JP2021014949A - Data processor, data processing program and data processing method - Google Patents

Abstract

To provide a device for calculating an operating state of a water air conditioning system by extracting pipe lengths and pipe diameters from drawing data.SOLUTION: An operating state calculation device 341 includes: a determination section 142 determining lengths and diameters of pipes on the basis of a circuit configuration data indicating a configuration of a circulation circuit that is a circuit in which a heat source machine, a pump and a plurality of heat exchangers are connected by the plurality of pipes and a heating medium circulates; a calculation section 144 calculating an operating state of the circulation circuit corresponding to an operating condition on the basis of the determined lengths and diameters of the pipes and the operating condition of the circulation circuit; and an output control section 145 outputting the operating state to a storage device.SELECTED DRAWING: Figure 3

Description

The present invention extracts the piping structure of an air conditioning system from drawing data in an air conditioning system that regulates the temperature of indoor air in an office building using a heat source unit and a plurality of utilization units, and confirms the operating state of the air conditioning system. Regarding technology for.

Conventionally, as disclosed in Patent Document 1, a heat source machine adjusts the temperature of water as a heat medium. There is a disclosure of an air conditioning facility that regulates the temperature of a room by transferring heat to the air flowing through the utilization unit by sending the temperature-controlled water to the utilization unit.

Japanese Unexamined Patent Publication No. 2014-3590

In Patent Document 1, based on the pressure data of the heat medium measured by the pressure measuring means and the flow rate data of the heat medium grasped by the flow rate grasping means, each of the plurality of user-side circuits is used in the piping and the heat exchanger. Obtain the pass resistance value for the heat medium.
In Patent Document 1, by obtaining the passing resistance value with respect to the heat medium, it is possible to specify the passing resistance value received by the heat medium flowing on the user side without providing a water meter for each user circuit, and the equipment. It is said that the cost can be suppressed.
Then, by utilizing each passing resistance value obtained in this way, it is possible to perform an operation in which the electric power required for processing the load required on the user side is suppressed to a small value.

However, with the method disclosed in Patent Document 1, the pipe resistance cannot be obtained in the absence of pressure data and flow rate data. Recently, in water-air conditioning systems, energy-saving tuning work that tunes the control operation so that the operation of the equipment is energy-saving according to the air-conditioning load of the installed office building has become common. Therefore, there is a need to estimate the energy-saving tuning effect on equipment operation changes before acquiring operation data and propose energy-saving tuning maintenance to the user. The technique of Patent Document 1 needs to acquire operation data such as pressure data and flow rate data. Therefore, in the technique of Patent Document 1, it is difficult to estimate the energy-saving tuning effect on the device operation change and propose the energy-saving tuning maintenance to the user before acquiring the operation data.

An object of the present invention is to provide an apparatus for extracting a pipe length and a pipe diameter from drawing data and calculating an operating state of a water-air harmonization system.

The data processing apparatus of the present invention
A circuit in which a heat source machine, a pump, and a plurality of heat exchangers are connected by a plurality of pipes, and the length and diameter of the pipes are based on circuit configuration data showing the configuration of a circulation circuit which is a circuit in which a heat medium circulates. And the decision-making part that decides
A calculation unit that calculates the operating state of the circulating circuit corresponding to the operating conditions based on the determined length and diameter of the pipe and the operating conditions of the circulating circuit.
It is provided with an output control unit that outputs the operating state to the storage device.

Since the data processing device of the present invention extracts the pipe length and the pipe diameter from the drawing data and calculates the operating state of the water-air harmonization system, it is possible to carry out an accurate simulation before acquiring the actual property operation data. ..

FIG. 5 is a diagram showing a system configuration of a water-air conditioning system 100 in the figure of the first embodiment. FIG. 5 is a diagram showing a configuration of a control device of the water-air conditioning system 100 in the figure of the first embodiment. In the figure of Embodiment 1, the figure which shows the hardware configuration of the operation state calculation apparatus 341. FIG. 6 is a schematic view showing acquisition of electronic data 333 in the figure of the first embodiment. FIG. 5 is a flowchart showing the operation of the operating state calculation device 341 in the figure of the first embodiment. FIG. 2 is a diagram showing acquisition of drawing data 334 in the figure of the second embodiment. FIG. 2 is a diagram showing the height direction of the installation positions of the heat source unit 301 and the utilization unit 302 in the figure of the second embodiment. FIG. 2 is a plan view showing a plan direction of installation positions of the heat source unit 301 and the utilization unit 302 in the figure of the second embodiment. FIG. 2 is a plan view showing the plan dimensions of the building 401 in the figure of the second embodiment. FIG. 3 is a diagram showing a water-air conditioning system 200 using pipes having different thicknesses in the figure of the third embodiment.

Embodiment 1.
*** Explanation of configuration ***
<System configuration>
FIG. 1 is a schematic view showing a system configuration of the water-air conditioning system 100 of the first embodiment. In each figure used in the present specification, the same reference numerals are given to common elements. The water-air conditioning system 100 is a system installed in a commercial building such as a building and capable of controlling the temperature of indoor air.

