JPH07209588A - Reflection type astronomical telescope - Google Patents

Abstract

PURPOSE:To provide the new reflection type astronomical telescope which is extremely small in the heat conductivity of its lens barrel, lightweight, and actualized at low cost. CONSTITUTION:At least the main mirror 10 of a reflector is a lightweight reflector constituted by integrally forming a thin glass layer 12 on the surface of foamed glass 11 whose top surface side is concave so that the surface is in a specific concave surface shape and also forming a reflecting mirror 13 on the top surface of the glass layer 12; and the lens barrel 20 is formed in structure obtained by laminating and caking a prepreg of aramid fiber fabric and has a >=130mm effective diameter.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION This invention is a "reflective astronomical telescope".
Regarding

[0002]

2. Description of the Related Art Astronomical observation conditions have deteriorated in urban areas due to nighttime lighting and air pollution, and it has become common to leave the urban areas for better observation. In such a case, an observer living in an urban area would bring an astronomical telescope to the observation site and set it up. However, a more or less specialized observation is possible. Effective diameter: 130 m
Astronomical telescopes of m or more are extremely heavy, including several tripods, mounts, and other installation tools, which weighs several tens of kilograms, and is therefore troublesome to handle during transportation and setting. Moreover, in the daytime astronomical observation, when the temperature of the lens barrel rises, an unstable flow of air occurs in the lens barrel, which hinders the observation.

The weight of the astronomical telescope main body is dominated by the weight of the reflecting mirror and the weight of the lens barrel, and attempts have been made to reduce these weights. For example, as a lighter weight reflector, there has been proposed one in which the substrate portion occupying most of the volume of the reflector is made of silicon oxide porous foam (Japanese Patent Laid-Open No. 4-353802). ). In addition, a lens barrel made of a special reinforced carbon fiber is known as a lens barrel whose weight is reduced (Japanese Patent Laid-Open No. 4-303627).

Therefore, it is possible to expect an astronomical telescope that effectively reduces the weight by combining the lightweight reflecting mirror and the lens barrel as described above.

However, the reinforced carbon fiber for the lens barrel is a special one having a thermal conductivity of 0.1 W / m · K or less and is expensive, so that there is a problem that the cost of the astronomical telescope becomes high.

Although it is conceivable that the lens barrel is made of a general carbon fiber reinforced composite material, the thermal conductivity of carbon fiber varies depending on the difference in elastic modulus.
From 5W / mK (W / mC), the larger one is 1
There are some that exceed 00 W / mK (W / mC).
When observing for a long time during the daytime, there is also a problem that the above-mentioned "unstable air flow" is likely to occur in the lens barrel.

[0007]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned circumstances, and a novel lens barrel having a very small thermal conductivity, a light weight, and a low cost can be realized. The purpose is to provide a reflective astronomical telescope.

[0008]

The "reflection type astronomical telescope" of the present invention has an effective diameter of 130 mm or more, and at least the main mirror of the reflection mirrors is composed of the "light weight reflection mirror". 1, 2). The invention according to claim 1 is characterized in that the lens barrel has a "laminated structure of prepreg of aramid fiber fabric", that is, a structure in which prepregs of aramid fiber fabric are laminated and cured.

According to a second aspect of the present invention, the lens barrel has an "alternate laminated structure of prepreg of aramid fiber woven fabric and prepreg of carbon fiber woven fabric", that is, prepreg of aramid fiber woven fabric and prepreg of carbon fiber woven fabric. Stacked alternately,
It is characterized in that it is composed of a cured structure.

The above-mentioned lightweight reflecting mirror is "a thin glass layer is integrally formed on the surface of bubble-containing glass having a concave surface side so that the surface has a predetermined concave shape. A reflecting mirror formed by forming a reflecting film on the surface thereof. Specifically, the reflecting mirror disclosed in the above-mentioned JP-A-4-353802 can be appropriately used.

The prepreg of the above aramid fiber woven fabric is
An aramid fiber known by "commercial name: Kevlar (Dupont, USA)" is used as a warp and a weft, and is formed into a woven fabric, which has flexibility and is cured at a temperature of 120 to 150 ° C. It becomes a solid solid. Therefore, if a plurality of prepregs of aramid fiber woven fabric are stacked to form a lens barrel shape and heated to the above temperature, a strong lens barrel can be realized.
The number of laminated prepregs of the aramid fiber woven fabric may be determined in consideration of the strength required for the lens barrel and the heat insulating property.

As the prepreg of the carbon fiber woven fabric, a prepreg made of an ordinary carbon fiber woven fabric can be used.

