JP4818012B2 - Electric stove - Google Patents

Description

  The present invention relates to an electric stove, and more particularly to an electric stove provided with a safety function such as sounding an alarm or stopping power supply to a heater when a flammable material such as a curtain or laundry touches or covers the stove. is there.

  In recent years, electric heaters using a heating element such as a sheathed heater or a quartz tube heater have become widespread as local heaters for homes, stores, offices and the like. Since such an electric stove is usually placed close to the user, sometimes it is hung on the stove to quickly dry wet towels and laundry. Such drying is usually applied for a short time under the supervision of the user, but may be left unremoved despite being dry. However, if such a combustible material is left on the stove, it may be overheated and discolored, burnt, burned, or ignited and burned to a combustible material such as a nearby curtain, causing a fire. If the heating element is a sheathed heater, this heating element does not red heat with a low wattage, so it cannot be seen from the outside that the heater is turned on, and it may inadvertently hang laundry. In such a case, the laundry or the like may be overheated, causing discoloration, scoring, or the like. In view of this, such an electric stove is provided with a safety device that does not ignite even when a combustible material is applied (see, for example, Patent Documents 1 and 2 below).

  FIG. 10 is a cross-sectional view of an electric heater described in Patent Document 1 below.

  An electric stove 20 shown in FIG. 10 includes a main body case 21 in which a heater unit 22 is incorporated, and a stand 23 that supports the main body case. An optical signal transmission unit 25 is provided above the main body case, and an optical signal is received by the stand 23. When the operation unit (not shown) is turned on, the heater unit 22 generates heat and an infrared signal is transmitted from the optical signal transmitter 25 to the optical signal receiver 27. ing. With this configuration, when a combustible material such as a curtain or laundry approaches the heater unit 22, the combustible material blocks an optical signal being transmitted from the optical signal transmission unit 25 and receives an optical signal transmitted through the light guide 26. Since the optical signal to the unit 27 is disconnected, the control circuit 24 is operated by this disconnection to stop the power supply to the heater unit 22, and the combustible material can be prevented from overheating and fire.

In addition, the electric stove described in the following Patent Document 2 is provided with an overheat protection element (temperature fuse) in the housing. The temperature fuse detects abnormal overheating of the stove and supplies power to the heating element. It has stopped.
JP-A-5-157251 (FIG. 1, paragraphs [0022] to [0025]) Japanese Unexamined Patent Publication No. 2006-23033 (FIG. 6, paragraphs [0021] to [0028])

  According to the electric stove of Patent Document 1 described above, when a combustible material approaches the stove, this is detected and power supply is stopped, so that ignition of the combustible material can be prevented in advance. However, since this electric stove detects the combustible material by transmitting and receiving an optical signal between the optical signal transmitting unit and the receiving unit, special detection means comprising the transmitting and receiving unit and its accessories (for example, a light guide). Therefore, the number of parts increases, the installation work becomes troublesome, and the cost increases. In addition, if such a detection means is to be attached to a swing-type electric stove, the transmitter / receiver must be divided into a main body case and a support stand, so that the receiver moves following the movement of the transmitter. This requires a mechanism for making the receiving unit complicated, and the mechanism of the receiving unit becomes complicated.

  In addition, since the electric heater described in Patent Document 2 uses a thermal fuse for the overheat protection element, if the fuse is cut, it cannot be replaced by the user himself and brought to a store or the like. They will have to be repaired, which is expensive and time consuming.

  Furthermore, in order to avoid malfunction of the thermal fuse, the operating temperature of the thermal fuse is set according to the maximum capacity of the heater, which becomes a factor that makes it difficult to detect an abnormality during use.

  The present invention has been made in order to solve such problems of the prior art, and an object of the present invention is to use a temperature sensor without using a special detection means such as a temperature fuse or a transceiver. An object of the present invention is to provide an electric stove that can quickly detect that a stove has been covered with a combustible material such as a curtain or laundry.

  Another object of the present invention is to provide an electric stove with improved safety by combining a detection means with a high detection speed and a stable detection means so that combustibles can be detected quickly and reliably. is there.

