KR920000287Y1 - Trmperature control circuit for medical cooler - Google Patents

Abstract

No content.

Description

Temperature power supply monitoring circuit of medical refrigerator

The accompanying drawings are circuit diagrams of the subject innovation.

* Explanation of symbols for the main parts of the drawings

10: A / D converter 20,30: de-litch

40: Roman 50: D-FF

60: counter 70: timer IC

80: TR-array 90: 7-segment

A: current source circuit B: temperature sensing and comparison circuit

C: negative power generation unit D: signal generation unit in case of power failure

Q ₁ -Q ₇ : Transistor R ₁ -R ₂₄ : Resistor

IC ₁ -lC ₃ : OP Amp C _l -C ₇ : Capacitor

D _l -D ₅ : Diode S: Time Selector

The present invention relates to a temperature power supply monitoring circuit of a medical refrigerator. In particular, when the temperature in the refrigerator falls below the set value (1 ℃ -6 "℃) temperature or rises above the set temperature, the digital display is detected and displayed. At the same time it was to inform the buzzer.

In general, vaccines and blood are stored in a medical refrigerator and stored within a certain temperature range.However, if the temperature goes below the set value or rises above the set value due to an abnormality in the refrigerator, it can be detected even when the temperature of the refrigerator rises during a power failure. There was a problem that these vaccines or blood is easy to be damaged because there is no device.

The present invention has been made in view of the above-mentioned problems, and it is possible to repeatedly detect and display the digital and buzzer when the temperature in the refrigerator changes above or below a set value. The explanation is as follows.

The present invention constitutes a current source circuit (A) for converting a voltage into a current by using an OP amplifier (IC ₁ ), a variable resistor (VR ₁ ) and a resistor (R ₁ -R ₅ ), and the output stage thereof is connected to a dummyster (TH) and an OP. The temperature sensing and comparing circuit (B) is connected to one end of the dummyster (TH) of the temperature sensing and comparing circuit (B) consisting of an amplifier (IC ₂ ) and a variable resistor (VR ₂ ) and a resistor (R ₆ -R ₁₀ ). ) and the resistor (R ₁₁ -R ₁₄ OP amplifiers (IC ₂₎ to the output terminal OP amplifiers (IC ₃₎₎ and the diode (D ₁₎ (D ₂₎ and the capacitor (C ₁₎ (the negative-positive power supply to C ₂₎ The generator C is connected to the A / D converter 10 to which the generator C is connected.

In addition, the output terminals O ₀ -O ₃ of the A / D converter 10 are connected to the address terminals A ₀ -A ₁₂ of the ROM 40 via the de-latch 20, 30. The data bus terminals D ₀ -D ₇ of the ROM 40 are connected to the 7-segment 90 via the TR-array 80 so that " Lo " when the temperature falls below the set value, " Lo " Hi "and" AC "at power failure.

In addition, among the terminals DS ₁ -DS ₃ of the A / D converter 10 for specifying the digit of the 7-segment 90, DS ₁ is a clock terminal of the D-FF 50 and a terminal of the timer IC 70. commonly connected to, and, DS ₂ is di-common to one input terminal of the latch 30, the clock end transistor of NOR gate (N ₄₎ connected to only the base and the output of the (Q ₁₎ is in the enable terminal of the ROM 40 of the DS ₃ is commonly connected to the clock terminal of the latch 20 and the base of transistor Q ₂ and the other input terminal of NOR gate N ₄ .

In the above, the emitters of transistors Q ₁ and Q ₂ are connected to one digit of 7-segment 90 and one digit below the decibel point, respectively.

On the other hand, the data bus terminal D ₇ of the ROM 40 is connected to the base of the transistor Q ₃ connected to the decibel point of the 7-segment 90 by the collector and the input terminal of the D-FF 50. Is connected to the clock terminal of the D-FF 50 in common to the emitter of the transistor Q ₂ , and the output terminal O ₃ of the A / D converter 10 is connected to the D-FF 50. Connect to the input terminal of.

