔP2 = (second predetermined length−l2) / second predetermined value (2)
ΔP2 is obtained (S46). Note that the second predetermined length may be the maximum pipe length assumed, for example, 50 m, and the second predetermined value may be about 100. If it does in this way, the target high pressure at the time of 0.1 Mpa cooling can be reduced for every 10 m shorter than the 2nd predetermined length.
[0025]
  Next, a screen asking whether to increase the air flow rate of the heat source unit is displayed on the display unit 307, and the user uses the input unit 306 to input whether or not to increase, and this information is the remote centralized management device. It is transmitted to 400 (S47).
  In S47, ΔP3 = predetermined value (> 0) is set (S48) when input is made to increase, and ΔP3 = 0 is set if not input (S49), ΔP1, ΔP2, and ΔP3 are set. make use of,
    Cooling target high pressure = original value−ΔP1−ΔP2−ΔP3 Equation (3)
    Heating target low pressure = original value + ΔP3 Formula (4)
Is calculated, and optimal control parameters for the cooling target high pressure and the heating target low pressure are set (S50). Note that ΔP3 needs to be set in consideration of the blower wind noise and the like at the design stage.
[0026]
  Next, the display unit 307 displays a screen asking whether there is a low-temperature device such as a showcase as an indoor environmental load, and the user uses the input unit 306 to input whether there is a low-temperature device. This information is transmitted to the remote centralized management apparatus 400 (S51).
  If it is input in S51 that there is a low-temperature device, the remote centralized management control means 401 uses the minimum value min. A predetermined value is set (S52), and further, a setting for performing dehumidification at the time of thermo-off is set to ON (S53). Note that, in the air conditioner and the low-temperature equipment, the air conditioner can perform more efficient operation. Therefore, it is preferable for energy saving control to reduce the work amount of the low-temperature equipment. Therefore, the target low pressure of the air conditioner is reduced to min. If the value is set to a predetermined value, the temperature difference between the air and the heat exchanger will increase during operation, and more humidity in the air can be taken, so the work used for moisture condensation in low-temperature equipment can be reduced. Overall, energy saving can be achieved.
[0027]
  If it is input in S51 that there is no low temperature device, a screen for inputting the sensible heat ratio of the indoor environment assumed during the cooling operation is displayed, and the user uses the input means 306 to display the sensible heat ratio. This information is transmitted to the remote centralized management apparatus 400 (S54).
  Next, from this input sensible heat ratio,
    ΔP4 = sensible heat ratio / third predetermined value (5)
ΔP4 is calculated (S55),
    Cooling target low pressure = original value + ΔP4 Equation (6)
Is calculated, and the optimum control parameter of the cooling target low pressure is set (S56).
  In S54, instead of directly inputting the sensible heat ratio, for example, the type and number of heat sources (OA equipment, etc.) existing in the space are input, and the sensible heat is based on the information of the parameter option D / B 406. The ratio may be calculated.
[0028]
  Next, a screen for inputting whether or not the air flow rate of the blower of the indoor unit may be increased (whether the noise level and draft feeling / comfort are allowed) is displayed, and the user uses the input means 306 to increase the air flow rate. This information is transmitted to the remote centralized management device 400 (S57).
  When there is an input to increase in S57, the remote centralized management control means 401 turns ON the setting for implementing the indoor unit blower air volume increase (S58).
[0029]
  After S53, S57, and S58 are executed, the display unit 307 displays a screen asking whether the place where the air conditioner is installed is the Sea of Japan side, the inland side, or the Pacific side. Is used to select one of them, and this information is transmitted to the remote centralized management apparatus 400 (S59).
  In the remote centralized management device 401, if the information sent in S59 is the environment on the Sea of Japan side, the defrost operation cycle is set to a predetermined “short” setting (the defrost cycle is short) (S60), and the inland environment may be used. For example, the defrosting operation cycle is set to a predetermined “medium” setting (defrosting cycle is standard) (S61), and if the environment is on the Pacific side, the defrosting operation cycle is set to a predetermined “long” setting (defrosting cycle is long). (S62), this control is terminated.
  In addition, the defrost operation is changed on the Sea of Japan side, the inland, and the Pacific side in this way. On the Sea of Japan side, frost is easily formed during the heating operation, and efficient heating operation can be obtained by frequently performing the defrost operation. On the Pacific side, even if the temperature is low, the actual amount of frost formation is relatively small, so that efficient heating operation can be obtained by avoiding defrost operation as much as possible.
