JPH0126495B2 - - Google Patents

Description

[Detailed Description of the Invention] (a) Field of the Invention The present invention relates to a temperature display device equipped with a temperature detection circuit and a display circuit, and particularly to a temperature display device that is equipped with a temperature detection circuit and a display circuit, and in particular, to prevent defects such as defects in a temperature sensing element provided in the temperature detection circuit, defects in wiring, etc. The present invention relates to a temperature display device that indicates a non-energization state.

(b) Prior art and its problems In the conventional temperature display device, when this temperature display device is installed, for example, the light-emitting elements provided in the display circuit unrelated to the internal temperature of the refrigerator are turned off and the lights are displayed. When this occurs, it is not possible to distinguish whether it is due to a failure in the temperature detection circuit or the display circuit, so the wiring and elements of each circuit must be inspected individually, making inspection work extremely complicated. have

(C) Object of the Invention An object of the present invention is to display on the temperature display device whether the temperature sensing element provided in the temperature display device is not energized, and to simplify inspection work.

(d) Key Points of the Invention A temperature display device comprising a temperature detection circuit and a display circuit, which indicates that a temperature sensing element provided in the temperature detection circuit is not energized by blinking a light emitting element provided in the display circuit. It is.

(e) Examples of the invention FIGS. 1 and 2 show an embodiment of the present invention.

Reference numerals 1 and 2 denote first and second busbars connected to first and second power supply terminals A and B, respectively, and a DC voltage is supplied between the respective power supply terminals A and B. The temperature display device shown as an embodiment of the present invention includes a temperature detection circuit 3 connected between the first and second bus bars 1 and 2.
, a display circuit 4, and an oscillation circuit 5. The temperature detection circuit 3 includes a temperature sensing element S having a negative characteristic, such as a thermistor, and a first diode 6.
The temperature sensing element S and the first A series circuit of a diode 6 and a first resistor 7 is connected, and the cathode side of the first diode 6 is connected to the + side input terminal of the amplifier 11. The temperature sensing element S, the first diode 6, the first to third
Resistors 7, 8, and 9 constitute a bridge circuit. Further, the midpoint of the series circuit of the third and fourth resistors 8 and 9 connected between the first and second bus bars 1 and 2 is connected to the (-) side input terminal of the amplifier 11 and is connected to the negative feedback terminal. It is connected to the output terminal of an amplifier 11 via a fourth resistor 10 forming a ring circuit. Further, the display circuit 4 includes first...fifth PNP transistors (hereinafter referred to as Tr) 12...16, and the respective
First...fifth light emitting elements _D1 ..., such as light emitting diodes, are connected between the emitter and collector of the Tr.
_D5 , the fifth to ninth resistors 17...21 for current limiting connected to the bases of the respective transistors, and the constant voltage characteristic resistors 17...21 connected between the respective resistors 17...21 and the amplifier 11. The circuit includes a series circuit of a second diode 22 and a Zener diode 23, and a constant current circuit 24 connected between the emitter of the first Tr 12 and the first bus 1 and made of a FET (field effect transistor). The first...fifth Tr12...1
The emitter and collector of No. 6 is such that the collector of the first Tr12 is connected to the emitter of the second Tr13,
The collector of the second Tr13 is connected to the emitter of the third Tr14.
The emitters and collectors of the fifth Tr 14, 15, and 16 are connected in series, and the collector of the fifth Tr 16 is connected to the second bus bar. Note that the second diode 22 is connected with the forward direction pointing toward the output terminal of the amplifier 11.

The oscillation circuit 5 includes a first inverter 25 to which power is supplied from the first bus 1 and a second inverter 26 to which power is supplied from the second bus 2.
, tenth and eleventh resistors 27 and 28, and a capacitor C. The connection point 29 is connected to the input terminal of the first inverter 25 via the tenth resistor 27, and the eleventh resistor 28 is connected to the input terminal of the first inverter 25. through the first inverter 2
5 and the input terminal of the second inverter 26, and is connected to the output terminal of the second inverter 26 via a capacitor C. Note that the connection point 29 is connected to the midpoint between the temperature sensing element S and the anode of the first diode 6 by a first wiring F that becomes a bias circuit via a fourth diode 30 whose direction is the forward direction of the contact 29. has been done. Further, the output terminal of the second inverter 26 is connected to the fifth to ninth resistors 17 to 21 by the second wiring G via the fifth diode 31 whose forward direction is toward the output terminal. There is.