In the water-air conditioning system 100, the heat source unit 301 installed on the roof, the primary pump 9, the secondary pump 1, the bypass valve 2, and the two utilization units 302A installed in the machine room in the building. It is configured by connecting the 302B with a water pipe.
The indoor air is supplied to the utilization unit 302 from the suction port installed in the room through the duct, and the air temperature controlled by the utilization unit 302 is supplied to the room from the outlet through the duct (not shown). ..
The heat source unit 301 is a heat source machine.
The utilization unit 302 shows two, the utilization unit 302A and the utilization unit 302B.
The utilization unit 302A and the utilization unit 302B have the same configuration, and the utilization unit 302A and the utilization unit 302B are distinguished by the letters A and B.
When there is no need to distinguish, it is described as the utilization unit 302.
The utilization heat exchanger 5A and the utilization heat exchanger 5B included in the utilization unit 302A and the utilization unit 302B are a plurality of heat exchangers. FIG. 1 shows a case where a plurality of heat exchangers are two.
In the water-air conditioning system 100, the heat medium forms a circulation circuit. In the water-air conditioning system 100, the heat medium is water.

<Piping>
In FIG. 1, the piping is as follows.
The pipe 3 is between the point p shown in the header 15 and the point q1.
The pipe 8 is between the point u shown in the header 16 and the point t1.
The pipe 4A is between the point q1 and the point r1 indicating the inflow port of the utilization heat exchanger 5A.
The pipe 7A is between the point t1 and the point s1 indicating the outlet of the utilization heat exchanger 5A.
The pipe 4B is between the point q2 and the point r2 indicating the inflow port of the utilization heat exchanger 5B.
The pipe 7B is between the point t2 and the point s2 indicating the outlet of the utilization heat exchanger 5B.
The operation state calculation device 341, which will be described later, determines at least the pipe length and the pipe diameter of the pipe 4A, the pipe 7A, the pipe 4B, and the pipe 7B.
The piping from the header 16 to the header 15 via the primary pump 9, the heat source unit 301, and the header 14 is called a heat source side piping.
The length and diameter of the heat source side pipe are often easily known, and usually, the pipe length and diameter of the heat source side pipe are stored in the operation state calculation device 341.
Of course, the operating state calculation device 341 may determine the pipe length difference and the pipe diameter of the heat source side pipe.
Further, in the following description, when the terms pipes 4 and 7 are described, the pipes 4A, 7A, 4B, and 7B are shown.

<Equipment>
The heat source unit 301 is an air heat source heat pump.
The utilization unit 302 is, for example, an air handling unit, and is composed of a utilization heat exchanger 5 and an electric two-way valve 6.
The utilization heat exchanger 5 is, for example, a fin tube type heat exchanger, which exchanges heat between water and air.
The electric two-way valve 6 can continuously change the opening degree.
The primary pump 9 is a spiral type, and is ON / OFF controlled by the operation of the heat source unit 301.
The secondary pump 1 is also a spiral type, but an inverter is connected (not shown), and the rotation speed is controlled by the operating state of the water circuit.
The opening degree of the bypass valve 2 is also controlled according to the operating state of the water circuit.

A temperature sensor 205 is installed at the outlet of the water pipe of the heat source unit 301 to detect the water temperature at the installation location.
Further, a temperature sensor 204 is installed on the suction side of the utilization heat exchanger 5 to detect the air temperature at the installation location.
Further, the load flow rate is detected by the load flow meter 202 installed in the pipe 8, and the used flow rate is measured by the used flow meter 207 installed at the outlet of the electric two-way valve 6 of the utilization unit 302.
Further, the differential pressure gauge 201 installed between the outbound header 14 and the outbound header 15 detects the water supply differential pressure, and is installed at the portion connecting the outlet of the electric two-way valve 6 from the inlet of the heat exchanger 5 of the utilization unit 302. The differential pressure gauge 206 is used to detect the differential pressure of the unit used.

<Control device>
FIG. 2 is a block diagram of the control device. The water-air conditioning system 100 includes, for example, a system control device 303 for adjusting the operating operation of the water-air conditioning system configured by a microcomputer. The utilization control device 313A is provided in the utilization unit 302A. The utilization control device 313B having the same specifications as the utilization control device 313A is installed in the utilization unit 302B. The monitoring device 323 is installed in a part of the central monitoring system for displaying the operating status of the equipment installed in many buildings and checking for any abnormality, and the building manager is in charge of the operating status. It is for being able to monitor.
If the building is small, it may be installed in a computer installed in the staff room. Further, it may be mounted on a computer or tablet terminal so that an external maintenance company can freely use it for regular maintenance.

The system control device 303 is provided with a system measurement unit 102, a system calculation unit 103, a system control unit 104, a system storage unit 105, and a system communication unit 106. In the system control device 303, various quantities detected by each sensor are input to the system measurement unit 102, various control parameters are calculated by the system calculation unit 103 based on the input information, and various control parameters are calculated by the system control unit 104. Therefore, each device such as the secondary pump 1 is controlled. The system storage unit 105 is composed of a semiconductor memory or the like, and stores set values, device control target values, and the like. Further, the system communication unit 106 can transmit and receive various information to and from the monitor device 323 wirelessly or by wire.

