DE1572760C - Variable resistance for photo-electric light meters of cameras - Google Patents

Description

1 ■ ■ ■■■. '■ /. 2

The invention relates to a variable counter Fig. 6 to. 8 show further embodiments

was for use in photoelectric beech- a strip-shaped variable resistor measurement meters for cameras. according to the invention, Fig. 6 and 7 plan

So far it has been customary to have a conductive body and sift them, while F i g. 8 is a side view. to connect a resistance element together, 5 Fig. 1 shows a circuit for the photoelectric; and an exposure value can be seen by the change in light meters for cameras, at which B - ^{v is} the distance from the connecting part of the conductive battery, C the conductor, D a photo resistor to the body and the resistance element to one for receiving the light rays, M A galvanic movable brush can be measured that slides along the meter, R the variable resistance to indicate the surface of the resistance. If the exposure value is io and Rg is a fixed resistor for such a known arrangement, the galvanometer changes. . . '

Resistance values within the measuring range almost Fig. 2 shows a variable resistance R

linear, so that the pointer of the galvanometer is accurate for use in the circuit of FIG. 1 of shows the correct exposure values, while in the known manner.

Proximity of the junction of the conductive body 15 In Fig. 2, C denotes the conductive body to and the resistance element expands following connection at point P for the variable reasons given, deviations from the resistance R; Bp and Br are movable brushes, linearity occur. their distance from each other during their movement

The object of the invention is therefore to create immutable, and / is an insulator between a resistor, in which the connection ao the conductive body and the resistance element or the interface between the conductive at the lowest light value, which is represented by the number 2 from body and the resistance element is pressed so formed. The width and the length of the insulator / is that the movable connection or the movable ones are larger and longer than the corresponding Abliche brush at the same time and parallel contact measurements of the brushes. Numbers 2 to 18 indicated in Fig. 2 with the conductive body and the conductive body are light values, around the light value the resistance has before the brush shows the measuring range of conventional cameras, bonding limit of the conductive body and the if For example, the movable brush Br reaches resistance elements. at the in F i g. 2 is located

The invention is based on a variable resistance value obtained on this, the light resistance for photoelectric exposure meters, 30 value 16. The resistance values and the corresponding ones, consisting of a conductive body and one of the light values, are resistance elements in the graph, between which a ver Fig. 3 shown. As can be seen from FIG. 3, there is a connection and a movable connection, in the case of the operation shown in FIG within the measuring range, however, indicates that part of one end of the body which conducts the resistance value continuously along a curve to zero immediately with part of the end of the resistance element, as is connected on the left-hand side of the graphic diagram, is the position of FIG . 3 shown. In other words, on and the remaining part of the conductive body extends on the outside of the measuring area in the vicinity of the allele to the resistance element up to a point of the maximum light value, ie at the connection point P , which is the end of the desired measuring area of the conductive Body and the resistance element, and that an insulator between which the resistance value decreases non-linearly to zero, parallel extending part of the conductive body and so that the display of the pointer of the galvanometer the corresponding part of the resistance element at this part does not use the correct exposure value so that the movable terminal is shown at 45. Furthermore, in this part the pointer is still moving, the conductive body and the resistive element of the galvanometer, so that if none is in contact at the same time before the terminal is delivered the signal indicating that the end of the connection is reached, the pointer is out of range is located for the

The known state of the art and some excerpts. User is at risk of getting this one correct Forms of execution of the invention result from the «50 actuation of the pointer, so that it assumes a The following description is used in connection with the incorrect display value. In the vicinity of the Drawing, namely shows ■ ■ 'the lowest light value 2 is the isolator /,

Fig. 1 shows a known circuit for a photographic so that when the movable brush Br is equipped with the electric light meter, which comes into contact with an insulator / having a greater width variable resistor, 55 and length than the brush Br has the resistance

F i g. Figure 2 is a top view of a variable value suddenly increasing to infinity. Resistance of a known type, as mentioned, shows with the known changeable

Fig. 3 is a graphical representation of measured borrowings. Resistance on the low cons-v side Resistance values above the light values under the understanding of the pointer still a certain application of the variable resistance after 60 resistance value when the brush is over the Fig. 2, measuring range moved out so that the user in

F i g. Figure 4 is a top plan view of an embodiment which, if mislead, is still a Invention, in which the variable resistance light measurement from a range of the measuring range is annular. accepts. Conversely, increases on the side of the high

5 shows a graphical representation of measured resistance, the resistance value suddenly changing to non-resistance values above the light values below Verfinite when the brush is over the place of the application of the variable resistance after light value 2 moved out. The resistance value F i g. 4, and is not reduced to zero until the

Brush in contact with the conductive body comes.

