JPS5928632A - Temperature display device - Google Patents

Abstract

PURPOSE:To display the non-conduction of a temp. sensitive element and to simplify an inspection operation, by flickering at least one of light emitting elements when the temp. sensitive element is non-conducting. CONSTITUTION:When a temp. sensitive element S is disconnected, a diode 6 is reverse biased and the voltage at a connecting point 29 of an oscillation circuit 5 decreases as well, resulting in a decrease in the input voltage of an inverter 25. Then the output of an inverter 26 goes to an L and a capacitor C is charged; the voltage at the connecting point 29 increases gradually, and the input of the inverter 25 goes to an H so that the circuit 5 continues oscillation. The cathode side of a diode 31 repeats an H and an L, and when said side is the H, the output of an amplifier 11 is zero; therefore, only a TR 16 turns off and only the light emitting element D5 is lighted. When said side is the L, the base currents of TRs 12-16 flow, and all TRs are on, thus prohibiting lighting of light emitting elements D1-D5. The disconnection of the element S is displayed by flickering of the element D5.

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 a 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 all 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

(/→ Purpose of the Invention The purpose 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.

B) 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. be.

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

(1) and (2) are the first and second busbars connected to the first and second power terminals (A) and (B), respectively.
) and (B), a DC voltage is supplied between them. The temperature display device shown as an embodiment of the present invention has the first and second busbars (
It consists of a temperature detection circuit (3) connected between 1) and (2), a display circuit (4), and an oscillation circuit (5). The temperature detection circuit (3) includes a temperature-sensitive element (S) having a negative characteristic, such as a thermistor, a first diode (6), and a first...
・The 47th resistor (7) (s+f9) (Iω) and an operational amplifier (hereinafter referred to as amplifier) (11), the first
, the bus line (1) of the rabbit 72 (between 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 (-1-1 side input terminal of the amplifier 01). Also, a third busbar connected between the first and second busbars (1) and (2),
The midpoint of the series circuit of the fourth resistors (8) and (9) is the amplifier θ1
) is connected to the output terminal of the amplifier θ1) via the fourth resistor connected to the → side input terminal and forming a negative feedback circuit. Further, the display circuit (4) is a first...
・The 50th PNT' type transistor (hereinafter referred to as 1"r) (1... Fifth light emitting element (Dl)...(D,)
, fifth...ninth resistors (17)...(2+) for current limiting connected to the base of each Tr, and respective resistors (1η...(2+1 and amplifier θ1)). A second diode (22) with constant voltage characteristics is connected between the series circuit of the Zener diode (c), the emitter of the first Tr Q2+, and the first bus bar (1), and is connected between the FET (electric field The constant current circuit (24) is composed of a constant current circuit (24) consisting of a
The emitter and collector of 21...06) are the 10th T'
(+21 collector is connected to the emitter of the second Tr C3), and the collector of the second Tr C3) is connected to the third Tr
(Connected to the emitter of 141, and similarly the third,
The emitters and collectors of the fourth and fifth Tr (+4)051 (1, 1 are connected in series, and the fifth 'J”r (+
The collector of 6) is connected to the second bus bar. Note that the second diode (22 is the amplifier θ1) is connected with the direction toward the output terminal as the forward direction.

The oscillation circuit (5) includes a first inverter (2S) 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). ,
10th, 1177th) resistor (27)
) to the input terminal of the first inverter (2!i+), and the output terminal of the first inverter (251) and the input of the second inverter (a) terminal, and the capacitor (connected to the output terminal of the second impark C61 via Q. Note that the connection point 29) is the fourth diode side whose direction is the connection point c2!l) in the forward direction. The temperature sensing element (S
) and the anode of the first diode (6). In addition, the second inverter (the output terminal of 20 is a fifth diode C whose forward direction is the direction to this output terminal)
'311, the second wiring (Gl leads to the fifth...
The ninth resistor a is connected to c2o.

The operation of the above circuit will be explained below. 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 c! of the oscillation circuit (5) is high). The oscillation circuit (5) does not oscillate because it is fixed at a high level via the fifth diode C31).
In order to fix the device in a reverse bias state, the first step (temperature display) is performed.