The usage control device 313 is provided with a usage measurement unit 112, a usage calculation unit 113, a usage control unit 114, a usage storage unit 115, and a usage communication unit 116. In the utilization control device 313, various quantities detected by the temperature sensor are input to the utilization measurement unit 112, various control parameters are calculated by the utilization calculation unit 113 based on the input information, and the utilization control unit 114 calculates various control parameters. , Electric two-way valve 6 and other devices are controlled. The usage storage unit 115 is composed of a semiconductor memory or the like, and stores set values, device control target values, and the like. Further, the utilization communication unit 116 can transmit and receive various information to and from the monitor device 323 wirelessly or by wire.

The monitor device 323 is provided with a monitor storage unit 125, a monitor communication unit 126, and a monitor display unit 127. In the monitor device 323, the monitor communication unit 126 receives the operation information transmitted from the system communication unit 106 and the utilization communication unit 116, so that the monitor display unit 127 can display the operation information to the user.

The monitor device 323 is installed in the computer 120.
Further, the computer 120 is an operating state calculation device 341 for simulating the operating state of the water-air conditioning simulation.
The operation state calculation device 341 is a data processing device.
The operation state calculation device 341 includes an acquisition unit 141, a determination unit 142, a reception control unit 143, an arithmetic unit 144, and an output control unit 145. The operating state calculation device 341 extracts the piping specifications of the water-air conditioning system 100.
Then, the operating state calculation device 341 simulates the water-air conditioning system 100 using the operating conditions, and calculates the operating state of the water-air harmonizing system 100 corresponding to the operating conditions as the simulation result.
Here, the operating conditions are the differential pressure of the secondary pump 1 and the outlet temperature of the heat source unit 301. The differential pressure of the secondary pump 1 is a measured value of the differential pressure gauge 201. The outlet temperature of the heat source unit 301 is a measured value of the temperature sensor 205. The operating state is, for example, the flow rate and water temperature of water which is a heat medium. The flow rate is obtained as a simulation result of the flow meters 207A and 207B and the flow meter 202. The water temperature is obtained as a simulation result of the temperature sensors 204A, 204B, 205.

*** Explanation of configuration ***
FIG. 3 shows the hardware configuration of the operating state calculation device 341. The hardware configuration of the operation state calculation device 341 will be described with reference to FIG.

The operating state calculation device 341 is a computer. The operating state calculation device 341 includes a processor 510. In addition to the processor 510, the operating state calculation device 341 includes other hardware such as a main storage device 520, an auxiliary storage device 530, an input IF 540, an output IF 550, and a communication IF 560. The processor 510 is connected to other hardware via the signal line 570 and controls the other hardware.

The operation state calculation device 341 includes a acquisition unit 141, a determination unit 142, a reception control unit 143, a calculation unit 144, and an output control unit 145 as functional elements. The acquisition unit 141, the determination unit 142, the reception control unit 143, the calculation unit 144, and the output control unit 145 are realized by the operation state calculation program 511.

The processor 510 is a device that executes the operating state calculation program 511. The operation state calculation program 511 is a program that realizes the functions of the acquisition unit 141, the determination unit 142, the reception control unit 143, the calculation unit 144, and the output control unit 145. The processor 510 is an IC (Integrated Circuit) that performs arithmetic processing. Specific examples of the processor 510 are a CPU (Central Processing Unit), a DSP (Digital Signal Processor), and a GPU (Graphics Processing Unit).

The main storage device 520 is a storage device. Specific examples of the main storage device 520 are SRAM (Static Random Access Memory) and DRAM (Dynamic Random Access Memory). The main storage device 520 holds the calculation result of the processor 510.

The auxiliary storage device 530 is a storage device that stores data in a non-volatile manner. A specific example of the auxiliary storage device 530 is an HDD (Hard Disk Drive). The auxiliary storage device 530 is a portable recording medium such as an SD (registered trademark) (Secure Digital) memory card, a NAND flash, a flexible disk, an optical disk, a compact disk, a Blu-ray (registered trademark) disk, or a DVD (Digital Versaille Disk). There may be. The auxiliary storage device 530 stores the operating state calculation program 511.

The input IF 540 is a port to which data is input from each device. The output IF 550 is a port to which various devices are connected and data is output to the various devices by the processor 510. A display device 600 is connected to the output IF 550.

The processor 510 loads the operation state calculation program 511 from the auxiliary storage device 530 into the main storage device 520, and reads and executes the operation state calculation program 511 from the main storage device 520.

The operation state calculation program 511 replaces the "units" of the acquisition unit 141, the determination unit 142, the reception control unit 143, the calculation unit 144, and the output control unit 145 with "process", "procedure", or "process". It is a program that causes a computer to execute each procedure or each process. Further, the operation state calculation method is a method performed by the operation state calculation device 341, which is a computer, executing the operation state calculation program 511. The operating state calculation program 511 may be provided by being stored in a computer-readable recording medium, or may be provided as a program product.

