JPH0360520B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION FIELD OF INDUSTRIAL APPLICATION The present invention relates to a safety device for an iron that detects the state of the iron and controls the supply of electricity to the heater.

Conventional technology Conventionally, an iron equipped with a safety device, as shown in Fig. 5, has a heater 2 on a base 1 of the ironing surface.
and a thermistor 3, and the iron handle 4 has a temperature detection section 5 electrically connected to the thermistor 3.
and an operation detection device 6 for detecting an ironing operation and an ironing operation stop with the base facing downward. Furthermore, a control section 7 was provided at the rear of the iron to turn on and off electricity to the heater using the temperature detecting section 5 and the operation detecting device 6.

The control unit 7 continues to energize the heater when the operation detection device 6 outputs a signal indicating the ironing operation state, and cuts off the energization to the heater after a certain period of time when the operation detection device 6 outputs a signal indicating the ironing operation state. This prevents fires and scorching of clothing caused by leaving the iron unattended.

To explain the above-mentioned motion detection device in more detail, for example, Japanese Patent Application Laid-Open No. 52-1555294 discloses that by observing the movement of the ball using a light source, it is possible to detect whether the iron with the base facing downward is moving or stationary. Disclosed is one that performs state detection.

Furthermore, Japanese Patent Application Laid-Open No. 59-85700 discloses a device that uses a mercury switch to detect the state of an iron, but this also detects whether the iron is moving with the base facing downward or when the iron is moving. This detects whether the vehicle is stationary or not.

Further, Japanese Utility Model Application Publication No. 59-37098 discloses a motion detection device using a mercury switch.
This motion detection device has three electrodes, and when the base is facing downward, it detects the static movement of the iron by the contact and separation between the mercury and the pair of electrodes, and when the iron is stationary, it detects the static movement of the iron. This is to cut off the power supply. In addition, when the iron is placed in a free-standing position with the tip of the base pointing upwards, in a resting state, the three electrodes are simultaneously short-circuited with mercury to detect the resting state. Ori,
In this case, energization to the heater is actively continued.

On the other hand, Japanese Utility Model Application Laid-Open No. 49-76090 discloses that a timer is activated during a work stoppage to cut off the power supply to the heater after a predetermined period of time. However, the timer does not operate when the base is facing downward.

Problems to be Solved by the Invention When observing the actual use of an iron, there are two situations in which the iron is moved with the base facing downward and the tip of the base is moved while ironing is actually being carried out and while the iron is being adjusted to the shape of clothes. There is a so-called work stop state in which the iron is held still with the iron facing upward and the ironing work is paused. It is no exaggeration to say that the work stoppage is much longer than the movement state in terms of time, and the movement state exists intermittently between the work stoppages.

For irons that are used in this way,
The biggest risk factor is when the iron is left with the base facing down. In this case, there is a risk that not only the clothes will be scorched, but also a fire may occur.

Another problem is to leave the work idle. In this case, there is a risk that a child may touch the hot base and get burnt, and there is also the possibility that a flammable object may catch fire due to the heat of the base. Furthermore, it leads to power consumption.

In the conventional iron described above, the main safety measure is against the so-called stationary state in which the iron is left with the base facing downward. Furthermore, the device described in the above-mentioned Utility Model Application Publication No. 49-76090 performs safe operation only when left unattended during work stoppage. Indeed, by simply combining them, it may be possible to envisage an iron that operates safely both in the stationary state and in the idle state.

However, this alone causes a serious problem in the actual use of the iron.

That is, as mentioned above, regarding the actual usage of the iron, the work stop state is much longer than the moving state. Therefore, if you set the time until safe operation that is compatible with the stationary state, the allowable time for the work stoppage will be too short, and the power to the heater will be cut off inadvertently, making the iron less convenient to use. There's a problem.

On the other hand, if you set the time required for safe operation to suit a state of work stoppage, the time required for safe operation to occur in a stationary state may become too long, which may cause burning of clothing or ignition, and the meaning of the safety measures may be diminished. I will lose my purpose.