  Here, in particular, the area is divided into three sections. For example, a prefecture name may be input, and a defrost operation cycle may be set for each prefecture.
[0030]
  Thus, in this embodiment, since the control parameter can be changed depending on the use environment, the optimum / energy-saving operation corresponding to the actual use environment can be realized.
  In addition, it is possible to cope with appropriate energy saving control even for conditions that are difficult to discriminate by automatic judgment of the area or the like.
  In addition, since some options are provided in advance, changes to inappropriate parameters can be suppressed, and determination can be facilitated in an artificial setting.
  In addition, since the control parameter is created by the remote centralized management device, the judgment S / W can be centrally managed and the version up is easy.
  In addition, since the control parameters are stored and managed in a centralized manner using a remote centralized management device, it is possible to centrally manage the status of individual changes and to check without going to the site, and even if the actual product is damaged, information remains and is restored. Is possible. Furthermore, when the controller of the heat source unit and the indoor unit is exchanged, the control parameters can be restored only with the local information such as the stored contents of the remote control device.
  In addition, since the consistency check of the control parameters is performed between the remote centralized management device and the remote operation device, it is possible to guarantee the operation with the accurate control parameters.
  In addition, since the control parameters are adjusted based on the horizontal and vertical refrigerant pipe length data, it is possible to realize energy-saving control adapted to the site for the initial value set for the longest time.
  Moreover, when it is known that the sensible heat ratio is high, such as a computer room, it is not necessary to take the humidity. Therefore, the control parameters can be changed according to the control parameter, and energy saving control adapted to the site can be realized.
  Further, if it is known that the draft feeling by the blower is not a problem as the indoor environment, the operating efficiency can be improved with respect to the initial state by the capacity up due to the increase in the air volume.
  Further, if it is known that there is a low-temperature device such as a showcase as an indoor environmental load, overall energy saving can be realized although the efficiency of the air conditioner is reduced.
[0031]
Reference example.
  FIG. 7 is a configuration diagram of the refrigerant circuit of the air-conditioning apparatus according to Embodiment 2. FIG. 8 is a configuration diagram of the control system of the air-conditioning apparatus according to Embodiment 2. 7 and 8, the same components as those described in FIGS. 1 and 2 and the corresponding components are denoted by the same reference numerals, and the description thereof is omitted.
  In FIG. 7, an outside air temperature detecting unit 8, an outside air humidity detecting unit 9, and a heat source side heat exchanger pipe temperature detecting unit 10 are newly added to the heat source unit 7. In addition, a drain pump 104, an intake air temperature detection means 105, a blown air temperature detection means 106, and an indoor heat exchanger pipe temperature detection means 107 are newly added to the indoor unit 103.
  In FIG. 8, an information determination unit 57 is newly added to the heat source controller 50, and an information determination unit 157 is newly added to the indoor unit controller 150.
[0032]
  Next, what kind of processing is performed in the control system shown in FIG. 8 when changing the control parameters of the air conditioner will be described based on the flowchart of FIG.
  First, the remote control device 300 acquires necessary operation data from the heat source controller 50 and the indoor unit controller 150 via the transmission line 500 (S71).
  Next, the operation data acquired via the public line 502 is transmitted from the remote operation device 300 to the remote centralized management device 400 (S72).
  In the remote centralized management apparatus 400, the remote centralized management control unit 401 utilizes the remote information determination unit 405 and the parameter option D / B 406 to determine the optimal control parameter.
[0033]
  Next, the remote centralized management control means 401 associates the determined optimum control parameter with the identification information of the target air conditioner, rewrites the contents of the control parameter storage means 403 (S74), and the control parameter is the I / F. The information is transmitted from the means 402 to the remote control device 300 via the modem 501 and the public line 502 (S75).
  In the remote operation device 300, the control parameter is received by the I / F unit 303, the parameter rewriting unit 305 is used to associate the control parameter with the identification information of the target air conditioner, and the content of the control parameter storage unit 304 is rewritten ( S76).
[0034]
  The remote operation device 300 transmits control parameters to the heat source unit controller 50 and the indoor unit controller 150 via the transmission line 500 (S77). In the heat source unit controller 50 and the indoor unit controller 150, the parameter rewriting means 56 and the parameters are transmitted. Using the rewriting means 156, the contents of the control parameter storage means 55 and 155 are rewritten with the transmitted control parameters (S78).
