NO121339B - - Google Patents

Description

Device at calculators.

The present invention relates to such calculators of the ten-key type, where the keys directly affect a special preset device that records and registers the numbers entered from the keyboard, and where one or more influencing keys are arranged to start the machine's electric motor, so that in The numbers entered by the preset are transferred to the machine's calculating body.

Such machines are previously known and have so far worked quickly after the calculation operation has been initiated, but have the disadvantage that instead there is a lot of waste of time, during which the operator has had nothing to do but wait for the machine to calculate finished.

In patent no. 93 272, a device is described, where this disadvantage is avoided by the fact that the pre-setting system is not only equipped with devices to register digits, but also to register an arithmetic operation, e.g. multiplication or division, so that two or more factors can be entered one after the other only separated by the operation sign, e.g. multiplication sign (x) or division sign (:), as the set factors and the sign become visible in one and the same number window, so that the listed arithmetic operation can be directly read and checked.

After complete transfer of the set values, e.g. to an actuator and a multiplication work, it then becomes possible to reset the preset work which thus becomes ready to receive the values for the next operation; the setting of this can therefore take place while the machine is performing the calculation of the previously entered values. Thereby, virtually all waste of time involved in the machine's calculation work is eliminated, as this can be used for a subsequent setting; setting a new calculation operation and reading the result of the previous one can take place in an uninterrupted sequence. The machine is therefore exceptionally fast and convenient.

The present invention relates to a setting mechanism which is particularly suitable for this type of machine, and the invention is distinguished mainly by the fact that each amount input key is arranged to influence a rotatable tooth segment with a number of teeth, which corresponds to the digit of the affected key, which tooth segment for each set digit (or character) is moved laterally to mesh with a gear that directly or indirectly meshes with

a setting disc in the pre-setting mechanism

with visible numbers — and possibly also calculation operation signs (x, :) — after which the segment, under the influence of the calculator's motor, which is started by a start button, is turned a full revolution, whereby the corresponding disc in the setting mechanism is turned forward such a distance that a digit corresponding to the suppressed amount tangent value appears in a digit window.

A particularly suitable embodiment of the invention is distinguished by the fact that all setting discs for each setting operation are shifted one step in the lateral direction so that the set disc is moved out of engagement with the toothed segment or its transmission wheel to instead engage with a gear wheel influenced by the machine's engine which turns the dials of the presetter when an operation key (start key) is affected, which disks thereby transfer the setting digits to e.g. an actuator respectively to a multiplier work or the like.

An embodiment of the invention will be described in more detail in connection with the drawings, where fig. 1 shows a side view of the various parts of the presetting mechanism, fig. 2, seen from above, all the elements which are arranged to control the tooth segments connected by the tangents in the lateral direction as well as the coupling means for the drive shaft, fig. 3 a detailed view of the drive shaft coupling's starting device, fig. 4 and 5 same parts as fig. 3, but in a different position, fig. 6 the means for initiating the setting operation and fig. 7 corresponding bodies for initiating the reset operation. Fig. 8 and 9 show two different views of the means for blocking the shaft which is affected by the tooth segments, and Fig. 10 and 11 an assembly of the coupling elements seen from the front and from the side, respectively.

Fig. 1 shows a number of amount input keys 109, one for each character to be set in the presetting device. The keys are stored on a shaft 110 and are held in their initial position by a coil spring 111 which presses them in a clockwise direction against a stop. They are controlled laterally by guide plates 108 and 112 (fig. 1 and 2).

When the key button 109a is actuated, the key is swung clockwise, during which it with its lower part 109b affects a swing arm 106 which in turn guides a segment 105 in the lateral direction. Such a segment exists for each digit or character that can be set. The segments have different numbers of teeth corresponding to the number of the keys, in the version shown from one to ten teeth.

The segments are stored on a shaft 103 and are turned by its rotation (with the help of a motor or similar) by a wedge 104. In the normal position, the segments run next to gear wheels 102 on a shaft 72.

