KR20020088930A - Controller for constant temperature and humidity apparatus or constant temperature and humidity chamber - Google Patents

Abstract

PURPOSE: A thermohydrostat and controller for the same are provided to control temperature and humidity with the single controller. CONSTITUTION: A thermohydrostat includes a dry and wet bulb hygrometer(110) having a dry bulb part(111) and a wet bulb part(112) to output second temperature measured by the dry bulb part and third temperature measured by the wet bulb part; a calculation circuit part(210) receiving the second temperature and the third temperature from the dry and wet bulb hygrometer to convert into second humidity and converting the second humidity and the second temperature into digital signal to output; a microcomputer(310) receiving the second temperature and the second humidity converted into digital signal from the calculation circuit part, comparing the second humidity with first humidity and the second temperature with first temperature, where the first humidity and the first temperature is stored therein in advance, generating control signal controlling a thermohydrostat or a working part of the thermohydrostat(20) to output and instructing to display the first temperature, the second temperature, the first humidity and the second humidity; and a display part(400) displaying the first temperature, the second temperature, the first humidity and the second humidity following the instruction of the microcomputer.

Description

Controller for constant temperature and humidity chamber {Controller for constant temperature and humidity apparatus or constant temperature and humidity chamber}

The present invention relates to a thermo-hygrostat or a thermo-hygrostat controller, and more particularly, to a thermo-hygrostat or a thermo-hygrostat controller that can control temperature and humidity with one controller.

Currently, research and development of high-tech industries such as various air conditioning equipment, environmental test equipment, durability tester, aging of semiconductor parts manufacturing plant, automobile parts tester, technology laboratory, quality assurance room, optical machine manufacturer, hospital, and precision machine assembly device In addition, the thermohygrostat and the thermo-hygrostat are used to maintain the cleanliness of the ambient temperature and humidity in the home.

However, the conventional thermo-hygrostat or the thermo-hygrostat is separately used by the controllers for cold, heating and humidification and dehumidification operation of the thermo-hygrostat or the thermo-hygrostat. As such, since the controllers for controlling the thermo-hygrostat or the thermo-hygrostat are separately provided, management and installation work are cumbersome and expensive. Especially, since there is no means for confirming various internal conditions from the outside, optimal control is provided. It was difficult and there is a problem that consumes a lot of power. In addition, in order to use a thermo-hygrostat or a thermo-hygrostat in an advanced industrial field, it is necessary to develop a high reliability controller capable of controlling temperature and humidity quickly and accurately.

Therefore, the technical problem to be achieved by the present invention is to provide a thermo-hygrostat or a thermo-hygrostat controller that can control the temperature and humidity quickly and accurately with a single controller to reduce the cost.

1 is a block diagram for explaining a thermo-hygrostat or a thermo-hygrostat controller according to an embodiment of the present invention; And

2 is a block diagram illustrating a thermo-hygrostat or a thermo-hygrostat controller according to another embodiment of the present invention.

The thermo-hygrostat or the controller for constant temperature / humidity according to an embodiment of the present invention for achieving the technical problem is: having a dry bulb portion and a wet bulb portion, the second temperature measured at the dry bulb portion and the third temperature measured at the wet bulb portion A wet and dry ball system to output; An arithmetic circuit unit receiving the second and third temperatures from the wet and dry sphere system and converting the second and third temperatures into second humidity, converting the second humidity and the second temperature into digital signals and outputting the digital signals; The second temperature and the second humidity converted into the digital signal are received from the arithmetic circuit unit, and the second humidity is compared with the first humidity stored in advance, and the second temperature and the first temperature stored in advance are stored in the digital signal. Compare and generate a control signal for controlling the operating unit of the thermo-hygrostat or the thermo-hygrostat and outputs to the operating unit of the thermo-hygrostat or the thermo-hygrostat, and displays the first temperature, the second temperature, the first humidity, and the second humidity. A microcomputer that commands to do; And a display configured to display the first temperature, the second temperature, the first humidity, and the second humidity by being commanded by the microcomputer.

At this time, the operation unit is installed to be connected to the microcomputer and outputs a second digital signal having information on the increase and decrease of temperature and humidity by the user's operation toward the microcomputer, the microcomputer is the second from the operation unit And receiving a digital signal to further generate a second control signal for controlling the operation unit of the thermo-hygrostat or the thermo-hygrostat.

