KR100926674B1 - Digital Thermostat for Detecting Fault - Google Patents

Abstract

The present invention relates to a digital thermostat for use in heat transfer articles. The present invention is to enable the user to easily recognize whether the heat-transfer article is operating normally or abnormally. If the heating article is in an overheated state, the red light emitting part of the color light emitting unit embedded therein rapidly blinks red, so that the user is visually and emotionally informed that it is overheated. In the case where the heat-dissipating product is in a disconnected state, the blue light emitting body of the color light emitting unit built in the body blinks rapidly, and the user is visually informed that the user is in a failure state other than an overheating state. Is given.

When using the digital temperature controller according to the present invention, the user can easily visually check whether the heat-transfer article is broken, and there is an advantage in that the presence position can be easily recognized even in a dark night room.

Thermostat, Electric Heater, Safety, Time Division Modulation, Fault Condition, LED

Description

Digital temperature controller for detecting disorder

The present invention relates to a temperature controller for controlling the temperature of a heat-transfer article, and more particularly, to control the temperature of the heat-transfer article such as electric blanket, electric yoke, electric jade mat, electric steamer and the like and visually determine whether the heat-fed article is broken. It relates to a digital temperature controller that can be identified by.

In general, electric appliances supply electric energy and convert the supplied electric energy into thermal energy so that the user feels warm, or the user's body promotes blood circulation or activates metabolism by thermal action. It is one of the household goods.

These heat products or heating products are built a heating wire therein, and supplies the electric energy from the outside to the heating wire, so that the heating wire generates heat, thereby providing a thermal action to the user. As described above, as long as the above-mentioned heat transfer products use electric energy, in order to control the supply time, the interruption time, and the supply amount of the electric energy, a temperature controller is necessary.

Typically, the thermostat may be determined by the user using a rotary button or an on-off button to determine whether the electric energy is supplied and / or cut off, and in the process of supplying the electric energy, by changing the resistance value therein, It is possible to control the amount of electrical energy supplied to the heating supplies.

By the way, the conventional thermostat is not limited to the supply and / or blocking function of such electrical energy, and it is not checked at all whether the operation of the heat-transfer article is electrically connected to the thermostat.

This means that the user of the heating appliance cannot know its normal operation while the heating appliance is in use. Also, even if the heating appliance fails, the thermostat cannot detect it at all. This means that you can't tell the user whether or not.

In addition, the conventional thermostat is because the power cord is disconnected or disconnected during the use of the heating supplies, even if the heating supplies do not receive electrical energy, the heating supplies do not generate thermal energy, and even if the heating supplies cannot perform any function at all. In this case, the user was not informed of this status at all.

Therefore, the conventional thermostat does not inform the user at all, even though the heating device is already causing the failure, the user is making the situation more difficult by continuing to use the heating device that caused the failure.

If the user fails to cope with this immediately in the state that the electric heating product has failed, the electric heating product may be burned out by overheating, and the electric heating product itself may not be used at all, or the user may burn the image. It may be coated. This phenomenon occurs mainly in a dark room, especially at night.

In this way, the conventional temperature controller does not check at all whether the heating supplies are abnormally operated when the heating supplies are used, and even if any of the heating appliances have caused a failure, they are not immediately checked whether the failure is notified to the user. It is true.

Accordingly, an object of the present invention is to provide a digital temperature controller that can promptly and visually notify the surrounding user or a family member of such a situation when the heating article is disconnected or overheated during operation of the heating article.

In addition, another object of the present invention is to provide a method of operating a digital temperature controller that can immediately and visually notify the surrounding users or family members, such as when the heating supplies are disconnected or overheated during the operation of the heating supplies. It is.

The digital temperature controller according to the present invention includes an input unit for allowing a user to input a temperature value or an operating time for a heating article; A power supply unit for converting and supplying external AC power to DC current; By receiving the DC set voltage from the power supply unit, and by receiving the set voltage by three amplitude modulation signals which are independently applied from the microcontroller while respectively containing a red light emitting body, a green light emitting body and a blue light emitting body, respectively, A color light emitting unit which emits the red light, the green light, and the blue light, independently or superimposed, respectively; Detects the change in the intensity of the set voltage supplied from the power supply unit to determine the normal operation and failure, and also applies the amplitude modulation signal and the setting current by the time division method to the color light emitting part of the color light emitting part over time A microcontroller for causing a change or stopping a change in color, and inducing the color light emitter to blink a specific single color light emitter when it is determined to be a failure; A temperature control unit capable of adjusting an amount of electric energy applied to a heat-transfer article according to a control signal by the microcontroller; Characterized in that it includes.

