JPWO2019171520A1 - Design support equipment for air conditioners - Google Patents

Abstract

(EN) In a design support device for an air conditioner, it is possible to automatically and easily grasp the necessity of safety measures for the air conditioner. The design support device 1 includes a reading unit 41 that reads data related to the design drawing 20 of the air conditioner in which the indoor units 101 to 104, the outdoor unit 200, the rooms 11 to 14, and the pipes a to g, and the read design drawing. Acquisition units 42 to 46 that acquire data on the indoor units 101 to 104, the outdoor unit 200, the rooms 11 to 14, and the pipes a to g from the data on 20, and the acquired indoor units 101 to 104 and the outdoor unit 200, And the amount of refrigerant required for the air conditioner is calculated based on the data on the pipes a to g, and the volumes of the rooms 11 to 14 are calculated on the basis of the acquired data on the rooms 11 to 14 to obtain the amounts of the refrigerant and the volumes. Based on the above, a judgment unit 47 that judges whether or not a safety measure is required for each of the rooms 11 to 14 and outputs the judgment result.

Description

  The present invention relates to a design support device for an air conditioner.

  In recent years, in order to reduce the environmental load, an air conditioner using alternative CFC gas as a refrigerant has been developed. As such a refrigerant, for example, a slightly flammable (combustible) A2L refrigerant such as R32 of hydrofluorocarbon (HFC) is used.

  When using a slightly flammable (flammable) A2L refrigerant in an air conditioner, safety measures against refrigerant leakage are required. In particular, when the amount of refrigerant used is large with respect to the volume of the air-conditioned space, the guidelines for safety measures as in Non-Patent Document 1 are set.

  In Non-Patent Document 1, the refrigerant concentration (filling rate) of the room is calculated from the volume of the room and the amount of the refrigerant based on the pipe length and the like, and when a predetermined threshold value is exceeded, safety measures are required. Has been described.

Facility guidelines for ensuring safety when refrigerant leaks from commercial air conditioners using slightly flammable (A2L) refrigerant, JRA GL-16: 2016, Japan Refrigerant Air Conditioning Industry Association, issued September 30, 2016.

  However, the work of manually inputting the volume of the room and the amount of the refrigerant from the design drawing and determining the necessity of the safety measure from the calculation result is complicated. Furthermore, it is difficult for an operator who does not know the calculation method in detail to perform such work.

  Therefore, the present invention relates to a technique capable of easily grasping the necessity of safety measures for an air conditioner.

  In order to solve the above problems, the design support device for an air conditioner according to an aspect of the present invention reads data related to a design drawing of an air conditioner in which an indoor unit, an outdoor unit, an air-conditioned space, and piping are marked. Means, acquiring means for acquiring data on the indoor unit, the outdoor unit, the air-conditioned space, and the pipe from the read data on the design drawing, and the acquired indoor unit, the outdoor unit, and the pipe Based on the data, the amount of refrigerant required for the air conditioner is calculated, based on the acquired data on the air-conditioned space, the volume of the air-conditioned space is calculated, and based on the refrigerant amount and the volume, And a judgment means for judging whether or not a safety measure for the air-conditioned space is necessary and outputting the judgment result.

  According to the present invention, it is possible to easily grasp the necessity of safety measures for an air conditioner.

It is a block diagram of a configuration of a design support device for an air conditioner according to an embodiment. It is a schematic diagram of a design drawing showing a floor plan of a building and an installation state of an air conditioner. It is explanatory drawing of the drawing which represented the recognized component with the diagram. It is a flow chart which shows the procedure which outputs the necessity of the safety measure to a refrigerant leak in a design support device.

  Hereinafter, a design support device 1 for an air conditioner according to an embodiment of the present invention will be described.

  FIG. 1 is a block diagram of a configuration of a design support device 1 for an air conditioner according to an embodiment.

  As shown in FIG. 1, an air conditioner design support device 1 includes a main body device 2, an input device 3, a display device 4, and an image acquisition device 5.