When the above-mentioned lateral displacement of the segments has taken place, these, on the other hand, engage with the gears 102 and thereby cause the shaft 72 to rotate. The size of this rotation depends on the number of teeth on the segment 105 which is brought into engagement with the wheel 102. These wheels, like the gear wheel 73, are firmly connected to the shaft 72. The wheels 102 and 73 have the same number of teeth, and the wheel 73 engages with a setting dial 61.

When a segment 105 is brought into rotation and at the same time engages with a wheel 102, the disc 61 is therefore turned by the shaft 72 and the wheel 73 forward as many steps as the number of teeth on the segment 105 determines. As soon as the wheel 73 has stopped, the setting disk slides out of engagement with the wheel 73 in a manner known per se (not shown) and a new setting disk engages with the same wheel. The set numerical value marked on the numerical ring 61a becomes visible in the window 66.

In order to achieve the aforementioned rotational movement of the shaft 103 with the segments 105, a special release and coupling device is arranged. A tangent bridge 117, fig. 1 and 3, has a projection 117a, which is affected by the tangent 109 by means of its stop 109c. A nose 117b on the tangent bridge blocks a projection 113a on a release bridge 113. The bridge 117 is rotatably supported on a pin 124 and a shaft 125 and is pulled clockwise by a spring 118, see fig. 1 and 3. The release bridge 113 is rotatably supported on a shaft 115 and is acted upon by a rotary spring 114 clockwise, fig. 1. When the key 109 is pressed down, the bridge 117 is swung clockwise via the stop 109c and the projection 117a. The nose 117b then releases the engagement with the projection 113a and the bridge 113 is swung clockwise by its spring 114.

At its other end, the bridge 113 is designed as a stop 113b which, during clockwise rotation, affects a release hoop 126 over a projection 126a, fig. 2, 6 and 9. The second part 126b of this bracket (fig. 6) serves as a catch and blocks an adjustment coupling 132, fig. 2 and 6. When the hoop 126 is affected by the bridge 113, the hoop is swung clockwise and then releases the engagement with a curve 132a on the coupling 132, which is thereby guided to the side by a spring 136. Thereby coupling teeth 132b engage with a steadily rotating wheel 133 by help of knobs 133a on this. Thereby, the shaft 103 is brought into anti-clockwise rotation, and the previously mentioned sequence of events with forward rotation of the set numerical value begins. The motor can be connected using a contact 122 which is affected by a projection 113c on the bridge 113.

A curve 123 is arranged on the shaft 103 which, during the rotation of the shaft, presses the hoop 113 back by acting against its stop 113d. During each revolution of the shaft 103, the hoop 113 is thus brought to the position shown in fig. 5. Thereby, the hoop 117 swings back and blocks the hoop 113, whereby the release system returns to the normal position according to fig. 3. While the hoop 113 assumes its position in fig. 4 shown position, the tangent tip 109b is blocked by the hoop edge 113a, whereby the tangent 109 is kept in its depressed position.

To prevent the shaft 103 from rotating several revolutions after one release, e.g. if the key 109 is maintained in the depressed position, a rotatable lock 120 is arranged on the hoop 117 (fig. 1, 3, 4 and 5). This latch is stored on the pin 119 and is pulled by a spring 121 against a stop stop 117c. In the starting position (Fig. 3), the latch stop 120a moves freely in relation to the projection 113a on the bracket 113. When the bracket 113 of the tangent 109 is swung clockwise, however, the latch 120a falls against the projection 113a, but does not prevent the bracket 113 from being swung by the spring 114 clockwise when the nose 117b has released the protrusion 113a. The resulting position of the elements is shown in fig. 4.

If the key 109 is still held down. occurs when the shaft 103 turns that in fig. 5 shown position, where the stop 120a is dropped in front of the projection 113a and prevents this from falling back when the curve 123 slides from the stop 113d. Any renewed release of the coupling mechanism then does not occur despite the fact that the key 109 is still held down.

In order to be able to start again, the key must be released back, whereby the stop 120a slides out of engagement with the projection 113a, while the nose 117b instead assumes a blocking position and the starting position is again provided.

In order to keep the shaft 72 in the correct position, a locking disc 136 is arranged on it (fig. 8 and 9). Holes 136a are arranged in this disc, one for each tooth position, i.e. ten in the embodiment shown. A ball 137 which is guided in a hole in the machine's end wall 70, is pressed by a spring 138 into the locking disc's hole, whereby the locking disc and the shaft are held in position.

