JPH08209637A - Dewing sensor for curve mirror and curve mirror with dewing preventing function using it - Google Patents

Abstract

PURPOSE: To prevent dew drops from generating on a convex mirror of a curve mirror main body. CONSTITUTION: A dewing sensor 20 in which a mirror face 21 exposed outward slanting from the vertical plane and an optical sensor 22 are joined together is provided, and a heater 11a for preventing a convex mirror 11 from dewing and a heater 21 a of the mirror face 21 are controlled to electrify them by output of the optical sensor 22. Because the mirror face 21 is slanted from the vertical plane, dewing is generated prior to the convex mirror 11, and by detecting this by means of the optical sensor 22, dew drops generated on the convex mirror 11 can be previously prevented.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dew sensor for a curve mirror which can easily realize high practicality even when a battery is charged by a solar cell and operated by an independent power source system, and a dew sensor for the same. Concerning the curve mirror with a condensation prevention function to be used.

[0002]

2. Description of the Related Art It is often the case that curve mirrors are installed along roads to improve traffic safety. However, a curved mirror consisting of a simple convex mirror has a drawback in that when dew condensation occurs on the surface, the reflected image becomes invisible and its function is lost.

Therefore, a curved mirror has been proposed in which a heater for preventing dew condensation is incorporated in a convex mirror (for example, Japanese Utility Model Laid-Open No. 92018/1992). This device is equipped with a temperature sensor and a humidity sensor for controlling the energization of the heater, and when the temperature is low or the humidity is high, the heater can be energized to prevent dew condensation on the convex mirror.
There is also known a type in which an electrode for detecting a water drop is provided on the surface of a convex mirror and a heater for preventing dew condensation is energized by detecting a change in electric resistance between the electrodes (Japanese Utility Model Publication No. 5-52801). Gazette).

On the other hand, in general, the curve mirror is not always installed in a place where a commercial power source can be obtained. Therefore, the dew condensation preventing heater is powered by a battery, and the battery is independently charged by a solar cell. The method is preferable. Also, in the curved mirror, when minute water droplets due to dew condensation adhere to the surface of the convex mirror, the reflected image becomes completely invisible, but even when large water droplets such as raindrops adhere, the reflected image becomes completely invisible. Not a translation.

[0005]

According to the former case of the prior art, the heater is designed so that when the temperature is lower than a set value,
Alternatively, when the humidity is higher than the set value, electricity is uniformly applied regardless of whether or not dew condensation occurs on the convex mirror. The problem was inevitable. Also, in the latter case, since only the electrode for detecting water droplets is provided on the surface of the convex mirror, it is not possible to distinguish between water droplets and raindrops due to dew condensation, and assuming that rain continues for a long time, the same applies. However, there is a problem that the capacity of the battery must be extremely increased.

Therefore, an object of the present invention is to easily distinguish between water droplets and raindrops due to dew condensation by combining a mirror surface obliquely exposed to the outside with an optical sensor, and therefore the capacity of a battery or a solar cell. It is an object of the present invention to provide a dew condensation sensor for a curve mirror that does not require excessive setting and can easily achieve high practicality, and a curve mirror with a dew condensation prevention function that uses the dew sensor.

[0007]

The structure of the first invention according to this application for achieving the above object is a mirror surface which is inclined from a vertical plane and is exposed to the outside, and an optical sensor which receives light projected on the mirror surface. And the mirror surface is provided with a heater having the same performance as a heater for preventing dew condensation provided on the convex mirror of the curved mirror body.

The optical sensor can be provided with a plurality of sets having different detection points.

A second aspect of the invention is a convex mirror having a heater for preventing dew condensation, a battery for supplying power to the heater, and a solar cell for charging the battery via a charge / discharge controller.
The gist of the present invention is to include a dew condensation sensor for a curve mirror according to the first aspect of the present invention, which controls energization of a heater.