<Driving operation>
Next, the operating operation of the water-air conditioning system 100 will be described by taking cold water operation as an example. The cold water operation is started when the cooling operation is performed by any one or more of the utilization units 302. Here, the operating state when the utilization unit 302A is in cold water operation and the utilization unit 302B is stopped will be described. The heat medium sent from the primary pump 9 is cooled by the heat source unit 301, proceeds to the outbound header 14, and is diverted to the pipe 10 or the secondary pump 1. After being pushed out, the water flowing into the secondary pump 1 is distributed to the water flowing through the bypass valve 2 or the pipe 3 by the outbound header 15. The water flowing in the bypass valve 2 direction joins the outbound header 14 after passing through the bypass valve 2. On the other hand, the water flowing through the pipe 4A cools the air supplied from the room by the utilization heat exchanger 5A, passes through the electric two-way valve 6A, and then passes through the pipe 7A. After that, it passes through the pipe 8 and joins the water flowing through the pipe 10 at the return header 16. After that, it proceeds to the primary pump 9 and circulates in the water circuit. The operating state is the same for the hot water operation that is started when the heating operation is performed by any one or more of the utilization units 302. The same applies to the utilization heat exchanger 5B.

The operating capacity of the heat source unit 301 is controlled by the heat source unit 301 so that the heat source outlet water temperature becomes the same as the set water temperature (for example, 7 ° C.). The heat source outlet water temperature is the temperature detected by the temperature sensor 205. Further, the secondary pump 1 rotation speed and the bypass valve 2 opening degree are controlled by the system control device 303 so that the water supply differential pressure between the outward path header 15 and the outward path header 14 becomes the target water supply differential pressure value (for example, 200 kPa). ing. The water supply differential pressure is a value detected by the differential pressure gauge 201. The load flow rate is the flow rate detected by the flow meter 202. Further, the electric two-way valve 6 is controlled so that the suction temperature becomes equal to the indoor set temperature. The suction temperature is a value detected by the temperature sensor 204. The electric two-way valve 6B has a fully closed opening (for example, 0% opening) because the utilization unit 302B is stopped, and the rotation speed of the primary pump 9 is constant (fixed) regardless of the operating state. Value).

<Piping specifications>
When simulating the operating state of the water-air conditioning system 100, the specification values of the heat source unit 301, the utilization unit 302, the secondary pump 1, the primary pump 9, the bypass valve 2, the electric two-way valve 6, the headers 14, 15 and 16 are It can be obtained from the model name of the device.
However, for pipes 4, 7, and 10, it is possible to recognize the construction status from the PDF drawing data, but the pipe length and the pipe specification value, which is the pipe diameter at that location, are not followed in detail from the PDF drawing. And the value cannot be obtained.
In particular, for the pipes 4 and 7 between the header 15 and the header 16, since the utilization unit 302 is often installed on each office floor of the office building, the construction state becomes complicated, and the specification value is obtained from the PDF drawing data. Cannot be read.
Therefore, in the past, the piping specifications of the pipes 4 and 7 were unknown, and the flow path resistance (pipe length) was determined from empirical intuition and actually measured operation data.
Regarding the piping 10, the heat source unit 301, the secondary pump 1, the primary pump 9, the bypass valve 2, the headers 14, 15 and 16 are often installed together in one section on the roof, and the piping specification values are set. It can be read from the PDF drawing.
The heat source unit 301, the secondary pump 1, the primary pump 9, the bypass valve 2, the headers 14, 15 and 16 are collectively referred to as a heat source related unit.

FIG. 4 shows the acquisition of electronic data 333 of the operating state calculation device 341. In the operation state calculation device 341, the data acquisition unit 141 acquires the specification values of each device including the piping specifications of the pipes 4 and 7 from the electronic data 333. Newly built properties in recent years are often designed using three-dimensional data such as BIM (Building Information Modeling) or 3D-CAD (Computer Aided Design).
The electronic data 333 is three-dimensional data such as BIM (Building Information Modeling) or 3D-CAD (Computer Aided Design) of the property.
The operating state calculation device 341 reads the piping specifications from the electronic data 333. Specifically, a plan view of the heat source machine room piping, a detailed piping view of the heat source machine room, a vertical section piping system diagram of the piping, and a building elevation view for confirming the building floor height, which have been conventionally obtained from PDF drawings. The operation state calculation device 341 extracts drawing data corresponding to the reference floor piping system diagram and the piping detailed diagram of the reference air conditioning machine room from the BIM, and extracts the piping length and the piping diameter. By doing so, it is possible to quantify the piping specifications according to the drawing, although there was an error in the reading value from the PDF drawing for each worker in the past. Then, high calculation accuracy can be ensured in the operation state calculation executed after this. The electronic data 333 is stored in a shared server on the cloud or the Internet, or a local computer, which can be accessed only by the persons concerned.

*** Explanation of operation ***
<Operation state calculation>
FIG. 5 is a flowchart showing the operation of the operating state calculation device 341. The operation of the operating state calculation device 341 will be described with reference to FIG. The operation procedure of the operation state calculation device 341 corresponds to the operation state calculation method. The program that realizes the operation of the operating state calculation device 341 corresponds to the operating state calculation program 511. The operating state calculation method is a data processing method. The operating state calculation program 511 is a data processing program.

<Step S1>
First, in step S1, the acquisition unit 141 acquires the electronic data 333 composed of, for example, BIM. The electronic data 333, which is the circuit configuration data, is extractable data capable of directly extracting the length and diameter of the pipe.