SUMMARY OF THE INVENTION It is an object of the present invention to solve these conventional problems and provide an iron that can operate accurately and safely while maintaining ease of use.

Means for Solving the Problems In order to achieve the above object, the present invention has the following features:
a base heated by a heater; a control means for controlling energization to the heater circuit; a resting state in which the base is standing still with its tip facing upward; a resting state in which it is standing still with its base facing downward; A detection means that detects three states of movement, in which the base is moving with the base facing downward during ironing work, and outputs different signals corresponding to each of these states, and a heater that responds to the output signal from the detection means. and timer means for controlling energization to the circuit, and the control means continues to energize the heater circuit when the detection means detects a moving state, and when the detection means detects a state of work stoppage, it continues to energize the heater circuit. When the power to the heater circuit is cut off and the stationary state is detected, the second
The power supply to the heater circuit is cut off at the time of .

Effects According to the above configuration, there is a work rest state in which the iron is standing still with the tip of the base facing upward, a rest state in which the iron is standing still with the base facing downward, and a rest state in which the iron is standing still with the base facing downward. Since a different signal is output depending on whether the iron is moving or not, it is possible to arbitrarily set the time until the heater circuit is shut off when the iron is at rest and when the iron is not working.

Therefore, when the iron is in a stationary state with the base facing downwards, the power to the heater circuit can be safely cut off in a short time, and when the iron is not working, the time can be set to take into account things like straightening clothes. It becomes possible.

Moreover, even if you forget to turn it off during the ironing process, the heater circuit is reliably shut off, and a safe iron that will not be left heated to high temperatures for a long time can be obtained.

Embodiment Hereinafter, an embodiment of the present invention will be described based on the accompanying drawings. In FIG. 1, 1 is a base heated by a heater 2, and this temperature is determined by a thermistor 3.
Detected in 4 is a handle provided with a temperature detection section 5 electrically connected to the thermistor 3 and a detection device 8 for detecting the state of the iron. , the temperature detection section 5 and the detection device 8 are installed at the rear of the iron.
A control circuit 9 that controls energization to the heater depending on the
has been established.

Next, the detection device 8 will be explained with reference to FIGS. 2 and 4. The detection device 8 includes a cylindrical body 10 and an electrode portion 1 provided at one end of the cylindrical body 10.
1 and mercury 12 which is a conductor that can move inside the cylinder 10. The electrode part 11 has two electrodes, and these two are
The book electrodes are placed in a conductive state and in a cut-off state, and the two electrodes are each connected to a control circuit 9.

The detection device 8 is mounted so as to form an angle α with respect to the horizontal direction.

This angle α is such that when the iron is operated during ironing work, the mercury 12 is
The range is determined within 0.

Therefore, when the iron is standing on its own and the tip of the base 1 is facing upward, when the iron is not working,
As shown in FIG. 4a, the mercury 12 moves toward the electrode portion 11 and stops, and the two electrodes become electrically connected. In addition, in a stationary state where the ironing operation is stopped with the base 1 facing downward, the mercury 12 moves to the end opposite to the electrode part 11 and stops, as shown in Figure 4b. , the two electrodes are electrically disconnected. Furthermore, when the iron is in a moving state when ironing is being performed with the base 1 facing downward, the mercury 12 moves within the cylinder 10 as shown by the arrow as shown in FIG. The portion 11 is repeatedly turned on and off.

Next, the operation of the configuration of this embodiment will be explained. First, when the iron is changed from a moving state in which ironing is performed with the base 1 facing downward to a resting state, the detection device 8 maintains the electrode portion 11 in a conductive state as shown in FIG. 4a. Therefore, if this state continues for _t1 hours as shown in FIG. 3a, the control circuit 9 automatically cuts off the power supply to the heater circuit.

Furthermore, when the iron is in a stationary state with the base 1 facing downward and the movement of the iron is stopped, the detection device 8
The electrode section 11 is held in a cut-off state as shown in FIG. b.
Therefore, if this state continues for _t2 hours as shown in FIG. 3b, the control circuit 9 automatically cuts off the power supply to the heater circuit.