  Furthermore, another object of the present invention is to provide an electric stove that prevents the detection means from malfunctioning even if the heater mode is changed during use.

In order to achieve the above object, the electric stove according to claim 1 includes a heater, a temperature sensor that detects an ambient temperature of the heater, and a control device that controls the heater and the like based on a detection value of the temperature sensor. The control device is detected by an increase rate detection means for calculating a temperature increase rate from the output of the temperature sensor, a storage means for storing predetermined data, and the increase rate detection means. First determination means for comparing the temperature rise rate with a reference value preset in the storage means to determine abnormal overheating around the heater, and an alarm is generated according to the determination result of the first determination means At least one of output and interruption of power supply to the heater is executed, an abnormal temperature value is set and stored in the storage means, and the control device detects the temperature detected by the temperature sensor. It further has a second determination means for determining whether the side temperature exceeds the abnormal temperature value, and when the first determination means does not determine abnormal overheating and the second determination means exceeds the abnormal temperature. Even when the determination is made, at least one of outputting an alarm and shutting off the power supply to the heater is executed based on the determination result, and the heater has a plurality of heater modes having different heater capacities, and the storage means The abnormal temperature value is set for each of the plurality of heater modes, and when the heater mode is changed after a lapse of a predetermined time from the start of the electric stove, the storage means Temporarily storing data indicating that the temperature and the heater mode have been changed, and when the heater mode is changed, the control device stores the heater mode stored in the storage means. A third determination means for comparing abnormal temperature around the heater by comparing the ambient temperature of the heater at the time of the change and the ambient temperature of the heater after a predetermined time has elapsed after the heater mode is changed; In addition, when data indicating that the heater mode has been changed is stored in the storage means, an alarm is issued based on the determination result by the third determination means without performing the determination by the second determination means. And / or cutting off the power supply to the heater .

Further, the invention according to claim 2, in the electric stove according to claim 1, wherein the storage unit, among the temporarily stored data, the ambient temperature of the heater at the time when the heater mode is changed Is stored as temperature division data divided into a plurality of stages so as to correspond to the plurality of heater modes, and the third determination means compares the temperature division data with the changed heater mode, When the temperature classification data is larger than the changed heater mode, the data temporarily stored in the storage means is deleted.

The invention according to claim 3, in electric stove according to any one of claims 1-2, wherein the heater is characterized in that a sheathed heater or a quartz tube heater.

  By providing the above configuration, the present invention has the following excellent effects. That is, according to the first aspect of the present invention, the temperature sensor that detects the ambient temperature is used, the rate of increase is calculated from the detected value of the sensor, and the magnitude of the calculated value is compared with the reference value. Therefore, it is possible to quickly detect the state when a combustible material such as a blanket hits the stove without providing a special detection means.

Further, according to the invention of claim 1, the reference value before the time point to stabilize the temperature rise rate based on the stable time of the heater to be a high rate of temperature rise, since from the time of stably set to a lower temperature increase rate Thus, the abnormal overheating can be detected more reliably by setting the reference value according to the heating state of the heater.

According to the first aspect of the present invention, since the detection of abnormal overheating is determined using both the temperature increase rate and the abnormal temperature value, abnormal overheating that cannot be detected at an early stage by the determination using the temperature increase rate is ensured. Can be detected quickly. In particular, when the detection based on the rate of temperature rise is detected several times, for example, four times in succession when the reference value is exceeded, the detection speed is delayed if no abnormality is detected even once in four times. Even in such a case, when the abnormal temperature value is exceeded, it is definitely determined as abnormal, so that safety is improved.

According to the first aspect of the present invention, since the abnormal temperature value is set for each heater mode, the determination can be made based on the appropriate abnormal temperature corresponding to the heater mode, so that abnormal overheating can be detected more reliably.

According to the first aspect of the present invention, when the power supply to the heater is inadvertently interrupted by the second determination means, specifically, when the heater mode is changed so that the heater capacity is reduced. By performing the determination using the third determination unit without performing the determination by the second determination unit, the heater control can be performed more appropriately.

According to the invention of claim 2, the functionality is further improved by efficiently deleting the data temporarily stored by the storage means.