Hereinafter, the circuit operation based on the temperature of the temperature sensing element (S) will be explained. First, the temperature sensing element (S) is at a low temperature and the fifth light emitting element (D,
) is lit, when the resistance value of the temperature sensing element gradually decreases due to the rise in temperature, the amplifier 01
The voltage at the (g) input terminals of ) increases, the potential difference with the (g) input terminals widens, and the output voltage increases. As the output voltage increases, the first...fourth Tr(121...(1
The base voltage of 5) also gradually increases, and the voltage of the fourth Tr (15) increases.
The first light emitting element (D4) is sequentially turned off until the first Tr Q is depleted, and the fourth light emitting element (D4) is turned on sequentially to the first light emitting element (DI) to display the temperature. Furthermore, 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 (1) input terminal of amplifier 01) decreases, and the output voltage decreases. descend. As the output voltage decreases, the base voltages of the first to fifth Tr C21...(+6) gradually decrease, and the first Tr (I is turned on sequentially from I depletion).

When the first Tr (121) is turned on, the anode and cathode are short-circuited, so the first light emitting element (D,) turns off.
The second light emitting element (D,) is also turned off, the temperature is displayed as shown in Figure 2 (a), and the third and fourth light emitting elements (D,) are also turned off.
s)(I)<) also turns off sequentially 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 second diode and Zener diode t2
31 are respectively V, , V2, and the voltage at the midpoint σ of the ninth resistor (Iη and the fifth diode C41) is 3, when viewed from the output terminal of amplifier 01), V s-V + + 'V t tonal. Further, the fifth (1) Tr Im no r-mitter voltage is equal to the forward voltage of the fifth light emitting element (D,), and this emitter voltage becomes the lighting voltage of the fifth light emitting element (mountain), and this lighting If the voltage is 4, and the voltage between the base and emitter which is the ON condition for the fifth transistor θe is V, then Vs
+V! Since the condition l > V4 is satisfied, the fifth
'1. "r (1G) is not turned on, the temperature of the temperature sensing element (S) decreases, and the fifth light emitting element continues to light up at output 5 of the amplifier (11). In addition, the constant current circuit (24) Since the gate and source are short-circuited, the first...fifth
Regardless of the number of light-emitting elements (D,)...(D,) that are lit, 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.

If the temperature sensing element (S) is disconnected due to poor connection while the display circuit (4) is displaying the temperature, the first diode (6) becomes reverse biased, and the first diode (6) The anode side of will have zero voltage. Then, the voltage at the connection point (29) of the oscillation circuit (5) also changes to the fourth diode (
The bias decreases due to the loss of bias from the oscillator circuit (5
) is the first inverter due to the voltage drop at the connection point (two blades). The output of rH,j (high) depends on 1.

Therefore, the input of the second inverter C≧□□□ is also “I”
Therefore, the output of the second inverter (26) is “L”.
” (low), and the capacitor (a is the 11th resistor (2
8) through the connection point (21) is charged towards the output of the second inverter Q barrel, the voltage at the connection point 12 gradually increases, through the 10th resistor - the first inverter i5)
The input becomes [■■-IK, and the output becomes [, J.

At the same time, the input of the second inverter (20) also becomes "I," and its output becomes r ■, I J. This time, the capacitor (0 is connected from the output side of the second inverter ff1f9 to the connection point (21) It is charged, and the voltage at the connection point (B) gradually decreases, and at the same time, the first invercouver (2) is also powered down by manual labor, and its output becomes r Hl again. ) continues to oscillate.

In the oscillation operation of the oscillation circuit (5), the cathode side of the fifth diode (111) repeats [HJ, rL-1, and first when JHJ, the temperature sensing element (Sl is disconnected and 7, the amplifier ( 11) is zero, the voltage at the midpoint (II) is low at approximately ■, and the voltage at the first...fourth Tr (121...
...(151 is disappointed with the on state, and the fifth 'T"r (
16) is off, and the first...fourth light emitting elements (1)
I)...(D4) does not light up, and the fifth light emitting element (D4)
4) only lights up. Next, when rLJ, the first...
Fifth Tr (121...(10 pace currents are the fifth Tr)
. . . flows through the ninth resistor aη (21), the Zener diode c2, the second diode (A), and the fifth diode Oυ, and each Tr is on, and the first... Since the light emitting elements (D,)...(D,) of 5 do not light up, the first...fourth Tr...09 is the oscillation circuit (5).
related to the oscillation operation (maintains the on state, the 1st...4th
The light emitting elements (DI)...(D4) do not light up, and only the fifth light emitting element (D,) blinks as shown in FIG. 2(c). Therefore, the temperature sensing element (S) may be disconnected or the temperature sensing element (S) may be disconnected.
) to the fifth light emitting element (
D, ) can be displayed by blinking, and can be distinguished from an abnormal temperature display due to a failure in other parts, such as the display circuit (4), and the inspection work for the failure location can be extremely simplified.

