KR970001083Y1 - Control device for calorimeter - Google Patents

Abstract

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Description

Calorimeter calculation control device

1 is a block diagram of an operation control device of a calorimeter according to the present invention.

2 is a circuit diagram of the embodiment of FIG.

3 is a signal waveform diagram shown in each part of the present invention (a) to (g).

(A) and (b) are input and output truth tables of the flip-flop and multiplexer of FIG.

* Explanation of symbols for main parts of the drawings

1: supply side temperature sensing part 2: reflux side temperature sensing part

3: battery voltage detection unit 4: switching unit

5 amplification unit 6 central processing unit

7: digital / analog converter 8: flow detector

9: Accumulated flow rate and temperature check unit 10: Display unit

The present invention relates to a computational control device in a calorimeter, and in particular, a calorimeter arithmetic control device that can display flow rate, input / output calories, and whether or not a battery is consumed, and at the same time prevent backflow. It is about.

The conventional calorimeter employs a counter method based on a digital signal, but this causes not only malfunction of the instrument by foreign substances but also various display functions cannot be displayed.

Therefore, the present invention has been devised to solve the conventional problems as described above, the purpose of which is to turn on the reed switch by a magnetic meter (on) to check the accumulated flow rate and the temperature of the supply side and the reflux side, the supply side temperature Is high and the discharge temperature is low, it is regarded as a normal state, and when the supply temperature is low and the discharge temperature is high, it is regarded as a reverse flow to prevent backflow, and by adopting an auxiliary battery, existing data can be exchanged. SUMMARY OF THE INVENTION An object of the present invention is to provide a calorimeter arithmetic and control device having various display functions capable of saving and checking battery consumption.

Hereinafter, with reference to the accompanying drawings will be described in detail the operation control device of the calorimeter of the present invention.

1 is a block diagram of a calculation and control device of the calorimeter of the present invention, the supply side temperature sensing unit 1 for sensing the supply side temperature, the reflux side temperature sensing unit 2 for sensing the reflux side temperature, and the battery voltage for detecting the Switching switching between the battery voltage sensing unit 3, the temperature sensed by the supply side temperature sensing unit 1, the temperature sensed by the reflux side temperature sensing unit 2 and the voltage signal sensed by the battery voltage sensing unit 3 A switching unit 4 for outputting, an amplifying unit 5 for amplifying a signal switched and output by the switching unit 4 by a predetermined magnitude, an output signal of the digital / analog converting unit and the amplifying unit 5 A central processing unit 6 for comparing the output signals and converting them into calories and then integrating them and outputting them to the display unit, a digital / analog converting unit 7 for converting a digital signal into an analog signal, and a flow rate detecting unit for detecting the flow rate (8) And the product which confirms accumulated flow rate and temperature An oil flow rate and temperature checking unit 9 and a display unit 10 for displaying an integrated calorific value output from the central processing unit 6 are provided.

The operation of the operation control apparatus of the calorimeter of the present invention configured as described above will be described with reference to FIG.

The present invention detects the input / output temperature of the flow rate through the supply side temperature sensing section 1 and the reflux side temperature sensing section 2 when the flow rate signal is detected through the flow rate sensing section 8 and through the battery voltage sensing section 3. Senses the voltage of the battery.

Then, the central processing unit 6 converts the sensed supply-side and reflux-side temperatures of the flow rate into calories, and the display unit 10 determines whether the display unit 10 is in a normal state, a reverse flow state, or a state in which the battery voltage is consumed a lot. Will be displayed.

First, when a flow rate signal is detected through the flow rate detection pressure sensor of the flow rate detection section 8, the output of the inverter U7A becomes a high state by the detected signal to the clock terminal CLK of the flip-flop U2A. Is entered.

Next, a low signal is output from the inverting output terminal Q of the flip-flop U2A.

As a result, the output of the NAND gate U7C becomes high, and then the output INT of the inverter U7D becomes low as shown in FIG.

When the signal detecting the flow rate from the above process is input to the central processing unit 6 as a low signal, the cob side temperature reduction part 1 and the reflux side temperature reduction part 2 detect the supply side temperature and the reflux side temperature of the flow rate, respectively. Done.

Accordingly, the temperature sensed by the supply side temperature sensing section 1 and the reflux side temperature sensing section 2 is switched by the multiplexer U6 of the perfect nut 4 to compare the signal of the CPU 6 of the central processing unit 6. Is entered.

That is, as the low signal output from the flow rate detection unit 8 and the high signal output from the power supply output terminal PWR are input to the input terminals A and B of the multiplexer U6 of the switching unit 4, the supply side sense is reduced. The temperature sensed by the on part 1 and the reflux side temperature sensing part 2 is switched by a signal input to the input terminals A and B and output through the output terminal X of the multiplexer U6.