In the present invention, it is preferable that the digital temperature controller further includes a warning sound generating unit for immediately generating a warning sound when the heating article is placed in an abnormal state. In addition, the digital temperature controller preferably further comprises a display unit for measuring the temperature of the heat-transfer article in real time to inform the user.

In the method of using the digital temperature controller according to the present invention, when the user turns on the power supply, the power supply is supplied from the power supply unit and the measured voltage detected by the microcontroller is in the normal operating state when the voltage is between the lowest set voltage and the highest set voltage. Determination step, if the measured voltage has a voltage value lower than the lowest set voltage, and determines the overheating state, and if the measured voltage has a voltage value higher than the highest set voltage, the determination step of whether or not to determine the disconnection state and ; If it is determined that the above-mentioned superheated state, the microcontroller selects a specific color emitter from the color emitters, and repeats the ON / OFF with the same cycle with the frequency modulation width set to 100% so that the specific single color emitter flickers. A warning step of overheating; If it is determined that the disconnection is in the above state, the microcontroller selects another specific color light emitting unit in the color light emitting unit, and repeats ON / OFF with the same cycle with a frequency modulation width of 100%. A disconnection warning step for blinking; Characterized in that it includes.

In the present invention, when it is determined that the above superheated state, it is more preferable that the specific single color light-emitting body flickering in the color light-emitting unit is a red light-emitting body.

Further, in the present invention, it is more preferable that the other specific single color light emitter flickering in the color light emitter when it is judged to be in the disconnection state is a blue light emitter.

In addition, in the present invention, the digital temperature controller generates a warning sound in conjunction with the flickering state of the single color light-emitting body when placed in the warning step of the overheated state or the disconnected state of the warning step. More preferred.

The digital thermostat according to the present invention is a user or a person in the vicinity of the digital thermostat, because when the heating supplies are disconnected or overheated, the color light emitting unit mounted therein blinks a single color very quickly. You will notice this easily, and you will immediately know if there is a problem with your heating supplies.

In particular, when the digital temperature controller of the present invention operates normally, various colors are gradually changed in the color light emitting unit, whereas in abnormal operation, the digital temperature controller is fixed at a specific color in the color light emitting unit at a very high speed. Since it flickers, the user has a very urgent and urgent feeling visually, there is an advantage that can lead to a quick response attitude emotionally.

In addition, when the digital temperature controller according to the present invention is formed so that a warning sound is generated when a failure occurs, the user can visually as well as visually confirm whether or not the electric heater is broken. There is also an advantage that can be detected.

In addition, since the digital thermostat according to the present invention becomes more visible in a dark place at night, there is no fear that the user or a family member will trample on it due to carelessness, and thus, there is an advantage of fundamentally preventing an artificial failure.

The present invention relates to a digital temperature controller that can visually check whether the normal operation and failure of the heat-transfer article while controlling the temperature of the heat-transfer article.

1 is a core circuit block diagram mounted inside the body of the digital thermostat 100 according to the present invention, Figure 1a is a state in which the digital thermostat is connected to the heat transfer article 200, Figure 1b 1A is a conceptual diagram illustrating the principle of confirming whether the digital temperature controller 100 is in normal operation and / or failure operation as a further embodiment of FIG. 1A, and FIG. 1C is another diagram of the digital temperature controller 100. A conceptual diagram showing a preferred embodiment;

2 is a flowchart showing an operation relationship when using the digital temperature controller 100 according to the present invention;

3 is a conceptual diagram illustrating a principle of confirming normal operation and / or failure by a microcontroller when using the digital temperature controller 100 according to the present invention.

4 is a conceptual diagram illustrating a principle in which a specific color is emitted from the color light emitter 130 when using the digital temperature controller 100 according to the present invention, and illustrates a working relationship between the microcontroller and the color light emitter. .

