NO133620B - - Google Patents

Description

The invention relates to an adjustable pressure mechanism-f

me which includes several pressure gauge carriers arranged side by side, a setting device which is common to all carriers and serves for setting a selected carrier, and a selection device for operating the setting device to thereby bring it into cooperation with a selected carrier.

From patent application no. 2218/70, a printing mechanism is known which includes a setting shaft which is axially displaceable stored in a housing and on one end of which, projecting from the housing, a setting wheel is attached. Under certain conditions of use, this setting wheel or setting knob will protrude significantly outside the actual circumference of the mechanism. This is a disadvantage both because of the additional space required thereby and because of the danger of destruction of the mechanism.

In the Norwegian patent application, for example, five printing belts are shown in one version. When the clutch gear is engaged with the left hand wheel 4, which drives the associated pressure belt, the overall width of the mechanism will be approximately doubled, because the button 16 will be fully expressed. This follows from the fact that the shaft 15 is made in one with the gear wheel 17 and the shaft and the button must therefore be moved as a unit to the left in the fig shown in the patent application. 2 when you want to set a pressure band.

The invention aims to provide an adjustable printing mechanism where these disadvantages are eliminated. This is achieved by providing an adjustable pressure mechanism as stated in claim 1. Further features of the mechanism are highlighted in the sub-claims.

The new adjustable pressure mechanism only requires

a very small axial movement of the operating button and the axial movement of the button will be the same regardless of the number of pressure bands. This is because the only control, i.e. the button, has only two settings, i.e. a position where it serves to select a carrier to be set, and another

- position where the selected carrier is set.

The invention will be explained in more detail with reference to the drawings where fig. IA and IB together form a longitudinal section through an embodiment of an adjustable pressing mechanism according to the invention. Fig. 2 shows an end view of part of the mechanism in fig. 1. Fig. 3 shows a section along the line III-III in fig. 1. Fig. 4 shows a section of a reading part in the mechanism. Fig. 5A, 5B and 5C respectively show a side view of a lead screw, a section through the lead screw and an end view of part of the lead screw device. Fig. 6 shows a longitudinal section through a drive part in the lead screw device. Fig. 7 shows a longitudinal section through a nut intended for cooperation with the lead screw. Fig. 8 shows an end view of the nut in fig. J. Fig. 9 shows a side view of the nut in fig. 7- Fig. 10 shows a longitudinal section through a sleeve which forms part of the mechanism. Fig. 11 shows an end view of the sleeve seen in the direction of arrow 11 in fig. 10. Fig. 12 shows an end view in the direction of arrow 12 in fig. 10. Fig. 1JA and 13B respectively show an end view and a side view of a detail. Fig. 14A and 14B respectively show a side view and an end view of an operating button in the mechanism. Fig. 15A, 15B and 15C respectively show a side view partially in longitudinal section of a part of a printing tape carrier frame, an end view of the frame, seen in the direction of arrow 15B in fig. 15A and an end view seen in the direction of arrow 15C in fig. 15A. Fig. 16A, 16B and 16c respectively show a side view of another part of the printing tape carrier frame, an end view in the direction of arrow 16B in Fig. 16A and an end view in the direction of arrow I6C in fig. 16A. Figures 17A, 17B and 17C respectively show an elevation of a modified spacer forming part of the printing belt frame and an elevation of a spring forming part of the modified spacer. Fig. 18 shows a perspective view of a second embodiment. Fig. 19 shows a perspective view of part of the mechanism in fig. 18 in an operating position. Fig. 20 shows a perspective view as in fig. 19, but with the mechanism in a different operating position. Fig. 21 shows a longitudinal section

through the mechanism in fig. 18 - 20.

The first embodiment, which is shown in fig.

