GB2048505A - Intermittent film advance - Google Patents

Abstract

Film is advanced intermittently along an arcuate path 24 by means of two pins 20 which simultaneously rotate and reciprocate, the pins being in engagement with the film for 60 DEG of each complete revolution. While stationary, the film is held by two reciprocal location pins (33, Figure 5) which move in synchronism with pins 20. Pins 20 are mounted on spring-biased cam follower 10 which engages stationary annular cam surface 12 which may be adjustably rotated by means of screws 17. Cam follower 10 is rotated by means of shaft 8 which is connected to a further shaft (45, Figure 6) by means of bevel gearing, the further shaft carrying a cam (43) which effects the reciprocal movement of the location pins via a spring-biased pivoted arm (38). <IMAGE>

Description

SPECIFICATION Advance mechanism This invention relates to a film advance mechanism.

At present afilm advance mechanism comprises a pivoted advance arm which carries out a reciprocating to and fro motion in the desired path of movement of the film The advance arm is associated with a cam which moves it into engagement with the film on its forward movement and leaves it free of the film on its return movement. Thus the exposure time of the film is determined by the return stroke ofthe advance arm.

In filming it can be an advantage to have as long an exposure or projection time as possible but, with the present system the only way of increasing this time is to increase the length of the advance arm and thereby the return stroke. However, the length ofthe advance arm and thereby the return stroke. However, the increase in size of the advance mechanism makes this an impractical arrangement. Moreover, the fact that the advance arm carries out a reciprocating motion means that there isatendency-foran uneven transition between the forward and return strokes of the advance arm.

An object of the present invention is to provide an improved film advance mechanism.

According to the present invention there is provided a film advance mechanism for advancing film along a desired path comprising a rotatable advance member movable into the film path during a predetermined angular movement of the advance membey so as in use to engage and advance the film.

Preferably the rotatable advance member is reciprocally movable from a retracted position out of the film path to an extended position in the fiim path in response to the changing surface profile of a cam.

The advance member in the preferred arrangement comprises two reciprocal film-engaging pins connected to the cam follower all of which are rotatable relative to a circular cam. The cam may have two circular cam halves arranged to be adjustable relative to one another so that the effective surface profile of the cam can be changed.

The invention also includes a film mechanism comprising a film track along which film is arranged to be advanced, a rotatable film advance member adjacent the film track, means for moving the film advance member into engagement with the film during a part of the angular rotation of the film advance member so as to advance the film stepwise, and means for retracting the film advance member so that the advance member is disengaged from the film whereby the film is stationary during the other part of the angular movement of the film advance member.

According to another aspect of the invention there is provided a method of advancing film comprising the steps of locating the film on a film track, continuously rotating a film advance member at a constant angular velocity, moving the film advance member into engagement with the film, advancing the film along the film track through a predeter mined angle of rotation of the film advance member per revolution thereof, and retracting the film advance member from engagement with the film so that in each revolution the film is stationary during the remainder of the angle of rotation of the film advance member.

The invention will now be described by way of example with references to the accompanying drawings in which:.

Figure lisa plan view of the preferred embodi mentofthe present invention; Figure 2 is a section on A-A in Figure 1; Figure 3 is a section on B-B in Figure 2; Figure 4 is a section on C-C in Figure 1; Figure 5is an end elevation in the direction of arrow D in figure 1 with the advance mechanism omitted for clarity; and Figure 6 is a view in the direction of arrow D in Figure 1 with the advance mechanism omitted for clarity; and Figure 6isaview in the direction of arrow Eon Figure 5 with the pressure plate partially broken away.

In the drawings a film advance mechanism has a back plate 1 and an upper support plate 2. Secured to the back plate 1 and upper support plate 2 respectively are spaced inner and outer housings 3 and 4 which house bearing assemblies 5 and 6. The bearing assembly 5 supports for rotation an inner wheel. member 7 connected to a drive shaft 8 and the bearing assembly 6 supports for rotation an outer wheel member 9. The inner and outer wheel members 7 and 9 are rotatable together about the axis of the drive shaft 8. The shaft 8 suitably has a flywheel 8' (omitted from Figure 2 but shown in Figure 6).

The inner wheel member 7 has mounted therein a slidable cam follower 10 biased by spring 11 into engagement with a circular cam element 12. The cam element 2 is mounted in a cam support 13 secured to the upper support plate 2 and consists of two circular halves, the extending cam half 14 and the retracting cam half 15. Thetwo cam halves 14 and 15 are angularly movable to one another and have teeth 16 which mesh with respective adjusting screws 17 to allow adjustment of the cam halves relative to one another and thereby alter the cam surface - see particularly Figure 3. The adjusting screws 17 being locked in position by means of associated grub screws 17'.

The biasing spring 11 for the cam follower 10 acts between a seating in the inner wheel member 7 and a connecting cross member 18, slidably received on the cam follower 10 but normally biassed by the spring 11 against a shoulder 19 on the cam follower 10. The connecting cross member 18 is elongate and has at each end a bore in which is locked a film-engagement pin 20. The film-engagement pins 20 are slidably mounted in diametric bores 21 and 22 in the respective inner and outer wheel members 7 and 9. Thus, the pins 20, through the connecting cross member 18, are movable with the cam follower 10 and the film-engaging free ends of the pins 20, which are supported in bearing bushes 23, are therefore retracted and extended in response to the surface profile of the cam element 12.

The film (not shown) passes through the film path 24 and is held in position by a film track 25 hinged at 27 and which has longitudinal channels 26 which cooperate with the film engaging free ends of the pins 20 during the advance movement. The pins 20 engage with the holes provided along the side of the film. The film track 25 during use is held in place by a spring-biased pin 28 which may be manipulated by knob 29 (Figure 4).