When the shaft 72 is turned in the manner described above by the segments 105 engaging with the gears 102, there is a certain danger that the shaft 72 may continue its rotation when the tooth segments 105 have stepped out of the engagement with the wheels 102. To prevent this, there is the shaft 103 has a curve 139 (fig. 8 and 9) which is designed as a segment with a larger radius that fits into the recess in the periphery of the locking disc 136. When the shaft 103 rotates, the curve 139 with its part 139a engages with the locking disc 136 at the same time as the last tooth on the segment 105 comes out of engagement with the wheel 102. When the teeth on the segment 105 come out of engagement with the wheel 102, the disc 136 is completely blocked by the curve 139, thereby eliminating the risk of misalignment.

As mentioned above, the setting disk 61, which is part of a pre-setting mechanism known per se, slides to the side during setting of a number and eventually out of engagement with the wheel 73, whereby a new setting disk engages with the same wheel. This sliding in the lateral direction is completely connected with the rotational movement of the shaft 103 and is controlled by the latter in a manner not shown here but known per se. When the shaft 103 rotates one revolution anti-clockwise, the presetting mechanism is simultaneously shifted one step to the left.

During the presetting mechanism's zero setting, this must instead be moved to the right, which is why the shaft 103 must also be able to rotate clockwise. In order to achieve this movement, a wheel 135 (fig. 2 and 10) is arranged which constantly rotates in the opposite direction to the wheel 133. An axially movable coupling 134 is mounted on the shaft 103 (fig. 7). This is held in the correct lateral direction by a catch 130 which is mounted on the shaft 125. The catch 130 is held pressed against the coupling by a spring 131. To release the catch 130, a zero arm 141 is mounted on a zero setting shaft 142 which, together with the arm 141, is pulled clockwise of a spring 144.

The zero setting shaft 142 is affected in a manner not shown here by a zero setting key in a clockwise direction, whereby the arm 141 is moved to the dashed position in fig. 7. The arm 141 then presses the catch hook 130 clockwise so that the hook 130b is released from its engagement with the coupling curve 134a. The spring 136 then brings the coupling 134 into engagement with the coupling wheel 135 and rotates with it, whereby the desired rotation of the shaft 103 in the clockwise direction is achieved.

When the arm 141 is pressed down, a part (141a) of this passes two jaw teeth, 128a and 129a (fig. 10 and 11). The hook 128 with the tooth 128a is arranged to lock the arm 141 in the working position, until the arm is moved to the right in a manner not shown here and frees itself from the hook 128. The arm is then moved clockwise until it is gripped by the tooth 129a on the hook 129. When the arm releases the engagement with the hook 128, it also releases the catch 130 which is pressed against the coupling 134 by its spring 131. The basket 134a which then slides against the hook 130b, then leads the coupling in the lateral direction out of engagement with the wheel 135 and the axle 103 stops. During the previously mentioned clockwise movement of the hook 130, the stop 130c hits the pin 127b on the locking hoop 127, which thereby causes a clockwise movement, which results in its hoop arm 127c coming inside the flange 132c, which causes the coupling 132 to be prevented from sliding to the left itself if the hook 126b were to be moved out of engagement. When the coupling 134 slides to the right, its flange 134b will come to lie directly in front of the hoop arm 127d, whereby the hoop

des in this position as long as the coupling 134

is in engagement with the wheel 135. Thereby fixed

the coupling 132 is kept in its lateral position even when, during the rotation of the shaft, below zero

position not against the chin 126b. To reach-

with this, the coupling 134 cannot slide to the right during setting rotation because the hoop arm 127c lies directly outside the flange 132c and thereby holds the arm 127d within the flange 134b.

In the previously mentioned zeroing movement, during which the shaft 103 rotates clockwise, the curve 134a is in such an angular position that the shaft stops after approx. % revolution from its normal position.