<Step S2>
The determination unit 142 is a circuit in which a heat source machine, a pump, and a plurality of heat exchangers are connected by a plurality of pipes, and each is based on circuit configuration data indicating a configuration of a circulation circuit which is a circuit in which a heat medium circulates. Determine the length and diameter of the piping. Here, the circulation circuit is the water-air conditioning system 100 shown in FIG. The circuit configuration data is electronic data 333. In step S2, the determination unit 142 directly extracts the length and diameter of the pipe from the electronic data 333, which is the extractable data. That is, the determination unit 142 extracts the pipe lengths and pipe diameters of the pipes 4 and 7 as pipe specifications from the electronic data 333 as quantitative values, and determines the pipe lengths and pipe diameters of the pipes 4 and 7.

<Step S3>
Next, in step S3, the reception control unit 143 receives input of specification information of the equipment constituting the water-air conditioning system 100, such as the specification values of the heat source unit 301 and the secondary pump 1. At this time, the reception control unit 143 may receive the pipe length and the pipe diameter of the heat source side pipe. Alternatively, the device specification information and the pipe length and diameter of the heat source side pipe may be stored in the auxiliary storage device 530, and the determination unit 142 may refer to the information stored in the auxiliary storage device 530. ..

<Step S4>
Next, in step S4, the reception control unit 143 receives the input of the operation condition 1A. The operating condition 1A is an operating condition before the change of the control operation by the energy saving tuning. In particular, the differential pressure value of the target water supply is often set excessively with a margin so that the water supply flow rate to the utilization unit 302 is not insufficient. For example, the target water supply differential pressure value is set to 300 kPa, and the frequency of the secondary pump 1 and the opening degree of the bypass valve 2 are controlled.

<Step S5>
The calculation unit 144 calculates the operating state of the circulation circuit corresponding to the operating conditions based on the length and diameter of the pipe determined by the determination unit 142 and the operating conditions of the circulation circuit. The calculation unit 144 calculates the power consumption corresponding to the operating state by using the calculated operating state. Specifically, it is as follows.
In step S5, the calculation unit 144 calculates the operation state 1B corresponding to the operation condition 1A by using the operation condition 1A. The calculation unit 144 also calculates the total power consumption 1C of the heat source unit 301, the secondary pump 1, and the primary pump 9 from the operation state 1B of the calculation result.

<Step S6>
In step S6, the reception control unit 143 receives the input of the operation condition 2A. The operating condition 2A is, for example, an operating condition after the control operation is changed by energy saving tuning. In particular, set the target water supply differential pressure value to the water supply differential pressure value that does not seem to be insufficient in the water supply flow rate from the piping specifications acquired this time. For example, the target thrust pressure is set to 200 kPa.

<Step S7>
In step S7, the calculation unit 144 calculates the operation state 2B corresponding to the operation condition 2A by using the operation condition 2A. The calculation unit 144 also calculates the total power consumption 2C of the heat source unit 301, the secondary pump 1, and the primary pump 9 from the operation state 2B of the calculation result.

<Step S8>
The output control unit 145 outputs the operating states 1B and 2B to the storage device. Further, the output control unit 145 outputs the power consumption calculated by the calculation unit 144 to the storage device. The storage device may be the main storage device 520 or the auxiliary storage device 530.
Specifically, it is as follows.
In step S8, the output control unit 145 outputs "operating condition 1A, operating state 1B, total power consumption 1C" and "operating condition 2A, operating state 2B, total power consumption 2C" to the storage device. Further, the output control unit 145 presents the operating state 1B, the total power consumption 1C, the operating state 2B, and the total power consumption 2C to a user such as the owner of the office building.
Specifically, the output control unit 145 displays "operating condition 1A, operating state 1B, total power consumption 1C" and "operating condition 2A, operating state 2B, total power consumption 2C" on the display device 600. The output control unit 145 can propose energy-saving tuning maintenance to the user by displaying it on the display device.

*** Effect of Embodiment 1 ***
By looking at the operating state 2B, the user can confirm whether or not the flow rate is insufficient in the utilization unit 302 with the target water supply differential pressure set in the piping specifications acquired from the electronic data 333 which is the BIM data.
Since the value indicated by the operating state 2B is based on the piping specifications (length, φ) actually constructed, the prediction accuracy of the operating state 2B is also high.
Further, with respect to the total power consumption 1C and the total power consumption 2C, the contribution of the power consumption change of the secondary pump 1 which is the target of the water supply differential pressure control is large.
The head, power consumption, and flow rate of the secondary pump 1 vary greatly with respect to the length and diameter of the pipes 4 and 7. Therefore, since the prediction using the operating state calculation device 341 is based on the piping specifications (length, φ) actually constructed, the prediction can be made with higher accuracy than before.

In the first embodiment, an example of using the operation state calculation device 341 is shown for energy-saving tuning maintenance, but there is also an application in which the effect on demand control is estimated in advance.
For example, when the power consumption (power consumption 1) when the outside air temperature is 35 ° C in the daytime in summer is calculated, and the outlet water temperature of the heat source machine is set from 7 ° C to 8 ° C and 9 ° C (or). Calculate the power consumption (power consumption 2) of the heat source machine when the upper limit of the operating capacity is lowered from 100% to 75%, and compare the power consumption to estimate the effect during demand control and propose the effect to the user in advance. be able to.
Furthermore, if the number of years of use increases, there is a possibility of equipment abnormality or performance deterioration, and an abnormality is also presented for equipment performance maintenance, which is maintenance for maintaining equipment performance.
For example, the "operating state 1B, total power consumption 1C" before the device performance deterioration and the "operating state 2B, total power consumption 2C" after the device performance deterioration are presented to the user.
This presentation makes it easier for the user to understand changes in "operating conditions and power consumption" due to performance degradation, and facilitates maintenance work execution.