[0010]

According to the structure of the first invention, the mirror surface is
Since it is exposed to the outside by inclining from the vertical surface, dew condensation occurs earlier in time than the convex mirror of the curve mirror installed vertically. Condensation generally occurs when the temperature drops and the temperature of the object falls below the dew point, but at this time, the horizontally installed object causes the earliest condensation,
It is known that a vertically installed object will cause dew condensation at the latest, and an obliquely installed object will cause dew condensation at an intermediate timing due to its inclination angle. On the other hand, the optical sensor can detect the presence or absence of dew condensation on the mirror surface depending on the level of the reflected light, depending on whether the light projected on the mirror surface is normally reflected or irregularly reflected. If the heater is controlled to be energized, the heater for preventing dew condensation can start energization earlier in time than dew condensation occurs on the convex mirror, thus preventing dew condensation from occurring.

Further, the optical sensor simultaneously energizes the heater on the mirror surface, and since the dew condensation on the mirror surface disappears, the energization of both heaters can be stopped. It is possible to minimize the required capacity of the battery. Since the heater on the mirror surface has the same performance as the heater for preventing the dew condensation on the convex mirror, when the dew condensation on the mirror surface disappears due to the former, the dew condensation on the convex mirror surely disappears. This is because it can be stopped.

When a plurality of sets of optical sensors are provided, each optical sensor detects the presence or absence of dew condensation at different detection points on the mirror surface. Therefore, when all of them detect dew condensation, the heater for preventing dew condensation on the convex mirror is energized, but when only part of them detects dew condensation, it is determined that it is a raindrop and the heater is not energized. It is possible to clearly distinguish between harmful dew condensation and harmless raindrops. In general, water droplets due to dew condensation become fine particles that uniformly adhere to a wide area of the mirror surface and are simultaneously detected by all optical sensors, but raindrops do not uniformly adhere to the mirror surface. , Because not all optical sensors are activated at the same time.

According to the structure of the second aspect of the invention, the dew condensation sensor can energize the dew condensation preventing heater before dew condensation occurs on the convex mirror, so that it is possible to surely prevent dew condensation on the convex mirror. Can be prevented.

[0014]

Embodiments Embodiments will be described below with reference to the drawings.

The curve mirror with a dew condensation preventing function is formed by combining the convex mirror 11 forming the curve mirror body 10, the dew condensation sensor 20 for the curve mirror, the solar battery PC and the battery B (FIG. 1).

The curve mirror main body 10 has a convex mirror 11 mounted on a pole (not shown).
A heater 11a for preventing dew condensation is attached. The heater 11a is mounted on the back side of the convex mirror 11 and is covered with a suitable heat insulating material. The heater 11a is assumed to generate heat almost uniformly with respect to the front surface of the convex mirror 11, and the heat generation capacity per unit area thereof may be 100 W / m ² or less at most, and practically several tens W / m.
^{2 is} enough.

The dew condensation sensor 20 mainly comprises a mirror surface 21 and an optical sensor 22 (FIGS. 1 and 2). Mirror surface 21
Is installed so as to be exposed to the outside while being inclined from the vertical plane V by an inclination angle θ via an appropriate supporting member 20a. The inclination angle θ is appropriately determined within the range of 10 to 50 degrees. In addition, the mirror surface 21 is
The tilt angle θ is preferably adjustable so that the tilt angle θ can be set at an arbitrary tilt angle θ. A heater 21a is attached to the mirror surface 21, and the thermal performance of the heater 21a is set to be the same as that of the heater 11a for preventing dew condensation of the convex mirror 11.

The optical sensor 22 is formed by integrally assembling a small-sized light emitting element and a light receiving element, can project light toward the mirror surface 21, and can receive reflected light from the mirror surface 21. The optical sensor 22 is a printed circuit board 3 on which the control circuit 32 is mounted.
2a is mounted on the printed circuit board 32a,
It is incorporated in the case 20b. The optical sensor 22
Faces the mirror surface 21 at a right angle, and the optical sensor 2
A protective cylinder 23 is provided around the periphery of the device 2 to block external light. In addition, the mirror surface 21 to which the optical sensor 22 is directed
It is assumed that the upper detection point A is located above the auxiliary line X pulled down by 45 degrees from the apex of the case 20b so that dew condensation does not easily occur at the detection point A under the influence of the case 20b.

