JPS6375436A - Controller for air handling unit - Google Patents

Abstract

PURPOSE:To permit the achievement of smooth indoor temperature control without generating hunting in a valve, by a method wherein a proportional gain, one of an operating parameters for the opening degree of the valve, is controlled at the optimum value in accordance with the rotating number of a fan by a parameter operating unit. CONSTITUTION:A set value is set in an indoor temperature setting unit 12 in a controller 11 and an indoor temperature is detected by a sensor 9 in a detecting unit 13 while the difference of the indoor temperatures is obtained in a comparing unit 14. Next, a fan rotating number commanding unit 15 operates the rotating number of a fan from the difference of the indoor temperatures and transmits a signal to an inverter 21. On the other hand, a set value is set in a feed air temperature setting unit 10 and a feed air temperature is detected by the sensor 10 in the detecting unit 17 while the difference of feed air temperatures is obtained in the comparing unit 18. Then, a parameter operating unit 19 determines a proportional gain, one of parameters for controlling PID, based on the rotating number of the fan. Subsequently, a valve opening degree commanding unit 20 determines the opening degree of a valve based on the difference of feed air temperatures and the proportional gain to transmit a signal to a valve driving unit 23. The indoor temperature may be kept constant by two kinds of controls in such a manner.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a control device for an air handling unit used for air conditioning of buildings and the like.

BACKGROUND OF THE INVENTION Conventionally, air handling units have been widely used for air conditioning in buildings, etc., but in recent years, control devices have become more sophisticated with the aim of improving comfort in air conditioning and reducing operating power.

Hereinafter, a conventional control device for an air handling unit as described above will be described with reference to the drawings.

In FIG. 4, reference numeral 1 denotes an air handling unit housing, and inside this air handling unit housing 1 there is a blower 2. Filter 4. It has a damper 5 for adjusting the exhaust air volume and the circulating air volume, and blows air into the air-conditioned room 7 via an air supply valve 7') 6:. The air handling unit, the housing 1, and the air-conditioned room 7 are connected by a return air duct 8. An indoor temperature sensor 9 electrically connected to the indoor temperature detection section 26 of the control device 240 is installed inside the air-conditioned room 7, and an air supply temperature detection section 3 of the control device 24 is installed inside the air supply duct 6. A supply air temperature sensor 10 electrically connected to ゜ is installed.

The control device 24 includes an indoor temperature comparing section 27 that compares the signal from the indoor temperature setting section 25 and the signal from the indoor temperature detecting section 26, and operationally amplifies the signal from the indoor temperature comparing section 27 and controls the rotation speed of the blower via an inverter. A blower rotation speed command section 28 to control, a supply air temperature comparison section 31 that compares the signal from the supply air temperature setting section 29 and a signal from the supply air temperature detection section 30, and an operational amplification of the signal from the supply air temperature comparison section 31. The valve opening command section 32 controls the water amount adjustment valve of the heat exchanger via a valve driving device. The blower rotation speed command section 28, the inverter 33% valve opening command section 32, and the valve drive device 36 are electrically connected, respectively.

In the above configuration, the operation will be explained next. The wind blown by the blower 2 is passed through the air supply duct 8. Air-conditioned room7. The return air returns to the air handling unit housing 1 via the return air duct 8, and passes through the damper 6 to the filter 4. The air is drawn into the blower 2 through the heat exchanger 3. The damper 6 adjusts the exhaust amount and intake amount by adjusting its rotation angle. On the other hand, the temperature signal obtained by the indoor temperature sensor 9 and the supply air temperature sensor 1o is the control bag r! 1240 is input to the indoor temperature detection section 26 and the supply air temperature detection section 29 to control the air handling unit.

Next, the second operation of the control device 24 will be explained.

The operation of the control device 24 is divided into a part that controls the blower 2 according to the room temperature and a part that controls the valve 34 according to the supply air temperature.

FIG. 6 is a flowchart showing a method of controlling the valve, and FIG. 6 is a flowchart showing a method of controlling the blower.

In FIG. 6, a set value TR is set by the operator in the indoor temperature setting section 25, and an indoor temperature tH is detected by the indoor temperature sensor 9 in the indoor temperature detecting section 26. The indoor temperature comparison section 27 calculates the indoor temperature deviation eR as shown in equation (1).

・R””R'R... Old... (1) The blower rotation speed command unit 28 uses the indoor temperature deviation eR obtained by the indoor temperature comparison unit 27 to calculate the equation (shown in A PID calculation is performed to determine the rotation avR of the blower, and a signal is sent to the inverter 33.

・・・・・・・・・・・・・・・(No, here KcR is the proportional gain, τiR is the integration time, “dR
is a parameter given a constant value by the operator in differential time.