[0035]
  Next, the control performed in S73 of FIG. 9 will be described based on the flowchart of FIG.
  First, the detection value (hereinafter referred to as “107 detection value”) detected by the indoor heat exchanger pipe temperature detection means 107 and the detection value (hereinafter referred to as “107 detection value”) detected by the heat source side heat exchanger pipe temperature detection means 10. (Referred to as “10 detection values”)
  ΔP5 = indoor low pressure value-heat source low pressure value
= F {(107 detection value)-(10 detection value)} Expression (7)
Is obtained (S81).
next,
    ΔP5 ′ = first predetermined ratio * ΔP5 Equation (8)
Is obtained (S82). Note that ΔP5 ′ is a relaxation amount of the high-pressure target value, and the first predetermined ratio can be about 10.
next,
    Cooling high pressure target value = original value−ΔP5 ′
Is obtained (S83).
  Next, using the suction air temperature detecting means 105 and the blowing air temperature detecting means 106 detected by the suction air temperature detecting means 105 and the blowing air temperature detecting means 106, respectively,
Sensible heat ratio equivalent value = (105 suction temperature−106 blowing temperature) * air volume / LEV opening command value (9)
Is obtained (S84). (LEV opening command value is a control amount for throttle amount adjustment control of the throttle device)
  next,
    ΔP6 = P6 predetermined value * sensible heat ratio equivalent value / fourth predetermined value Formula (10)
Is obtained (S85). Note that the P6 predetermined value is a value that defines the upper limit of the change range of the target pressure, and can be about 0.02 MPa.
  Next, from the time when the drain pump 104 was in the ON state,
    Drain estimated value = Drain pump ON time / (Drain pump ON time + Drain pump OFF time) Equation (11)
Is obtained (S86).
  next,
    ΔP7 = P7 predetermined value * drain estimated value / fifth predetermined value (12)
Is obtained (S87). Note that the P7 predetermined value is a value that defines the upper limit of the change range of the target pressure, and can be about 0.02 MPa.
[0036]
  Next, it is determined whether or not the outside air temperature Tout detected by the outside air temperature detecting means 8 exceeds T1 and whether or not it exceeds T2 (S88).
  In S88, if Tout <T1, ΔP8 = predetermined value a (S89), if T1 ≦ Tout ≦ T2, ΔP8 = predetermined value b (S90), and if T2 <Tout, ΔP8 = predetermined value c (S91). Here, the predetermined value a> the predetermined value b> the predetermined value c is set.
[0037]
  After S89 is executed, a screen asking whether the place where the air conditioner is installed is the Sea of Japan side, the inland side, or the Pacific side is displayed on the display unit 307. The user uses the input unit 306, One of them is selected, and this information is transmitted to the remote centralized management apparatus 400 (S92).
  When the Sea of Japan side is selected in S92, the estimated humidity is set to A (S93),
ΔP9 = second predetermined ratio * A (13)
Is obtained (S94).
  If inland is selected in S92, the estimated humidity is set to B (S95),
ΔP9 = second predetermined ratio * B (14)
Is obtained (S96).
  If the Pacific side is selected in S92, the estimated humidity is set to C (S96), ΔP9 = second predetermined ratio * C (Equation (15))
Is obtained (S97).
[0038]
  Similarly, after S90 is executed, the display unit 307 displays a screen asking whether the location where the air conditioner is installed is the Sea of Japan side, the inland side, or the Pacific side. Use to select one of them, and this information is transmitted to the remote centralized management apparatus 400 (S99).
  Here, when the Sea of Japan side is selected, the estimated humidity = D (S100),
ΔP9 = second predetermined ratio * D (16)
Is obtained (S101).
  If inland is selected in S99, the estimated humidity is set to E (S102).
ΔP9 = second predetermined ratio * E (17)
Is obtained (S103).
  If the Pacific side is selected in S99, the estimated humidity = F (S104), ΔP9 = second predetermined ratio * F (18)
Is obtained (S105).
[0039]
  Similarly, after S91 is executed, the display unit 307 displays a screen asking whether the location where the air conditioner is installed is the Sea of Japan side, the inland side, or the Pacific side. Use to select one of them, and this information is transmitted to the remote centralized management apparatus 400 (S106).