The solar cell PC and the battery B are connected to the charge / discharge controller 31. The output of the charge / discharge controller 31 is output to the convex mirror 11 via the control circuit 32.
Heater 11a for preventing dew condensation on the surface, and heater 21a for the mirror surface 21
The output of the optical sensor 22 is connected to the control circuit 32. The battery B and the charge / discharge controller 31 are housed in a common base 20c that supports the support member 20a and the case 20b.

The solar battery PC includes a charge / discharge controller 31.
The battery B is charged with the electric power generated by the sunlight. Further, the battery B includes a charge / discharge controller 31,
Electric power can be supplied to the heaters 11a and 21a through the control circuit 32. However, the control circuit 32 uses the condensation sensor 2
It is assumed that the optical sensor 22 is opened and closed according to the output of the optical sensor 22 of 0. Therefore, the optical sensor 22 can control the energization of the heaters 11a and 21a via the control circuit 32.

The optical sensor 22 receives the reflected light from the mirror surface 21 when there is no dew condensation on the mirror surface 21, and the control circuit 32.
open. That is, the control circuit 32 shuts off the circuit from the battery B to the heaters 11a and 21a,
The power supply to a and 21a is cut off.

When the temperature drops and dew condensation occurs on the surface of the mirror surface 21, the level of the reflected light received by the optical sensor 22 decreases, and the optical sensor 22 closes the control circuit 32 and the heater 11 is closed.
The energization of a and 21a is started. Here, while the convex mirror 11 of the curved mirror body 11 is installed in the vertical direction, the mirror surface 21 is installed at an angle of inclination θ from the vertical plane V, so that the mirror surface 21 is more than the convex mirror 11. , Condensation occurs quickly in time. That is, when the optical sensor 22 starts energizing the heaters 11a and 21a, the mirror surface 21
Condensation occurs on the convex mirror 11, but no condensation occurs on the convex mirror 11. Therefore, the optical sensor 22 can prevent the dew condensation on the convex mirror 11 by energizing the heater 11a prior to the dew condensation on the convex mirror 11. When the heater 21a is energized and the dew condensation on the mirror surface 21 disappears, the optical sensor 22 opens the control circuit 22 to stop energizing the heaters 11a and 21a.
After that, the same operation is repeated.

Generally, a mirror surface 21, which is installed outdoors,
The reason why dew condensation occurs on the convex mirror 11 is that the temperature drops and the water vapor in the atmosphere condenses into fine water drops. Therefore, the mirror surface 21 that is installed to be inclined from the vertical surface V is more likely to receive a falling water droplet and is more likely to cause dew condensation than the convex mirror 11 that is installed vertically. On the other hand, when the decrease of the temperature is stopped, no new water droplets are generated in the atmosphere, and the mirror surface 21 and the convex mirror 11 do not generate new dew condensation, however low the temperature itself at that time is.
That is, when the temperature of the convex mirror 11 starts to decrease,
If the heater 11a is energized prior to dew condensation to prevent dew condensation from occurring, then even if the heater 11a is de-energized, there is no risk of new dew condensation unless a new temperature drop occurs. Absent. Therefore, this system detects dew condensation on the mirror surface 21 through the optical sensor 22 to effectively prevent the dew condensation on the convex mirror 11 while minimizing the energization time to the heaters 11a and 21a. You can

In the above description, the dew condensation sensor 20 is
It may be formed in any other mechanical structure other than that shown in FIG. For example, the optical sensor 22 is formed integrally with the mirror surface 21, and includes the charge / discharge circuit 31, the control circuit 32, and the battery B.
May be completely separate from the optical sensor 22 and the mirror surface 21. Further, the inclination angle θ of the mirror surface 21 is determined by the mirror surface 21 and the convex mirror 1
Since it is related to the timing when dew condensation occurs on No. 1, the former may be arbitrarily set so that the time difference preceding the latter becomes optimal.

Further, the control circuit 32 may add an appropriate time delay element. The control circuit 32 at this time immediately starts energizing the heaters 11a and 21a when the optical sensor 22 detects dew condensation on the mirror surface 21, but the optical sensor 2
When 2 detects the disappearance of the dew condensation on the mirror surface 21, the heaters 11a and 21a are activated after a suitable delay.

