KR101043197B1 - A cold and hot water purifier control system - Google Patents

Abstract

Cold and hot water system control system according to the heating and cooling load fluctuation using a refrigerator-only controller according to the present invention is a plurality of cold and hot water connected to the pump with an inverter, the first header connected to the supply pipe oil of the cold and hot water, and the outlet of the first header A load portion connected to and supplying hot and cold air to the building, and a second header connected to the load portion, the cold and hot water flowing through the load portion and flowing out to the pump, the outlet temperature of the cold and hot water heater, and the outlet temperature of the first header. And a refrigerator-only controller that recognizes the inflow temperature into the second header and the outflow temperature of the cold / hot water machine, and controls the operation of the cold / hot water machine and the flow rate through the system, and precisely recognizes the cold / hot water outlet temperature and the inflow temperature of each cold / hot water machine. Refrigerator control that maintains proper operation of each cold and hot water machine through this medium. It is possible to precisely control by the roller to maintain the optimum operation of the air conditioner, as well as the energy saving and power saving can be excellent effect.

Description

Cold and hot water purifier control system according to air-conditioning load variation using dedicated controller

The present invention relates to a cold / hot water controller system according to air-conditioning load variation using a dedicated controller for refrigerators. More specifically, the present invention relates to a cold-water heater requiring proper operation of an air-conditioning / cooling water heater according to air-conditioning load variation of a building where people live and work. The present invention relates to a cold / hot water logarithmic control system according to a heating / cooling load variation using a dedicated refrigerator controller that saves energy and enables energy savings by controlling an appropriate number of operations.

In general, the logarithmic water control system of a cold and hot water heater according to the heating and cooling load fluctuations used in a conventional building controls the heat source of the cold and hot water heater by control by heat quantity, control by temperature difference, and flow rate control.

That is, as shown in Figure 1, the pump 2 is installed in each of the plurality of cold and hot water heaters 1 installed in the basement of the building, the cold water (summer) and hot water (winter) treated in the cold and hot water supply is supplied by the cold and hot water heaters (1) It is collected in the header (3) and branched from the supply header (3) and supplied to each floor of the building to supply a heat source to a heat source equipment such as an air conditioner and a coil of each floor, and the flow rate and the differential pressure valve returned through the heat source equipment ( 4) is combined with the flow rate through the cold and hot water heater (1) is a structure.

In the conventional logarithmic water control system for supplying cold and hot water, the control part of the cold / hot water machine supplies the temperature of the supply part temperature sensor (3) to a portion flowing out from the supply header (3) in which the treated water passing through the cold / hot water machine (1) is collected. 5) is attached and checks the temperature, and compares the difference of the temperature detected by the return part temperature sensor (5 ') to the part to be returned by turning each layer to determine the number of running of each cold and hot water heater (1) In addition, such a method has a problem in that it is impossible to use a cold or hot water machine electrically or efficiently because it cannot be precisely controlled in a manner of controlling the number of operating units of the cold and hot water machine by indirectly obtaining a load by the temperature difference between the supply side and the return side.

The control by the flow rate is a method of controlling the operation of the cold / hot water machine by comparing the change in the flow rate on the supply side and the return side, but in general, it is not suitable because the change in load amount and the change in flow rate do not form a linear proportional relationship.

In addition, the control based on the amount of heat is a method of controlling the operation number of the cold / hot water machine by detecting the change of the temperature and the flow rate of the supply side and the return side of the fluid flowing in the load system. Although it is possible, however, precise control of cold and hot water heaters such as minute temperature change or flow rate change is impossible, so it is impossible to recognize the difference of minute temperature or difference in flow rate, so the heating and cooling cost of the building is increased so that energy management cannot be efficiently managed. There was a problem.

An object of the present invention is to solve this problem, by precisely recognizing the cold and hot water outflow temperature and inlet temperature of each cold and hot water machine, by means of this controller precisely by a dedicated controller for maintaining the operation of the appropriate number of each cold and hot water machine It is possible to control the air conditioner to maintain the optimum operation of the air conditioner, as well as to provide a cold and hot water logarithmic control system according to the heating and cooling load change using a dedicated controller that can save energy and power saving.