A thermo-hygrostat or a thermo-hygrostat controller according to another embodiment of the present invention for achieving the technical problem is: having a dry bulb portion and wet bulb portion and outputs a second temperature measured at the dry bulb portion and a third temperature measured at the wet bulb portion A measuring unit including a wet and dry sphere and an electronic sensor for measuring and outputting a second humidity; Receiving the second and third temperatures and the second humidity, converting the third humidity from the second and third temperatures, converting the second temperature, the second humidity, and the third humidity into a digital signal; An outputting circuit circuit; Receives any one selected from the second humidity and the third humidity converted into the digital signal from the computing circuit unit, compares the second humidity or third humidity and the first humidity stored in advance to the second humidity and the second temperature And a control signal for controlling the operating unit of the thermo-hygrostat or the thermo-hygrostat by comparing the first temperature stored in advance with the first temperature, and outputting the control signal to the operating unit of the thermo-hygrostat or the thermo-hygrostat, and calculating the first temperature and the first humidity and the operation. A microcomputer for instructing to display the temperature and humidity input from the circuit unit; An operation unit installed to be connected to the micom, the operation unit having an input mode button for instructing the micom to receive one of the second humidity and the third humidity converted into the digital signal from the computing circuit unit; And a display unit for displaying the first temperature and the first humidity and the temperature and the humidity inputted from the computing circuit unit by the command from the microcomputer.

At this time, the operation unit outputs a second digital signal having information on the increase and decrease of temperature and humidity by the user's operation toward the micom, and the micom receives the second digital signal from the operation unit and the thermo-hygrostat Or further generating a second control signal for controlling the operation unit of the constant temperature and humidity chamber.

In each example according to the present invention, the microcontroller is further provided with a remote controller which is installed in the micom and the remote place and outputs a third digital signal having information on the increase and decrease of temperature and humidity toward the micom by the user's operation The controller may further generate a third control signal for controlling the thermo-hygrostat and the operation unit of the thermo-hygrostat by receiving the third digital signal from the remote controller.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a block diagram illustrating a controller for a thermo-hygrostat or a constant temperature / humidity chamber according to an example of the present invention, and FIG. 2 is a block diagram illustrating a controller for a thermo-hygrostat or a constant temperature / humidity chamber according to another example of the present invention. 1 and 2, the same reference numerals will be omitted as repeated components as performing the same function, and the arrows indicate the flow of signals or the flow of data.

Example 1

Referring to FIG. 1, a controller for a thermo-hygrostat or a thermo-hygrostat according to an example of the present invention (hereinafter, referred to as a thermo-hygrostat) is a wet and dry sphere 110, a calculation circuit unit 201, and a microcomputer ( 310 and the display unit 400.

Wet and dry sphere 110 measures the temperature of the site where the thermo-hygrostat (tank) is installed. Briefly explain the principle of wet and dry system.

The wet and dry bulb system 110 uses the difference between the amount of water evaporated from the wet bulb and the amount of water vapor contained in the surroundings. The wet and dry sphere 110 is wrapped in a gauze or a thin cloth or cotton and the like in the temperature-sensitive portion of the wet bulb temperature sensor, sucks the water from the end, and the wet bulb portion 112 is to evaporate the water in the temperature-sensitive portion, the wet bulb When the water is evaporated from the unit 112 is made of a dry bulb 111 for measuring the temperature of the surroundings. At this time, when the surrounding water vapor is small, the water evaporates from the wet bulb part 112, and the difference between the dry bulb temperature measured by the dry bulb part 111 and the wet bulb temperature in the wet bulb part 112 becomes large. At this time, the amount of ambient water vapor is determined by the difference between the dry bulb temperature and the wet bulb temperature.

Since the wet bulb has wet surfaces, the water vapor pressure at the wet bulb portion 112 is interpreted as the saturated water vapor pressure at the wet bulb temperature. Therefore, the ambient water vapor pressure e is calculated using the following equation using the saturated water vapor pressure e _s ' at the wet bulb temperature.

Here, e is the water vapor pressure in the air to be obtained, e _s ' is the saturated water vapor pressure of the wet bulb temperature t _w , A is the dry-wet bulb constant, t _d is the dry bulb temperature, t _w is the wet bulb temperature and p is the air pressure.