The digital temperature controller 100 according to the present invention includes an input unit 110 through which a user can input a temperature value for an electric heating article or an operation time.

In the present invention, the input unit 110 may be operated by a key button formed in the body portion (not shown) of the thermostat, and can be input by setting the use temperature for the heat transfer article 200, the operation The time can be set and input. The input unit 110 is connected to the micro-controller 140 for controlling the use and operation relationship of the heat transfer article. Since the input unit 110 is commonly used in the temperature controller, a detailed description thereof will be omitted.

The digital temperature controller 100 according to the present invention includes a power supply unit 120 which converts an external AC power and supplies the DC power.

In the present invention, the power supply unit 120 receives an AC power supplied from the outside, a home AC power supplied from the outside, or an AC power used in an industry, and converts it into a low voltage DC power. The power supply unit 120 preferably converts an AC voltage of 100V to 220V supplied from the outside into a DC voltage (output voltage) of 1.5V to 12V to supply the inside of the temperature controller.

In the present invention, the power supply unit 120 supplies the DC voltage converted by itself, some of which are sent to the detection line 122 having an internal resistance (r ₀ ) to supply to the microcontroller 140. The remainder is preferably sent to the branch line 124 having the heat resistance r _t and supplied to the heat transfer article 200. (FIG. 1B; see FIG. 3). In this case, the voltage measured by the microcontroller 140 is a difference occurs according to the voltage supplied to the heat transfer article 200.

In the present invention, the power supply unit 120 supplies the output voltage to the color light emitting unit 130 and the micro-controller 140 at the same time, and supplies the same set voltage. When the power supply unit 120 supplies the same set voltage to the color light emitting unit 130 and the microcontroller 140 at the same time, the microcontroller 140 emits the color light by the time division modulation method. By applying to the unit 130, the color light emitting unit 130 to emit a predetermined color. Detailed description thereof will be made below.

The digital temperature controller 100 according to the present invention includes a color light emitter 130 having a red light emitter R, a green light emitter G, and a blue light emitter B. The color light emitter 130 connects the red light emitter R, the green light emitter G, and the blue light emitter B independently to the microcontroller 140, and independently from the microcontroller 140. It is desirable to receive the frequency modulated signal. In addition, in the present invention, the color light emitting unit 130 is characterized by receiving the same set voltage from the power supply unit 120 and the micro-controller 140.

In the present invention, the color light emitting unit 130 is applied to the DC set voltage output from the power supply unit 120 on the one hand, and applied to the set voltage output from the microcontroller 140 on the other hand. Will receive. At this time, the set voltage output from the microcontroller 140 is independently applied to the red light emitter R, the green light emitter G, and the blue light emitter B, and each of the set voltages has three amplitudes. The amplitude is changed time-divisionally by the modulation signal, or the amplitude is not applied but is applied respectively. The set voltage is preferably a DC voltage of 1.5V to 12V. In the present invention, when the amplitude is changed by the time division method, the color of the color light emitting unit 130 is changed to the intensity over time, but when the amplitude is not changed, the intensity of the color is not changed. Will not.

In the present invention, the color light emitting unit 130 is the red light emitting unit (R) and the green light emitting unit (G) and blue by the setting voltage supplied from the power supply unit and the time-divisionally supplied setting voltage from the microcontroller. The light emitters B may be emitted independently or overlapping with each other, thereby providing different color colors to the outside.

In addition, in the present invention, the color light emitting unit 130 controls the light emission order and the degree of light emission of the red light emitter R, the green light emitter G, and the blue light emitter B by the control method of the microcontroller. It can change over time. However, the time-dependent change of the color light emitting unit 130 may be performed when the heat-transfer article 200 is placed in a normal state, and whether or not the operation is performed in a normal state (this is the pre-patent patent application 10 of the present invention). -2007-80069) is outside the scope of the present invention, a detailed description thereof will be omitted.

Digital temperature controller 100 according to the present invention includes a micro-controller 140 to detect the change in the intensity of the set voltage supplied from the power supply unit 120 to determine whether the normal operation or failure.