According to invention of Claim 3 , the effect of Claims 1-2 can be show | played with a sheathed heater or a quartz tube heater.

  Hereinafter, the best embodiment of the present invention will be described with reference to the drawings. However, the embodiment shown below exemplifies an electric stove for embodying the technical idea of the present invention, and is not intended to specify the present invention to this electric stove. Other embodiments within the scope are equally applicable.

  1 is a front view of an electric stove according to an embodiment of the present invention, FIG. 2 is a front view in which a part of a heater built in the electric stove of FIG. 1 is visible from the front, and FIG. 3 is an electric stove of FIG. 4 is a side view as seen from one side, and FIG. 4 is a side view in which the side plate of FIG. 3 is removed so that the built-in heater can be seen.

  As shown in FIGS. 1 to 4, the electric stove 1 includes a base 2 and a heater body 3 that is erected from the base 2 and accommodates a heater. The heater body 3 is connected to the base 2. It has the structure connected with the member J.

  The base 2 is a pedestal having a substantially circular or elliptical shape in plan view, the surface 2a is curved upward in an arc shape, a space is formed in the bottom 2b, and can be placed on the floor surface. . The base 2 is formed with a recess 2c having a predetermined size at a substantially central portion of the surface 2a, and the connecting member J is inserted into the recess 2c.

Further, as shown in FIG. 2, the heater body 3 includes a housing 4 having a front surface opened to accommodate a plurality of, for example, two heaters H ₁ and H ₂ and their accessories, and a front surface of the housing 4. For example, a sheathed heater is used as each of the heaters H ₁ and H ₂ .

  The housing 4 has a substantially rectangular parallelepiped box shape surrounded by both side plates 4a, 4b and a back plate 4c and opened at the front and top and bottom, and is formed by bending a metal plate. A reflective plate is attached to the back plate 4c. In the housing 4, the base plate 5 is fixed to the lower opening, and the upper opening is covered with the lid body 6.

Although not shown, the lid 6 is provided with an operation plate on the surface and a control board below. The operation plate is provided with a power switch, a heater capacity changeover switch, an indicator lamp, and the like. A temperature sensor 9 is attached below the lid 6. The temperature sensor 9 is provided at a location approximately 30 mm away from the heaters H ₁ and H ₂ . The “heater capacity” is used to indicate the amount of electric power (wattage) of the heater and the amount of heat dissipation associated therewith.

The two sheathed heaters H ₁ and H ₂ each have a predetermined heater capacity (for example, 400 W each). The end portions of these heaters are fixed to the upper and lower plates, and power lines are connected to the terminal portions of the sheathed heaters. The protective net 7 is provided on the front surface of the housing 4 and serves as a safety fence.

  Next, the electric stove control device 10 of the present invention and the safety function of the electric stove operated by the control device 10 will be described.

  FIG. 5 is a block diagram showing the configuration of the control device provided in the electric stove of the present invention, and FIG. 6 shows each characteristic from the start of power supply to the heater of the electric stove in FIG. 1 until 20 minutes. ) Is a characteristic diagram showing the relationship between the ambient temperature of the heater measured by the temperature sensor and time, and FIG. 6B is a characteristic diagram showing the rate of temperature increase based on the ambient temperature measured by the temperature sensor. FIG. 7 shows each characteristic after 15 minutes have elapsed from the start of power supply to the heater of the electric stove in FIG. 1, and FIG. 7 (a) shows the relationship between the ambient temperature of the heater measured by the temperature sensor and time. FIG. 7B is a characteristic diagram showing the rate of temperature increase based on the ambient temperature measured by the temperature sensor. These values are values confirmed by experiments.

The control device 10 includes a control unit 10A including a microcomputer having an input unit 10 ₁ , an output unit 10 ₂ , a control unit 10a, a calculation unit 10b, a time measuring unit 10c, a determination unit 10d, and a storage unit 10e. the input portion 10 ₁ of 10A, the power switch 11 _1, the heater mode switching unit 11 _2, the timer setting unit 11 ₃ and the temperature sensor 9 for detecting the ambient temperature of the heater are connected, the output unit 10 _2, The sheathed heaters H ₁ and H ₂ , the alarm indicator 13 and the power switch off means 14 are connected. In addition, a predetermined temperature increase rate and an abnormal temperature value serving as a reference are input from the temperature increase rate / abnormal temperature setting means 12 and stored in the storage unit 10e. And is input to the input unit 10 ₁ Data are for electrical stove 1 overall controlled by a predetermined control signal various processing is performed is generated by the control unit 10a and the calculation unit 10b.