  Here, when the Sea of Japan side is selected, the estimated humidity is set to G (S107),
ΔP9 = second predetermined ratio * G (19)
Is obtained (S108).
  If inland is selected in S99, the estimated humidity is set to H (S109),
ΔP9 = second predetermined ratio * H Expression (20)
Is obtained (S110).
  If the Pacific side is selected in S99, the estimated humidity = J (S111), ΔP9 = second predetermined ratio * J Equation (21)
Is obtained (S112).
  Note that there is a relationship of estimated humidity A = estimated humidity D = estimated humidity G> estimated humidity B = estimated humidity E = estimated humidity H> estimated humidity C = estimated humidity F = estimated humidity J.
  The numerical setting of the estimated humidity is preferably averaged from statistical materials, but the estimated humidity A = 70%, the estimated humidity B = 60%, and the estimated humidity C = 50% may be used.
[0040]
  After the processing of S94, S96, S98, S101, S103, S105, S108, S110, and S112 is completed,
  Cooling target low pressure = original value + (sixth predetermined value−ΔP5) + ΔP6 + ΔP7 + ΔP8 + ΔP9 (22)
(S113), based on the 105 indoor intake temperature detected by the intake air temperature detection means 105,
  ΔP10 = third predetermined ratio * (seventh predetermined value−105 indoor suction temperature)
                                                        ... Formula (23)
(S114),
    Heating target high pressure = original value + ΔP10 Formula (24)
(S115).
[0041]
  Next, it is determined whether or not the pipe temperature (hereinafter referred to as “10 pipe temperature”) detected by the heat source side heat exchanger pipe temperature detecting means 10 is higher than 0 ° C. (S116). In this case, the defrost cycle is Ta (S117).
  If it is determined in S116 that the temperature is 0 ° C. or less, it is determined whether or not the outside air temperature: Tout exceeds T3 and whether it exceeds T4 (S118). If Tout <T3, the defrost cycle is determined. Is set to Tb (S119), if T3 ≦ Tout ≦ T4, the defrost cycle is set to Tc (S120), and if T4 <Tout, the defrost cycle is set to Td (S121), and then the process ends. Here, Ta> Tb> Tc> Td is set, and numerically, for example, Ta = 180 minutes, Tb = 120 minutes, Tc = 90 minutes, and Td = 60 minutes.
[0042]
  Here, the optimum control parameter is determined in the remote centralized management apparatus. However, the information determination means 57 and 157 of the heat source device controller 50 and the indoor unit controller 150 are configured to rewrite the control parameter by an original determination. Of course it is also possible.
[0043]
  In this embodiment, since optimum control parameters are set based on the values detected by the heat source unit and the indoor unit, it is possible to cope with appropriate energy saving control without manpower. Furthermore, appropriate energy-saving control can be handled by appropriately changing the actual usage environment.
  Further, by estimating the sensible heat ratio of the cooling load from the cooling capacity of the indoor unit and changing the cooling target low pressure accordingly, the operation efficiency can be improved by increasing the low pressure.
  In addition, by knowing the drain water generation status from the drain water drainage status, estimating the sensible heat ratio of the indoor cooling load therefrom, and changing the cooling target low pressure accordingly, the operating efficiency can be improved by increasing the low pressure.
  Further, it is possible to improve the operating efficiency by using the outside air humidity from the assumption that the outside air humidity affects the indoor environment humidity, and increasing the cooling target low pressure based on the determination that the dehumidifying capacity is unnecessary as the humidity decreases.
  In addition, it is possible to improve the operating efficiency by estimating the outside air humidity according to the outside air temperature from the assumption that the absolute humidity varies according to the outside air temperature and the information on the locality, and increasing the cooling target low pressure as the humidity is lower .
  Further, the operating efficiency can be improved by increasing the cooling target low pressure as the outside air temperature is lower, based on the assumption that the absolute humidity varies depending on the outside air temperature.
  In addition, since the heating load can be determined from the indoor suction temperature, the lighter the load, the lower the heating target high pressure, thereby reducing the input and improving the operation efficiency.
  In addition, when the outside air temperature is low, the absolute humidity is also low, so that the amount of frosting is determined, so that the heating operation efficiency can be improved by changing the defrost cycle according to the outside air temperature.
  Moreover, heating operation efficiency can be improved by changing a defrost cycle according to piping temperature by judgment that there is basically no frost when piping temperature is 0 degreeC or more.
[0044]
Embodiment2.