When then the connection of the basket and the catch hook

130 is moved to the side, the bending arm 127d releases its engagement with the flange 134b, whereby bending

len 127 of a spring 131b is swung counter-clockwise

clean, so that the arm 127c no longer prevents the link 132 from moving laterally. By having the hook 126b in this angular position on the axis

len does not block the coupling 132, this slips, influenced by the spring 136, into engagement with the wheel 133 and causes the shaft to rotate counter-clockwise. As soon as the curve 132a has hit the hook 126b, the coupling is moved sideways

is directed to the right and releases the engagement with the wheel 133, whereby the axle stops. During this last % turn clockwise, the curve 134c has been lying directly in front of the chin 129, which has thereby acquired a clockwise movement and no longer blocks the arm 141

which thereby returns to its normal style-

ling.

During all that time the arm 141 and the shaft 142

is held down by the chin 128 (or ha-

ken 129) blocks the latches 107 in a manner not shown here, fig. 1 and 2, which in turn prevents the keys 109 from being pressed. The latches 107 also lock the keys 109 together, so that only one key at a time can be pressed.

A setting operation therefore takes place

in the following manner. When the key button 109a is pressed down, the tang 109 swings

counter-clockwise, whereby the estimate 109c vir-

ker on the tangent bridge's tab 117a. The tangent arm's lower end 109b leads the swing arm 106 to the side, whereby this drives a

intended 105 in the lateral direction so this comes straight out for a gear 102. When the bridge 117

of the key arm is swung clockwise, the nose 117b releases the engagement with the projection 113a of the release bridge. The spring 114 thereby swings the bridge 113 clockwise, whereby the edge 113e blocks the tangent

while lower end 109b in its forward-swinging position.

The stop 113b on the bridge 113 drives the release bracket 126 clockwise, whereby the hook 126b slides away from the coupling 132 which is guided by the spring 136 to the side to engage with the wheel 133. This is driven from a motor which is started when the bridge 113 stops breaking

the field 122.

The shaft 103 now rotates with the wheel 133

counterclockwise. The segment 105 then drives the gear wheel 102 and the shaft 72 clockwise until all the teeth on the segment have passed. At the same time as this occurs, the locking curve 139 has rotated into engagement with the disk 136, whereby the shaft 72 is stopped. The toothed wheel 73 and the adjusting disc 61 driven by it are now turned forward as many teeth as there are on the segment

tet 105, whereby the set value of

is read in window 66.

As soon as segment 105 has ended

by driving the gear wheel 73, the curve 123 during the continued rotation of the shaft 103 hits the stop 113d, whereby the bridge 113 is driven clockwise until it in fig. 5 shown position. If the tangent is then free to move

back to the normal position, the nose 117b falls in over the projection 113a and blocks the bridge 113. On the other hand, if the tangent is held forward

splits the down pressure, the latch 120a falls in instead and blocks the bridge. To obtain a new setting release, the key must be released

pushed back so that the stop 120a slides away from the bridge's projection 113a, whereby the nose 117b slides into the locking position.

Claims (2)

1. Device for calculators of the ten-key type, where the keys directly affect a special preset mechanism that records and registers the numbers set from the keyboard, and where one or more influence keys are arranged to start the machine's electric motor, so that in the preset mechanism entered numbers over is fed to the machine's calculating body, characterized in that each amount input key (109) is arranged to influence a rotatable toothed segment (105) with a number of teeth, which corresponds to the affected key's digit, which toothed segment for each set digit (or character) is moved in the lateral direction into engagement with a gear wheel (102) which directly or indirectly engages with a setting disk (61) in the presetting mechanism with visible digits — and possibly also arithmetic operation signs (x, :) —, after which the segment under the influence of the calculator's motor, which is set in motion by an initiation key, a full turn is made, whereby the corresponding disc in the preset mechanism is turned forward such a distance that a digit corresponding to the value of the depressed amount key appears in a digit window. 2. Device according to claim 1, characterized in that all setting disks for each setting operation are shifted one step in the lateral direction, so that the set disk is brought out of engagement with the tooth segment or its transfer wheel instead to engage with one of the gears affected by the machine's motor which turns the dials of the preset mechanism when an operating key (start key) is affected, which disks thereby transfer the set digits to e.g. an actuator respectively to a multiplier mechanism or similar.