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 Embodiments In the above embodiments, a temperature display device in which only one light emitting element blinks when the temperature sensing element is not energized was described.
Hereinafter, based on FIG. 3, a description will be given of a temperature display device in which a plurality of light emitting elements blink when the temperature sensing element is not energized. In addition, the same reference numerals as those in the above embodiments refer to the same items 17,
Furthermore, detailed explanations of similar components will be omitted.

The output terminal of the second inverter (26) is a variable resistor 02
is connected to the 00 side input terminal of the amplifier 01) through a series circuit with the sixth diode G3) whose (1) input terminal direction of the amplifier (11) is the forward direction. The anode of the fourth diode α and the sixth diode c331
, a series circuit of a third inverter (34) and a seventh diode 09 is connected between the midpoint (mouth) of the variable resistor (32). The direction from the anode of the diode 00) to the middle point is connected, and the seventh diode t3m is connected to the third inverter (3
4) Connected with the direction as the forward direction.

Hereinafter, - the operation of the above-mentioned temperature display device will be explained. First, when the temperature sensing element (S) is energized, the input of the third σ) inverter 434+ is ``one input, so the output voltage is
At L j, the output of the second inverter (26) [■■-
1 is connected to the output [L through the seventh diode (351).
-1, and the sixth diode 031 is in a reverse bias state. Therefore, similarly to the above embodiment, the first...
-Temperature is displayed by lighting the fifth light emitting element (D,)...(D,).

Next, when the temperature sensing element (S) becomes de-energized due to a poor connection, the first diode (6)
becomes reverse biased and its anode side has zero voltage. Then, the oscillation circuit (
The voltage at the connection point 21 of 5) decreases, and 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 θ1) repeats ")" and "L". First, when the cathode side of the fifth diode C31) is "H", the variable resistor θ2
and the sixth diode α, the (1) input terminal of the amplifier (11) becomes rHJ, and at the same time the output becomes “■(
”, and the first...fifth Tr (+2)...(1
6) The pace current is limited, and each Tr is turned off to
...The fifth light emitting element 0)I)...(D,) lights up. Next, the cathode side of the fifth diode (31) is “L”
In this case, the fifth diode (31), the second diode (2 diodes and the zener diode (2 diodes) are connected to the first...
The base current of the fifth Trα r...(16) flows, and each Tr is turned on, causing the first...fifth light emitting element (Dl).
...(D,) goes out. Thereafter, the fifth diode C3
As the cathode side of No. 11 repeats r HJ and r L J, the first...fifth light emitting elements (I), )...
・(1)5) continues to blink.

When the above blinking occurs, the resistance value of the variable resistor 02 is gradually increased (as a result, the input voltage of the amplifier 01) gradually decreases.
Accordingly, the output voltage also decreases, and the first light emitting element (1) +
), the light emitting elements gradually stop blinking, and the number of blinking light emitting elements decreases. Contrary to the above, when the resistance value of the variable resistor near 0 is gradually reduced, the (G) input voltage of the amplifier 01) gradually increases, the output voltage also increases accordingly, and the first light emitting element (D, ) The number of blinking light emitting elements gradually increases until the light emitting element blinks.

Therefore, the first...
・Fifth light emitting element (D,)...(D, 1) Can be displayed by blinking multiple light emitting elements, and abnormality in temperature display due to failure of other parts, for example, display circuit (4) This can greatly simplify the inspection work of the temperature detection circuit (3) and display circuit (4).As mentioned above, when the temperature sensing element (S) is not energized, the variable By adjusting the resistor C13, a desired number of light emitting elements can be blinked, 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, parts costs can be kept low and it can be distinguished from malfunctions in the display circuit, etc., which greatly simplifies inspection work for the temperature detection circuit and display circuit. I can do it.

[Brief explanation of the drawing]

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 other embodiments. (3)...Temperature detection circuit, (4)...Display circuit,
(5)...Oscillation circuit, (S)...Temperature sensing element,
(Ill... operational amplifier, 02-(16)... first
...Fifth transistor, (Dl) ~ (D,)・
...First...Fifth light emitting element, C3 side...Variable resistor.

Claims (1)

[Claims] 1. A temperature display circuit comprising a temperature detection circuit equipped with a temperature sensing element and an operational amplifier, a plurality of transistors, and a plurality of light emitting elements connected between the collectors and emitters of the transistors. /lf@ in the display device, characterized in that an oscillation circuit is provided so that at least one of the light emitting elements blinks when the temperature sensing element is not energized. 2. A 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.