  The main body device 2 is configured by, for example, a general-purpose computer system including a processor and a memory, and individual constituent elements or functions in the main body device 2 described below are realized by executing a computer program, for example. . The computer program can be stored in a computer-readable recording medium. The input device 3, the display device 4, and the image acquisition device 5 are connected to the main body device 2. The input device 3 is, for example, a keyboard, a pointing device, or the like. The display device 4 is, for example, a display device or the like. The image acquisition device 5 is, for example, a scanner or a camera.

  The main body device 2 includes a refrigerant characteristic storage unit 31, a refrigerant amount storage unit 32, a reading unit 41, a component recognition unit 42, a dimension acquisition unit 43, a pipe diameter / pipe length acquisition unit 44, and a room height. An acquisition unit 45, a model / capacity acquisition unit 46, and a determination unit 47 are provided.

  The design support device 1 reads data related to design drawings in an air conditioner that uses a slightly flammable (A2L) refrigerant, recognizes constituent elements such as an indoor unit and an outdoor unit from the data, and information related to each constituent element. Is acquired, and processing for determining whether or not a safety measure for refrigerant leakage is necessary is performed. If a safety measure is required, the operator selects the measure and reflects it on the design drawing to determine whether or not the allowable concentration is satisfied. The refrigerant used in this embodiment is R32.

表１は、非特許文献１の表１に相当する。ＬＦＬ（Ｌｏｗｅｒ Ｆｌａｍｍａｂｉｌｉｔｙ Ｌｉｍｉｔ）は、燃焼下限界であり、ＩＳＯ８１７で定められた、冷媒と空気と均一に混合された状態で火炎を伝播することが可能な冷媒の最小濃度である。The refrigerant characteristic storage unit 31 stores the types and characteristics of the slightly flammable (A2L) refrigerant as shown in Table 1 below.
(Table 1)

Table 1 corresponds to Table 1 of Non-Patent Document 1. LFL (Lower Flammability Limit) is the lower limit of combustion, and is the minimum concentration of a refrigerant that can propagate a flame in a state of being uniformly mixed with a refrigerant and air, which is defined by ISO817.

  The refrigerant amount storage unit 32 stores the refrigerant amount according to the types and capacities of the indoor unit and the outdoor unit, and the refrigerant additional amount according to the pipe diameter.

  The reading unit 41 reads the image data of the design drawing 20. The image data is data regarding the image of the design drawing 20 acquired by the image acquisition device 5.

  FIG. 2 is a schematic diagram of a design drawing 20 showing the floor plan of the building 10 and the installation state of the air conditioner.

  In the design drawing 20, rooms 11 to 14 in the building 10, indoor units 101 to 104 provided in the rooms 11, 13, and 14, doors 501 to 503 for entering and exiting the rooms 11, 13, and 14, The ventilation devices 301 and 302, the pipes a to g, and the outdoor unit 200 outside the building 10 are shown. Note that the color corresponding to each component may be determined in advance, and before the design drawing 20 is acquired by the image acquisition device 5, the operator may color the component of the design drawing 20 with a marker pen or the like. . For example, each of the rooms 11 to 14 is colored so as to be surrounded by a red pen, the indoor units 101 to 104 are colored so as to be surrounded by a blue pen, and the outdoor unit 200 is colored so as to be surrounded by a green pen. ~ G may be colored by tracing with a yellow pen.

The component recognizing unit 42 recognizes the components such as the room, the piping, the ventilation fan, the indoor unit, and the outdoor unit from the read image data based on the structure and shape. When each component is colored, each component may be recognized based on the color. Then, the component recognizing unit 42 displays the recognition result on the display device 4. For example, the drawing 21 showing the recognized components shown in FIG. 3 in a diagram and the following Table 2 in which the recognized components and their numbers are numbered are displayed on the display device 4. Numbers are added to the displayed drawings. In addition, the same numbers as those used in the description of the design drawing 20 of FIG. 2 are used as the attached numbers. The pipes a to g are recognized as one pipe between the indoor units 101 to 104 or the outdoor unit 200 and the branch portion of the pipe and between the adjacent branch portions.
(Table 2)

  If there is a different part between the design drawing 20 and the design drawing 20 based on the displayed drawing and Table 2, the operator appropriately corrects / adds the different part using the input device 3. Further, the component recognition unit 42 may recognize the ventilation devices 301 and 302. In addition to the recognized components, FIG. 3 illustrates the mechanical ventilation device 300 and the shutoff valve 400 that are additional components.

