EP0407929A1 - Support for component of a colour picture tube - Google Patents

Abstract

A support for a deflection unit (10) for a picture tube has pins (17) which support a thread (19) in the longitudinal direction over a part of their circumference. The pins run in guide holes which are constructed such that they have a recess of at least the angle of magnitude of the thread. Each pin is initially aligned with respect to the associated guide hole such that the thread runs in the said recess. In this position, each pin is pushed forward to the tube cone (18.K) after alignment of the deflection unit. Each pin is then rotated through 90 DEG , as a result of which the said thread cuts into the non-recessed wall of the guide hole. In consequence, each pin is fixed and the pitch of the thread simultaneously results in a stress between the deflection unit and the tube. <IMAGE>

Description

TECHNICAL AREA

The invention relates to a support device for a picture tube component, in particular for a deflection unit. As a rule, the deflection unit is clamped to the neck of the picture tube with the aid of a clamping ring and it is supported on the tube cone with the aid of the support device.

STATE OF THE ART

As soon as a deflection unit that is already firmly connected to the neck of the picture tube is aligned in such a way that imaging properties within predetermined tolerances are met, the unit is to be fixed to the tube in the position achieved. According to the prior art, this is done either by turning screws which are mounted in a holding part until they rest against the tube cone, or by pushing wedges between said holding part 1 and the tube cone. With both types of attachment, it has been found that it is difficult to carry out the fixing so that the set position of the deflection unit is retained. It should be noted that the deflection unit, like the picture tube, is firmly held within the alignment device. If an operator now turns one of the screws mentioned more tightly than the others, the holding part warps a little. Accordingly, an elastic force builds up, which relaxes when the tube with the fixed deflection unit is removed from the alignment device. The same happens when one of the fixing wedges is pressed more firmly between the cone and the holding part than the others.

Accordingly, when using helical support elements as well as wedge-shaped support elements, it is not guaranteed that the aligned position of the deflection unit is maintained when it is released by the alignment device.

Accordingly, there has long been a problem in providing a support device for a deflection unit for a picture tube, which is designed such that the deflection unit does not change its position when it is removed after being fixed to the picture tube within an alignment device of this device.

PRESENTATION OF THE INVENTION

The support device according to the invention is characterized in that each support element is guided in a bearing in the bearing direction and can be locked in this bearing position in several positions. Such a support device is particularly suitable for the adjusted holding of a deflection unit, but can also be used for the adjusted holding, e.g. B. a magnetic multipole unit can be used.

To illustrate the advantages of the invention, it is first assumed that the support element is a pin which is guided in a bearing aligned with the picture tube and can be glued in any position in the bore. If this pin is moved so far after reaching the desired orientation that it comes into contact with the picture tube, the pressing force on the pin has no influence on the holding part of the deflection unit, since the pin can be moved freely in the bore in the holding part. Only when the pin is glued in the hole can it transmit a force between the picture tube and the deflection unit. However, if the pin is essentially inelastic, no adjustment force occurs even after it has been glued.

The fact that a force between the picture tube and the deflection unit can only be a force which results from an elastic deformation of the displaced pin can be used to selectively set a tension force between the picture tube and the deflection unit. Has the pen z. B. at its front, on the picture tube end a cap made of elastic material, this will deform depending on the pressing force of the pin on the tube. This pressing force can be made relatively uniform, so that the same clamping force is exerted at all support points, as a result of which the alignment position achieved remains unchanged. Such a relatively precise setting of a prestressing force was not possible using conventional support elements. If conventional screws were used, they would all have to be tightened with the same torque and it would have to be ensured that the torque is not influenced by friction, but is solely due to the preload force just achieved. In practice, this condition is never met, since the parts used are plastic parts, which means that some screws can be turned very easily and others only with great difficulty. The torque is therefore largely determined by friction, which is why the same preload forces do not occur at the same torques. The situation is similar when using conventional wedges. With the help of a relatively low feed force, a relatively high pretensioning force can be achieved with a wedge. With a constant feed force on different wedges, however, different clamping forces are set, since the feed force strongly depends on the friction of the wedge between it and the picture tube or it and the holding part. It should also be noted that wedges with different angles are used in practice in order to bridge different distances between the deflection unit and the picture tube at different points. Even with the same frictional forces and the same feed forces, different clamping forces result when wedges with different angles are used.