In the present invention, the micro-controller 140 detects the set voltage supplied from the power supply unit 120, and determines whether or not the connection of the heat-transfer article 200 is broken or not according to the measured voltage value (S). 110). At this time, the set voltage is a DC voltage output from the power supply unit 120 means a voltage of 1.5 V to 12 V. In FIG. 3, the voltage is marked as + 5 V, but this is a value representing the set voltage.

1B and 3 illustrate in detail how the microcontroller 140 determines whether or not a connection is made to the heat-transfer article 200.

First, when the DC voltage is supplied from the power supply unit 120, the current flows to the detection line 122 connected to the microcontroller 140 and the branch line 124 connected to the heat transfer article 200, respectively. The microcontroller 140 detects the voltage transmitted through the detection line 122.

At this time, if the temperature controller 100 of the present invention is securely connected to the heat transfer article 200 and is normally operating, the microcontroller 140 outputs the output voltage supplied from the power supply unit 120 (eg, : + 5V) will be detected a lower voltage value, in this case the microcontroller 140 is determined to be normal operation (S 112).

On the other hand, the temperature controller 100 according to the present invention, if the heating article 200 is overheated during use, this state is determined to be an overheated state of the heating article (S 130 ~ S 134). When the heat transfer article 200 is overheated, its resistance r _t becomes very small.

In this case, according to FIG. 3, the output voltage from the power supply unit 120 flows to the branch line 124 relatively much as compared to the detection line 122 as much as the resistance r _t of the heat transfer article is lowered. As a result, the overcurrent flows to the branch line 124 connected to the heat transfer article 200. Therefore, most of the current supplied from the power supply unit 120 flows to the branch line 124, and the current input to the microcontroller 140 is changed to a very small amount. In this case, the microcontroller 140 detects a very low voltage value, and determines the state as an overheated state of the heating article (S 130 to S 134).

In the present invention, a voltage value that can be determined as an overheated state in the microcontroller 140 may be defined as the lowest voltage. Typically, when the temperature of the heat-transfer article 200 exceeds 80 ℃, it is likely to burn the user, and also increases the risk of fire. Therefore, when the temperature of the heat-transfer article 200 detected by the temperature sensor exceeds 80 ℃, the current flowing into the branch line 124 is very large, the voltage detected by the microcontroller 140 in that state Can be used as the lowest voltage. Therefore, the minimum voltage described above can be changed depending on how much the allowable temperature of the heat-transfer article is made, and it is not necessarily fixed.

In the present invention, when the microcontroller 140 is a measurement voltage in the range of 1% to 20% of the output voltage when the microcontroller 140 is based on the output voltage from the power supply unit 120, the heating article is overheated. It is preferable to judge that the state is in a state. Therefore, in this case, the lowest voltage may be said to mean 20% or less of the output voltage of the power supply. The minimum voltage may be determined differently according to the type and characteristics of the heat-transfer article.

When the present invention is determined to be in an overheated state (S 132), the red light emitting body R of the color light emitting unit 130 is thereby quickly flickered (S 134), which will be described in detail below ( 5).

The present invention, although the red light emitting device (R) blinks to warn of an overheating state, the user does not notice or expects to be in the absence, and when the predetermined time elapses, the automatic It is preferable to cut off the power applied to the heat transfer article 200 (S 136). The predetermined time can be set to 2 to 10 minutes, more preferably 3 to 4 minutes. In this case, after the above overheating condition is warned, the power is automatically cut off after a predetermined time. To this end, the micro-controller 140 may cut off the power applied to the triac 152 of the temperature controller 150, it can cut off the power applied to the heat transfer article 200.

On the other hand, when the temperature controller 100 of the present invention is not connected to the above-mentioned heat-transfer article 200 or is dropped out in use, it is determined that this state is a disconnected state (S 140 to S 144).

In this case, according to FIG. 3, since the heat-transfer article is disconnected, the output voltage from the power supply unit 120 flows to the detection line 122 instantaneously. As a result, the output voltage (eg, + 5V) of the power supply unit 120 is input to the microcontroller 140 as it is. In this case, the microcontroller 140 instantly detects a voltage value that is greater than or equal to the output voltage (eg, + 5V) of the power supply unit 120, and determines the state as a disconnected state (S 140 to S). 144).