  The size acquisition unit 43 acquires the standard size from the read image data. For example, when the dimensions such as the length of one side of the building 10 or the rooms 11 to 14 and the lengths of the pipes a to g are described in a part of the design drawing 20, the dimensions are acquired as the reference dimensions. To do. Then, the dimension acquisition unit 43 calculates the side lengths and floor areas of the rooms 11 to 14 based on the acquired dimensions and displays them on the display device 4. If the displayed floor area or the like is different from the design drawing 20, the operator appropriately corrects it. When the reduced scale is written on the design drawing 20, the reduced scale may be acquired as a reference dimension. When the reference dimension cannot be acquired, the dimension acquisition unit 43 may display an input screen on the display device 4 to prompt the operator to input the reference dimension.

  The pipe diameter / pipe length acquisition unit 44 acquires the pipe diameter and the pipe length of each of the pipes a to g from the read image data. For example, when the design drawing 20 describes the pipe diameters and the pipe lengths of the pipes a to g, they are acquired as the pipe diameters and the pipe lengths of the pipes a to g. The pipe diameter / pipe length acquisition unit 44 displays the acquired pipe diameter and pipe length on the display device 4. If the displayed pipe diameter and pipe length are different from those in the design drawing 20, the operator appropriately corrects them. When part or all of the pipe diameter and the pipe length cannot be acquired, the pipe diameter / pipe length acquisition unit 44 displays an input screen on the display device 4 and prompts the operator to input the pipe diameter and the pipe length. You may

  The room height acquisition unit 45 acquires the heights of the rooms 11 to 14 from the read image data. For example, when the heights of the rooms 11 to 14 are described in the design drawing 20, they are acquired. The room height acquisition unit 45 displays the acquired heights of the rooms 11 to 14 on the display device 4. If the displayed height of each of the rooms 11 to 14 is different from the design drawing 20, the operator appropriately corrects the height. The room height acquisition unit 45 displays an input screen on the display device 4 when a part or all of the heights of the rooms 11 to 14 cannot be acquired, and prompts the operator to check the height of each of the rooms 11 to 14. You may be prompted for input.

  The model / capacity acquisition unit 46 acquires the models and capacities of the outdoor unit 200 and the indoor units 101 to 104 from the read image data. For example, when the design drawings 20 describe the models and capacities of the outdoor unit 200 and the indoor units 101 to 104, those are acquired. The model / capacity acquisition unit 46 displays the acquired models and capacities of the outdoor unit 200 and the indoor units 101 to 104 on the display device 4. If the displayed model and capacity are different from those in the design drawing 20, the operator appropriately corrects them. The model / capacity acquisition unit 46 may display an input screen on the display device 4 to prompt the operator to input the model / capacity when part or all of the model and capacity cannot be acquired.

The determination unit 47 determines the model and capacity acquired by the model / capacity acquisition unit 46, the pipe diameter and pipe length acquired by the pipe diameter / pipe length acquisition unit 44, and the indoor unit stored in the refrigerant amount storage unit 32. The refrigerant amount is calculated based on the refrigerant amount according to the model / capacity of the outdoor unit and the refrigerant additional amount according to the pipe diameter, and the calculation result of the refrigerant amount shown in Table 3 is displayed on the display device 4.
(Table 3)

In addition, the determination unit 47, based on the calculated refrigerant amount, the height of each room 11-14 acquired by the room height acquisition unit 45, and the floor area of each room 11-14 calculated by the dimension acquisition unit 43, Determine the necessity of safety measures for refrigerant leakage in each room. The determination unit 47 displays on the display device 4 the following Table 4 as a necessity result and the drawing 21 in which the components recognized by the component recognition unit 42 of FIG.
(Table 4)

The determination unit 47 calculates the concentration (kg / m ³ , refrigerant filling rate) when all the refrigerant leaks into each of the rooms 11 to 14, and the concentration value is ¼ LFL (which is stored in the refrigerant characteristic storage unit 31). When the value is equal to or larger than the value of (allowable concentration), "necessary" is displayed as the necessity of countermeasures, and "no" is displayed when it is smaller. At this point, the determination unit 47 displays only the portion on the left side of the column of countermeasure necessity in Table 4. It should be noted that since no indoor unit is arranged in the room 12, the necessity determination is not made, but the necessity determination of the room 12 may be made.