In the first embodiment, the case where the number of the utilization units 302 is two is shown, but the present invention is not limited to this, and the case where the number of the utilization units 302 is three or four or more can be applied.

The output control unit 145 determines the length of the piping for each heat exchanger from the position on the outflow side of the heat source machine from which the heat medium flows out to the inflow port of the heat medium in each of the heat exchangers of the plurality of heat exchangers. , Output in any order, longest or shortest.
Specifically, it is as follows.
Further, regarding the pipe 4 for which the determination unit 142 has decided to use, the output control unit 145 orders the pipe 4A and the pipe 4B in the order of the pipe length among the pipe 4A and the pipe 4B in the order of the longest pipe length. Specify in descending order of pipe length.
By doing so, the user can grasp in advance the route where water is unlikely to flow before the calculation, so that it is easy to check the operating state after the calculation.

Embodiment 2.
The second embodiment relates to the determination of the piping specifications by the determination unit 142. In the second embodiment, only the parts different from the first embodiment will be described.
FIG. 6 is a conceptual diagram in which the operating state calculation device 341 acquires drawing data 334.
In the second embodiment, the drawing data 334, which is unobtainable data such as a PDF drawing, is used instead of the electronic data 333, which is the extractable data, as compared to the first embodiment. The drawing data 334 is circuit configuration data. Unacquirable data is data in which the values of the piping specifications, which are the piping length and the piping diameter, cannot be directly extracted. Conventionally, the operator has had to read the value of the piping specification from the drawing data 334.

Drawing data 334, which is unobtainable data, is data in which the length and diameter of the pipe cannot be directly acquired, as described above. Further, the drawing data 334, which is unobtainable data, shows the model names of the plurality of heat exchangers and the positional relationship between the positions of the heat source machines and the plurality of heat exchangers.
The determination unit 142 can know the pipe diameter of the pipe connected to the heat exchanger from the model name of the heat exchanger. Information on the pipe diameter corresponding to the model name is stored in, for example, the auxiliary storage device 530. As will be described later, the determination unit 142 determines the length and diameter of the pipe based on the model name and the positional relationship shown in the drawing data 334, which is unobtainable data.

Conventionally, the operator manually extracts the values of the pipe length and the pipe diameter from the pipe route diagram shown in the drawing data 334. In the case of manual work, the reading of the pipe length value may differ greatly depending on the operator. Therefore, in the operating state calculation device 341,
The determination unit 142 obtains the piping specifications, that is, the piping length and the piping diameter from the installation positions of the heat source unit 301 and the utilization unit 302.
FIG. 7 is a schematic view showing the height direction of the installation positions of the heat source unit 301 and the utilization unit 302 installed in the building 401. The heat source unit 301, which is a heat source machine, is arranged on the roof of a building 401 having a plurality of floors. Since the utilization unit has the utilization heat exchanger 5, the two utilization heat exchangers 5A and the utilization heat exchanger 5B are arranged on any one of the plurality of floors. Although the coordinates 402 are shown in FIG. 7, the height direction of the building 401 is the Z-axis direction.
FIG. 8 is a plan view of the installation positions of the heat source unit 301 and the utilization unit 302.

From FIG. 7, the determination unit 142 can know the height difference between the pipes 4A and 7A and the pipes 4B and 7B. The drawing data 334 stores scale information so that the determination unit 142 can know the height difference, and the determination unit 142 refers to the scale information. Assuming that the scale information is 1/100 of the scale, 2 cm in the drawing data 334 is actually information such as 2 m. Alternatively, the scale information is stored in the auxiliary storage device 530, and the determination unit 142 refers to the scale information of the auxiliary storage device 530.

For example, assume that the utilization unit 302A is installed on the third floor of the building 401 and the utilization unit 302B is installed on the second floor of the building 401. The pipe length in the height direction of the building 401 is Ha in the utilization unit 302A and Hb in the utilization unit 302B with respect to the heat source unit 301. The determination unit 142 determines the pipe length of the building 401 in the height direction as Ha for the utilization unit 302A and Hb for the utilization unit 302B.

Further, the determination unit 142 can determine the length of the pipes 4 and 7 in the plane direction, that is, in the XY direction from FIG. 8 which is a plan view.
As shown in FIG. 8, the heat source unit 301 and the utilization unit 302A have a distance of La1 in the vertical direction in the Y-axis direction and a distance of La2 in the horizontal direction in the X-axis direction. The determination unit 142 determines that the lengths of the pipes 4A and 7A in the plane direction are La1 + La2 in total.
The heat source unit 301 and the utilization unit 302B have a distance of Lb1 in the vertical direction in the Y-axis direction and a distance of Lb2 in the horizontal direction in the X-axis direction. The determination unit 142 determines that the lengths of the pipes 4B and 7B in the plane direction are Lb1 + Lb2 in total.