1 - 17, is an adjustable pressure mechanism intended for use in

a label applicator. The mechanism includes a frame or housing with end plates 10, 11, and between these end plates the working parts of the mechanism are arranged. The end plate 10 has a

flat outer surface, while the inner surface is provided with a relatively small, hollow cylindrical boss 12 and with a relatively large, hollow cylindrical boss 14. The latter boss is stepped at the inner end 16. The end surface 11 ^ar. an outer, hollow cylindrical boss 18' which is coaxial with the boss 14, and it also has on the inside a hollow cylindrical boss 20 which is the same size as and lies directly opposite and coaxial with the boss 12 on the end plate 10. The end plates 10, 11 are held together using a

the periphery construction 22 in which there is a transverse opening or slot 24 which forms a reading portion. This will be described in more detail below. The end plates 10, 11 will usually form parts of the housing of the device or apparatus in which the mechanism is to be used.

The boss 18 on the end plate 11 accommodates an operating button 30 (fig. 1, 14A, 14B). The control button has an elongated shape and enables the operator to grasp the control button with the hand. The operating button has a split pin 32 which on the inner end has a circular, chamfered flange 34. This flange serves to hold the button firmly in a drive part (fig. 6). The split pin has two flat parts 35. The flat parts lie in planes that are at right angles to the planes that form the split or slot in the pin.

The flat parts 35 cooperate with internal teeth 37 (fig. 6) in a hollow boss 36 in the drive part 38. The hollow boss 36 lies on the same axis as the pivot axis of the button 30. The drive part thus occupies the pin 32 in its boss 36, and a drive transfer from the button to the drive part takes place via the flat parts 35 and the teeth 37. The bending resistance in the two pin parts is such that under normal conditions the drive contact between the button and drive part will be maintained, but if the resistance in the mechanism as such becomes too great for one reason or another, then the pin parts will be deflected

against each other, and the flat parts 35 and the teeth 37 will then slide relative to each other, whereby the drive connection is broken. On it

This way, damage to the mechanism is avoided.

The part 38 has a flange 39 which extends from the boss 36, and this flange is made in one with a cup part 39A which has a flange 39B at the end. On the side of the flange 39 that faces the button 30, thirteen teeth 39c are arranged which extend axially into the housing. Each tooth has a sector shape. The cup part 39A is rotatably stored in a bearing sleeve 39D arranged in the inner part of the boss 18.

The drive part 38 is arranged at the end of a lead screw 40. The lead screw has three threads 41 and has a part 42 with a smaller diameter at the end. In this part, a ring groove 44 is designed for receiving a lock ring 45. To ensure a correct assembly, a thread 4IA (fig. 5A) is made with a wider width than the other threads, and the nut, which is shown in fig. 1, 7, 8 and 9> are designed in a corresponding manner. The screw's head 46 has a sleeve or cup-shaped part 47 at the end which extends coaxially and inwards in the direction of the screw itself, because this sleeve has a flange 48.

In the head 46 there are recesses 49 (fig. 5B) for receiving the teeth 39C on the drive part and also for receiving teeth 52 on a cage-shaped sleeve 54 (fig. 1, 10 and 11) which extends coaxially with the lead screw 40. The individual longitudinal elements 53 (13 pieces) in this sleeve 54 are shown in fig. 10 and 11, and they are, at the end opposite the teeth 52, joined together with a flange-like part 55 which lies directly outside the stepped part 42 of the lead screw 40. On this flange 55, several teeth 56 are arranged designed to cooperate with teeth 58 formed on the inner surface of the end plate 10. The flange 55 also has an extension 60 which serves as a support for one end of a spiral spring 63 whose other, smaller end rests against the locking ring 45. The flange 55 also has a cylindrical co-axial surface 6l which provides support for the sleeve 54, ie. the sleeve with this surface has a sliding fit in a sleeve 6lA mounted in the boss 14 on the end plate 10.

On the guide screw 40, a nut 62 (fig.:1, 7, 8 and 9) is screwed on which is guided along the individual longitudinal elements in the sleeve 54 by means of several teeth 64 which also serve to cooperate with corresponding internal teeth 66 on the reading wheel 70. These reading wheels are mounted between the head flange 48 on the head 46 of the lead screw 40 and the stepped end part 60 of the boss 14 on the end plate 10. The evenly spaced internal teeth 66 on each reading wheel 70 serve to push the wheel against the sleeve 54. each wheel there is a ring 74 which forms a distance or gap between each wheel 70.