The worker selects a safety measure for the room 13 that is determined to require measures. As an option, the operator selects at least one of the shutoff valve 400 and the mechanical ventilation device 300 of FIG. In this embodiment, a case where the shutoff valve 400 is selected will be described. The operator selects the shut-off valve 400 and inputs the position where the shut-off valve 400 is installed on the displayed drawing. When the determination unit 47 detects that an input is made by the operator, the shutoff valve position, the shutoff valve leakage amount, and the shutoff valve operating concentration (kg / m ³ ) are displayed on the right side of the countermeasure necessity column in Table 4. indicate. Then, the determination unit 47 displays “OK” when the concentration at the time of refrigerant leakage (refrigerant filling rate) in the room 13 is smaller than the value of 1/4 LFL due to the countermeasure. That is, the determination unit 47 determines whether the input safety measure is valid. When the concentration at the time of refrigerant leakage in the room 13 is the same as or larger than the value of 1/4 LFL due to the countermeasure, the determination unit 47 displays "NG" and re-inputs the safety countermeasure to the operator. Urge.

Further, when the calculated total leakage concentration is outside the range determined by the design conditions, the determination unit 47 displays “wrong” in the necessity of countermeasure. Here, the range defined by the design conditions is a range defined by the volume of the room, the minimum refrigerant amount of the indoor unit, and the maximum refrigerant amount of the refrigerant. The upper limit of the range is the maximum refrigerant amount in Table 1 (59.8 kg for R32) and the minimum volume of the room to which the minimum capacity indoor unit is applied (for example, 24 m ³ (= 10 m ² (floor area ) * 2.4 m (height)) (2.49 kg / m ³ ). The lower limit of the range is the refrigerant amount of the indoor unit with the smallest capacity (for example, 0.4 kg), It is a value (0.009 kg / m ³ ) obtained from the volume of the room (for example, 30 m ³ (= 15 m ² (floor area) * 3.0 m (height))) in which the installation of the indoor unit is recommended. When “incorrect” is displayed in the necessity of countermeasure, it indicates that there is an erroneous detection or an erroneous input in the numerical values acquired by the acquisition units 43 to 46. Then, the determination unit 47 calculates. When it is judged that the total leakage concentration is outside the range determined by the design conditions Displays a table 3 and 4 the display device 4, prompting confirmation of whether there is inaccurate value of each item to the operator, so as to correct the numerical value.

  The air conditioner design support device 1 having the above-described configuration reads the data relating to the design drawing in the procedure described below, and outputs the necessity of safety measures against refrigerant leakage.

  FIG. 4 is a flowchart showing a procedure for outputting the necessity of safety measures for refrigerant leakage in the design support device 1.

  First, the reading unit 41 reads the image data of the design drawing 20 acquired by the image acquisition device 5 (S101). From the read image data, the component recognizing unit 42 recognizes the components such as the room, the piping, the ventilation fan, the indoor unit, and the outdoor unit based on the structure / shape and displays the recognition result on the display device 4 (S102). ). Specifically, the drawing 21 showing the recognized components shown in FIG. 3 in a diagram and the above-mentioned Table 2 regarding the recognized components are displayed on the display device 4. The component recognizing unit 42 reflects the input result on the drawing 21 when an input such as correction / addition is made by the operator.

  The dimension acquisition unit 43 acquires the standard dimensions from the read image data, calculates the side lengths and floor areas of the rooms 11 to 14, and displays them on the display device 4 (S103). When the reference dimension cannot be acquired, the dimension acquisition unit 43 displays the input screen on the display device 4 and prompts the operator to input the reference dimension, thereby acquiring the reference dimension.