  FIG. 11 is a configuration diagram of a control system according to the third embodiment, which controls the defrost operation. In FIG. 11, the same reference numerals are used for the same configuration as in FIG. 2 and the corresponding configuration, and the description is omitted.
  In FIG. 11, the remote operation device 300 includes a remote operation control unit 301, a remote operation transmission unit 302, a heat source unit number storage unit 306, and a defrost standby operation unit 307. In addition, a plurality of heat source machine controllers 50 from No. 1 to No. n are connected to the remote control device 300 via a transmission line 500. The heat source machine controller 50 includes a heat source machine controller 51, a heat source machine. Transmission means 54 and defrost standby means 58 are provided.
[0045]
  Next, the operation of the defrost operation control during the heating operation in the control system of FIG. 11 will be described based on the flowchart of FIG.
  Here, the operation of the remote control device 300 and the operation of the heat source controller 50 will be described separately.
  First, in the defrost standby operation means 307 of the remote control device 300, i = 1 corresponding to the outdoor unit No. is set (S130), and the defrost operation of the No. i unit is set to the standby state (specifically, the defrost standby is set in the heat source unit). Information is transmitted, and the defrost stand-by flag in the defrost stand means 58 of the heat source machine is turned ON).
  Next, i = i + 1 is set (S132), and it is determined whether i = n + 1 based on the number n stored in the heat source unit number storage means 306 (S133).
  If it is determined in S133 that i is not n + 1, S131 and subsequent steps are executed again.
  In S133, when i is n + 1 (at this time, the defrost stand-by flag is turned on in all the heat source machines), i = 1 is set again (S134), the defrost stand-by of i-th unit is canceled, and the defrost is set. A permission state is set (specifically, defrost standby release information is transmitted to the heat source unit, and the defrost standby flag in the defrost standby unit 58 of the heat source unit is turned OFF) (S135).
  Next, it waits for a predetermined time to elapse (S136), and after i = i + 1 (S137), it is determined whether i = n + 1 (S138).
  When it is determined in S138 that i = n + 1, the n-th machine is put into a defrost standby state (S139), and S134 and subsequent steps are executed again.
  If it is determined in S138 that i = n + 1 is not true, the i-1 unit is placed in a defrost standby state (S140), and S135 and subsequent steps are executed again.
[0046]
  Next, the operation of the heat source device controller 50 will be described.
  First, it is determined whether or not the defrost enable flag of the defrost standby means 58 is ON (S151). If it is not ON, it is determined whether or not the defrost start condition is satisfied (S152).
  If it is determined in S152 that the defrost start condition is satisfied, the defrost enable flag is set to ON (S153).
  Next, it is determined whether or not the defrost standby flag of the defrost standby means 58 is ON (S154). If it is determined that the defrost standby flag is not ON, the defrost operation is executed (S155). In addition, when it determines with it being ON, a normal driving | operation is performed (S156).
[0047]
  If the defrost operation is executed in S154, it is determined whether or not the defrost end condition is satisfied (S157). If it is determined that the end condition is satisfied, the defrost enable flag is turned OFF. (S158), wait for a fixed time (S159), and then execute S151 and subsequent steps again.
  Note that if it is determined in S157 that the end condition is not satisfied, the process proceeds to S159.
[0048]
  With such a configuration, the time of defrost operation of each heat source unit can be shifted, and the effect of defrost on the indoor environment can be mitigated in terms of ensuring comfort as a background in implementing energy saving operation. It has an effect in the form of
[0049]
Embodiment3.
  FIG. 13 is a flowchart showing the operation of the control system according to the fourth embodiment. When the remote centralized management device 400 creates optimal control parameters, each remote control device 300 is charged. Is.
  In FIG. 13, an access request for requesting creation of a control parameter is issued from the remote operation device 300 to the remote centralized management device 400 (S161).
  After receiving this access request, remote centralized management apparatus 400 makes an inquiry to remote operation apparatus 300 as to whether or not to accept the billing (S162). In S162, when the remote centralized management device 400 replies that the remote operation device 300 responds to the billing within a certain time, it is based on the information transmitted from the remote operation device 300 as shown in FIG. An optimal control parameter is generated (S163). Also, if there is no reply within a certain period of time, or if there is a reply that does not respond to billing, the process is terminated, and the control parameter generation process even if the setting condition information is transmitted from the remote operation device 300 Do not execute.
