JPH10317330A - Reflecting mirror - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent dew condensation and frosting over a long period by holding a mirror surface plate with a back plate, inserting a radioactive material covered with a shield between the mirror plate and the back plate, and warming the mirror surface plate with the decay heat generated when the radioactive material decays. SOLUTION: The front surface of a mirror surface plate 1 made of a synthetic resin or a metal is formed into a mirror surface 11, and the front surface of the mirror surface plate 1 is polished to form a mirror surface layer with an acrylic resin. A back plate 2 for holding the mirror surface plate 1 is fitted to the back face of the mirror surface plate 1, and the back face side of the back plate 2 is fixed to a support metal 3 fitted to a stanchion 4 erected on a road surface. A radioactive material 5 covered with a shield 51 of lead to prevent the leakage of noxious radioactive rays to the outside is inserted between the mirror surface plate 1 and the back plate 2. The decay heat generated when the radioactive material 5 decays warms the mirror surface plate 1 through the shield 51. Uranium generates decay heat until it is finally stabilized, and dew condensation and frosting can be semipermanently prevented without requiring maintenance.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reflector having an anti-fog function, and more particularly, to a reflector suitably used as a road reflector installed on a road or the like.

[0002]

2. Description of the Related Art In general, at a corner of a road or a place where visibility is poor, a reflector having a mirror plate disposed on a front surface is installed in order to ensure the safety of traveling of a vehicle and pedestrians.
However, in the conventional reflecting mirror, dew condensation may occur on the mirror plate due to a sudden rise in temperature immediately after dawn, and the function of the reflecting mirror may be reduced. The same also occurs when the humidity and temperature in the atmosphere rise rapidly due to showers caused by passing through the warm front, and the function may be deteriorated regardless of the daytime or the four seasons. Further, in severe winter, its function is reduced by frost on the mirror surface plate.

[0003]

In order to prevent dew condensation and frost formation on the mirror plate as described above, the temperature of the mirror plate needs to be slightly raised from the surrounding air temperature. Conventionally, as energy to be used, electricity, solar heat, and geothermal energy are used.

Devices using electric energy use a commercial power source as a means for obtaining electric energy,
There are those that convert the light energy of sunlight into electric energy using solar cells and those that convert the kinetic energy of wind power into electric energy using a wind power generator.The electric energy obtained in this way is converted into heat energy. For conversion, a heating element arranged on the back side of the mirror plate is used.

In the case of using solar heat, a heat storage body is disposed on the back side of a mirror plate, and heat is stored in the heat storage body by heat transfer from daytime high temperature, and is stored in the heat storage body when the temperature decreases. Heat is transmitted to the mirror plate by heat conduction, and the mirror plate is heated.

[0006] In the case of using geothermal energy, a hole that goes deep into the ground is formed by boring, geothermal energy is collected by a heat pipe, and the collected heat is transferred to a mirror plate by convective or conductive heat transfer in the heat pipe. The mirror plate is warmed by the carried heat.

However, among those using electric energy, those using a commercial power supply require a running cost, and those using sunlight cannot generate electricity if bad weather continues, and require a power storage device. For this reason, periodic replacement or maintenance of the power storage device is required, and those using wind power have a problem in that the movable part is worn and maintenance is also required.

[0008] In addition, solar heat is vulnerable to inclement weather, and the heat storage body itself is cooled when low-temperature days such as continuous winter days continue, so that the temperature of the mirror plate is kept low even when the temperature rises. There is a problem that causes an adverse effect.

Further, those utilizing geothermal heat require drilling, which causes a problem of high installation cost.

Therefore, the present invention does not provide a reflecting mirror which solves the above-mentioned problems, does not require external energy, warms the mirror plate for a long time without maintenance, and can prevent dew condensation and frost formation. It is assumed that.

[0011]

In order to achieve the above object, the present invention has the following arrangement. That is, the reflecting mirror according to the present invention, the back plate holding the mirror plate is attached to the back surface of the mirror plate, the radioactive material covered by the shield between the mirror plate and the back plate is installed, the collapse of the radioactive material It is characterized in that the mirror plate is warmed by the decay heat generated at that time.

According to the present invention, a radioactive material covered with a shield is provided between the mirror plate and the back plate, and the mirror plate is heated by decay heat generated when the radioactive material collapses. As a result, there is no running cost and no maintenance is required because there are no moving parts, and the mirror surface plate is semi-permanently warmed regardless of the weather and season, preventing condensation and frost formation.

[0013]

Next, an embodiment of the present invention will be specifically described with reference to the drawings. FIG. 1 is a sectional view showing an embodiment of the reflecting mirror of the present invention.

In the drawings, reference numeral 1 denotes a mirror plate disposed on the front surface, which is made of synthetic resin, metal, or the like, and the front surface of the mirror plate 1 has a mirror surface 11. The mirror surface 11 may be formed by mirror-polishing the front surface of the mirror plate 1,
A mirror surface layer made of acrylic resin, glass, stainless steel, or the like may be formed on the front surface of the mirror plate 1, and is not particularly limited.

Reference numeral 2 denotes a back plate made of synthetic resin, metal, or the like, and is attached to the back surface of the mirror plate 1 so as to hold the mirror plate 1. A support fitting 3 is usually attached to the back side of the back plate 2, and the support fitting 3 is attached to a support column 4 erected on a road surface or the like.

Reference numeral 5 denotes a radioactive substance covered with a shield 51 such as lead so as to prevent radiation harmful to the human body from leaking outside.
It is provided between the mirror plate 1 and the back plate 2. The radioactive substance 5 generates decay heat at the time of decay, and the decay heat is transmitted to the mirror plate 1 through the shield 51, so that the mirror plate 1 is warmed. The radioactive substance 5 is generally uranium 238, uranium 235, uranium 23
4, uranium 233, plutonium 239, etc. are used.

For example, uranium 238 repeats α-decay and β-decay, and eventually becomes radium and becomes stable. During this period, even without supplying external energy, decay heat accompanying the decay continues to be generated, and its half-life is 4.47 × 10 ⁹
The heat is generated almost semi-permanently for a year.

The half life of uranium 235 is 7.04 × 1.
0 ⁸ years, uranium 234 is 2.45 × 10 ⁵ years, uranium 2
33 is 1.62 × 10 ⁵ years, plutonium 239 is 2.
It is 44 × 10 ⁴ years, and all continue to generate heat almost semi-permanently.

[0019]

As described above in detail, the reflecting mirror of the present invention has a radioactive material covered with a shield between a mirror plate and a back plate, and is provided by a decay heat generated when the radioactive material decays. Because the face plate is warmed, there is no running cost, and there are no moving parts, so no maintenance is required.The mirror face plate is semi-permanently warmed regardless of the weather and season, and condensation and frost are formed. Is prevented.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view showing one embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Mirror surface plate 11 Mirror surface 2 Back plate 3 Support bracket 4 Support post 5 Radioactive material 51 Shield

Claims (1)

[Claims] 1. A back plate for holding a mirror plate is attached to the back surface of a mirror plate, and a radioactive material covered with a shield is provided between the mirror plate and the back plate, which is generated when the radioactive material collapses. A reflecting mirror characterized in that the mirror surface plate is heated by decay heat.