  Before explaining the operation of the control device, first, the temperature characteristics around the 400 W and 800 W heaters detected by the temperature sensor 9 and the temperature characteristics when each heater is covered with a blanket will be described with reference to FIG. In addition, the temperature of each figure is the value detected by the temperature sensor 9 provided in the location about 30 mm away from the heater.

  When the power switch is turned on and power is supplied to the 400 W heater, as shown by a curve A in FIG. 6A, the ambient temperature of the heater detected by the temperature sensor 9 gradually increases from 20 ° C. of room temperature over time. After about 15 minutes, the surface temperature reaches a substantially maximum temperature (about 510 ° C.), and the subsequent temperature becomes almost in an equilibrium state and becomes a stable state of the heater. At this time, the temperature sensor 9 detects approximately 47 ° C. Similarly, as shown by the curve B in FIG. 6A, the temperature increase rate of the 800 W heater almost stops after about 15 minutes, and the heater is in a stable state (the surface temperature of the heater at this time is about 660 ° C.). It becomes. At this time, the temperature sensor 9 detects about 62 ° C.

Thus, as shown by curves A and B in FIG. 6A, 400 W and 800 W heaters gradually rise from room temperature 20 ° C. and become stable after about 15 minutes. When this occurs, the ambient temperature undergoes a rapid change as described below, for example, when the heater is on and when it is stable.
(I) Before the heater is stable Before the heater is stabilized, for example, when a blanket is applied or already applied when the heater is turned on, the ambient temperature of the 400 W and 800 W heaters rapidly increases as shown in FIG. The temperature curve changes from the curves A and B to the curves A ′ and B ′. Further, as shown by curves A ₁ ′ and B ₁ ′ in FIG. 6B, the temperature increase rate at this time rises at a stretch from about 1 minute after both heaters are turned on, and 10 minutes after 2 minutes. This rate of increase exceeds C / min and is significantly higher than the rate of increase before the blanket is applied (see curves A ₁ and B _{1 in} FIG. 6B).
(Ii) After the heater is stable When a blanket is applied after the heater is stabilized, the ambient temperature of each heater of 400 W and 800 W is stable at a substantially maximum temperature when there is no blanket or the like. The temperature rise curve becomes steeper. That is, as shown in temperature curves C and D of FIG. 7A, the ambient temperature is about 400 minutes after the passage of 2 to 3 minutes from the temperature exceeding about 47 ° C. at the time of 15 minutes when entering the stable state ( That is, the temperature exceeds 80 ° C. after 17 to 18 minutes), and similarly, the 800 W heater has a value exceeding 100 ° C. after about 62 minutes from about 62 ° C. As shown in temperature curves C ₁ and D ₁ in FIG. 7 (b), the temperature increase rate at this time is as high as 5 ° C./400 W or 800 W in less than 1 minute immediately after entering the stable state. The value exceeds the minute.

  When a blanket is applied to the heater in this way, the heater ambient temperature rises at a rapid rate of increase as in (i) and (ii) above. The safety function according to the first embodiment of the present invention for controlling the heater off and the like will be described. FIG. 8 is a control flowchart of the electronic stove according to the first embodiment.

  In the electric stove of the first embodiment, the determination unit determines that the rate of temperature increase exceeds a predetermined value, for example, 10 ° C./min in the above (i) and 5 ° C./min in the above (ii). By detecting with 10d (first determination means), it is possible to detect abnormal overheating of the heater. The slope values (for example, 10 ° C./min and 5 ° C./min) are set by the temperature increase rate / abnormal temperature setting means 12 and stored in the storage unit 10e by referring to the determination unit 10d. Make a decision.