This object of the present invention, a plurality of cold and hot water connected to the pump with an inverter, a first header connected to the outlet of the cold and hot water, a load portion connected to the outlet of the first header and supplying a hot and cold air to the building, and In the cold water heater algebraic control system comprising a second header connected to the load portion and the cold and hot water flowing through the load portion flows out to the pump, the outlet temperature of the cold and hot water heater, the outlet temperature of the first header and the second header Achieved by a cold and hot water log control system according to the heating and cooling load variation using the freezer controller according to the present invention equipped with a freezer controller for recognizing the inlet temperature, the outlet temperature of the cold and hot water machine, and controls the operation of the cold and hot water machine and the flow rate flowing through the system. do.

Cold water heater Log control system according to the heating and cooling load fluctuation using the refrigerator-only controller according to the present invention, a plurality of cold and hot water connected to the pump with an inverter, a first header connected to the supply pipe of the cold and hot water, and the outlet of the first header And a second header connected to the load unit and supplying a cooler to the building, and a second header connected to the load unit and allowing the cold and hot water to flow through the pump and flowing out to the pump. It is equipped with a freezer controller that recognizes the temperature, the inlet temperature to the second header, the outlet temperature of the cold and hot water machine, and controls the operation of the cold and hot water machine and the flow rate through the system. Refrigerant cone for recognizing and maintaining proper operation of each water heater That is able to be precisely controlled by the roller to maintain the operation of the Cooling & Heating at best, as well as a superior effect that the saving with the telephone section of the energy available.

As shown in FIG. 2, a cold / hot water logarithmic control system A according to a cooling / heating load variation using a dedicated refrigerator controller according to the first embodiment of the present invention includes: a plurality of cold / hot water heaters 10 connected to the pump 11; A first header 20 connected to a supply pipe of the cold / hot water heater 10, a load part 30 connected to an outlet of the first header 20, and supplying a cold / hot air to a building, and connected to the load part 30. And a second header 40 flowing cold and hot water past the load part and flowing out to the pump 11.

The cold and hot water pump control system (A) includes a freezer controller 50, the freezer controller 50, the outlet temperature of the cold water heater 10, the outlet temperature of the first header 20, and the second header Recognizing the inlet temperature of the furnace, the outlet temperature of the cold water heater 10 and controls the operation of the cold water heater and the flow rate of the fluid flowing through the system.

The cold / hot water machine 10 is a device for supplying cold / hot water for maintaining cooling or heating of a building, and cooling or heating does not show a structure such as a compressor or a heat radiating fan installed in its cold / hot water machine 10. When the cold and hot water machine 10 is used in the summer, the cooling tower is installed but not shown. The cold and hot water machine 10 is connected to the freezer controller 50 so that the required number of units is operated by the command of the freezer controller 50.

A pump 11 is installed at the rear of the cold / hot water machine 10, the pump 11 is installed with an inverter 12, and the inverter 12 is a controller dedicated to the refrigerator to adjust the rotation speed of the pump 11. Is connected to (50), it is possible to adjust the rotational speed of the pump 11 to the required rotational speed by receiving the necessary command by the dedicated refrigerator controller (50). That is, the inverter 12, for example, it is possible to convert the rotational speed of 1800rpm of the conventionally used pump to 900, 1200rpm by the command of the refrigerator-only controller 50 to reduce the power consumption Will be. In the present embodiment, the pump 11 and the inverter 12 are used to be separated, but the inverter pump attached to the inverter and the pump will also be said to belong to the scope of the present invention.

In this embodiment, four pumps 11 are installed in three of the cold and hot water heaters 10 including a preliminary pump, and an inverter 12 is provided for each pump 11.

The first header 20 is a storage container for temporarily storing the fluid, which is cold water or hot water flowing out of the cold / hot water machine 10, and the cold water or hot water stored therein flows out to the load part 30 again and the cold air in the load part. It will supply warmth.