In the present invention, the voltage value that can be determined as the disconnection state in the microcontroller 140 may be defined as the highest voltage. Therefore, when the voltage measured by the microcontroller 140 is greater than or equal to the output voltage, it is determined that it is in a disconnected state. In the present invention, when the microcontroller 140 senses 95% or more of the output voltage supplied from the power supply unit 120 and receives it as the measurement voltage, it is preferable to determine this state as a disconnected state. In this case, the maximum voltage means 95% or more of the output voltage of the power supply unit.

When the present invention is judged to be in a disconnected state (S 142), the blue light emitting body B of the color light emitting unit 130 is led to flicker quickly (S 144), which will be described in detail below. 6).

The present invention, despite the warning of the disconnection state by the flashing of the blue light emitting body (B), the user does not notice or expects to be in the absence, when the predetermined time elapses, the heat transfer automatically It is preferable to cut off the power applied to the article 200 (S 146). In addition, it is preferable to set said predetermined time to 2 to 10 minutes. To this end, the micro-controller 140 may cut off the power applied to the triac 152 of the temperature controller 150, it can cut off the power applied to the heat transfer article 200.

Therefore, according to the present invention, according to the magnitude of the voltage value detected by the micro-controller 140, it is possible to determine by checking the overheating state of the heating article 200, disconnection with the heating article, and the normal operating state of the heating article. It is possible to take appropriate action for each state according to the result.

In addition, in the present invention, the micro-controller 140 has a feature that allows the color light emitting unit 130 to change color over time, so that the user can be visually informed of the failure. 4 illustrates the operating principle of the color light emitting unit 130.

In the present invention, the micro-controller 140 has three signal lines 132 independently of the red light emitter R, the green light emitter G, and the blue light emitter B of the color light emitter 130. 134, 136 are connected. The microcontroller 140 independently applies or cuts a set voltage to each of the three signal lines 132, 134, and 136, and also independently applies an amplitude modulation signal. The set voltage is 1.5 V to 12 V, which means a voltage value equal to the set voltage applied from the power supply unit 120. In this case, the microcontroller 140 performs time division amplitude modulation on the three signal lines 132, 134, and 136 independently. Through this, the microcontroller 140 causes the color light emitting unit 130 to change the electrical energy over time, thereby causing the color light emitting unit to change the color over time.

The digital temperature controller 100 according to the present invention includes a temperature controller 150 capable of adjusting the amount of electrical energy applied to the heat transfer article 200 according to the control signal by the microcontroller 140.

In the present invention, the temperature control unit 150 drives the triac driver 152 according to the temperature control signal of the microcontroller 140, accordingly the external electrical energy through the triac 154 ( 220V, 60Hz) is preferably to be turned on (ON) / off (OFF) in real time to the heat transfer article 200. 1C illustrates this state by way of example. However, the supply method of the electric energy by the triac is a conventional one and is beyond the scope of the present invention, and thus detailed description thereof will be omitted.

In the present invention, the digital temperature controller 100 preferably further includes a display unit 160 for measuring the temperature of the heat-transfer article in real time and informing the user thereof. The display unit 160 is more preferably formed on the surface of the body portion, it is more preferably a digital display unit for displaying the temperature of the heat-transfer article in real time by a digital number by the liquid crystal. The digital display may utilize a method commonly performed in the art.

The digital temperature controller 100 according to the present invention smoothly and neatly solves the problem of the present invention through the following interaction.

First, when the user connects the digital temperature controller 100 of the present invention to the heat-transfer article 200, and turns on the power, it is determined whether the failure (S110).

In the present invention, the step of determining whether the failure (S 110) is determined as a normal operating state when the measured voltage detected by the microcontroller 140 is between the lowest voltage and the highest voltage (S 120 and S). 122). In addition, when the measured voltage of the microcontroller 140 has a voltage value lower than the minimum voltage is determined as an overheating state (S 130 ~ S 134), when the measured voltage has a voltage value higher than the maximum voltage. It is determined as a disconnected state (S 140 ~ S 144). Since the detailed description has already been made above, this will not be repeated.