The temperature difference between the wet and dry bulb (t _d -t _w ) and the steam pressure difference (e _s ' -e) are proportional to each other.

Here, a represents a constant with respect to the wind speed, and the saturated steam pressure e _s ' at the dry bulb temperature t _d is obtained by the saturated steam equation.

At this time, the relative humidity u (% RH) is calculated by the following equation (3).

On the other hand, the dry bulb temperature and the wet bulb temperature measured by the wet and dry ball system 110 may be displayed relative to the humidity table. In this case, however, the measurement error of humidity is very high, and power consumption is disadvantageous.

The dry bulb temperature and the wet bulb temperature respectively measured by the dry bulb 111 and the wet bulb 112 of the wet and dry sphere 110 are output from the dry and dry sphere 110 and calculated through the first and second amplifying circuits 11 and 12. Input to the circuit section 210, respectively. The calculation circuit unit 210 converts the dry bulb temperature and the wet bulb temperature measured by the wet and dry ball system 110 into humidity using Equations 1 to 3 above. Then, the converted humidity and dry bulb temperature is converted into a digital signal, and then output to the microcomputer 310 through the third amplifier circuit 13.

The microcomputer 310 stores the temperature and humidity desired by the user in advance. The microcomputer 310 receives a digital signal of temperature and humidity output from the operation circuit unit 210, and compares the temperature and humidity desired by the user with the temperature and humidity input from the operation circuit unit 210. ) Generates a control signal with information that raises or lowers the temperature and humidity of the installed site toward the operating unit 20 of the thermo-hygrostat. Then, the display unit 400 instructs the user to display the temperature and humidity desired by the user and the dry bulb temperature and humidity input from the calculation circuit unit 210 so that the user can compare the temperature and humidity.

The display unit 400 is formed of an LCD display panel. The display unit 400 receives a command of the microcomputer 310 to display a temperature and humidity desired by the user and a temperature and humidity input from the computing circuit unit 210 to the microcomputer 310. In addition, the operation unit 20 of the thermo-hygrostat (tank) receives the control signal output from the microcomputer 310 to operate so that the temperature and humidity of the site where the thermo-hygrostat (tank) is installed to the temperature and humidity desired by the user. .

On the other hand, the user sees the temperature and humidity displayed on the display unit 400, the operation unit 510 for manually controlling the thermo-hygrostat (tank) is further connected to the microcomputer 310 is installed. When a user generates a digital signal with information that increases or decreases the temperature and humidity of the site where the thermo-hygrostat is installed in the operation unit 510, the microcomputer 310 may output the digital signal generated by the operation unit 510. A second control signal for receiving the input and controlling the operation unit 20 of the thermo-hygrostat (trial) is generated toward the operation unit 20 of the thermo-hygrostat (trial).

In addition, the remote controller 600, which is connected to the microcomputer 310 and wired or wirelessly, is further installed in order to allow the user to remotely control the thermo-hygrostat. When the user generates a digital signal with information that raises or lowers the temperature and humidity of the site where the thermo-hygrostat is installed in the remote controller 600, the microcomputer 310 generates the digital signal generated by the remote controller 600. A third control signal for controlling the operation unit 20 of the thermo-hygrostat (jow) is generated by receiving the signal toward the operation unit 20 of the thermo-hygrostat (jow).

Subsequently, the operation of the controller for the thermo-hygrostat according to an example of the present invention will be summarized.

When the dry bulb temperature and the wet bulb temperature measured at the site having a constant temperature and humidity chamber (joet) are input to the calculation circuit unit 210, the calculation circuit unit 210 converts the humidity from the dry bulb temperature and the wet bulb temperature and digitally converts the dry bulb temperature and the converted humidity. The signal is converted into a signal and output toward the microcomputer 310. When the microcomputer 310 generates a control signal by comparing the temperature and humidity output from the arithmetic circuit unit 210 with the desired temperature and humidity stored in advance, the driving unit 20 of the thermo-hygrostat (jow) receives the control signal. It receives the input and operates so that the temperature and humidity of the site become the temperature and humidity that the user wants. At this time, when the user operates the operation unit 510 or the remote controller 600 to generate a digital signal, the microcomputer 310 receives the digital signal to generate a control signal, the driving unit 20 of the thermo-hygrostat ) Receives the control signal and operates so that the temperature and humidity of the site become the temperature and humidity desired by the user.