  However, for example, when the sensing blanket is displaced due to the swinging motion of the stove or the wind, or when the sensing temperature is distorted due to the influence of power supply noise or instantaneous wind, the above (i), ( The temperature rise rate is not as in ii), and abnormal overheating may not be detected. In other words, when detecting the rate of temperature rise, if there is an output that causes the slope value to be greater than the abnormal slope value multiple times continuously at unit time intervals, the slope value is detected so that it is judged as a slope abnormality. In such a case, depending on the external environment, desired sensing may not be performed and an error may occur even when the heatable material is in contact with the electric heater.

  In preparation for such a case, it is more preferable to set an abnormal temperature for each heater capacity such as 400 W, 800 W, or the like, that is, for each heater mode so that it can be determined as abnormal overheating when the abnormal temperature is exceeded. Therefore, the abnormal temperature for each heater mode is determined in advance by setting the determination table shown in Table 1 below in the storage unit 10e by the temperature rise rate / abnormal temperature setting means 12, and by the determination unit 10d (second determination unit). To do. The abnormal temperature set in the determination table is a value at which the combustible material does not discolor, burn, burn, or ignite when a combustible material such as a blanket is applied to the stove.

This abnormal temperature is a value obtained by adding a predetermined margin to the stable temperature for each heater mode. This margin is set in consideration of the above-mentioned blanket position deviation or sensing temperature deviation as well as eliminating malfunctions that are judged as abnormal during normal operation when no blanket is applied. / It is preferable that the temperature is appropriately changed by the abnormal temperature setting means 12.

  As for the setting of the predetermined margin, for example, the 800 W heater has a stable ambient temperature at 20 ° C. at room temperature (a value detected by the temperature sensor 9) is about 62 ° C. (see FIG. 6). If a value near this temperature is set to an abnormal temperature, an abnormality is determined even during a normal operation where no blanket is applied, causing a malfunction. Therefore, a predetermined margin, for example, 39 ° C. is added to the temperature of 62 ° C. to set it to 101 ° C.

  This abnormal temperature value is a safety value when abnormal overheating is not detected at the rate of temperature increase in the above (i) and (ii). Further, in the 400 W and 500 W heaters, the heater does not glow red, but if this abnormal temperature is set, discoloration and scorching of combustible materials such as blankets can be eliminated.

  Hereinafter, with reference to FIG. 8, the control apparatus of Example 1 and its operation | movement are demonstrated.

  First, when a heater mode 5 (see Table 1) with a predetermined heater capacity, for example, a heater capacity of 800 W is set and the power switch is turned on (step S10), energization of the heater is started (step S11), and the ambient temperature Begins to rise gradually immediately after the switch is turned on, and becomes stable after approximately 15 minutes (see FIG. 6). Then, when the heater mode is set to the heater capacity of 800 W and driven, the elapsed time measured by the timer unit 10c is detected (step S12), and if the elapsed time is 15 minutes or more, the temperature rises later. The abnormal slope value used when detecting the rate is set to 5 ° C./minute (step S13). If the elapsed time is 15 minutes or less, the abnormal slope value is set to 10 ° C./minute (step S14). When the abnormal inclination value is set, the inclination value of the temperature increase rate calculated by the calculation unit 10b from the ambient temperature detected by the temperature sensor 9 and the abnormal inclination value set in the steps S13 and S14 are discriminated. In comparison with the part 10d, it is detected whether or not an abnormal temperature rise has occurred (step S15). Thereby, it becomes possible to detect whether or not the combustible material touches or covers the heater.

  For example, if a combustible material is covered before the heater stabilizes, the heater temperature is low and the temperature rise is low regardless of the presence of the combustible material for a while immediately after the power switch is turned on. Therefore, the reference temperature increase rate, that is, the abnormal slope value is increased, and the comparison is performed by the determination unit 10d at 10 ° C./minute shown in step S14 in detail. In addition, when the combustible material is covered after the heater is stabilized, the heater has already reached the maximum temperature in a stable state, and therefore the reference temperature increase rate, that is, the abnormal slope value is low, and more specifically, 5 ° C. shown in step S13. As a / min, the determination unit 10d performs comparison.