The operation of the above circuit will be explained below. When the temperature sensing element S is energized and in use, and its temperature is within the detection range, the anode voltage of the first diode 6 is high, and the potential of the connection point 29 of the oscillation circuit 5 is high. Since the oscillation circuit 5 does not oscillate and the fifth diode 31 is fixed in a reverse bias state, the first... ...The fifth light emitting elements _D1 ... _D5 are turned on and off to display a temperature based on the temperature of the temperature sensing element S.

Hereinafter, the circuit operation based on the temperature of the temperature sensing element S will be explained. First, when the temperature sensing element S is at a low temperature, the fifth light emitting element
When only D ₅ is lit, as the resistance value of the temperature sensing element gradually decreases due to the rise in temperature, the voltage at the (+) side input terminal of the amplifier 11 increases, and the voltage at the (-) side input terminal increases. The potential difference between the output voltage and the output voltage increases, and the output voltage increases. As the output voltage increases, the first...
The base voltage of the fourth Tr12...15 also gradually increases, and the fourth Tr15 to the first Tr12 are turned off, and the fourth light emitting element _D4 is turned on to the first light emitting element _D1 to display the temperature. I do. moreover,
As the temperature of the temperature sensing element S gradually decreases, the resistance value of the temperature sensing element S gradually increases, the voltage at the (+) side input terminal of the amplifier 11 decreases, and the output voltage decreases. As the output voltage decreases, the first...fifth
The base voltages of the Tr12...16 gradually decrease, and the first Tr12 is turned on sequentially. When the first Tr12 is turned on, the anode and cathode are short-circuited, so the first light emitting element D ₁ turns off, and the second light emitting element D1 turns off.
D ₂ also goes out, and the temperature is displayed as shown in FIG. 2A, and the third and fourth light emitting elements D ₃ and D ₄ also go out in sequence as the temperature decreases. In addition, it is assumed that the light emitting elements shaded with diagonal lines in FIG. 2 are lit.

Here, the forward voltages of the second diode 22 and the Zener diode 23 are respectively V ₁ and V ₂ ,
If the voltage at the midpoint H between the ninth resistor 17 and the fifth diode 31 is V ₃ , then when viewed from the output terminal of the amplifier 11, V ₃ =V ₁ +V ₂ . Also, the fifth Tr1
The emitter voltage of 6 is equal to the forward voltage of the fifth light emitting element _D5 , and this emitter voltage becomes the lighting voltage of the fifth light emitting element _D5 , and this lighting voltage is _V4 ,
If the voltage between the base and emitter, which is the ON condition for the fifth transistor 16, is _V5 , then _V3 + _V5 > _V4
Since the conditions are satisfied, the fifth Tr16 is not turned on, the temperature of the temperature sensing element S decreases, and the amplifier
Even if the output voltage of D is zero, since V ₃ exists, the fifth light emitting element D ₅ continues to light up as shown in FIG. 2B.
Note that since the gate and source of the constant current circuit 24 are short-circuited, the first...fifth light emitting elements _D1 ...
Regardless of the number of _D5 lights, a constant current is always supplied to the light emitting elements that are lit, and the brightness of the light emitting elements is kept constant.