Thereafter, the process returns to the indoor temperature detection section 26 and the same operation is repeated.

In FIG. 6, a set value Ts is set by the operator in the supply air temperature setting unit 29, and a supply air temperature t3 is detected by the supply air temperature sensor 1o in the supply air temperature detection unit 30. The supply air temperature comparison section 31 calculates the supply air temperature deviation es as shown in 2).

es; Ts-ts ......0) The valve opening command section 32 performs the PID calculation shown in equation (4)K from the supply air temperature deviation es obtained by the supply air temperature comparison section 31 to determine the valve opening. Determine Uv and send a signal to the valve drive device 36.

・・・・・・・・・・・・・・・(4) Here' Ka
s is a proportional gain, ``is'' is an integral time, and Tds is a differential time, which are parameters to which constant values are given by the operator.

Thereafter, the process returns to the supply air temperature detection section 3o and the same operation is repeated.

The indoor temperature can be kept constant through the above two controls.

Problems to be Solved by the Invention However, in the above configuration, the valve opening calculation parameter is constant, so depending on the rotation speed of the blower, the proportional gain KC8, which is one of the valve opening calculation parameters, may be affected by a large load such as an air conditioner. This has the problem that the value may be inappropriate in response to fluctuations, causing hunting in the valve and making it impossible to achieve smooth indoor temperature control.

The present invention solves these problems and aims to provide an air handling unit that can achieve smooth indoor temperature control without causing valve hunting.

Means for Solving the Problem In order to solve this problem, the air handling unit control device of the present invention includes an indoor temperature detection section to which a signal is input from a temperature sensor that detects the indoor temperature, and a temperature sensor for setting the indoor temperature. an indoor temperature setting section that compares the signal output from the indoor temperature detection section with the signal output from the indoor temperature setting section; A blower rotation speed command unit that controls the rotation speed, a supply air temperature detection unit that receives a signal from a supply air temperature sensor that detects the supply air temperature, a supply air temperature setting unit that sets the supply air temperature, and a supply air temperature setting unit that sets the supply air temperature. a supply air temperature comparison section that compares the output signal of the temperature detection section and the output signal of the supply air temperature setting section; and a parameter calculation section that inputs the rotation speed signal of the blower rotation speed command section and calculates a valve opening calculation parameter. and a valve opening command section which inputs the output signal of the supply air temperature comparison section and the output signal of the parameter calculation section and controls the valve via a valve driving device.

Effect: With this configuration, the blower rotation speed is calculated in the blower rotation speed command section based on the signal from the indoor temperature comparison section, and the valve opening calculation parameter is calculated in the parameter calculation section based on the rotation speed signal from the blower rotation speed command section. The valve opening command unit calculates the valve opening based on the signal from the supply air temperature comparison unit and the output signal from the valve opening calculation parameter calculation unit, thereby controlling the valve.

EXAMPLE Hereinafter, an example of the present invention will be described with reference to FIGS. 1 to 3.

In FIG. 1, the same parts as in the conventional example are given the same numbers and detailed explanation thereof will be omitted.

That is, the present invention is characterized by a control device, and the configuration of the control device 11 will be explained.

an indoor temperature detection unit 13 electrically connected to the indoor temperature sensor 9 that detects the temperature in the air-conditioned room 7; an indoor temperature setting unit 12 that sets the indoor temperature to maintain a constant temperature; The indoor temperature comparison unit 14 inputs and compares the set indoor temperature and the set indoor temperature and calculates the difference.

It also has a blower rotation speed command unit 16 that inputs this calculated temperature difference, performs calculations to change the rotation speed of the blower 2 to reach a set indoor temperature, increases or increases the air volume, and outputs a signal. are doing.

Furthermore, a supply air temperature detection section 17 is electrically connected to a supply air temperature sensor 10 that detects the temperature of nitrogen gas discharged from the blower 2 in the duct, and a temperature sensor 17 is set to maintain the supply air temperature constant. The supply air temperature setting section 16 includes a supply air temperature comparison section 18 that inputs and compares the two detected supply air temperatures and the set supply air temperature and calculates a difference. The rotational speed signal of the blower rotational speed command section 16 is input, and calculation parameters are calculated. The two signals, this calculated signal and the signal output from the supply air temperature comparison section 18, are input to the valve opening command section 20, and based on the calculated value, the valve opening,
It is configured to control the drive device 23.

Next, the second operation of the control device 11 will be explained.

The operation of the control device 11 is divided into a part that controls the blower according to the room temperature and a part that controls the valve according to the supply air temperature.