The differential pressure valve 60 is installed between the first header 20 and the second header 40, and the differential pressure valve 60 is the pressure of the fluid introduced into the load part 30 and the pressure of the fluid drawn out. Is sensed by the differential pressure sensor 323 is connected to the refrigerator dedicated controller 50 to control the differential pressure valve 60, the differential pressure valve 60 is connected to the refrigerator dedicated controller 50 to the pressure It sends out to the dedicated refrigerator controller 50 and receives a command by the dedicated refrigerator controller 50 performs the operation of opening and closing the differential pressure valve 60 as necessary. The differential pressure gauge 61 installed in parallel with the differential pressure valve 60 transmits the pressure of the flow rate to the freezer controller 50.

The load unit 30 is installed on each floor of a building that requires air conditioning. The air conditioner (AHU) or fan coil (FCU) for heating and cooling the inner circumference of the building is operated through a duct (not shown).

An inlet temperature detector 311 is installed at an inlet of the inlet unit 31 provided between the first header 20 of the load unit 30 to measure the temperature of the fluid flowing out of the first header 20. The inlet temperature sensor 311 is connected to the refrigerator controller 50 and transmits the recognized temperature to the refrigerator controller 50.

An outlet temperature detector 321 for measuring the outlet temperature of the fluid is installed at the outlet of the outlet portion 32 provided between the second header 40 of the load portion 30 and a flow meter 322 for detecting the flow rate. Is installed, and outputs the signal recognized by the take-out temperature sensor 321 and the flow meter 322 to the refrigerator dedicated controller 50.

The load unit 30 is itself connected to a heat source device controller (not shown).

As shown in FIG. 2, the refrigerator-only controller 50 is connected to each cold / hot water machine 10, is connected to an inverter 12 for operating the pump 11, and an inlet part of the load unit 30 ( 31 is connected to the inlet temperature sensor 311 of the load unit 30, and is connected to the outlet temperature sensor 321 and the flow meter 322 of the outlet unit 32 of the load unit 30, the differential pressure valve 60 and the differential pressure gauge 61 )

As shown in FIG. 3, the refrigerator only controller 50 includes a control module 51, a power module 52 for supplying power, an operator interface 53, an I / O module 54, and a base module. It consists of 55.

The control module 51 is a pivotal part of the dedicated controller 50 for the refrigerator, and is combined with the operator interface 53, the I / O module 54, and the base module 55 to control the refrigerator dedicated controller 50. ). As shown in FIG. 4, the control module 51 includes a first communication unit 511 communicating with the operator interface 53, and a second communication unit 512 communicating with the I / O module 54. And a power input unit 513 through which the power module 51 is input, and a control unit 514 which receives the received signal and converts the received signal into a necessary command.

The power module 52 supplies power to the control module 51, the operator interface 53, the I / O module 54, and the base module 55. The power module 52 supplies power to a power input unit 521 to which commercial power is supplied, a control module power unit 522 to supply power to the control module 51, and the I / O module 54. It includes an I / O power supply unit 523, the specific configuration is composed of a switching connector, a seal, and a fuse, not shown in detail.

The operator interface 53 is a display unit having a color LCD and a touch panel, and the connection level can be distinguished by a password so that the operator interface 53 can be used as a parameter setter of a service representative, and also functions as an LED display unit of power, alarm, and power failure stop. Also perform.

The I / O module 54 is connected to the control module 51 by mounting a communication LSI therein as an input / output part. Power supply or communication connection to the I / O module 54 is performed by the base module 55. The I / O module 54 has an AI (Analog Input) module (DC4-20 mA current input 2 points), AO (Analog Output) module (DC4-20 mA current output 1 point), MM module (Feedback Modutrol Motor output 1) (DI) Digital input module (5 points of no-voltage contact input), DO (digital output) module (4 points of no-voltage a contact output), DIO (digital input / output) module (24 VDC instantaneous voltage output) There are a plurality of inserts into which the card in which each module is stored is inserted so that 1 point + 2 voltage input contacts are operated.

The base module 55 is a module for power supply, communication connection, and address setting for the I / O module 54. By having a function as a terminal block of the I / O module 54 and connecting the I / O module 54 with a plug-in, the I / O module 54 can be separated without disconnecting wiring.

The operation of the cold and hot water logarithmic control system (A) according to the air-conditioning load fluctuation using the refrigerator-only controller according to the present invention having such a configuration will be described in detail below.