From FIGS. 7 and 8, the determination unit 142 determines the pipe lengths of the pipes 4A and 7A as "La1 + La2 + Ha". Further, the determination unit 142 determines the pipe lengths of the pipes 4B and 7B as "Lb1 + Lb2 + Hb". For the pipe diameters of the pipes 4A and 7A, the determination unit 142 adopts the value of the diameter of the pipe connected to the utilization unit 302A. For the pipe diameters of the pipes 4B and 7B, the determination unit 142 adopts the value of the diameter of the pipe connected to the utilization unit 302B.
By doing so, the reading variation by the operator can be eliminated and the calculation quality can be kept constant, as compared with the case where the piping is specifically traced from the PDF drawing. Here, the value of the diameter of the pipe connected to the utilization unit 302A and the value of the diameter of the pipe connected to the utilization unit 302B are described in the drawing data 334, and the determination unit 142 extracts them. Alternatively, the value of the diameter of the pipe connected to the utilization unit 302A and the value of the diameter of the pipe connected to the utilization unit 302B are stored in the main storage device 520 or the auxiliary storage device 530, and the determination unit 142 stores the value. Refer to the value that is set. As described above, the determination unit 142 can determine the value of the piping specification based on the drawing data 334.

As described above, the drawing data 334, which is the circuit configuration data, includes the model names of the plurality of heat exchangers, the installation position of the heat source machine in the building plan view, and the installation position of the plurality of heat exchangers in the building plan view. , The installation floor where the heat source machine and multiple heat exchangers are installed is shown, and the length and diameter of each pipe cannot be obtained directly.
Then, the determination unit 142 is based on the model name shown in the drawing data 334, the installation position of the heat source machine and the installation positions of the plurality of heat exchangers, and the installation floor of the heat source machine and the plurality of heat exchangers. , Determine the length and diameter of the pipe.

The plan view data of FIG. 8 describes the plan view dimensions of the building 401 in which the water-air conditioning system 100 is installed.
If building 401 cannot get the floor plan of FIG.
The determination unit 142 determines the pipe lengths of the pipes 4A and 7A and the pipes 4B and 7B from the installation floor of the utilization unit 302 and the heat source unit 301 and the dimensions of the building 401.
FIG. 9 shows a method of determining the piping specification value by the determination unit 142. According to FIG. 9, the determination unit 142 determines that the dimensions of the pipes 4A and 7B and the pipes 4B and 7B in the plane direction are "Lab1 + Lab2" as a common value. The installation positions of the utilization unit 302A and the utilization unit 302B in the height direction of the building 401 are the same as those in FIG. 7. Therefore, the determination unit 142 determines the lengths of the pipes 4A and 7A as "Lab1 + Lab2 + Ha", and determines the lengths of the pipes 4B and 7B as "Lab1 + Lab2 + Hb".

By such a determination method by the determination unit 142, the determination unit 142 has an effect of being able to determine the piping specifications even if the details of the installation position of the utilization unit are unknown.

Embodiment 3.
In the third embodiment, only the parts different from the first embodiment will be described.
FIG. 10 shows a water-air conditioning system 200 that uses pipes of different thicknesses. In the third embodiment, the pipe 3 having a diameter larger than that of the pipes 4A and 4B is connected to the upstream side of the pipes 4A and 4B with respect to the first embodiment. The pipe 3 is between the point p and the point q1 in FIG. Further, a pipe 8 having a diameter larger than that of the pipes 7A and 7B is connected to the downstream side of the pipes 7A and 7B. The pipe 8 is between the point t1 and the point u in FIG. The operating state calculation device 341 calculates the operating state by separately considering the pipes 3, 4, 7, and 8.

When pipes 3 and 4 having different pipe diameters are connected between the heat source related unit and the utilization unit 302 as in the third embodiment, the operation state calculation device 341 considers the difference in pipe diameters. , The calculation accuracy of the operating condition is improved.

Specifically, in step S2 of the flowchart of FIG. 5, the determination unit 142 acquires the pipe length and the pipe diameter, which are the pipe specification values of the pipe 3 and the pipe 8, in addition to the pipe 4 and the pipe 7, and in step S4. , The calculation unit 144 calculates using the pipe specification values of the pipes 3, 4, 7, and 8. By doing so, even if the pipe diameter changes in the middle, the operating state can be calculated in consideration of the actual construction state.
Even if there are many places where the pipe diameter is changed in the middle between the heat source related unit and the utilization unit 302, it can be reflected in the calculation of the operation state calculation device 341 by the same method as this time. ..

In the operation state calculation device 341 described from the first embodiment to the third embodiment, the determination unit 142 is data other than the piping specification value that can be determined from the electronic data 333 or the drawing data 334, and the calculation unit 144 calculates. The data necessary for the data may be stored in the auxiliary storage device 530, or may be configured to be received by the reception control unit 143.

In the first to third embodiments, the operating state calculation device 341 targets the water-air conditioning system 100, but the operating state calculation device 341 uses the circuit configuration data of a multi-air conditioner for building, that is, a so-called multi for building. Simulation may be performed using the data of the circulation circuit.