To prevent the nut from jamming at the ends of the screw, stop surfaces 62A (fig. 8 and 9) are arranged at each end of each thread in the nut, and these stop surfaces cooperate with corresponding stop surfaces ^40A at the head end of the threads 41 and stop surfaces 40B on a spacer 65 (Figs. 13A and 13B). The spacer 65 is located between the locking ring 45 and the step in the lead screw 40.

As shown in fig. 3, the reading wheels 70 have external teeth fl, with the reading characters or reading floats 79 arranged on the outer surface of each tooth. From Fig. 1 one will see

that the ratio between the axial thicknesses of the reading wheels is 3 '• 4 : 6, and the same ratio applies to the printing belts and printing wheels which will be described in more detail below. The combination of wheels can be changed to enable the use of printing belts 8l with corresponding widths and possibly with other characters. This is particularly important when letters that differ from the Latin ones are to be used and when numbers that differ from the usual Arabic ones are to be used.

As shown in fig. 3, the teeth 71 on each wheel 70 constantly engage with protrusions 80 arranged on the circumference of an associated pressure belt wheel 82. The pressure belts 8l abut against the circumference of each carrier wheel below the outer circumference of the projections 80. Each carrier wheel has several peripheral notches 83 arranged at equal distances . These distances are equal to the distances between the character-carrying segments in the printing tape. The pressure belt carrier wheels 82 are rotatably mounted on a shaft 86 via a sleeve 89, and the shaft is supported in the bosses 12, 20 in the end plates 10, 11 by means of respective end parts 88. The shaft 86 and the sleeve

89 is conically designed to facilitate manufacture. The assembly

is facilitated by means of two studs 89A (fig. 15A) arranged on the end of the sleeve 89. These studs 89A are intended for engagement in the openings 89B (fig. 16C).

The number and thickness or width of the printing belt carrier wheels 82 naturally correspond to the number and width of the reading wheels 70, and these printing belt carrier wheels are placed at a distance from each other by means of thin plates 90 which are threaded on a fixed rod 92. Each printing belt 8l is placed around this fixed rod 92 and is kept at a distance from each other by means of the plates 90. On its lower surface, the rod 92 has a shallow U-shaped groove 93 in which one of the elevations 95 on the inside of each printing belt engages in any printing position of the belt. Each such elevation is provided at the back of each

character-bearing segment in the tape. When the elevation 95 lies in the groove 93, the corresponding reading wheel 70 will show which character is ready for printing. This can be seen in the window 24. The rod 92 is made in one piece with a plate 87 which is connected to the sleeve 89. The shaft 86 is provided with a plate 96 (fig. 1 and 16B), and in this plate 96 you will find the before said openings 89B which co-operate with the tabs 89A on the end of the sleeve 89. The rod 92 has two thickened areas 100, one on each side of the groove 93, and these thickened parts serve to control the parts of the printing bands which are located on each side of the press position.

The plates 90 serve several purposes. Among other things, they serve to support an elastic part 102 which has a part 103 intended for engagement in one of the notches 83 in the wheel 82. Another part 105, which has a semi-circular shape, extends towards, but does not have contact with, the printing belt. A part 107 goes under a tab 108 on the plate 90, and a bent end part (not shown) goes into an opening in the plate near the tab 108. At the other end 110. there is a bend, and this end part cooperates with a groove formed in a projection 111 on the plate 90. When the whole is assembled on the sleeve 89, the yielding parts 102 cannot be released from the respective plates 90.

In a modified version, the plates 90 are replaced with spacers 120, as shown in fig. 17A and 17B. Each such spacer has a planar annular portion 121 and a. mainly rectangular part 122 with a square opening for receiving the rod 92. Raised parts 123A are formed on the plates by means of extrusion. It is these parts that take over the distance function of the distance element. The sleeve 89 is received in the annular part 121. The rectangular part 122 has two notches 123 on each long side, and each pair of notches facilitates the formation of a projection 124.