In addition, the output terminal of the D-FF 50 ( ) Is connected to the address terminal A ₈ of the ROM 40, the output terminal Q is connected to the input terminal of the timer IC 70, and the output terminal is connected to the reset terminal of the binary up counter 60. N ₃ ) to one input terminal.

The DU and Eoc terminals of the A / D converter 10 are connected to the input terminal E of the counter 60, the address terminal A ₁₂ of the ROM 40 is connected to the output terminal, and the resistor R _22), but connected to the base of the diode (D ₅₎ to the collector resistor (R ₂₃ through) and a buzzer (BZ) is a transistor (Q ₇₎ connected to the contact point of the resistors (R ₂₂₎ and a diode (D ₅₎ It is connected to the terminal of the timer IC 70 via the diode D ₄ .

The timer IC 70 is connected with a time selector S of 80 minutes and 5 minutes.

In addition, the signal generator D is connected to the clock and reset terminals of the counter 60 in order to generate a signal during a power failure. The signal generator includes a normal AC power supply such as a transformer (T), a bridge diode (BD), and a regulator. It is configured to be applied to the transistors Q ₄ -Q ₆ and the noah gate N ₁ (N ₂ ) via RE.

In the drawings, BT is a battery test terminal, BA is a battery, C ₄ -C ₇ is a capacitor, ZD is a Zener diode R ₁₅ -R ₂₁ is a resistor, and Vcc is a DC power supply.

According to the present invention configured as described above, when the temperature in the refrigerator falls below the set temperature, the resistance of the dummy amplifier TH having the negative polarity becomes large, so that the output terminal of the OP amplifier IC ₂ is within the output range of 0-5V. A high level close to 5V is output and input to the A / D converter 10. At this time, the voltage is converted into a current source through the current source circuit A, so that the ratio of one side of the dummy amplifier TH to the OP amplifier IC ₂ is increased. Commonly applied to the inverting terminal (+), generated in the pulse generator consisting of the OP amplifier (IC ₃ ), the capacitor (C ₃ ) and the resistors (R _11- R ₁₄ ) which are opened through the negative electrostatic source generator (C) The A / D converter 10 is always applied to the A / D converter 10 because the pulse is applied to the A / D converter 10 while being a constant negative power supply through the capacitor C ₁ (C ₂ ) and the diode D ₁ (D ₂ ). Stable operation

Therefore, A / D converter 10, the output terminal (O ₀ -O ₃₎ is converted into a digital output through D-through latch 20, 30 is an address terminal of the ROM (40), (A ₁₂ -A _O ), Data corresponding to the value is output through the data bus terminals D ₀ -D ₇ and then displayed on the 7-segment 90 via the TR-array 80.

At this time, the DS ₃ output of the A / D converter 10 turns on the transistor Q ₂ and applies a clock to the D-FF 50 to designate the number of digits below the decibel point of the 7-segment 90. When there is an output from the data bus terminal D ₇ of the ROM 40, the transistor Q ₃ is turned on to designate the decibel point of the 7-segment 90 to the output terminal Q of the D-FF 50. The high level is output to operate the timer IC 70 and at the same time reset the counter 60 through the NOR gate N ₃ .

In addition, the DU and Eoc signals of the A / D converter 10 are inputted to the E terminal of the counter 60, and the timer IC 70 outputs high and low levels at the interval of 0.5 seconds from the counter 60. When in operation, the transistor (Q ₇ ) is turned on via the resistor (R ₂₂ ) and diode (D ₅ ) so the buzzer (BZ) will cry at 0.5 second intervals, while the timer (70) will not operate when the counter (60) ) Is grounded through resistor R ₂₂ and diode D ₄ , so transistor Q ₇ is turned off so that buzzer BZ does not cry at this time.

In other words, when the temperature in the refrigerator drops below the set temperature, the address is assigned to the ROM 40, and then the value of " Lo " is set to 7-segment 90 at intervals of 5 seconds through the data bus and the TR-array 80. The buzzer sounds as the temperature drops repeatedly.