Further, in the invention according to claims 1 and 2, a "supporting member" for supporting the main mirror and attaching it to the lens barrel.
“A rib structure formed by laminating prepregs of aramid fiber woven fabric, molding and curing”
Alternatively, it may be "having a rib structure formed by alternately laminating prepreg of aramid fiber fabric and prepreg of carbon fiber fabric, molding and curing" (claim 3), or " It may have a rib structure made of aluminum ”(claim 4).

[0014]

As described above, the reflective astronomical telescope of the present invention has an effective diameter of 130 mm or more. Broadly speaking,
The weight of the reflecting mirror is proportional to "the square of the effective diameter", and the weight of the lens barrel is proportional to the effective diameter. Therefore, as the effective diameter gradually increases from the small diameter, the weight of the telescope itself increases remarkably from a certain aperture. In an astronomical telescope having an effective diameter smaller than 130 mm, the effect of weight reduction by the configuration of the present invention is not so remarkable, and in a telescope having such a small effective diameter, there is little need to intentionally reduce the weight.

Laminating prepregs of aramid fiber woven fabric,
The so-called "aramid fiber reinforced composite material" formed by curing has a coefficient of thermal expansion in the "pavement" direction,
It is as small as 2-3 × 10 ⁶ / K (10 ⁶ / degree C), and therefore expansion and contraction of the lens barrel due to temperature change is effectively prevented.

The thermal conductivity of the aramid fiber reinforced composite material is 0.7 to 0.9 W / m · k in the “through layer” direction.
Which is 40-50% smaller than carbon fiber reinforced composites with low modulus carbon fiber fabrics. Therefore, the lens barrel made of the aramid fiber reinforced composite material can effectively prevent the influence of the external temperature inside the lens barrel.

According to the second aspect of the invention, the lens barrel constituted by alternately laminating the prepreg of the aramid fiber woven fabric and the prepreg of the carbon fiber woven fabric and curing the prepreg is extremely low in the carbon fiber reinforced composite material. It is possible to have both the thermal expansion property and the high heat insulating property of the aramid fiber reinforced composite material.

Since the astronomical telescope of the present invention uses at least the above-mentioned "light weight reflecting mirror" as the main mirror, the "supporting member" for supporting the main mirror and attaching it to the lens barrel does not require so much strength. According to the invention as set forth in claim 3, as the supporting member, a lightweight "having a rib structure of an aramid fiber-reinforced composite material" or "a prepreg of an aramid fiber woven fabric and a prepreg of a carbon fiber woven fabric are alternately laminated. It is also possible to use "a rib structure formed by molding and curing" (claim 3) or "a rib structure made of aluminum" (claim 4).

[0019]

EXAMPLES Specific examples will be described below. Figure 1
1 shows an embodiment of the present invention. This embodiment is an example in which the inventions of claims 1 and 4 are applied to a "Newton-type reflective astronomical telescope". Reference numeral 10 indicates a "primary mirror",
Reference numeral 20 indicates a "lens barrel", reference numeral 30 indicates a "oblique mirror", and reference numeral 40 indicates a main mirror rim which is a "support member".

The oblique mirror 30 is, of course, supported at a predetermined position in the lens barrel 20 by a known supporting means (not shown).

The main mirror 10 is the above-mentioned "light weight reflecting mirror", and as shown in FIG. 2, a thin glass layer 12 is formed on the surface of a bubble-containing glass 11 having a concave surface side, and a predetermined surface. It is formed integrally so as to have a surface shape, and a reflection film 13 is formed by vapor deposition on the surface of the glass layer 12.

The production of such a lightweight reflecting mirror is specifically described in the above-mentioned Japanese Patent Laid-Open Nos. 4-353802 and 5-5.
It can be realized by the method disclosed in detail in JP-60909.

In this embodiment, the primary mirror 1 is as follows.
0 was created. First, about 14 ppm of silicon dioxide powder containing about 200 ppm of hydroxyl groups and having a particle size of 50 μm or less is used.
Using a mold having the shape of the bubble-containing glass 11 at a temperature of 00 ° C., a sintered body was obtained by “molding and sintering”.
After heating reaction in an ammonia atmosphere at a temperature of 0 ° C. to “ammonia”, further heating in a reduced pressure atmosphere at a temperature of 1600 ° C. for 3 hours to cause fusion and foaming by a desorbing gas, Foamed glass 11 was obtained.

Subsequently, in the concave portion of the surface of the bubble-containing glass 11, thin, bubble-free quartz glass previously formed in the concave shape is melted on the surface of the bubble-containing glass 11 at a temperature of 1600 ° C. The glass layer 12 was made to be integrated by being attached. Aluminum was vapor-deposited on the surface of the glass layer 12 to form a reflective film 13.

The primary mirror 10 thus obtained is so light that it floats on water (specific gravity: 1 or less).