  The pipe diameter / pipe length acquisition unit 44 acquires the pipe diameters and pipe lengths of the respective pipes a to g from the read image data, and displays the acquired pipe diameters and pipe lengths on the display device 4 (S104). When a part or all of the pipe diameter and the pipe length cannot be acquired, the pipe diameter / pipe length acquisition unit 44 displays an input screen on the display device 4 and allows the operator to input the pipe diameter and the pipe length. , Pipe diameter and pipe length are acquired.

  The room height acquisition unit 45 acquires the heights of the rooms 11 to 14 from the read image data, and displays the acquired heights of the rooms 11 to 14 on the display device 4 (S105). The room height acquisition unit 45 displays an input screen on the display device 4 when a part or all of the heights of the rooms 11 to 14 cannot be acquired, and prompts the operator to display the heights of the rooms 11 to 14. By inputting, the height of each room 11-14 is acquired.

  The model / capacity acquisition unit 46 acquires the models and capacities of the outdoor unit 200 and the indoor units 101 to 104 from the read image data, and displays the acquired models and capacities of the outdoor unit 200 and the indoor units 101 to 104 on the display device 4. It is displayed (S106). When part or all of the model and capacity cannot be acquired, the model / capacity acquisition unit 46 displays an input screen on the display device 4 and allows the operator to input the model / capacity to acquire the model / capacity. . Further, the model / capacity acquisition unit 46 calculates the refrigerant amount based on the acquired model and capacity, the pipe diameter and the pipe length, and the refrigerant amount and the refrigerant addition amount stored in the refrigerant amount storage unit 32. The calculation result of the refrigerant amount shown in Table 3 above is displayed on the display device 4.

  The determination unit 47 determines whether or not a safety measure for refrigerant leakage is necessary for each room based on the calculated amount of refrigerant, the height of each room 11-14, and the floor area of each room 11-14 (S107). It is determined whether there is a room requiring safety measures (S108). When there is a room requiring safety measures (S108: YES), the determination unit 47 determines whether or not there is an input of safety measures on the drawing 21 displayed on the display device 4 by the operator (S109). When there is an input from the operator (S109: YES), the determination unit 47 determines whether or not the refrigerant leakage concentration in the room requiring the safety measure is smaller than the allowable concentration, based on the input safety measure. (S110). If there is no room requiring safety measures (S108: NO), and if the concentration at the time of refrigerant leakage is equal to or higher than the allowable concentration (S110), the determination unit 47 ends the process.

  According to the design support device 1 for an air conditioner as described above, the data regarding the design drawings 20 of the air conditioner in which the indoor units 101 to 104, the outdoor unit 200, the rooms 11 to 14, and the pipes a to g are described. From the reading unit 41 to be read and the read data on the design drawing 20, the respective acquisition units 42 to 46 for acquiring the data on the indoor units 101 to 104, the outdoor unit 200, the rooms 11 to 14, and the pipes a to g were acquired. Based on the data on the indoor units 101 to 104, the outdoor unit 200, and the pipes a to g, the amount of refrigerant required for the air conditioner is calculated, and the volumes of the rooms 11 to 14 are calculated based on the acquired data on the rooms 11 to 14. And a determination unit 47 that determines whether or not a safety measure is required for each of the rooms 11 to 14 based on the calculated amount of refrigerant and each volume, and outputs the determination result. With this configuration, it is possible to easily and automatically grasp the necessity of safety measures for the air conditioner.

  In addition, when the acquisition units 42 to 46 cannot acquire the data on the indoor units 101 to 104, the outdoor unit 200, the rooms 11 to 14, or the pipes a to g from the read data on the design drawing 20, the data is input. Output the screen to do. As a result, even if there is data that cannot be automatically acquired, the data can be acquired only by manual input work, and the necessity of safety measures for the air conditioner can be easily grasped.

  Further, the determining unit 47 calculates the refrigerant filling rate of each of the rooms 11 to 14 by dividing the refrigerant amount by each volume, determines whether the refrigerant filling rate is within a predetermined range, and the refrigerant filling rate is If it is not within the predetermined range, information indicating that there is an error in data acquisition by each of the acquisition units 42 to 46 is output. As a result, it is possible to suppress the necessity / unnecessity of the safety measure based on the erroneous detection in the acquisition units 42 to 46.