When the display circuit 4 is displaying the temperature, if the temperature sensing element S is disconnected due to a poor connection, the first diode 6 becomes reverse biased, and the anode side of the first diode 6 becomes zero voltage. . Then, the voltage at the connection point 29 of the oscillation circuit 5 also decreases because the bias from the fourth diode 30 disappears, and the oscillation circuit 5 first changes the input voltage of the first inverter 25 to the tenth voltage due to the voltage drop at the connection point 29. It is pulled down through the resistor 27 to the connection point 29, so that the output of the first inverter 25 becomes "H".
(get high) Therefore the second inverter 26
Since the input of the second inverter 26 also becomes "H", the output of the second inverter 26 becomes "L" (low), and the capacitor C is connected from the connection point 29 to the second inverter via the eleventh resistor 28.
is charged toward the output of the inverter 26, the voltage at the connection point 29 gradually increases, and the voltage at the tenth resistor 27 increases.
The input of the first inverter 25 is "H" through
The output becomes "L". At the same time, the second
The input of the second inverter 26 also becomes "L", its output becomes "H", and the capacitor C is charged from the output side of the second inverter 26 toward the connection point 29, and the voltage at the connection point 29 gradually decreases. At the same time, the input voltage of the first inverter 25 also decreases, and its output becomes "H" again, and thereafter the oscillation circuit 5 continues to oscillate in the same manner.

Due to the oscillation operation of the oscillation circuit 5, the cathode side of the fifth diode 31 repeats "H" and "L",
First, when the voltage is "H", the temperature sensing element S is disconnected and the output of the amplifier 11 is zero, so the voltage at the midpoint H is approximately
V is low at ₃ , the first...fourth Tr12...15 remain on, only the fifth Tr16 is off, and the first...
The fourth light emitting elements _D1 ... _D4 do not light up, and only the fifth light emitting element _D5 lights up. Next, when it is "L",
The base current of the first...fifth Tr12...16 is the fifth
...9th resistor 17...21, Zener diode 2
3, the current flows through the second diode 22 and the fifth diode 31, and each Tr is on, and the first...fifth light emitting elements _D1 ... _D5 do not light up, so the first...
The fourth Tr12...15 remains on regardless of the oscillation operation of the oscillation circuit 5, and the first...fourth light emitting elements
_D1 ... _D4 do not light up, and only the fifth light emitting element _D5 blinks as shown in FIG. 2C. Therefore, disconnection of the temperature sensing element S or disconnection of the wiring connecting the temperature sensing element S,
A connection failure can be indicated by the blinking of the fifth light emitting element _D5 , and can be distinguished from an abnormality in temperature display due to a failure in other parts, such as the display circuit 4,
It is possible to extremely simplify the inspection work for the failure location. Furthermore, as described above, since only one light emitting element blinks to indicate an abnormality, the display also has the effect of not giving an excessive impression to the customer.

(F) Other Examples In the above example, when the temperature sensing element is not energized, 1
Although a temperature display device in which only one light emitting element blinks has been described, a temperature display device in which a plurality of light emitting elements blink when the temperature sensing element is not energized will be described below based on FIG. Components having the same reference numerals as in the previous embodiment are the same, and detailed explanations of similar components will be omitted.

The output terminal of the second inverter 26 is connected to the (+) side of the amplifier 11 by a wiring K through a series circuit of a variable resistor 32 and a sixth diode 33 whose forward direction is the (+) side input terminal direction of the amplifier 11. A series circuit of a third inverter 34 and a seventh diode 35 is connected to the input terminal, and is connected between the anode of the fourth diode 30 and the midpoint E of the sixth diode 33 and the variable resistor 32. has been done. still,
The third inverter 34 is connected from the anode of the fourth diode 30 toward the midpoint E, and the seventh diode 35 is connected with the direction of the third inverter 34 as the forward direction.

The operation of the temperature display device will be explained below. First, when the temperature sensing element S is energized, the input of the third inverter 34 is "H", so
The output is "L", the output "H" of the second inverter 26 is drawn to the output "L" via the seventh diode 35, and the sixth diode 33 is in a reverse bias state. Therefore, similarly to the embodiment described above, temperature display is performed by lighting the first to fifth light emitting elements D ₁ to D ₅ .