Next, in the present invention, the principle that the color light emitting unit 130 emits a specific color is described.

4 is a conceptual diagram illustrating a state in which the microcontroller 140 and the color light emitter 130 are electrically connected to each other.

In the present invention, the color light emitting unit 130, on the one hand, receives a predetermined set voltage directly from the power supply unit 120, while on the other hand, the color light emitting unit 130 is also predetermined through the microcontroller 140. The set voltage of is being applied. In the case of FIG. 4, the set voltage is indicated as + 5V, but this is merely an example. For example, the set voltage is preferably selected and applied within a range of 1.5V to 12V.

In the present invention, since the color light emitting unit 130 is directly applied with the set voltage from the power supply unit 120, the red light emitting unit R, the green light emitting unit G, and the red light present therein Each of the blue light emitting bodies B is in a state where the set voltage (+ 5V) is applied thereto. At this time, if the voltage is not applied to the microcontroller 140 at all (ie, 0V), the set voltage (+ 5V) applied from the power supply unit 120 flows in the direction of the microcontroller. Red, green, or blue colors are generated in the light emitter through which the set voltage flows. However, when the set voltage is applied to the color light emitting unit 130 by the microcontroller 140 (that is, + 5V), there is no voltage difference in the color light emitting unit 130, so that any current flows. Therefore, the color light emitting unit 130 does not emit color.

Therefore, when the set voltage is applied to the color light emitter 130 in the microcontroller 140, the color light emitter 130 is turned off to generate no color at all, while the microcontroller 140 is When 0 V is displayed, the color light emitter 130 is turned on and generates a corresponding color.

Therefore, the present invention can control the color of the color light emitting unit 130 by controlling the conditions of the microcontroller 140. To this end, the present invention provides three signal lines 132, 134 and 136 independent of the red light emitting device R, the green light emitting device G, and the blue light emitting device B to the microcontroller 140. Each is connected.

Next, a description will be given of the principle that the thermostat according to the present invention operates the color light emitting unit when the heat-transfer article is in a faulty state, thereby giving a user a warning message based on the color.

FIG. 5 illustrates a principle in which a red light emitter is selected as a specific color in the color light emitter when the digital temperature controller 100 according to the present invention is overheated, and the red light blinks in the state. Conceptual diagram.

When the digital temperature controller 100 according to the present invention is determined to be in the overheated state, the microcontroller 140 selects a specific color light emitter from the color light emitter 130. To this end, the microcontroller 140 performs frequency modulation on one color light emitter, while applying the set voltage (eg, + 5V) to the other two color light emitters.

In the present invention, when it is judged that it is in an overheated state, it is preferable that the color light-emitting body that performs the frequency modulation is specified as a red light-emitting body (R). This is to blink the red color by frequency modulation, so that the user can immediately notice visually and sensibly that it is overheated.

In this case, it is preferable to repeat ON / OFF in the same cycle in this state at 100%, without changing the amplitude of the said red light emitting body R in this case. The cycle time t ₁ of the cycle is preferably 0.1 seconds to 2 seconds. This is because when the cycle time t ₁ is shorter than 0.1 second, it flickers too fast, whereas when the cycle time t ₁ is longer than 2 seconds, it flickers too slowly and it is difficult to give tension to the user. The cycle time t ₁ may be kept constant, but the cycle time t ₁ is not limited thereto, and the cycle time t ₁ may be operated at different cycle times t ₂ . At this time, the cycle time t ₁ of the cycle is more preferably set to 0.3 seconds. On the other hand, the other time period (t ₂₎ of the above is preferably set 0.6 seconds.

FIG. 6 illustrates that when the digital temperature controller 100 according to the present invention is used, the blue light emitting body B is selected as another specific color in the color light emitting unit 130 when it is determined to be in a disconnected state. This is a conceptual diagram explaining the principle that B) flickers.

When it is determined that the digital temperature controller 100 according to the present invention is in the disconnection state, the microcontroller 140 selects a specific color light emitter from the color light emitter 130. In this case, as described above, the microcontroller 140 performs frequency modulation on one color light emitter, while applying the set voltage (eg, + 5V) to the other two color light emitters. do.