  When the safety measures for the rooms 11 to 14 are input, the determination unit 47 determines whether or not the safety measures are effective based on the amount of refrigerant leaking to the rooms 11 to 14 after the safety measures and the volume of the rooms. to decide. With this, it is possible to easily grasp whether or not the safety measures are effective.

  The present invention is not limited to the above-mentioned embodiments. Those skilled in the art can make various additions and changes within the scope of the present invention.

  For example, in the above-described embodiment, the cutoff valve 400 is selected to be installed in the room determined to require safety measures, but the mechanical ventilation device 300 may be selected. When the mechanical ventilation device 300 is selected, the required amount of ventilation for the corresponding room is automatically calculated, and the installation position is also selected. In addition to the mechanical ventilation device 300 and the shutoff valve 400, a detector and an alarm device may be installed in a room determined to require safety measures. Further, the data regarding the design drawing 20 read by the reading unit 41 may be CAD data.

1: Design support device, 101 to 104: Indoor unit, 200: Outdoor unit, a to g: Pipes 11 to 14: Room, 20: Design drawing, 41: Reading unit, 42: Element recognition unit, 43: Dimension acquisition unit , 44: Pipe diameter / pipe length acquisition unit, 45: Room height acquisition unit, 46: Model / capacity acquisition unit, 47: Judgment unit

The determination unit 47 determines whether or not a safety measure for refrigerant leakage is necessary for each room based on the calculated amount of refrigerant, the height of each room 11-14, and the floor area of each room 11-14 (S107). It is determined whether there is a room requiring safety measures (S108). When there is a room requiring safety measures (S108: YES), the determination unit 47 determines whether or not there is a safety measure input to the drawing 21 displayed on the display device 4 by the operator (S109). When there is an input from the operator (S109: YES), the determination unit 47 determines whether or not the refrigerant leakage concentration in the room requiring the safety measure is smaller than the allowable concentration, based on the input safety measure. (S110). If there is no room requiring safety measures (S108: NO), or if the concentration at the time of refrigerant leakage is less than the allowable concentration (S110 : YES ), the determination unit 47 ends the process.

1: design support apparatus, 101-104: indoor unit, 200: outdoor unit, a to g: piping 11-14: room 20: design drawing, 41: reading unit, 42: component recognition unit, 43: Dimensions obtain Part, 44: pipe diameter / pipe length acquisition part, 45: room height acquisition part, 46: model / capacity acquisition part, 47: judgment part

Claims (4)

A reading means for reading the data regarding the design drawing of the air conditioner in which the indoor unit, the outdoor unit, the air-conditioned space, and the piping are marked,
An acquisition unit that acquires data regarding the indoor unit, the outdoor unit, the air-conditioned space, and the piping from the read data regarding the design drawing,
Based on the acquired data on the indoor unit, the outdoor unit, and the piping, calculate the amount of refrigerant required for the air conditioner, and based on the acquired data on the air-conditioned space, calculate the volume of the air-conditioned space. A design support device for an air conditioner, comprising: a determination unit that determines whether or not a safety measure is required for the air-conditioned space based on the refrigerant amount and the volume, and outputs a determination result.   When the acquisition unit cannot acquire data on the indoor unit, the outdoor unit, the air-conditioned space, or the piping from the read data on the design drawing, it outputs a screen for inputting the data, The design support device for an air conditioner according to claim 1. The determination means is
Calculate the refrigerant filling rate of the air-conditioned space by dividing the refrigerant amount by the volume, to determine whether the refrigerant filling rate is within a predetermined range,
The design support of the air conditioner according to claim 1 or 2, wherein when the refrigerant filling rate is not within a predetermined range, information indicating that the data acquisition by the acquisition unit has an error is output. apparatus. When the safety measure for the air-conditioned space is input, the determining means determines whether or not the safety measure is effective based on the refrigerant amount and the volume leaking to the air-conditioned space after the safety measure. The design support device for an air conditioner according to claim 1.

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