Next, when the temperature sensing element S becomes de-energized due to a poor connection, for example, the first diode 6 becomes reverse biased, and its anode side becomes zero voltage, as in the previous embodiment. Then, the voltage at the connection point 29 of the oscillation circuit 5 decreases via the fourth diode 30,
The oscillation circuit 5 starts oscillating as in the previous embodiment. Due to the oscillation operation of the oscillation circuit 5, the cathode side of the fifth diode 31 repeats "H" and "L". First, when the cathode side of the fifth diode 31 is "H", the (+) side input terminal of the amplifier 11 becomes "H" via the variable resistor 32 and the sixth diode 33, and at the same time, the output is becomes "H",
The base current of the first...fifth Tr12...16 is limited, each Tr is turned off, and the first...fifth light emitting element _D1
… _D5 lights up. Next, when the cathode side of the fifth diode 31 is "L", the fifth diode 3
1. The base current of the first...fifth Tr12...16 flows through the second diode 22 and the Zener diode 23, and each Tr is turned on and the first...fifth Tr is turned on.
The light emitting elements D ₁ ...D ₅ turn off. Thereafter, as the cathode side of the fifth diode 31 repeats "H" and "L", the first...fifth light emitting elements _D1 ... _D5
continues to blink.

When the resistance value of the variable resistor 32 is gradually increased during the blinking, the (+) side input voltage of the amplifier 11 gradually decreases, and the output voltage also decreases accordingly.
Light emitting element D ₁ gradually stops blinking, and the number of blinking light emitting elements decreases. Contrary to the above, if the resistance value of the variable resistor 32 is gradually decreased, the amplifier 1
The (+) side input voltage of D1 gradually increases, the output voltage also increases accordingly, and the number of blinking light emitting elements gradually increases until the first light emitting element _D1 blinks.

Therefore, when a disconnection of the temperature sensing element S or a disconnection of the wiring connecting the temperature sensing element S or a disconnection due to a poor connection is detected, the blinking of a plurality of light emitting elements among the first to fifth light emitting elements D ₁ to D ₅ is detected. This can be distinguished from an abnormal temperature display caused by a failure in other parts, for example, the display circuit 4, and the inspection work for the temperature detection circuit 3 and display circuit 4 can be extremely simplified. In addition, as mentioned above, when the temperature sensing element S is not energized,
By adjusting the variable resistor 32 in advance, it is possible to blink a desired number of light emitting elements, and it is possible to reliably notify that the temperature sensing element is not energized.

(e) Effects of the invention For example, without installing a new display device using a light emitting element in the temperature display device, the blinking of the light emitting element used in the temperature display device can prevent disconnection of the temperature sensing element, poor connection, etc. Since energization can be displayed, component costs can be kept low, and it can be distinguished from failures in the display circuit, etc., and inspection work for the temperature detection circuit and the display circuit can be extremely simplified.

[Brief explanation of drawings]

FIG. 1 is an electric circuit diagram showing one embodiment of the present invention, FIG. 2 is a lighting state diagram of a light emitting element, and FIG. 3 is an electric circuit diagram showing another embodiment. 3...Temperature detection circuit, 4...Display circuit, 5...
Oscillation circuit, S... Temperature sensing element, 11... Operational amplifier, 12 to 16... First... Fifth transistor,
_D1 to _D5 ...first...fifth light emitting elements, 32...variable resistor.

Claims (1)

[Scope of Claims] 1. A bridge circuit equipped with a temperature sensing element and a diode for detecting disconnection on one side, a temperature detection circuit equipped with an operational amplifier whose input is the output of this bridge circuit, and a temperature detection circuit that is connected in parallel with each other and that A display circuit including a plurality of transistors whose bases are connected to an output terminal of an operational amplifier, a plurality of light emitting elements each connected between the collector and emitter of the transistors, and first and second inverters connected in series. ,
Consisting of a resistor connected between the input and output terminals of the second inverter of both inverters, a time constant circuit of a capacitor, and a bias circuit connected between the temperature sensing element, the diode and the time constant circuit, A temperature display device comprising: an oscillation circuit that provides an output to blink at least one of the light emitting elements when the temperature sensing element is not energized. 2. The temperature display device according to claim 1, wherein the oscillation circuit is connected to the temperature detection circuit via a variable resistor that controls the number of blinking light emitting elements.