[0050]
  In this way, both users and manufacturers are satisfied by providing appropriate paybacks to the air conditioner and its system providers (manufacturers), while providing energy saving benefits to users. Obtainable.
[0051]
【The invention's effect】
  As described above, according to the control system for an air conditioner of the present invention, the heat source device including the compressor and the heat source side heat exchanger, the heat source device controller for controlling the heat source device, the expansion device, and the use side heat exchanger are provided. An indoor unit equipped with the air conditioner, an air conditioner including an indoor unit controller for controlling the indoor unit, a remote control device connected to the air conditioner via a transmission line and controlling the operation of the air conditioner, and an air conditioner After machine installationShows the pipe length of the air conditioner or the vertical relationship between the heat source unit and the indoor unitAn input means for inputting the setting condition information and outputting the setting condition information to the remote control device; a remote control device provided at a position separated from the site where the air conditioner and the remote control device are installed via a public line Remote centralized management device connected via a public line to the remote centralized management device based on the setting condition information received from the remote control deviceSo that air conditioner becomes energy saving operationA control parameter determining means for determining a control parameter; and a remote operation transmitting means for transmitting the determined control parameter to the remote operation device via a public line. The remote operation device receives the control parameter transmitted from the remote centralized management device. Because the control parameters received via the public line and the received control parameters are set in the air conditioner connected by the transmission line, the control parameters can be set more optimally according to the installation conditions, thereby saving energy. And a more comfortable use environment can be maintained.
[0052]
  According to the remote centralized management apparatus of the present invention, a heat source unit, a heat source unit controller for controlling the heat source unit, an indoor unit, a plurality of air conditioners including an indoor unit controller for controlling the indoor unit, and air A remote centralized management device for remotely managing a control system with a plurality of remote control devices connected to a conditioner via a transmission line and controlling the operation of the air conditioner via a public line,Shows the pipe length of the air conditioner or the vertical relationship between the heat source unit and the indoor unitBased on the interface means for receiving the setting condition information and the setting condition information received by the interface meansSo that air conditioner becomes energy saving operationControl parameter determination means for determining the control parameters of the air conditioner and transmitting the determined control parameters to the air conditioner via the remote control device, so that energy-saving control adapted to the site can be performed remotely. .
[0053]
  Further, according to the control method of the control system of the present invention, the heat source unit, the heat source unit controller for controlling the heat source unit, the indoor unit, and the air conditioner and the air conditioner provided with the indoor unit controller for controlling the indoor unit In a control method for a control system comprising a remote control device for controlling the operation of the remote control device and a remote centralized management device connected to the remote control device, the input means connected to the remote control device includes:Shows the pipe length of the air conditioner or the vertical relationship between the heat source unit and the indoor unitA step of accepting input of setting condition information; a step of transmitting the setting condition information to a remote centralized management apparatus via a line; and a remote centralized management apparatus based on the setting condition informationSo that air conditioner becomes energy saving operationDetermining the control parameters of the air conditioner and returning the control parameters determined via the line to the remote control device; the air conditioner receives the control parameters from the remote control device; and the heat source controller with the received control parameters The step of rewriting the contents of the control parameter storage means is provided, so that energy-saving control adapted to the site can be performed remotely.
[0054]
[Brief description of the drawings]
FIG. 1 is a refrigerant circuit diagram of an air conditioner according to Embodiment 1. FIG.
FIG. 2 is a configuration diagram of a control system in the first embodiment.
FIG. 3 is a flowchart of the control system in the first embodiment.
FIG. 4 is a flowchart of the control system in the first embodiment.
FIG. 5 is a flowchart of the control system in the first embodiment.
FIG. 6 is a flowchart of a control system in the first embodiment.
7 is a refrigerant circuit diagram of the air-conditioning apparatus according to Embodiment 2. FIG.
FIG. 8 is a configuration diagram of a control system in a second embodiment.
FIG. 9 is a flowchart of the control system in the second embodiment.
FIG. 10 is a flowchart of a control system in the second embodiment.
FIG. 11 is a configuration diagram of a control system in a third embodiment.
FIG. 12 is a flowchart of the control system in the third embodiment.
FIG. 13 is a flowchart of the control system in the fourth embodiment.
