SU1534420A1 - Arrangement for fixing a slide - Google Patents

Abstract

The invention relates to photographic technology and allows to simplify the design and increase the reliability of the device for fastening the slide. The surface of the first frame 1 along the perimeter of the personnel window is corrugated, and in the corners of the frame 1 pins 3 are fixed with protrusions 5 with the possibility of their placement in the holes of the second frame with a gap. The slit film 4 is placed between the frames 1, 2, with the holes 6 of the perforations located on the tops of the corrugations 7, and the pins enter the holes 6 of the perforations. The elastic forces of the corrugation 7 provide tension for the diapolotive 4, while the displacement of the edges of the corrugation 7 under the action of the elastic forces P _y exceeds the linear expansion of the transparency when heated, which leads to optimal compensation for the increase in the linear dimensions of the transparency. 1 hp f-ly, 4 ill.

Description

The invention relates to a photo kinotekhnika, namely to projection equipment.

The aim of the invention is to simplify the construction and increase reliability.

FIG. 1 and 2 show the first and second frames of the attachment device, respectively; in fig. 3, view A in FIG. in fig. k is a section element of a corrugated surface.

The device contains the first 1. and second 2 frames with frame windows a. The corners of the first frame 1 are fixed with pins 3 for fixing the slide through the perforation holes b, as well as fixing both frames 1 and 2 with the help of protrusions 5 and holes 6 made in the second frame 2, with the holes being made The pins 3 are placed in them with a gap and move in the direction of the action of elastic forces (Fig. 3).

In order for the pins 2 not to get out of engagement with the second frame 2 from the opening 6, the protrusions 5 must be larger than they can be moved by the action of elastic forces with a linear expansion of the slide. The side of frame 1 (Fig. 3) is in prestressing P ,. providing a guaranteed sample of the gap in the pin-perforation joint and the tension of the slide over its entire area to eliminate its distortion during storage and during charging, as well as reducing the deflection during projection and sharpening across the screen image field.

The surface of frame 1 along the length of the sides of the personnel window a (Fig. 1) is corrugated in the perpendicular direction. Since the slide C has perforations b, symmetrically located along its edges, this reduces its rigidity in these areas, which can lead to deflection in these areas of the dia- positive. Therefore, the tops of the corrugations 7 (Fig. 4) are located along the perforation holes b and thereby fix the transparency b at the points critical to the deflection, and the distance between adjacent vertices of the corrugation is equal to the punch perforation.

The elastic forces of the corrugation 7 are determined at the places of its bending, i.e. at

the vertices of the corrugation 7. It is necessary that, whenever possible, there should be a maximum vector of these forces, directed along the surface of the transparency and determining the elastic forces (expansion, Ru). If we consider the vector of these forces within the triangle formed by one link of the corrugation 7 (Fig. A), then it increases significantly if the angle at the top of the corrugation exceeds 90 °, and the more the angle increases, the greater the horizontal component of the forces slide surface. However, an increase in the angle at the apex to 180 ° is impossible, since in this case the corrugation will not be able to expand (the corrugation will be in the form of a plane) and with an increase in the linear dimensions of the transparency as a result of the heating, the elastic force will be absent. The optimum corners at the top of the corrugation (90-1 O0) With these limits of the angle, the relative position of the vertices of the corrugation 7 and the perforations is ensured, since with a linear expansion of the slide k (increasing the pitch of the perforations), the corrugation 7 and its tops also proportionally displaced, t. e, the distance between the tops of the corrugations also increases. A possible slight lag in the displacement of the vertices of the corrugation 7 from the movement of the perforations b, since the perforations b have finite dimensions (about 2 mm), practically does not affect the operation of the device, i.e. the tops of the corrugations 7 are still within the perforations b. In order to optimally compensate for the increase in the linear dimensions of the slide, due to its heating by radiant energy during projection, it is necessary that the relative displacement X of the edges of the corrugation under the action of the elastic forces F. exceeds the value of the linear expansion of the transparency when it is heated.

F ..

 Ve 1.

- elastic force of the corrugated half of the frame;

- coefficient of elasticity of the corrugation frame;

- temperature coefficient of linear expansion of the emulsion layer of the slide;

t is the heating temperature of the slide at the projection; 1 - linear dimensions of the slide.

Fulfillment of this condition will allow the slide of the slide to be tensioned by the elastic forces of the corrugation even with an increase in its linear dimensions during projection under the influence of radiant energy, as well as to correct the slide due to its distortion during hryne. Thus, a significant decrease in the deflection of the slide during projection is provided, and the sharpness of the screen image is enhanced. The corrugated frame 1 can be made of an elastic material (for example, rubber), and the sides of the corrugation 7 can be made of thin plates (for example, plastic) pasted on the elastic base of the frame 1.

The device works as follows.

Corrugated frame 1 is slightly compressed around the perimeter, for example, by pressing the fingers of his left hand on the sides of the frame inside. Then, on the pins 3 with the right hand, with the base of the film, the corrugations 7 are placed with perforations b of the transparency and are latched with the help of pins 3 between frames 1 and 2. The transparency 4 is thus straightened, i.e. its warping due to storage and residual temperature distortion is excluded. Frames 1 and 2 with a slide are placed in the film channel of the pidppector, the light source is switched on, and a projection is in progress. Since the emulsion layer of the slide located from the screen through the thickness of the film is mainly heated by radiant energy due to the greater absorption of radiation than the base film, the slide tends to penetrate the screen. However, the elastic forces of the corrugation 7 provide tension on the slide, and this tension acts from the base of the slide 4, since the slide is laid on the base of the corrugation, i.e. on the opposite side of the emulsion layer (mainly heated). The slit film not only stretches along the length, width, but also straightens under the action of forces directed on the other side of the thickness

five

10 15

to d5 50 55 206

slide 4. The action of the elastic forces in the direction of the length and width of the slide provides ultimately a sharpening across the field of the screen image.

Since the relative displacement of the edges of the corrugation / under the action of elastic forces (in case there is no transparency on the clamps of the corrugated half limiting the maximum displacement of the edges of the corrugation) exceeds the linear expansion of the transparency when heated, the optimum increase in the linear dimensions of the slide is effected, i.e. even with significant heating of the slide (as a result of prolonged exposure to radiant energy, which

20 usually happens at a projection),

the elasticity reserve of the corrugation 7 will be sufficient. The holes b for fixing the pins 3 in the second frame 2 have the ability to provide movement

25 pins 3 in the direction of the elastic forces of the corrugated frame 1, i.e. along the length and width of the slide. Since the landing distance between the pins 3 is greater than the corresponding distance between the perforations b, the transparency is straightened at the beginning from warping, and then, in the process of prolonged exposure to radiant energy, it compensates22 for the temperature distortion of the slide.

Claims (2)

1. A device for fastening a slide, containing two frames with personnel windows, one of which has pins fixed, and another frame has holes for placing pins, characterized in that, in order to simplify the design and increase reliability, the surface of the first frame The perimeter of the personnel window is made perpendicular to the sides of the personnel window and with a corner at the top of each corrugation within, and the distance between adjacent vertices of the corrugation is equal to the punch perforation step of the transparency, and on the pins There are protrusions for placement in the perforations of the slide, with the pins located in the corners of the frame and installed so that they can be placed in the holes of the second frame with a gap. 7153I20 2. The device according to claim 1, characterized in that the corrugated surface of the first frame is made in a form of an elastic base, on which successive plates are glued. view BUT Fig.Z FIG. g $ Lerforho Perforations 6 Figm