  As described above, when the temperature increase rate of the ambient temperature shows an inclination value larger than the abnormal inclination value as a result of detection in step S15 (Yes in step S15), the process proceeds to step S17 and the power switch off means 14 turns off the heater. At this time, an alarm may be issued by the alarm indicator 13.

  On the other hand, when the temperature increase rate of the ambient temperature shows a slope value smaller than the abnormal slope value in Step S15 (No in Step S15), the process proceeds to Step S16, and the ambient temperature detected by the temperature sensor 9 is The determination unit 10d determines whether the temperature is lower than the abnormal temperature set for each heater mode. At this time, for example, when the heater is driven in the heater mode 5 with a heater capacity of 800 W, as shown in Table 1, if the ambient temperature is higher than the abnormal temperature 101 ° C., the process proceeds to step S17 and the power switch is turned off. When the heater is turned off by the means 14 and the ambient temperature is lower than the abnormal temperature 101 ° C., the process proceeds to step S12, and thereafter steps S12 to S16 are looped.

  According to the abnormality detection operation of the first embodiment described above, an abnormal overheat is detected only by calculating the rate of temperature increase using a temperature sensor that detects a normal ambient temperature without using a special detection means. Yes, you can increase the speed of detection.

  In addition, even if the heater is covered with a combustible material, if it is not determined that the heater is turned off at the time of determination shown in step S15, that is, a temperature increase rate larger than the abnormal inclination value may not be obtained. However, if the determination using the abnormal temperature shown in step S16 is performed, an abnormality that cannot be determined by the rate of temperature increase can be reliably detected by setting an abnormal temperature for each heater mode. Therefore, by combining the discriminating means using the temperature rise rate with a fast detection speed and the discriminating means based on the absolute temperature that can be detected stably, it is possible to reliably and quickly detect an abnormality while preventing malfunction.

  According to the electric stove control operation shown in the first embodiment, contact of a heatable material can be efficiently detected. However, for example, the heater is turned on in heater mode 5 (heater capacity 800 W) for a predetermined time. When the heater mode is changed to the heater mode 1 (heater capacity 400 W) later, the power switch-off means 14 may be inadvertently operated because the abnormal temperature is changed with the change of the heater mode depending on the ambient temperature. Can be considered. Therefore, in the following, a case where the heater is not turned off carelessly even in the case described above as the second embodiment will be described. FIG. 9 is a control flowchart of the electric stove according to the second embodiment of the present invention. Further, the electric stove control device according to the second embodiment is the same as that shown in FIG.

  In addition to the data described in the first embodiment, the storage unit 10e of the control device 10 according to the second embodiment is provided with an area for storing a flag for storing that the heater mode has been changed. In addition, a discrimination table corresponding to a plurality of temperature sections as shown in Table 2 below is stored. Note that this temperature category is to continuously detect the ambient temperature detected by the temperature sensor 9 and constantly monitor which temperature category the ambient temperature belongs to, and this temperature category corresponds to the heater mode. As in the heater mode discrimination table, the abnormal temperature is set for each. In addition, there are overlapping temperatures in the detection temperature range of adjacent temperature division levels, but this has hysteresis characteristics so that the temperature division level is not changed each time for a minute change in detection temperature. It is

Next, the control operation of the electric heater 1 according to the second embodiment having the above configuration will be described with reference to FIG.

In the control device 10 provided in the electric heater 1 of the second embodiment, first, when a heater mode 5 (see Table 1) having a predetermined heater capacity, for example, a heater capacity of 800 W is set and the power switch is turned on (step S20), Energization of the heater is started (step S21), and the ambient temperature starts to gradually increase immediately after the switch is turned on, and becomes stable after approximately 15 minutes (see FIG. 6). At the same time as the power switch is turned on, the temperature classification of the ambient temperature detected by the temperature sensor 9 is monitored. Then, it is detected whether change of the heater mode is made by a heater mode switching unit 11 ₂ (step S22). At this time, if the heater mode is changed, the temperature section of the ambient temperature that has been sequentially monitored is temporarily stored in the storage unit 10e (step S23), and a flag indicating the change of the heater mode in the storage unit 10e (Step S24), the process proceeds to Step S25. If the heater mode has not been changed, the process proceeds to step S25 as it is.