Example 2

Referring to FIG. 2, a controller for a thermo-hygrostat according to another example of the present invention includes a measuring unit, an arithmetic circuit unit 220, and a microcomputer 320 including a wet and dry sphere 110 and an electronic sensor 120 for measuring humidity. ) And a display unit 400 and an operation unit 520.

The wet and dry sphere 110 measures the temperature of the site where the thermo-hygrostat is installed, and the electronic sensor 120 measures the humidity of the site where the thermo-hygrostat is installed. Since the wet and dry sphere system 110 is the same as that described in Embodiment 1, the repeated description is omitted. The electronic sensor 120 measures the humidity of the site as a capacitive hygrometer and outputs the humidity toward the operation circuit unit 220.

The dry bulb temperature and the wet bulb temperature measured by the dry bulb unit 111 and the wet bulb unit 112 of the wet and dry bulb system 110 and the second humidity measured by the electronic sensor 120 are the first and second amplifier circuits 11 and 12, respectively. Are respectively input to the arithmetic circuit unit 220 through. The calculation circuit unit 220 converts the third humidity from the dry bulb temperature and the wet bulb temperature measured by the wet and dry ball system 110. The converted third humidity, the dry bulb temperature, and the second humidity input from the electronic sensor 120 are converted into digital signals, and then output to the microcomputer 320 through the third amplifying circuit 13.

The microcomputer 320 also stores a desired temperature and first humidity in advance, and the microcomputer 320 inputs any one selected from the second humidity and the third humidity output from the calculation circuit unit 220 and the dry bulb temperature. do. At this time, the humidity input to the microcomputer 320 is selected by the user operating the input mode button of the operation unit 520. The microcomputer 320 compares the temperature and the first humidity desired by the user with the temperature input from the operation circuit unit 220 and the second or third humidity to increase the temperature and humidity of the site where the constant temperature and humidity chamber (bath) is installed, or A control signal having a lowering information is generated toward the operation unit 20 of the thermo-hygrostat. In addition, the display unit 400 instructs the user to display the desired temperature and the first humidity and the dry bulb temperature and the second or third humidity input from the calculation circuit unit 220 so that the user can compare the temperature and the humidity. .

The operation unit 520 is connected to the microcomputer 320 and controls the thermo-hygrostat using the third humidity converted by using the temperature measured by the wet and dry ball system 110, or the electronic sensor 120. An input mode button is provided for selecting whether to control the thermo-hygrostat using the second humidity measured from the control. Therefore, when the user operates the input mode button of the operation unit 520, only the digital signal for the selected humidity is input from the operation circuit unit 220 to the microcomputer 320.

On the other hand, the operation unit 520 generates a digital signal toward the microcomputer 320 to control the thermo-hygrostat when the user manually views the temperature and humidity displayed on the display unit 400. When the operation unit 520 generates a digital signal having information for raising or lowering the temperature and humidity of the site where the thermo-hygrostat is installed by the user's operation, the microcomputer 320 generates the digital signal generated by the operation unit 320. A second control signal for receiving the input and controlling the operation unit 20 of the thermo-hygrostat (trial) is generated toward the operation unit 20 of the thermo-hygrostat (trial).

In this embodiment, the remote controller 600 is further installed as in the case of the first embodiment.

Subsequently, the operation of the controller for the thermo-hygrostat according to another example of the present invention will be summarized.

When the dry bulb temperature, the wet bulb temperature, and the humidity measured at the site where the constant temperature / humidity (jo) are input to the calculation circuit unit 220, the calculation circuit unit 220 converts the humidity from the dry bulb temperature and the wet bulb temperature, and the humidity converted to the dry bulb temperature. The humidity measured in the field is converted into a digital signal and outputted toward the microcomputer 320. When the microcomputer 320 generates a control signal by comparing any one of the humidity output from the operation circuit unit 220 and the dry bulb temperature and the pre-stored temperature and humidity, the driving unit 20 of the thermo-hygrostat Receives a control signal and operates so that the temperature and humidity of the site is the temperature and humidity desired by the user. At this time, when the user operates the operation unit 520 or the remote controller 600 to generate a digital signal, the microcomputer 320 receives the digital signal to generate a control signal, the driving unit 20 of the thermo-hygrostat ) Receives the control signal and operates so that the temperature and humidity of the site become the temperature and humidity desired by the user.