[0026]

Other Embodiments The optical sensor 22 of the dew condensation sensor 20 can be provided with a plurality of sets having different detection points Ai (i = 1, 2, ...) On the mirror surface 21 (FIG. 3). At this time,
Each sensor 22 may be of a type in which a light emitting element and a light receiving element are integrally assembled ((A) in the same figure), or a plurality of light receiving elements 22b and 22b are combined with a common light emitting element 22a. It may be (Fig. (B)).

At this time, the dew condensation sensor 20 energizes the heaters 11a and 21a through the control circuit 32 only when the level of the reflected light is lowered at all the different detection points Ai, and only a part of the detection points Ai is detected. When the level of the reflected light decreases, it is determined that the water droplets on the mirror surface 21 are not due to dew condensation but to raindrops, and the heater 1
It is possible to prevent wasteful energization of 1a and 21a. Unlike water droplets caused by dew condensation, raindrops do not adhere finely and uniformly on the mirror surface 21. Therefore, the level of reflected light from the detection point Ai decreases uniformly.
This is because there are very few stochastically.

It should be noted that, in FIG. 3, generally, the detection points Ai may be arbitrary two or more points separated by several tens of mm or more on the mirror surface 21, and even the minimum two points are sufficient. It is known to be practical. In addition, it is preferable that the mirror surface 21 at this time be easily wet with water so that raindrops are not finely dispersed and adhere to the mirror surface 21.

In each of the above embodiments, the convex mirror 11 of the curve mirror body 10 may be a general convex mirror, a plane mirror or a concave mirror, or a cylindrical mirror, depending on the installation location of the curve mirror body 10. May be.

[0030]

As described above, according to the first invention of this application, by combining the optical sensor with the mirror surface inclined from the vertical surface and exposed to the outside, the optical sensor is a curved mirror. The dew condensation on the mirror surface can be detected prior to the dew condensation on the convex mirror, and the disappearance of the dew condensation on the convex mirror can be detected by detecting the disappearance of the dew condensation on the mirror surface by energizing the heater on the mirror surface. Therefore, there is an excellent effect that the required capacity of the battery or the solar cell can be minimized. In addition, if a plurality of sets of optical sensors having different detection points are provided, it is possible to accurately distinguish harmful dew condensation on which minute water droplets adhere and large-sized harmless raindrops, which further improves the practicality. be able to.

According to the second aspect of the present invention, the convex mirror having a heater for preventing dew condensation, the battery, the solar cell, and the dew condensation sensor according to the first aspect of the present invention are combined to provide an independent power source system having excellent practicability. There is an effect that can be easily constructed.

[Brief description of drawings]

FIG. 1 is a block diagram of the overall configuration

FIG. 2 is an explanatory diagram of a main part configuration

FIG. 3 is an explanatory diagram of a main part configuration showing another embodiment.

[Explanation of symbols]

 B ... Battery PC ... Solar cell V ... Vertical plane A, Ai (i = 1, 2 ...) ... Detection point 10 ... Curve mirror body 11 ... Convex mirror 11a ... Heater 20 ... Dew condensation sensor 21 ... Mirror surface 21a ... Heater 22 ... Optical sensor 31 ... Charge / discharge controller

Claims (3)

[Claims] 1. A mirror surface, which is inclined from a vertical plane and is exposed to the outside, and an optical sensor for receiving light projected on the mirror surface, the mirror surface being for preventing dew condensation attached to a convex mirror of a curved mirror body. A dew condensation sensor for a curved mirror, which is equipped with a heater having the same performance as the heater of. 2. The dew condensation sensor for a curve mirror according to claim 1, wherein the optical sensor is provided with a plurality of sets having different detection points. 3. A convex mirror having a heater for preventing dew condensation,
Condensation comprising a battery for supplying power to the heater, a solar cell for charging the battery via a charge / discharge controller, and a dew sensor for a curve mirror according to claim 1 or 2 for controlling energization of the heater. Curved mirror with prevention function.