Then, it is amplified by the comparison amplifier U8A of the switching section 4, and then amplified again through the amplifying element of the amplifying section 5, and then input to the signal comparison terminal COMP of the central processing unit 6. Will be.

In such a state, the central processing unit 6 sets the output signal of the inverted output terminal Q of the flip-flop U2A as the high signal by the reset signal of the sensor reset terminal SENRES, and sets the power output terminal PWR. After the low state, the voltage value of the flow temperature of the supply-side temperature sensing section 1 and the reflux-side temperature sensing section 2 inputted through the signal comparison terminal COMP is compared with the reference input voltage VREF to compare the reference input voltage ( VREF) or more, the detected flow rate temperature is converted into calories and integrated.

Then, the accumulated calorific value is displayed through the display unit 10.

At this time, if the voltage value of the flow temperature sensed by the supply side temperature sensing unit 1 and the reflux side temperature sensing unit 2 is greater than or equal to the reference input voltage VREF, the output is output through the display unit 10 in a normal state, while the reference input voltage ( VREF) or less A display such as is output through the display unit 10 to indicate that the abnormal state.

On the other hand, when the reed switch SW1 is detected to be in an on state by the magnet meter reading in the integrated flow rate and temperature check unit 9, the signal of the inverted output terminal Q of the flip-flop U2B is turned low. The integrated flow rate and temperature checking unit 9 outputs a low signal to the central processing unit 6.

Accordingly, the supply side temperature sensing section 1 and the reflux side temperature sensing section 2 detect the supply side temperature and the reflux side temperature of the flow rate, respectively.

Then, the CPU 6 converts the integrated flow corresponding signal of the low signal inputted from the integrated flow rate and temperature confirming unit 9 and the high signal outputted through the power output terminal PWR to the switching unit 4. Output to the input terminals A and B of the multiplexer U6.

Accordingly, the temperature sensed by the supply side temperature sensing section 1 and the reflux side temperature sensing section 2 is switched by the signals input to the input terminals A and B and is output through the output terminal X of the multiplexer U6. Is output.

Then, it is amplified by the comparison amplifier U8A of the switching unit 4, and then amplified again through the amplifying element of the amplifying unit 5 and then input to the signal comparison terminal COMP of the central processing unit 6. .

In such a state, the central processing unit 6 sets the output signal of the inverted output terminal Q of the flip-flop U2A as the high signal by the reset signal of the switch reset terminal SWIRES, and sets the power output terminal PWR. After the low state, the voltage value of the flow temperature of the supply-side temperature sensing unit 1 and the reflux-side temperature sensing unit 2 inputted through the signal comparison terminal COMP is compared with the reference input voltage VREF to compare the reference input voltage ( VREF) or more, the detected flow rate temperature is converted into calories and integrated.

Then, the accumulated calorific value is displayed through the display unit 10.

In this case, when the voltage value of the flow temperature detected by the supply side temperature sensing unit 1 and the reflux side temperature sensing unit 2 is equal to or greater than the reference input voltage VREF, the output is output through the display unit 10 in a normal state, while the reference input voltage Below (VREF) A display such as is output through the display unit 10 to indicate that the abnormal state.

When detecting the flow rate, the accumulated flow rate, and the temperature sensing unit at the same time, the signal of the inverted output terminal Q of the flip-flop U2A of the flow rate detecting unit 8 and the integrated switch and the reed switch of the temperature confirming unit 9 ( From the signal of SW1), the signal is preferentially processed by the minute time difference.

The input and output signal waveforms of the power output terminal PWR and the multiplexer U6 shown in the above description are as shown in Figs. 3A to 3G.

As described above, according to the present invention, the present invention can check the flow rate and supply side and the reflux side temperature of the magnetic meter in the calorimeter, display the input / output calories and the consumption of batteries, and prevent the backflow phenomenon. Not only does it improve the performance of the calorimeter, but it also has the effect of preserving existing data when replacing the main battery by adopting an auxiliary battery.

Claims (1)

In the supply side temperature sensing unit 1 for sensing the supply side temperature, the reflux side temperature sensing unit 2 for sensing the reflux side temperature, the battery voltage sensing unit 3 for detecting the battery voltage, and the supply side temperature sensing unit 1 A switching unit 4 for switching and outputting the sensed temperature, the temperature sensed by the reflux side temperature sensing unit 2 and the voltage signal sensed by the battery voltage sensing unit 3, and the switching unit 4 by Comparing the output signal of the amplifying unit 5 and the digital / analog converter and the output signal of the amplifying unit 5 to amplify the signal to be converted and output by a predetermined size converted into calories, and then add it to the display unit A central processing unit (6), a digital / analog converting unit (7) for converting a digital signal into an analog signal, a flow rate detecting unit (8) for detecting a flow rate, and a flow rate for checking the integrated flow rate and temperature by a magnetic meter reading Acid flow rate and temperature check unit (9) and the central processing unit And a display unit (10) for displaying the integrated calorific value outputted from (6).