The lens barrel 20 has four prepregs made of aramid fiber woven fabric and having a thickness of 0.25 mm on the peripheral surface of a cylindrical mold.
It was laminated in layers, cured and molded, and then decoreed to form a molded product having a thickness of about 1 mm. The length of the lens barrel 20 is 600 mm.

The "front rim" designated by the reference numeral 201 is obtained by laminating 20 layers of prepreg of aramid fiber woven fabric having a thickness of 0.25 mm, curing and molding, and then decoreing.
Formed as a molded product with a thickness of about 5 mm and a width of 20 mm,
The lens barrel 20 was fitted and fixed in the opening on the front end side.

The supporting member 40 that supports the main mirror 10 and is attached to the lens barrel 20 is formed of aluminum to have a "rib structure" as shown in FIG.

A reflective astronomical telescope as shown in FIG. 1 was produced with an effective diameter of 300 mm. As a result, the weight of the main body of the telescope is 6 times that of the case where the glass main mirror, the aluminum lens barrel and the iron support member are used (weight: 45 kg).
It was possible to reduce the weight by about 0%.

As another embodiment, two layers of a prepreg (thickness: 0.2 mm) made of a carbon fiber woven fabric having a low elastic modulus and a prepreg (thickness: 0.25 mm) made of an aramid fiber woven fabric are alternately laminated to obtain a thickness. A similar weight saving effect was obtained by replacing the lens barrel having a diameter of about 1 mm with the lens barrel in the above-mentioned embodiment.

In each of the above embodiments, the prepreg is
The “warp direction” was used by being substantially parallel to the axial direction of the lens barrel. In any of the above-mentioned two examples, there was no deviation of the optical axis due to thermal expansion of the lens barrel, and no unstable air flow was generated in the lens barrel even when observed for a long time during the day.

The support member attached to the lens barrel 20 is
Laminated prepreg of aramid fiber woven fabric, having a rib structure formed by molding and curing, or prepreg of aramid fiber woven fabric and prepreg of carbon fiber woven fabric are alternately laminated, molded and cured. It can also be implemented as a rib structure formed by the above (claim 3).

Although the present invention is applied to the Newton type reflection astronomical telescope in the above embodiment, the present invention is not limited to the type of the embodiment, and a known appropriate reflection astronomical telescope, for example, Makstow type. , Cassegrain type, Schmidt-Cassegrain type, Dilworth type, etc.

[0034]

As described above, according to the present invention, a novel reflective astronomical telescope can be provided. Since the reflective astronomical telescope of the present invention has the above-mentioned configuration,
The telescope body can be configured to be extremely lightweight, and as the weight is reduced, it is possible to use a lightweight pedestal or tripod that supports the telescope body, which facilitates handling during transportation and setting.

Further, since the main mirror is lightened, there is almost no distortion due to the weight of the main mirror, and good imaging performance can be secured. The thermal expansion coefficient of the lens barrel is extremely small, and the thermal conductivity is extremely low. Virtually no air flow is generated. Therefore, good observation can be performed.

[Brief description of drawings]

FIG. 1 is a diagram for explaining one embodiment of the present invention.

FIG. 2 is a diagram for explaining a primary mirror 10 in the above embodiment.

FIG. 3 is a perspective view showing a support member 40 in the above embodiment.

[Explanation of symbols]

 10 primary mirror 20 lens barrel 30 oblique mirror 40 support member

Claims (4)

[Claims] 1. At least a main mirror of the reflecting mirrors is formed by integrally forming a thin glass layer on a surface of bubble-containing glass having a concave surface side so that the surface has a predetermined concave shape. , A lightweight reflecting mirror formed by forming a reflecting film on the surface of the glass layer, characterized in that the lens barrel is formed by laminating a prepreg of an aramid fiber woven fabric and curing it. A reflective astronomical telescope with a diameter of 130 mm or more. 2. A thin glass layer is integrally formed on a surface of bubble-containing glass having a concave surface side so that at least a main mirror of the reflecting mirrors has a predetermined concave shape. , A lightweight reflecting mirror formed by forming a reflecting film on the surface of the glass layer, wherein the lens barrel is formed by alternately laminating an aramid fiber woven prepreg and a carbon fiber woven prepreg and curing the prepreg. The effective diameter is 130m.
Reflective astronomical telescope of m or more. 3. The reflection type astronomical telescope according to claim 1, wherein the supporting member for supporting the main mirror and attached to the lens barrel is formed by laminating prepregs of aramid fiber woven fabric, molding and curing. A reflection structure characterized by a rib structure formed by alternately forming a aramid fiber woven prepreg and a carbon fiber woven prepreg by alternately laminating, molding and curing. Astronomical telescope. 4. The reflection type astronomical telescope according to claim 1 or 2, wherein the supporting member for supporting the main mirror and attached to the lens barrel has a rib structure made of aluminum. .