In the present invention, when judged to be in a disconnected state, it is preferable to specify the color light emitting body for performing the frequency modulation as a blue light emitting body (B). This is to cause the user to notice immediately and visually that the blue phase is flickered by the frequency modulation so that the user is not overheated and caused a malfunction by another factor.

In the present invention, in this case as well, it is preferable to repeat ON / OFF with the same cycle in a state of 100% without changing the amplitude of the blue light-emitting body (B). Also, the cycle time t ₁ of the cycle is preferably 0.1 second to 2 seconds. The cycle time t ₁ may be kept constant, but the cycle time t ₁ is not limited thereto, and the cycle time t ₁ may be operated at different cycle times t ₂ . The cycle time t ₁ of the cycle is more preferably set to 0.3 seconds. Further, the other cycle time t ₂ is more preferably 0.6 seconds.

In addition, in the present invention, the digital temperature controller 100 is interlocked with the flickering state of the color light emitting unit 130 when placed in the warning step of the overheated state or the warning step of the disconnected state. It is more preferable to generate a warning sound. The warning sound may be provided by the warning sound generating unit 160.

Although the digital temperature controller according to the present invention has been described in detail above, this is only for describing the most preferred embodiments of the present invention, and the present invention is not limited thereto, and the scope thereof is determined by the appended claims. Are limited.

In addition, anyone of ordinary skill in the art will be able to make various modifications and imitations by the description of the specification of the present invention, but it will be apparent that this is also outside the scope of the present invention.

1 is a core circuit block diagram mounted inside the body of the digital thermostat 100 according to the present invention, Figure 1a is a state in which the digital thermostat is connected to the heat transfer article 200, Figure 1b Is a conceptual diagram illustrating the principle of the digital temperature controller 100 to determine whether the normal operation and / or failure operation, Figure 1c is a conceptual diagram showing another preferred embodiment of the digital temperature controller 100;

2 is a flow chart showing the operating relationship of the digital temperature controller 100 according to the present invention;

3 is a conceptual diagram illustrating the principle of confirming the normal operation and / or failure of the digital temperature controller 100 according to the present invention,

4 is a conceptual diagram illustrating a principle in which a specific color is emitted from the color light emitting unit 130 of the digital temperature controller 100 according to the present invention.

5 is a conceptual diagram illustrating the principle that the red light emitter flickers when the digital temperature controller 100 according to the present invention is determined to be in an overheated state.

6 is a conceptual diagram illustrating a principle that the blue light emitter flickers when it is determined that the digital temperature controller 100 according to the present invention is disconnected.

♠ Explanation of reference numerals for the main parts of the drawings.

100: the present invention (digital temperature controller), 110: input unit,

120: power supply unit, 122: detection line,

124: branch line, 130: color light emitting portion,

140: microcontroller, 150: temperature controller

160: warning sound generating unit, 170: display unit

Claims (17)