The protrusions are intended for receiving end parts of a leaf spring 125 as shown in fig. 17C. In fig. 17C, the spring is shown in the tensioned position with full solid lines. The central part 126 of the spring is intended for engagement in one of the notches 83 on the associated wheel 82, and the two elbow parts 127, which are arranged symmetrically about the central bent part 126, serve to exert a tightening force on the pressure band 8l. Each spring also has two further bends 128 between each of the elbows 127 and the middle bend 126. The spring 125 is inserted with its ends under the projections 124.

The embodiment example described above works in the following way. Where the nut 62 is located on the lead screw 40 can be seen through the slot 24 because the nut is produced in a color that forms a clear contrast with the color of at least the sleeve 54 and the lead screw 40. When the nut 62 is in the desired position, one simply turns the knob 30 until the desired new character can be read in the slot 24. Turning the knob 30 causes the teeth 390 on the drive part 38, which teeth go into the recesses 4.9 in the head 46 of the lead screw, to drive the lead screw. At the same time, the teeth 52 on the sleeve 54, which teeth interact with the same recesses 49, will drive the sleeve 54 which in turn drives the nut 62. The nut 62 drives the wheel 70 with its teeth 64. The projections 80 on the pressure belt carrier wheel 82 are turned by their interaction with the teeth 71~ on the reading wheel 70. Thereby the printing belt 8l is moved step by step between positions such as. is determined by the spring 102 or 125 which cooperates with the notches 83, and the groove 93 on the bar 92, which groove cooperates with the elevations or ridges 95 on the back of the printing belt.

When it is necessary to shift one of the other pressure bands, the button 30 is pressed in and the teeth 390 on the drive part then serve to drive the teeth 52 on the sleeve 54 out of cooperation with the recesses 49 in the head 46 of the lead screw, at the same time that the teeth 56 on the the other end of the sleeve is brought into contact with the fixed teeth 58 on the end plate 10. The sleeve 54 is thereby prevented from turning, and a turn of the button 30 will then only serve to drive the lead screw 40. Because the nut 62 has threaded cooperation with the lead screw, and is held against rotation, the nut 62 will move along the lead screw, until it is located directly opposite the reading wheel 70 to be set. When the nut is correctly positioned, you will be able to see it through the slot' 24. When you release the button 30, i.e. relieve the axial stress on the button, the button will move outwards under the influence of the spring 63. The teeth 56 and 58 are then brought out of engage with each other, and the teeth 52 go back into the recesses 49 on the head 46. You can then again turn the selected reading wheel and the associated printing belt as described above.

The teeth 52 on the sleeve are designed so that when they are mainly brought out of engagement, the teeth will click over the edges of the recesses in the head 46 under the influence of the spring 63. The pitch of the threads 4l is chosen so that the nut 62 moves a distance equal to the distance between two of the narrowest printing bands 8l during three clicks and moves a distance equal to that of the second widest printing band i. during four clicks and a distance equal to the widest printing band during six clicks.

Some parts will now be described which of course have no connection with the basic construction when it comes to the setting of characters in the mechanism, but which are used for control of the printing and for locking when the mechanism is arranged in a label application device.

As can be seen from fig. 1, 15A, 15B, 16A and 16B, each of the plate-like parts 87, 96 has protruding protrusions 130, 131 - The protrusion 130 has a circular cross-section, and the protrusion 131 has a rectangular cross-section. In these figures there is also shown a curved flange 132 and radially directed projections 133 which, in cooperation with other parts of the labeling apparatus, exercise a locking function so that the printing mechanism cannot swing as such when it is to be set.

Alternatively, the printing belt can be replaced by printing wheels. The reading wheels are then made thinner so that a narrow gear-like part appears. The reading characters are then arranged on the rest of the reading wheel and the narrow part serves to drive a gear wheel which is pivotally connected to the associated pressure wheel.