  Next, the elapsed time measured from step S20 is detected by the timing unit 10c (step S25), and if the elapsed time is 15 minutes or more, an abnormal slope value used when detecting the rate of temperature increase later is set to 5 ° C / Minutes (step S26), if the elapsed time is 15 minutes or less, the abnormal slope value is set to 10 ° C./minute (step S27). When the abnormal inclination value is set, the inclination value of the temperature increase rate calculated by the calculation unit 10b from the ambient temperature detected by the temperature sensor 9 and the abnormal inclination value set in the steps S13 and S14 are discriminated. Compared with the part 10d, it is detected whether or not an abnormal temperature rise has occurred (step S28). Thereby, it becomes possible to detect whether or not the combustible material touches or covers the heater.

  If the temperature increase rate of the ambient temperature shows a larger slope value than the abnormal slope value as a result of the detection in step S28 (Yes in step S28), the process proceeds to step S34 and the power switch off means 14 uses the heater. Is set to OFF. At this time, an alarm may be issued by the alarm indicator 13. On the other hand, if the temperature increase rate of the ambient temperature shows a slope value smaller than the abnormal slope value in step S28 (No in step S28), the process proceeds to step S29, and the temperature classification level based on the current ambient temperature When the current heater mode is lower than the current temperature level (No in step S29), the flag is set in step S24. The flag is reset (step S30), and the temperature classification data at the time of switching stored in step S23 is deleted, and the process returns to step S22. On the contrary, when the current heater mode is higher than the level of the current temperature classification (Yes in step S29), it is detected whether or not a flag is set in the storage unit 10e (step S31), and the flag is set. In this case (Yes in step S31), the temperature division level of the ambient temperature detected by the current temperature sensor 9 is compared with the temperature division level at the time of switching temporarily stored in step S23, and the current temperature division level is compared. If it is larger (No in step S32), the process returns to step S22. If the temperature classification level at the time of switching is larger (Yes in step S32), the process proceeds to step S34 and the heater is turned off by the power switch-off means 14. Is set to OFF. If the flag is not set in step S31, that is, if the heater mode is not changed, is the ambient temperature detected by the temperature sensor 9 in step S33 smaller than the abnormal temperature set for each heater mode? The determination unit 10d determines whether or not. At this time, for example, when the heater is driven in the heater mode 5 with a heater capacity of 800 W, as shown in Table 1, if the ambient temperature is higher than the abnormal temperature 101 ° C., the process proceeds to step S34 and the power switch is turned off. When the heater is turned off by the means 14 and the ambient temperature is lower than the abnormal temperature 101 ° C., the process proceeds to step S22, and thereafter steps S22 to S33 are looped.

  These operations will be described using specific examples. For example, when the power is turned on, the driving is started in the heater mode 5 with a heater capacity of 800 W, and after a predetermined time elapses, for example, 20 minutes later, the heater mode 5 starts the heater at an ambient temperature of 85 ° C When the mode is changed to mode 1, the temperature classification level at the time of switching is selected and stored from table 2 in step S23 and S24, and a flag indicating the change of the heater mode is set. At this time, if the control is performed by the operation shown in the first embodiment, the heater mode that is currently driven is level 1, and the abnormal temperature in this heater mode is 80 ° C. Therefore, when the abnormal temperature is detected, An abnormality is detected and the heater is turned off. However, since the heater mode is changed to a heater mode with a smaller heater capacity, the temperature after the change is lowered, and there is a case where no danger is caused. Therefore. By performing the control of the second embodiment, that is, when the flag is confirmed in step S31 and the flag is set, the current temperature section is equal to or lower than the temperature section at the time of switching, that is, the surroundings after the heater mode switching. When the temperature is lowered, the process returns to step S22 and loops without detecting the abnormal temperature.