[Explanation of symbols]
  1 compressor, 2 four-way valve, 3 heat source side heat exchanger,
  4 heat source side heat exchanger blower fan, 5 compressor output high pressure detector,
  6 Compressor input low pressure detector, 7 Heat source machine,
  8 outside air temperature detecting means, 9 outside air humidity detecting means,
  10 heat source side heat exchanger piping temperature detection means,
  50 heat source machine controller, 51 heat source machine control means,
  52 heat source machine sensor input means, 53 heat source machine actuator output means,
  54 heat source machine transmission means, 55 control parameter storage means,
  56 control parameter rewriting means, 57 information determining means,
  58 defrost waiting means,
  100 expansion valve, 101 indoor heat exchanger,
  102 indoor side heat exchanger blower fan, 103 indoor unit,
  104 drain pump, 105 suction air temperature detection means,
  106 blowing air temperature detection means,
  107 indoor side heat exchanger piping temperature detection means,
  150 indoor unit controller, 151 indoor unit control means,
  152 indoor unit sensor input means, 153 indoor unit actuator output means,
  154 indoor unit transmission means, 155 control parameter storage means,
  156 parameter rewriting means, 157 information judging means,
  201 first piping, 202 second piping,
  300 remote operation device, 301 remote operation control means,
  302 remote operation transmission means, 303 I / F means,
  304 control parameter storage means, 305 control parameter rewrite means,
  306 heat source unit number storage means, 307 defrost standby operation means,
  400 remote centralized management device, 401 remote centralized management control means,
  402 I / F means, 403 control parameter storage means,
  404 parameter rewriting means, 405 remote information judging means,
  406 Parameter option D / B,
  500 transmission line, 501 public line connection device, 502 public line.

Claims (3)

A heat source unit including a compressor and a heat source side heat exchanger, a heat source unit controller that controls the heat source unit, an indoor unit including an expansion device and a use side heat exchanger, and an indoor unit controller that controls the indoor unit An air conditioner equipped,
A remote control device connected to the air conditioner via a transmission line to control the operation of the air conditioner;
Setting condition information indicating the pipe length of the air conditioner or the vertical relationship between the heat source unit and the indoor unit is input, and input means for outputting the setting condition information to the remote control device;
A remote centralized management device provided at a position separated from the site where the air conditioner and the remote control device are installed via a public line, and connected to the remote control device via the public line;
The remote centralized management device sets the control parameters of the air conditioner according to the pipe length or the vertical relationship so that the air conditioner performs energy saving operation based on the setting condition information received from the remote operation device. Control parameter determining means for determining a value at which the high-pressure side pressure of the machine decreases , and remote control transmission means for transmitting the determined control parameter to the remote control device via the public line,
The remote control device receives the control parameter transmitted from the remote centralized management device via the public line, and sets the received control parameter in the air conditioner connected by the transmission line. Air conditioner control system. Heat source unit, heat source unit controller for controlling the heat source unit, indoor unit, a plurality of air conditioners including an indoor unit controller for controlling the indoor unit, and the air connected to the air conditioner via a transmission line A remote centralized management device for remotely managing a control system having a plurality of remote control devices for controlling the operation of the harmony machine via a public line,
An interface means for receiving setting condition information indicating a pipe length of the air conditioner or a vertical relationship between the heat source unit and the indoor unit;
Based on the setting condition information received by the interface means, the high-pressure side pressure of the heat source unit is reduced according to the piping length or the vertical relationship of the control parameters of the air conditioner so that the air conditioner can perform energy saving operation. And a control parameter determining means for determining the value and transmitting the determined control parameter to the air conditioner via the remote control device. Heat source unit, heat source unit controller for controlling the heat source unit, indoor unit, air conditioner including an indoor unit controller for controlling the indoor unit, remote control device for controlling the operation of the air conditioner, and remote control In a control method of a control system comprising a remote centralized management device connected to a device,
An input unit connected to the remote control device accepts an input of setting condition information indicating a pipe length of the air conditioner or a vertical relationship between the heat source unit and the indoor unit;
The remote control device transmitting the setting condition information to the remote centralized management device via a line;
The remote centralized management device reduces the high-pressure side pressure of the heat source unit according to the piping length or the vertical relationship so that the control parameter of the air conditioner is energy-saving based on the setting condition information. a step of determining a value, returns the control parameter determined via the line to the remote operation apparatus,
The air conditioner receives the control parameters from the remote control device, and rewrites the contents of the control parameter storage means of the heat source controller with the received control parameters;
A control method for a control system comprising:

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