According to a further development of the invention: the arrangement can be made so that when the movable brush moves to a point immediately outside the point of maximum resistance, e.g. B. LV 2, moves, the resistance value suddenly decreases to zero, with the result that the user can rely on the display · of the pointer of the galvanometer even with low light values.

In Fig. 4 shows an embodiment of the invention in the form of a ring. One end of each of the conductor C and the resistance element R ' are connected to one another in such a way that they are partially parallel to one another, the insulator I _{1 being located} between these two ends. As shown in Fig. 4, in the vicinity of the junction P, a part of the end of the conductive body is connected to a part of the end of the resistance element a », and the remaining part of the end of the conductive body is extended to a point which is approximately coincides with the first measuring point, for example with the light value 18, of the resistance element, so that at this extension point the movable brush Br comes into contact with both the conductive body and the resistance element at the same time. The width of the insulator I ₁ at the part of the light value 18 is wider than the width of the brush Br, so that when the brush comes into contact with this part of the insulator I ₁ , the brush only contacts the resistance element and the pointer the correct one Value for the light value 18 displays. When the brush seen in FIG. 4, moved further to the left, it also comes into contact with the conductive body, so that the resistance value suddenly decreases to zero.

Furthermore, in the vicinity of the other end of the measuring range of the resistance element, for. B. at light value 2, the resistance element R ' and the conductive body C to each other partially parallel to the end measuring point, z. B. the light value 2.

In the arrangement according to FIG. 4 comes when the movable brush Br with the first or end measuring point, e.g. B. at light value 18 or 2, comes into contact, the brush at the same time with the conductive body C and the resistance element R ' in contact, so that at each of these points the resistance suddenly decreases to zero and the pointer of the galvanometer M in its movement to Standstill comes.

In the embodiment according to FIG. 4, the variable resistance has a ring shape, while F i g. Figure 6 shows the terminal end of both elements C and R ' which are strip-shaped instead of ring-shaped, with the conductive body C and the resistance element R' "being connected obliquely to the insulator I ₂ inserted between them. Figure 7 shows an arrangement in which the width of the resistance element R 'is quite narrow, while the conductive body C is substantially wider and part of the end of the conductive body is formed so as to form an extension parallel to the resistance element R'. 4 show that at the connecting parts, the conductive body C and the resistance element R are flatly connected to each other in a parallel arrangement. Fig. 8 shows an embodiment in which the connecting part is made in a three-dimensional arrangement in parallel. In Fig. 8 the end of the resistance element is R! Is connected to the conductive body C, "however the latter is overlapped on the 'resistive element R' , and the overlapped part forms the parallel le connection end under insulated condition.

As explained above, the galvanometer's pointer always shows the zero position when it moves to a part outside of the measuring range, so that the user can see clearly can when the exposure meter is out of action. This applies to both the beginning and the End measuring point to.

Claims (3)

Patent claims: 1. Variable resistor for photoelectric light meter, consisting of a conductive body and a resistance element between which there is a connection, and a movable terminal which slides on the surface of the variable resistor, characterized in that a part (F) of one end of the conductive body (C) is directly connected to part of one end of the resistance element (R ') and the remaining part of the conductive body extends parallel to the resistance element to a point which corresponds to the end of the desired measuring range, and that an insulator ( / 1) is inserted between the parallel extending part of the conductive body (C) and the corresponding part of the resistance element {R ') , so that the movable terminal (Br) with the conductive body (C) and the resistance element (R') . at the same time has contact before the connection (Sr) reaches the end (P) of the connection. 2. Variable resistor according to claim 1, characterized in that one end of the resistance element (R ' ) is in direct contact with a part of the corresponding end of the conductive body (C), and the remaining part of the conductive body (C) is parallel and isolated from the resistance element (/? ') to a point which corresponds to the end of the measuring range (Figs. 7 and 8). 3. Variable resistor according to claim 1, characterized in that the end of the conductive body (C) corresponding to the greatest resistance value overlaps in parallel and isolates the end part of the resistance element (R ') so that the brush (Br) overlaps both parts (C and R ¹ ) of the resistor shorts. 1 sheet of drawings