First, in the state where four load units 30 are set in the summer, the set temperature of the load unit 30 is set to 23 ° C., the external temperature is about 30 ° C., and cooling is started. Two cold and hot water heaters 10 needing operation is required. When the output of each of the two cold and hot water heaters 10 is set to a maximum of 100 and 200 is output, each of the load units 30 requires 50 energy, so that the load unit 30 starts cooling.

In this state, the first load part 30 and the second load part 30 of the highest order and the next order reach the set temperature of 23 ° C., and the third and fourth load parts 30 are 26 ° C. and 27 ° C., respectively. If the required energy is required to 100, since the operation of the two cold and hot water heater 10 is operated and only 100 outputs, the dedicated controller 50 for the refrigerator to give a command to the inverter 12 each pump Reduce the maximum output of (11) by half or instruct only one pump (11) to run. Recognition when the set temperature of the first load portion and the second load portion 30 reaches the temperature is transferred from the take-out temperature sensor 321 to the freezer controller 50 in real time and the fluid in the flow meter 322. Flow rate is transmitted to the dedicated controller 50 for the refrigerator and the pressure of the differential pressure valve 60 and the differential pressure gauge 61 is transmitted to the dedicated controller 50 for the refrigerator, so that the set temperature is reached in the load unit 30 in real time. Becomes recognized.

In this manner, when the third load portion and the fourth load portion 30 also reach the set temperature, the controller recognizes this in real time and terminates the operation of the cold water heater 10, and when the temperature exceeds the set temperature again, Select the number to be run.

The cold and hot water logarithmic control system according to the heating and cooling load variation using a dedicated refrigerator controller according to the present invention will be said to be an invention that can be industrially available because it can be repeatedly reproduced in a general manufacturing plant.

1 is an instrumentation diagram of a logarithmic control system of a cold and hot water heater according to a conventional embodiment

2 is an instrumentation diagram of a cold / hot water logarithmic water control system according to a first embodiment of the present invention;

3 is a block diagram of the cold and hot water logarithmic control system of FIG.

4 is a block diagram of a dedicated controller for a refrigerator

* Description of the symbols for the main parts of the drawings *

10. Hot and cold water heater 11. Pump 12. Inverter

20. First header 30. Load part 40. Second header

50. Controller 60. Differential pressure valve 61. Differential pressure gauge

Claims (2)

A plurality of cold and hot water heaters 10 connected to the pump, the first header 20 connected to the outlet of the cold and hot water heater 10, and the load unit 30 is connected to the outlet of the first header 20 and supplies the cold and hot air to the building And a cold / hot water controller based on a cooling / heating load variation using a refrigerator-only controller including a second header 40 connected to the load part 30 and the cold / hot water flowing through the load part and flowing into the pump. ), The cold and hot water logarithmic water control system (A) includes a refrigerator only controller 50, The refrigerator-only controller 50 is connected to each cold / hot water machine 10, is connected to an inverter 12 for operating the pump 11, and the inlet temperature sensor 311 of the inlet part 31 of the load part 30 is connected. It is connected to the withdrawal temperature sensor 321 and the flow meter 322 of the withdrawal section 32 of the load section 30, The differential pressure valve 60 is installed between the first header 20 and the second header 40, and the differential pressure valve 60 and the differential pressure gauge 61 are connected to the refrigerator-only controller 50. Cold and hot water logarithmic control system according to air-conditioning load fluctuation The method of claim 1, The refrigerator-only controller 50 includes a control module 51, a power module 52 for supplying power, an I / O module 54, and a base module 55, The control module 51 may include a first communication unit 511 communicating with an operator interface 53, a second communication unit 512 communicating with the I / O module 54, and the power module 52. An input power input unit 513 and a control unit 514 which receives the received signal and converts the received signal into a necessary command, The power module 52 supplies power to a power input unit 521 to which commercial power is supplied, a control module power unit 522 to supply power to the control module 51, and the I / O module 54. Cold and hot water logarithmic control system according to the heating and cooling load change using a refrigerator-only controller characterized in that it comprises an I / O power supply unit 523

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