1A operating condition, 1B operating condition, 1C total power consumption, 2A operating condition, 2B operating condition, 2C total power consumption, 1 secondary pump, 2 bypass valve, 3 piping, 4A piping, 4B piping, 5 utilization heat exchanger, 5A heat exchanger, 5B heat exchanger, 6 electric two-way valve, 6A electric two-way valve, 6B electric two-way valve, 7A piping, 7B piping, 8 piping, 9 primary pump, 10 piping, 14, 15, 16 Header, 100, 200 Water-Air Harmonization System, 120 Computer, 201 Differential Pressure Gauge, 202 Flow Meter, 204 Temperature Sensor, 204A Temperature Sensor, 204B Temperature Sensor, 205 Temperature Sensor, 206 Differential Pressure Gauge, 206A Differential Pressure Gauge, 206B Differential Pressure Gauge, 207 flow meter, 207A flow meter, 207B flow meter, 301 heat source unit, 302 utilization unit, 302A utilization unit, 302B utilization unit, 303 system control device, 102 system measurement unit, 103 system calculation unit, 104 system control unit, 105 system Storage unit, 106 system communication unit, 313 usage control device, 112 usage measurement unit, 113 usage calculation unit, 114 usage control unit, 115 usage storage unit, 116 usage communication unit, 313A usage control device, 313B usage control device, 323 monitor Equipment, 125 monitor storage unit, 126 monitor communication unit, 127 monitor display unit, 333 electronic data, 334 drawing data, 341 operating state calculation unit, 141 acquisition unit, 142 decision unit, 143 reception control unit, 144 calculation unit, 401 building , 402 coordinates, 510 processor, 520 main storage, 530 auxiliary storage, 540 input IF, 550 output IF, 560 communication IF, 570 signal lines.

Claims (9)

A circuit in which a heat source machine, a pump, and a plurality of heat exchangers are connected by a plurality of pipes, and the length and diameter of the pipes are based on circuit configuration data showing the configuration of a circulation circuit which is a circuit in which a heat medium circulates. And the decision-making part that decides
A calculation unit that calculates the operating state of the circulating circuit corresponding to the operating conditions based on the determined length and diameter of the pipe and the operating conditions of the circulating circuit.
A data processing device including an output control unit that outputs the operating state to a storage device. The calculation unit
Using the calculated operating state, the power consumption corresponding to the operating state is calculated.
The output control unit
Output the power consumption to the storage device,
The data processing device according to claim 1. The circuit configuration data is
It is extractable data that can directly extract the length and diameter of the pipe.
The decision unit
The data processing apparatus according to claim 1 or 2, wherein the length and diameter of the pipe are directly extracted from the circuit configuration data which is the extractable data. The circuit configuration data is
The model names of the plurality of heat exchangers, the positional relationship between the positions of the heat source machines and the plurality of heat exchangers are shown, and the length and diameter of the pipes cannot be directly acquired with unobtainable data. Yes,
The decision unit
The data processing apparatus according to claim 1 or 2, wherein the length and diameter of the pipe are determined based on the model name and the positional relationship shown in the circuit configuration data which is the unobtainable data. .. The heat source machine
Located on the roof of a building with multiple floors
The plurality of heat exchangers
It is located on one of the multiple floors mentioned above.
The circuit configuration data is
The model names of the plurality of heat exchangers, the installation position of the heat source machine in the plan view of the building, the installation position of the plurality of heat exchangers in the plan view of the building, and the heat source machine and the plurality of heat exchanges. The installation floor where the vessel is installed is shown, and the length and diameter of the pipe cannot be obtained directly.
The decision unit
The model name shown in the circuit configuration data, which is unobtainable data, the installation position of the heat source machine, the installation position of the plurality of heat exchangers, the heat source machine, and the plurality of heat exchangers. The data processing apparatus according to claim 1 or 2, wherein the length and diameter of the pipe are determined based on the above-mentioned installation floor. The output control unit
The length of the pipe for each heat exchanger from the position on the outflow side of the heat source machine from which the heat medium flows out to the inflow port of the heat medium in each of the heat exchangers of the plurality of heat exchangers. The data processing apparatus according to any one of claims 1 to 5, which outputs in any order of longest length and shortest length. The circuit configuration data is
The data processing device according to any one of claims 1 to 6, which shows the configuration of the circulation circuit of the multi-air conditioner for a building. On the computer
A circuit in which a heat source machine, a pump, and a plurality of heat exchangers are connected by a plurality of pipes, and the length and diameter of the pipes are based on circuit configuration data showing the configuration of a circulation circuit which is a circuit in which a heat medium circulates. And the decision process to determine
Based on the determined length and diameter of the pipe and the operating conditions of the circulating circuit, arithmetic processing for calculating the operating state of the circulating circuit corresponding to the operating conditions, and
A data processing program that executes an output control process that outputs the operating state to a storage device. The computer
A circuit in which a heat source machine, a pump, and a plurality of heat exchangers are connected by a plurality of pipes, and the length and diameter of the pipes are based on circuit configuration data showing the configuration of a circulation circuit which is a circuit in which a heat medium circulates. Decide,
Based on the determined length and diameter of the pipe and the operating conditions of the circulating circuit, the operating state of the circulating circuit corresponding to the operating conditions is calculated.
Output the operating state to the storage device,
Data processing method.

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