Here, the reason why the time selector (S) of 80 minutes and 5 minutes is set is that, for example, 80 minutes is set to operate for about 3 hours when the refrigerator is operated for the first time. The error during this time is not a big problem. The timer does not start even if an error occurs for 80 minutes, that is, 1 hour and 30 minutes, so that the buzzer (BZ) does not ring unnecessarily.

In other words, if the time selector (S) is placed in the 5 minute state, the timer will not operate for 5 minutes, contrary to the normal state of operation of the timer, and the timer will run for 5 minutes at the end of 5 minutes, causing the buzzer (BZ) to sound when an error occurs. After this period of operation (5 minutes), it will resume standby.

In addition, if the time selector S is placed in the 80-minute state, the motor is stopped for 80 minutes and then operated from the end of the 80-minute period. Thus, a signal is input during the 80 minutes in which the timer is stopped.

On the other hand, as described above, when the temperature in the refrigerator rises above the set temperature, the resistance of the dummyster TH decreases, so a level close to 0V is output to the output terminal of the OP amplifier IC ₂ within a range of 0-5V. After the input to the A / D converter 10, the buzzer (BZ) is sounded at the same time as the 7-segment 90 displays "Hi" and the temperature higher than the set value repeatedly. The user can know the abnormal condition of the refrigerator temperature.

In addition, when an error message occurs from the data bus terminal D ₇ of the ROM 40, this high level is input to the terminal of the D-FF 50, and the high-level output of the D-FF 50 is noar gate N _3. It is converted to the low level through the) to release the reset state of the counter (60).

Therefore, high and low levels are output from the counter 60 at 0.5 second intervals to cause the buzzer BZ to sound at 0.5 second intervals, and at the same time the high level is input to the address terminal A ₁₂ of the ROM 40. In the 7-segment 90, "Er" is displayed for 0.5 seconds, and then 0.5 seconds and then "Hi" is displayed for 0.5 seconds and the buzzer (BZ) sounds at 0.5 second intervals. .

On the other hand, in the steady state between 1 ° C. and 6 ° C., the AC power source turns on the transistors Q _{4 to} Q ₆ through the transformer T, the bridge diode BD, the regulator RE, and so on. ₁₎ is applied at a low level at one side of the counter 60, but to remain in a reset state, a transistor (Q by the battery (BA) during a power outage ₄₎ (Q ₆₎ transistors (Q ₅ at the same time off as soon) Is turned on, and a high level is applied to one side of the noah gate N ₁ , so that the reset of the counter 60 is canceled and a clock is applied to the counter 60 to start counting. Accordingly, the output of the counter 60 The buzzer BZ is operated by turning on the transistor Q ₇ , and the timer IC 70 is in a standby state.

At the same time, it can be seen that the address designated at the time of power failure from the ROM 40 displays "AC" at the interval of 0.5 seconds in the 7-segment 90 through the data bus and the TR-array 80.

As described above, the present invention displays the temperature at the same time while the temperature of the medical refrigerator changes below or above a set value or displays each state such as "Hi", "Lo", or "AC" for 0.5 second at the time of power failure. Since the buzzer (BZ) is crying, the user can grasp the abnormal state of the refrigerator temperature in advance.

Claims (1)

The de-latch 20 (at the output terminal O ₀ -O ₃ ) of the A / D converter 10 to which the current source circuit A, the temperature sensing and comparison circuit B, and the negative electrostatic source generator C are connected. 30), the ROM 40, the TR-array 80 and the 7-segment 90 are sequentially connected, and the D-FF 50 and counter between the A / D converter 10 and the ROM 40. The output terminal Q of the D-FF 50 to the input terminal of the timer IC 70, and the output terminal to the address terminal A ₈ of the ROM 40, and the counter 60 Output of () ) Is connected to the address terminal A ₁₂ of the transistor Q ₇ and the ROM 40 to which the buzzer is connected, and the signal generator D at the time of power failure is common to the clock terminal and the reset terminal of the counter 60. A temperature power supply monitoring circuit for a medical refrigerator characterized in that the display and the buzzer (BZ) ring at predetermined time intervals when the temperature inside the refrigerator is out of the set value by connecting.