In contrast, as explained, the clamping force when using an elastic pin depends solely on the pressing force used, provided that there is no very great friction between the pin and the bore. The latter can be easily prevented, however, since it does not matter in the least on the appropriate guidance of the pin in the bore.

For a quick fastening of a support element in the bearing, it is particularly advantageous if the support element and the bearing have catches which only allow the support element to be displaced in the direction of the picture tube. Here the fixation is achieved immediately when the end position is reached. However, there is a path difference between different fixing positions, which depends on the detent, which can lead to slightly different tensions.

It is particularly advantageous if the support element is designed as a pin, which has a thread in the longitudinal direction over part of its circumference and the guide is designed such that it has a recess of at least the angular circumference of the thread. As long as the support element sits in the guide so that the partial thread runs in the recess, it can be pushed back and forth in the guide with very little force. If it is moved to the desired position, it only needs to be turned slightly to be fixed in relation to the guide. Depending on the pitch of the thread, the pin undergoes a further forward movement relative to the guide by a predetermined amount when it is twisted. A precisely defined tension can thus be set, which depends solely on the pitch of the thread and the angle of rotation used.

BRIEF DESCRIPTION OF THE FIGURES

• 1 side view of a deflection unit fixed to a (only partially shown) picture tube;
• FIG. 2 top view of the deflection unit according to FIG. 1;
• Fig. 3 side view of a pin-shaped support element with partial thread;
• 4A and 4B are cross sections through a guide with a pin according to FIG. 3, once in the shift position (FIG. 4A) and once in the fixing position (FIG. 4B);
• 5 shows a longitudinal section through a guide with a displacement pin with notches; and
• Fig. 6 longitudinal section through a guide with a glued in the guide pin.

WAYS OF CARRYING OUT THE INVENTION

The deflection unit 10 according to FIGS. 1 and 2 has a holding part with a front holding ring 11 and a rear clamping ring 12. The holding part carries a (schematically shown) deflection winding 13 and contacts 14.

On the circumference of the retaining ring 11 there are three support feet 15 at the same angular distances. Each support foot 15 has a guide bore 16 (FIG. 4) with a pin 17 mounted therein. Each pin 17 acts as a support element for supporting the deflection unit 10 on the cone 18.K of the tube. The deflection unit is fastened to the tube neck 18.H with the aid of the clamping ring 12.

The formation of the pins 17 and the associated guide bores 16 can be seen from FIGS. 3 and 4. Each pin 17 has two partial threads 19 in the longitudinal direction, each of which extends over part of its circumference. The tips of the threads have a larger circumference than the rest of the pin, which is designed without a thread. This can be seen particularly clearly from FIG. 4A. The guide bore 16 has two recesses which are designed to match the partial threads 19 so that the pin 17 in the guide bore 16 can be easily moved when it is inserted into the bore such that the partial threads 19 are aligned with the recesses 21 . In this position (FIG. 4A), each pin 17 can be pushed back and forth as desired in the associated guide bore, that is to say pushed in particular up to the bearing on the tube cone 18.K. If the pin 17 is rotated by 90 °, the partial thread 19 cuts into the non-recessed parts of the wall of the guide bore 16. As a result, the pin 17 is fixed in the guide bore 16 and at the same time it becomes a small distance depending on the direction of rotation, the angle of rotation and the thread pitch shifted.