Referring now particularly to Figures 1, and 6 the film advance mechanism also includes a film locating mechanism for holding and locating the film when not being advanced. In Figure 1 the film is advanced from leftto right and is guided and held in position on a fixed track 30 by means of respective upstream and downstream pressure or dancing plates 31 and 31'. During loading, the upstream pressure or dancing plate 31 may be manipulated by means of lifting plate 32 so as to allow the film to be positioned on the fixed track 30.

Associated with the fixed track 30 are front and rear location pins 33 mounted on a plate 34 and slidably received in respective front and rear guide bushes 35 and 36 (bush 35 has been omitted from figure 1 for clarity). The plate 34 has a depending portion provided with a protruding pin 37 which cooperates with a pivoted lever arm 38 so as to be movable in response to movement thereof. The lever arm 38 is L-shaped and is pivoted at 39 in a fixed lever block 40. The end of the lever arm 38 which cooperates with the pin 37 is slotted at 41 to form a lost motion connection and the other end has a P.T.F.E. insert 42 which bears against a rotatable cam 43. The lever arm 38 is biased against the cam 43 by means of a spring 44. The cam 43 has a raised cam surface 49 and is mounted on one end of a shaft 45 which is rotatable in bearings 46.The other end of the shaft 45 has a bevel gear 47 which coooperates with a bevel gear 48 on the drive shaft 8 so that the film advance and locating mechanism are synchronised.

In use the film is set up so that the pins 20 engage the holes in the film (this will simultaneously ensure that location pins 33 are disengaged) and the film track 25 shut, the drive shaft 8 is then rotated so that the inner and outer wheel members 7 and 9 also rotate and, through gearing 47,48, the cam 43. The rotation of members 7 and 9 also causes the cam follower 10, with the pins 20 carried thereby, to move relative to the surface profile of the cam element 12 is preferably adjusted so that the total pressure angle when the film-engaging pins 20 are extended is a maximum of about 60". However, as will be understood, this angle can be varied as desired.

Thus, on constant rotation of the drive shaft 8, the cam follower 10 rotates causing the film engagement pins 20 to advance the film during about a 60 angle of rotation; for the remaining 300 of rotation the film is stationary. During the same 60 angle the cam surface 49 causes the lever arm 38 to pivot about 39 disengaging the location pins 33 during advance; forthe remaining 300" the location pins 33 are engaged.

The arrangement of the present invention enables the film to be stationary for a much greater time between advance steps without a bulky advance mechanism i.e. whereas the ratio of advance steps to when the film is stationary was previously 1:1 the ratio with the present invention may be greater than 1:3 and preferably about 1:6. Moreover, as the reciprocating to and fro motion is replaced in the present invention by a constant circular movement, the uneven transition at the end of the strokes on the know advance mechanism is no longer encountered.

Claims (15)

1. Afilm advance mechanism for advance film along a film path comprising a rotatable film advance member movable into the film path during a predetermined angular movement and arranged in use to engage and advance the film during said angular movement.

2. Afilm advance mechanism according to claim 1 wherein the rotatable advance member is reciprocally movable from a retracted position out of the film path to an extended position in the film path.

3. Afilm advance mechanism according to claim 2 wherein the reciprocation of the rotatable advance member is effected in response to the changing surface profile of a cam.

4. A film advance mechanism according to any one of the preceding claims wherein the film advance member comprises two reciprocal filmengaging pins connected to a cam follower, the pins and the cam follower being rotatable relative to a circular cam the changing surface profile of which governs the reciprocal movement of the pins.

5. A film advance mechanism according to claim 4wherein the cam comprises two circular halves arranged to be adjustabie relative to one another so that the effective surface profile of the fam can be changed.

6. Afilm advance mechanism according to any one of the preceding claims including a film locating mechanism comprising reciprocal location means for engaging the film during the angular movement of the film advance member when the film is not being advanced and means for disengaging the location means from the film during advance thereof.

7. Afilm advance mechanism according to claim 6wherein the reciprocal location means comprises two reciprocal location pins movable in response to the surface profile of a cam rotated in synchronism with the rotation of the film advance member.

8. Afilm advance mechanism according to claim 7 wherein the reciprocation of the location pins is effected by movement of a pivoted lever arm which follows the surface profile of the cam.

9. Afilm advance mechanism comprising afilm track along which film is arranged to be advanced, a rotatable film advance member mounted adjacent the film track, means for moving the film advance member so as to advance the film stepwise, and means for retracting the film advance member so that the advance member is disengaged from the film whereby the film is stationary during the other part of the angular movement of the film advance member.

10. Afilm advance mechanism according to claim 9 wherein the film track includes a curved portion corresponding to the curvature of rotation described by rotation of the advance member.

11. Afilm advance mechanism according to claim 9 or 10 wherein the ratio of the time the film is in movement to the time the film is stationary is greater than 1:3.

12. Afilm advance mechanism according to claim 11 wherein the ratio is approximately 1:6.

13. A method of advancing film comprising the steps of locating the film on a film track, continuously rotating a film advance member at a constant angular velocity, moving the film along the film track through a predetermined angle of rotation of the film advance member per revolution thereof, and retracting the film advance member from engagement with the film so that in each revolution the film is stationary during the remainder of the angle of rotation of the film advance member.

14. A method of advancing film according to claim 13 wherein the film is advanced for an angle of rotation of the advance member of about 60'.

15. A method of advancing film according to claim 13 or 14 comprising the further steps of providing a locating member for locating the film on the film track, moving the locating member into engagement with the film when the film is stationary and disengaging the locating member from the film when the film is being advanced, the movement of the film advance member and locating member being synchronised.