In the embodiment shown in fig. 18 - 21, the mechanism includes several pressure wheels 110' which are supported on a fixed shaft (not shown). On one side, each pressure wheel has a ring of pins 111' which serve as gear teeth.•

A gear wheel 112 engages with the ring of pins 111' and is rotatably mounted on a shaft 113 which is stored in the housing 131A (fig. 21). A reading wheel 114 is rotatably connected to the gear wheel 112, and there is thus a gear wheel 112 and a reading wheel 114 for each pressure wheel 110. An indicator finger 115, which serves to show which pressure wheel is set, is mounted on a transverse shaft 116 which is mounted in the engine house. The finger 115 is rigidly connected to a fork member 115A which grips the drive 120' and thus ensures that the finger follows the drive.

In order to be able to turn the gear wheel 112 and thereby also the associated pressure wheel 110', the drive 120' is mounted so that it can be turned, and it can also move in the direction of its own axis of rotation. When a special gear 112 is selected, the drive 120 can be caused to rotate.

The parts of the mechanism which enable this selective axial movement and rotary movement of the drive will be described below. The drive 120' is slidably mounted on, in this case, two rods 121' which form guides. The drive has two internal threads which are adapted to the threads 122' on the shaft 123. The ends of the rods 121' are attached to a disc 124' and to one half 125 of a claw coupling provided with several teeth 126'. This half of the coupling is freely rotatably mounted on the shaft 123'. The other half 127' of the coupling is designed as a disk with a central bore 128' and has several peripheral grooves 129'• Each of these grooves corresponds in shape to the teeth 126' on the coupling half 125'. The coupling half 127' is fixed in one side wall of the housing 131A. The shaft 123' has a tubular extension 123A with a transverse slot 123B. A pin 131B which sits in a spindle 130' is received in this slot. This spindle is firmly attached to an operating button 132' which is located on the outside of the housing 131A and has a ridge 133' which facilitates the operation of the button. As shown in 'Fig. 18, the disk 124' is pressed in the direction of the coupling halves 125', 127' by means of a spring 135 which acts between the disk and the end of the housing (fig. 21).

The mechanism's operation will now be described with particular reference to fig. 19 and 20. If one assumes that each press-

wheel 110' is oriented so that it is set to the desired

boring character, and that you then want to change the character on one of the pressure wheels 110', then you turn the button 132' without pressing it in. The coupling is then active, and the rotary movement of the button will then cause a rotation of the shaft 123' while the rods 121' remain at rest due to the fact that the coupling is engaged. The drive 120' will thereby move along the shaft 123' > due to the thread interaction, until the drive lies directly opposite the tooth

wheel 112 which corresponds to the pressure wheel 110' to be set

read. For setting, the drive 120' must be turned step by step, whereby one turns the gear wheel 112 and thereby also sets the desired

boring sign on the pressure wheel. For this purpose, the coupling must be disconnected, as shown in fig. 20. This happens by the button 132' being pressed axially' inwards against the action of the spring 135- Pin-

nen 131' by this impressed movement takes the coupling half 125' with it and thus causes a release of the coupling. The coupling half 125' will rotate together with the shaft 123' and thereby the drive 120' can also be turned without it shifting axially. The turning can take place until the desired character is read on the reading wheel 114. When the button 132' is released, the spring 135 causes the coupling halves to engage and the drive can then no longer be turned. The finger 115' is carried along with the drive 120' during its axial movement, due to the arrangement of the fork member 115A. In this way, you always ensure that you are turning the correct pressure wheel.

In all design examples, the number of print-

wheel or pressure plate can be varied as needed, since one only needs to arrange the same number of selector elements. They did not show described parts of the printing device, such as e.g. a labeling device, may be of a conventional nature.