An input unit 110 for allowing a user to input a temperature value for the heat transfer article or an operation time; A power supply unit 120 for converting and supplying external AC power to DC current; A color light emitter 130 including a red light emitter (R), a green light emitter (G), and a blue light emitter (B) that emit light in response to a set voltage applied from the power supply unit; A micro-controller 140 for sensing the set voltage supplied from the power supply unit to determine whether it is in normal operation or failure and controlling to operate the color light emitting unit according to the normal operation or failure; A temperature controller 150 capable of adjusting the amount of electrical energy applied to the heat-transfer article according to the control signal by the microcontroller; In the thermostat for a heating appliance comprising a, The color light emitter 130 independently includes a red light emitter R, a green light emitter G, and a blue light emitter B, and the red light emitter R, the green light emitter G, and the blue light emitter are independently included. (B) are independently connected to the microcontroller 140 so that the control signals generated from the microcontroller 140 are independently applied to each other; The micro-controller 140 determines whether a heat-fed article is out of order by sensing the measured voltage coming from the output voltage supplied from the power supply unit 120 to the detection line 122, and time-dividing the color light emitting unit 130. By applying an amplitude modulation signal and a setting current according to a method, the color light emitting part may change color over time or stop the color change, and if it is determined that the color light emitting part 130 causes a specific single color light emitting body, Digital temperature controller for heating supplies, characterized in that to induce blinking. delete The method of claim 1, The micro-controller 140, when the measured voltage detected through the detection line 122 is detected as more than 95% of the output voltage of the power supply unit 120, it is determined that the heat-transfer article is disconnected Digital thermostat for heating appliances. The method of claim 1, The microcontroller 140 determines that the heating element is overheated when it is detected that the measured voltage detected through the detection line 122 is 20% or less of the output voltage of the power supply unit 120. Digital thermostat for heating appliances. The method according to any one of claims 1, 3, or 4, In addition to the built-in micro-controller 140, further comprises a warning sound generating unit 160 for immediately generating a warning sound when the heat supply is placed in an abnormal state, the digital temperature controller for heat supplies . The method according to any one of claims 1, 3, or 4, In addition to the built-in micro-controller 140, further comprising a display unit 170 for measuring the temperature of the heating goods in real time to inform the user of the digital temperature controller for heating goods. The microcontroller 140 detects the output voltage of the power supply unit 120 by dividing the output voltage of the power supply unit 120 into the detection line 122 connected to the microcontroller 140 and the branch line 124 connected to the heat transfer article 200. The measurement voltage is input through the line 122, but when the user turned on the power supply, the measured voltage detected by the microcontroller 140 is 20% to 95% of the output voltage of the power supply 120 If it is within the range of%, it is determined that the normal operating state, and if the measured voltage is measured to be 20% or less of the output voltage of the power supply unit 120, it is determined to be an overheating state, and the measured voltage is the power supply unit 120 Determining whether or not a failure is determined as disconnected when measured at 95% or more of the output voltage of the power supply; If it is determined that the overheated state, the micro-controller 140 selects a specific color light emitter from the color light emitting unit 130, and repeats the specific single by repeating the ON / OFF in the same cycle with the frequency modulation í�� at 100% A warning step of an overheating state causing the color light emitter to blink; When it is determined that the circuit is disconnected, the microcontroller 140 selects another specific color light emitter in the color light emitter 130 and repeats ON / OFF with the same cycle with the frequency modulation width set to 100%. A disconnected warning step of causing another single color emitter to blink; Method of using a digital temperature controller for heating appliances comprising a. delete The method of claim 7, wherein In the warning step of the overheat state, the microcontroller 140 selects the specific color light emitting body as the red light emitting body (R), and blinks the red light emitting body (R) in the state. How to use a digital thermostat. The method of claim 9, The blinking cycle period (t ₁ ) (t ₂ ) of the red light emitting unit (R), characterized in that 0.1 seconds to 2 seconds, using the digital temperature controller for heat appliances. The method of claim 10, The cycle period (t ₁ ) of the red light emitter (R) is 0.3 seconds, while the other cycle period (t ₂ ) is characterized in that 0.6 seconds, the method of using a digital temperature controller for heat appliances. The method according to any one of claims 9 to 11, After the red light emitting unit R blinks and warns of an overheating state, when 2 minutes to 10 minutes have elapsed, the power applied to the heating device 200 is cut off. How to use the regulator. The method of claim 12, The power applied to the heat transfer article 200 is cut off by the power applied to the triac 152 of the temperature controller 150 by the microcontroller 140, characterized in that the heat transfer article, How to use digital thermostat. The method of claim 7, wherein The warning step of the disconnection state is characterized in that the microcontroller 140 selects the specific color light emitting body as the blue light emitting body (B), and blinks the blue light emitting body (B) in the state. How to use a digital thermostat. The method of claim 14, Blinking cycle period (t ₁ ) (t ₂ ) of the blue light emitting body (B) is characterized in that 0.1 seconds to 2 seconds, using the digital temperature controller for heat appliances. The method of claim 14, The cycle period (t ₁ ) of the blue light emitting body (B) is 0.3 seconds, while the other cycle period (t ₂ ) is characterized in that, 0.6 seconds, the method of using a digital temperature controller for heat appliances. The method according to any one of claims 7, 9, or 14, The micro-controller 140 generates a warning sound in conjunction with the flickering state of the color light emitting unit 130, characterized in that the use of the digital temperature controller for heating appliances.

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