As a result of controlling the temperature and humidity of the thermo-hygrostat by using the controller according to Example 2, the error of the controlled temperature with respect to the temperature set in the thermo-hygrostat was ± 0.2 ° C, and the relative temperature set by the thermo-hygrostat The error of controlled humidity with respect to humidity was ± 0.2 Rh.

According to the controller for the thermo-hygrostat or the thermo-hygrostat according to the present invention as described above, since the temperature and humidity can be controlled by one controller, the management and installation work is easy and the cost is reduced, and the means for checking various external conditions There is provided for optimum control.

In addition, since the humidity and temperature of the field can be accurately measured using a wet or dry sphere or wet and dry gauge and an electronic sensor, it can be widely used in high-tech industries.

The present invention is not limited to the above embodiments, and it is apparent that many modifications are possible by those skilled in the art within the technical spirit of the present invention.

Claims (5)

A dry and dry bulb having a dry bulb and a wet bulb, and outputting a second temperature measured by the dry bulb and a third temperature measured by the wet bulb; An arithmetic circuit unit receiving the second and third temperatures from the wet and dry sphere system and converting the second and third temperatures into second humidity, converting the second humidity and the second temperature into digital signals and outputting the digital signals; The second temperature and the second humidity converted into the digital signal are received from the arithmetic circuit unit, and the second humidity is compared with the first humidity stored in advance, and the second temperature and the first temperature stored in advance are stored in the digital signal. Compare and generate a control signal for controlling the operating unit of the thermo-hygrostat or the thermo-hygrostat and outputs to the operating unit of the thermo-hygrostat or the thermo-hygrostat, and displays the first temperature, the second temperature, the first humidity, and the second humidity. A microcomputer that commands to do; And a controller configured to display the first temperature, the second temperature, the first humidity, and the second humidity as commanded by the microcomputer. A measuring unit comprising a dry bulb unit and a wet bulb unit having a dry and wet bulb meter which outputs a second temperature measured by the dry bulb unit and a third temperature measured by the wet bulb unit, and an electronic sensor that measures and outputs a second humidity; Receiving the second and third temperatures and the second humidity, converting the third humidity from the second and third temperatures, converting the second temperature, the second humidity, and the third humidity into a digital signal; An outputting circuit circuit; Receives any one selected from the second humidity and the third humidity converted into the digital signal from the computing circuit unit, compares the second humidity or third humidity and the first humidity stored in advance to the second humidity and the second temperature And a control signal for controlling the operating unit of the thermo-hygrostat or the thermo-hygrostat by comparing the first temperature stored in advance with the first temperature, and outputting the control signal to the operating unit of the thermo-hygrostat or the thermo-hygrostat, and calculating the first temperature and the first humidity and the operation. A microcomputer for instructing to display the temperature and humidity input from the circuit unit; An operation unit installed to be connected to the micom, the operation unit having an input mode button for instructing the micom to receive one of the second humidity and the third humidity converted into the digital signal from the computing circuit unit; And a display unit for displaying the first temperature and the first humidity and the temperature and the humidity inputted from the computing circuit unit by the command from the microcomputer. The apparatus of claim 1, further comprising an operation unit installed to be connected to the micom and outputting a second digital signal toward the micom, the second digital signal having information on the increase and decrease of temperature and humidity by a user's operation, The microcomputer receives the second digital signal from the operation unit and generates a second control signal for controlling the operation unit of the thermo-hygrostat or the thermo-hygrostat chamber. The method of claim 2, wherein the operation unit outputs a second digital signal having information on the increase and decrease of temperature and humidity by the user's operation toward the micom, the micom receives the second digital signal from the operation unit A controller for a thermo-hygrostat or a thermo-hygrostat, further comprising generating a second control signal for controlling the operating unit of the thermo-hygrostat or the thermo-hygrostat. The remote controller according to any one of claims 1 to 4, further comprising a remote controller installed at the microcomputer and a remote site and outputting a third digital signal to the microcomputer, the third digital signal having information on the increase and decrease of temperature and humidity by a user's operation. Equipped, The microcomputer receives the third digital signal from the remote controller to generate a third control signal for controlling the thermo-hygrostat and the operation unit of the thermo-hygrostat, characterized in that the thermo-hygrostat or the thermo-hygrostat controller.