Claims (10)

1. Adjustable pressure mechanism with. several printing character carriers arranged side by side, a common setting device for the carriers for setting a selected carrier, and a selection device for operating the setting device to thereby bring it. for cooperation with a selected carrier, characterized by a single, rotatable member (30; 132') which is common to the setting device (62; 120') and the selection device (40, 54; 121', 123') and constitutes the only operating device for both of the aforementioned devices, which rotatable device can be selectively shifted axially between two positions and in one of these positions can influence the selection device to thereby bring the setting device into operating cooperation with a new carrier (8l; 110') and in the second position can influence the setting device. 2. Adjustable pressing mechanism according to claim 1, characterized in that the guide device (40, 54; 121', 123) serves to move the setting device (62; 120') transversely in relation to the carriers (8l; 110'). 3. Adjustable pressing mechanism according to claim 1 or 2, characterized in that the selection device and the setting device include a common screw member (40) which carries a toothed member (62) in the setting device so that a relative angular movement between the screw member and the toothed member (62) causes a relative axial movement between the screw member and the tooth member, and in that the selection device further includes a device (56, 58) for selectively allowing and preventing said relative angular movement so that a rotary movement of the screw member (40), when the tooth member (62) is in a selected position, and relative angular movement is prevented, can cause a setting of the selected carrier to produce the desired print character to print position. 4. Adjustable pressure mechanism according to claim 3, - characterized in that the device which is to selectively prevent and allow the mentioned relative angular movement includes a claw coupling, one half of which is rotatably connected to the screw member (40) - in the setting device and the other half is attached to a housing (10) in the mechanism, an axial movement of said rotatable member (30) between said two positions serving to engage and disengage the coupling. 5- Adjustable pressing mechanism according to claims 1-4, characterized by an overload device (32, 36) for breaking the operation from the rotatable member (30) and to the mechanism in the event that one or more parts in the mechanism jam. 6. Adjustable printing mechanism according to claim 4, where each carrier is a printing band (84) which is placed around a carrier wheel (82) which is assigned to a corresponding reading wheel (70), which reading wheel has peripheral tooth-like parts (71) > internal tooth-like parts " (66) and a peripheral series of positive characters corresponding to the characters found on the associated printing belt, each carrier wheel including peripheral tooth-like parts "(80) which are in engagement with the peripheral tooth-like parts (71) on the associated reading wheel , character!-3S characterized in that said toothed member includes a nut (62) which is screwed onto the screw member (40) and has peripheral tooth-like parts (64) intended for engagement with the internal tooth-like parts (66) on one of the reading wheels (70), and in that the device for selectively preventing and allowing a relative turning movement includes a sleeve (54) which extends over and surrounds the screw member (40), the nut (62) being slidable in h the sleeve, as well as in that the klbkablirig includes a ring of teeth (56) at one end of the sleeve, which teeth can be brought into engagement with a complementary ring of teeth (58) on the housing (10), the cooperation between the two rings of teeth serves to prevent a turning of the nut (62) so that a turning movement of the screw member (40) causes the nut (62) to move axially. 7. - Adjustable pressure mechanism according to claim 6, characterized by a spring (63) which presses the toothed rings (56, 58) into the free position". 8. Adjustable pressing mechanism according to claim 6 or 7, characterized in that the said rotatable member is a button (JO) which drives a row of teeth (39C) which is rotatable together with the button, as well as a corresponding row of teeth (46) which is rotatably connected to the screw member . 9. Adjustable pressure mechanism according to claim 8, characterized by a row of teeth (52)" which is rotatably connected to the sleeve and engages with the row of teeth (46) on the screw member (40) when the screw member (40) and the sleeve (54) are to be turned together, an axial movement of the knob to one of its two axial positions serves to disengage the rows of teeth on the screw member and the sleeve from each other. 10. Adjustable pressure mechanism according to claim 9, characterized in that the teeth which can be turned together with the button (39C) are dimensioned so that they do not cause a complete release from the tooth row (46, 52) on the screw member and the sleeve, so that the teeth in the said rows snap over each other as the nut (62) moves across the row of pressure bands.