  By providing the configuration as described above, the power switch-off means 14 and the alarm indicator 13 are not inadvertently operated, and a more convenient electric stove can be provided. As can be seen from Tables 1 and 2, the temperature classification and heater mode discrimination tables are each provided with a level “abnormal”. In this case, the heater capacity is zero, that is, the heater is off, and at the same time, the abnormal state. If the ambient temperature detected by the temperature sensor 9 needs to be lower than 50 ° C. as shown in Table 2, the safety is further improved.

FIG. 1 is a front view of an electric heater according to an embodiment of the present invention. FIG. 2 is a front view in which a part of the heater built in the electric heater of FIG. 1 is visible from the front. FIG. 3 is a side view of the electric heater of FIG. 1 viewed from one side. FIG. 4 is a side view in which the side plate of FIG. 3 is removed so that the built-in heater can be seen. FIG. 5 is a block diagram showing the configuration of the control device provided in the electric heater of the present invention. FIG. 6 shows each characteristic from the start of power supply to the heater of the electric stove in FIG. 1 until 20 minutes, and FIG. 6A shows the relation between the ambient temperature of the heater measured by the temperature sensor and time. FIG. 6B is a characteristic diagram showing the rate of temperature increase based on the ambient temperature measured by the temperature sensor. FIG. 7 shows each characteristic after 15 minutes have elapsed from the start of power supply to the heater of the electric stove in FIG. 1, and FIG. 7 (a) shows the relationship between the ambient temperature of the heater measured by the temperature sensor and time. FIG. 7B is a characteristic diagram showing the rate of temperature increase based on the ambient temperature measured by the temperature sensor. FIG. 8 is a control flowchart of the electric heater according to the first embodiment. FIG. 9 is a control flowchart of the electric heater according to the second embodiment. FIG. 10 is a cross-sectional view of a conventional electric heater.

Explanation of symbols

1 Electric heater (electric heater)
2 base 3 heater body 4 housing 9 temperature sensor H ₁ , H ₂ heater 10 control device 10a control unit 10b calculation unit 10c timekeeping unit 10d determination unit 10e storage unit 10A control means

Claims (3)

An electric stove comprising a heater, a temperature sensor that detects the ambient temperature of the heater, and a control device that controls the heater and the like based on a detection value of the temperature sensor, wherein the control device detects a temperature from an output of the temperature sensor An increase rate detection means for calculating an increase rate, a storage means for storing predetermined data, a temperature increase rate detected by the increase rate detection means and a reference value preset in the storage means are compared. First determination means for determining abnormal overheating around the heater, and executing at least one of output of an alarm and interruption of power supply to the heater according to a determination result of the first determination means,
An abnormal temperature value is set and stored in the storage means, and the control device further includes second determination means for determining whether or not an ambient temperature detected by the temperature sensor exceeds the abnormal temperature value. Have
Even when the first determination means determines that the abnormal overheat is not determined and the second determination means determines that the abnormal temperature is exceeded, the alarm output and the power supply to the heater are cut off based on the determination result. Run at least one,
The heater has a plurality of heater modes having different heater capacities, and the abnormal temperature value is set in the storage means for each of the plurality of heater modes.
When the heater mode is changed after a lapse of a predetermined time after the electric stove is activated, the storage means temporarily stores the ambient temperature of the heater and data indicating that the heater mode has been changed at this time. And when the heater mode is changed, the control device stores the temperature around the heater at the time when the heater mode stored in the storage means is changed and a predetermined time after the heater mode is changed. 3rd judging means for judging abnormal heating around the heater by comparing with the ambient temperature of the heater after the elapse of time, and data indicating that the heater mode has been changed is stored in the storage means. If it is determined, the determination by the third determination means is not performed by the second determination means, and the output of the alarm and the interruption of the power supply to the heater are minimized. Electric stove and executes one. The storage means includes temperature division data that is divided into a plurality of stages so that the ambient temperature of the heater at the time when the heater mode is changed among the temporarily stored data so as to correspond to the plurality of heater modes. In the third determination means, the temperature classification data is compared with the changed heater mode, and when the temperature classification data is larger than the changed heater mode, The electric stove according to claim 1 , wherein data temporarily stored in the storage means is deleted. The heater, electric stove according to any one of claims 1-2, characterized in that a sheathed heater or a quartz tube heater.