In FIG. 2, in the indoor temperature setting section 12, a set value TR is set by the operator, and the indoor temperature detecting section 13
Then, the indoor temperature tH is detected by the indoor temperature sensor 9. The indoor temperature comparison section 14 calculates the indoor temperature deviation eR as shown in equation (5).

eH=THtH・・・・・・・・・・・・・・・・・・)) The blower rotation speed command unit 15 performs the PID calculation shown in equation (6) from the indoor temperature deviation eR obtained by the indoor temperature comparison unit 14. , determine the rotation speed VR of the blower, and set the inverter 2.
Send a signal to 1.

・・・・・・・・・・・・・・・(6) Here, KcR
is a proportional gain, iR is an integral time, and dR is a differential time, which are parameters to which a constant value is given by the operator.

Thereafter, the process returns to the room temperature detection section and the same operation is repeated.

In FIG. 3, in the supply air temperature setting section 1e, a set value Ts is set by the operator, and the supply air temperature detection section 1
At 7, the supply air temperature tS is detected by the supply air sensor 10. The supply air temperature comparison section 18 calculates the supply air temperature deviation es as shown in equation (7).

θs:”s 's ”””””””'(
7) In the parameter calculation unit 19, the blower rotation speed command unit 15
Based on the blower rotation speed vR calculated in Equation (8)
The proportional gain K, which is one of the PID control parameters, is
. Determine S.

Here, vmax is a constant given by the operator at the maximum rotational speed of the blower. Further, kc8 is a constant given by the operator as the optimum proportional gain when the rotational speed of the blower 2 is maximum.

The valve opening command section 2o performs the PID calculation shown in equation (9) from the supply air temperature deviation es obtained by the supply air temperature comparison section 18 and the proportional gain Kcs calculated by the parameter calculation section 19, and determines the valve opening. Determine Uv and send a signal to valve drive bag #23.

・・・・・・・・・・・・・・・(9) Here, TiS
is an integral time, and TdS is a differential time, which are parameters given constant values given by the operator.

Thereafter, the same operation is repeated when the supply air temperature detecting section returns.

The indoor temperature can be kept constant through the above two controls.

Effects of the Invention As is clear from the description of the embodiments above, according to the present invention, the parameter calculation unit calculates one of the valve opening calculation parameters.
The proportional gain, which is It is possible to achieve smooth indoor temperature control without causing valve hunting.

[Brief explanation of the drawing]

Fig. 1 is a diagram showing a schematic configuration of an air handling unit and its control device in an embodiment of the present invention, Fig. 2 is a flowchart showing the control of the blower of the control device, and Fig. 3 is a diagram showing the control of the air blower of the control device. Flowchart showing the control, Fig. 4 is a diagram showing the schematic configuration of a conventional air tone link unit and its control device, Fig. 6 is a flowchart showing the control of the blower of the same control device, Fig. It is a flow chart showing valve control. 2...Blower, 9...Indoor temperature sensor, 10...Supply air temperature sensor, 11...
Control device, 12... Indoor temperature setting section, 13...
... Indoor temperature detection section, 14 ... Indoor temperature comparison section, 15 ... Blower rotation speed command section, 16 ...
...Supply air temperature setting section, 17... Supply air temperature detection section, 18... Supply air temperature comparison section, 19...
...Parameter calculation unit, 2o...Valve opening command unit, 21...Inverter, 22...Valve,
23...Valve 1 drive device. Name of agent: Patent attorney Toshio Nakao and 1 other person2-
- 1 mention of mold J Maki 9 - 11 room 'Inside person's death so T - - In - \ - data f5 - Frog 1 hole iso and l vs rental + i-g input iLI setting ship No. 4 Fig. 5 Figure 27 --- ,=Jauryshu 2B-Ut, E second position 9Jireihou 32-Samurai opening and closing end Reishu

Claims (1)

[Claims] an indoor temperature detection section into which a signal from a temperature sensor that detects the indoor temperature is input; an indoor temperature setting section that sets the indoor temperature;
an indoor temperature comparison section that compares a signal output from the indoor temperature detection section and a signal output from the indoor temperature setting section;
a blower rotation command section that inputs the signal from the indoor temperature comparison section and controls the rotation speed of the blower; a supply air temperature detection section that receives the signal from the supply air temperature sensor that detects the supply air temperature; a supply air temperature setting section for setting the supply air temperature, a supply air temperature comparison section for comparing the output signal of the supply air temperature detection section and the output signal of the supply air temperature setting section, and a rotation speed signal of the blower rotation speed command section. a parameter calculation unit that inputs the input and calculates a valve opening calculation parameter; and a valve opening command that inputs the output signal of the supply air temperature comparison unit and the output signal of the parameter calculation unit and controls the valve via the valve driving device. A control device for an air handling unit consisting of two parts.