When the iron is in motion during ironing work, the detection device 8 repeats interruption and conduction at short intervals. Since this cycle is shorter than the times t ₁ and t ₂ , the control circuit 9 continues to energize the heater circuit without cutting it off.

The iron of the present invention can be operated in a resting state in which the iron is stationary with the tip of the base facing upward, in a resting state in which the iron is stationary with the base facing downward, and in a resting state in which the iron is moving as the iron is being ironed. By detecting three moving states and outputting different signals depending on the state, in the work stop state, the power to the heater circuit is cut off after ₁ hour, and the base remains stationary with the base facing downward. Then, cut off the power to the heater circuit after ₂ hours. In a moving state in which the iron is being moved during ironing, the heater circuit continues to be energized.

Therefore, if the above t ₁ is changed to 10 to 15 minutes, t ₂
By setting the time to about 1 to 2 minutes, if the base 1 is left facing down while it is being heated to a high temperature, the power to the heater circuit can be cut off in a short time, preventing damage to clothing and the occurrence of a fire. can be eliminated. In addition, when the work is stopped, such as when clothes are being shaped during a short break during ironing, the heater circuit is shut off only after a longer period of time than when the base is stationary with the base facing down. As a result, the base temperature may drop inadvertently.
In addition to eliminating the problem of hindrances to ironing, even if the device is left unattended due to forgetting to turn off the power, the heater circuit can be reliably shut off after ₁ hour.

In the above embodiment, the detection device 8 is in the conductive state in the work stop state, but the reverse may be possible. The point is that by detecting three states and outputting different signals depending on the state, the first one cuts off power to the heater when each stationary state is detected.
and the second time.

Effects of the Invention As described above, the present invention can be used in a resting state in which the iron is stationary with the tip facing upward, in a resting state in which the iron is stationary with the base facing downward, and in a state in which the iron moves during ironing. It has a detection means that detects three moving states and outputs a different signal depending on each state, and controls the energization of the heater according to the difference in the output signal, and also detects a work stop state. When the iron is stationary, the power to the heater circuit is cut off at the first time, and when the stationary state is detected, the power to the heater circuit is cut off at the second time. It is capable of safe operation.

Therefore, it is possible to reliably prevent not only thermal damage to clothing and ignition, but also burn injuries to young children, and is also effective in terms of energy conservation.

Moreover, during actual use, the power supply to the heater is not cut off inadvertently, so it is possible to maintain safety and ease of use, which is an excellent effect.

[Brief explanation of drawings]

Fig. 1 is a sectional view of the main parts of an iron showing an embodiment of the present invention, Fig. 2 is an explanatory diagram of the detection device of the iron, Fig. 3 is an explanatory diagram of the operation of the control circuit of the iron, and Fig. 4 is an explanatory diagram of the operation of the control circuit of the iron. FIG. 5, which is an explanatory diagram of the operation of the detection device, is a sectional view of the main part of a conventional iron. 1... base, 8... detection device (detection means),
9...Control circuit (control means).

Claims (1)

[Scope of Claims] 1. A base heated by a heater, a control means for controlling energization to the heater circuit, and a work stop state in which the base is stationary with its tip facing upward;
Detection means that detects three states: a stationary state in which the base is standing still with the base facing down, and a moving state in which the base is moving with the base facing down during ironing work, and outputs a different signal corresponding to each state. and timer means for controlling energization to the heater circuit in accordance with an output signal from the detection means, and the control means continues to energize the heater circuit when the detection means detects a moving state. The iron cuts off power to the heater circuit at a first time when a work stop state is detected, and cuts off power to the heater circuit at a second time when a stationary state is detected. 2. The iron according to claim 1, wherein the second time is set shorter than the first time. 3 1-2 minutes for the second time, 10-15 minutes for the first time
The iron according to claim 2, wherein the iron is set to minutes.