In order to fix a deflection unit to a picture tube, support elements designed in this way are used as follows. First, the deflection unit is pushed in a conventional manner over the picture tube neck 18.H and then fastened to the tube neck in a fixed longitudinal position by tightening a clamping screw 22 on the clamping ring 12. Then the tube and the deflection unit 10 are contacted and in the operation of these parts the deflection unit 10 is adjusted with the aid of an adjusting device until imaging properties are within predetermined tolerances. The deflection unit 10 must be fixed in the aligned position. This is where the described pins 17 begin to be used. These are namely in the position shown in FIG. 4A except for the Tube cone 18.K pushed. For forces between deflection unit 10 and tube cone 18K, it is irrelevant here how strong the pressing forces on pins 17 are, in particular whether the forces on all pins are the same or not. If a respective pin 17 is brought into contact with the tube cone 18.K, it is rotated by 90 ° into the position according to FIG. 48, in the direction which causes the tube cone to move forward relative to the deflection unit 10. The pins 17 are fixed by this twisting, which at the same time leads to the set position of the deflection unit 10 being fixed. The small forward movement of the pins during fixation results in a small tension between the deflection unit 10 and the tube, which leads to a particularly secure fit of the deflection unit 10. This does not change the adjusted position. The extent of the tension only depends on the thread pitch with an always fixed rotation of 90 °, so it can be specified with the help of the same.

The pins 17 shown in FIGS. 1-3 carry a widened head with a slot 24 for rotation. However, there must be no widened head and instead of a slot, e.g. B. an outer or inner polygon. Furthermore, the pin can be modified so that 19 more or less partial threads are present instead of two partial threads. If there is only a partial thread, there is the advantage that when fixing z. B. can be rotated by 270 ° to thereby achieve a particularly large fixing voltage, if this should be necessary.

The pin 17.5 and the guide bore 16.5 according to FIG. 5 have catches 25.17 and 25.16, respectively, which are aligned in such a way that they allow the pin 17 to be displaced in the direction of the picture tube cone 18.K. The pin 17.5 has a rubber cap at its front end. The pin is used when fixing the deflection unit specified force pressed against the tube cone. The rubber cap 26 is slightly compressed. The longitudinal displacement position of the pin 17.5 in the guide bore 16.5 is determined by the detent achieved in each case. If the deflection unit is released by the alignment device, the elastic deformation force of the rubber cap 26 has the effect that the deflection unit is braced against the tube with a predetermined force.

In the embodiment according to FIG. 6, a pin 17.6 with grooves 27 is present. The associated guide bore 16.6 has an adhesive channel 28 for gluing the grooved pin 17.6 when it is displaced up to the picture tube cone. The grooved pin 17.6 also has a rubber cap 26 at its front end for the purpose explained above.

The exemplary embodiments relate to configurations of guide bores and pins which are adapted to one another in such a way that the pins can be displaced in the guide bore without great force, but can be fixed relative to the guide in a plurality of displacement positions, preferably in any displacement position. Combinations of guides and pins with these properties can be produced in many other embodiments, e.g. B. also in dowel-like embodiments, d. H. with arrangements in which a wedge is driven into the pin after its advancement to the tube cone in order to expand the pin and thereby jam it in the guide. The pin is advantageously slotted for such a purpose.

The pins according to the exemplary embodiments are further designed such that a predetermined voltage between the deflection unit and the tube cone can be achieved with them. A tension of a predetermined size can, however, also be realized in that the support feet 15 are given a predetermined by the alignment device Force is withdrawn while the pins are being advanced to and attached to the tube. After the deflection unit has been released by the alignment arrangement, the elastic restoring force of the support feet 15 provides the desired clamping force. It is pointed out that there are not necessarily three support feet 15 in the deflection unit, but that it can also be a different number.

The exemplary embodiment relates exclusively to a deflection unit. Pins that can be moved and locked in the manner described can also be used to hold other components in an adjusted position, e.g. B. for magnetic multi-poles, as used for setting z. B. serve convergence and color purity. In such an application, the pins can be supported on the tube neck or on the deflection unit in front of it.

Claims (5)

1. Support device for a picture tube component (10), with several support elements,
characterized in that each support element (17; 17.5, 17.6) is mounted in a guide (16; 16.5, 16.6) so as to be displaceable in the support direction and it can be locked in several positions in this guide. 2. Support device according to claim 1, characterized in that each support element is designed as a pin (17), the longitudinal direction of which carries a thread (19) over part of its circumference and the guide (16) is designed such that it has a recess (21st ) of at least the angular circumference of the thread. 3. Support device according to claim 1, characterized in that each support element (17.5) and each guide (16.5) have mutually matching catches (25.16, 25.17) which allow displacement in the direction of the picture tube, but block displacement in the opposite direction. 4. Support device according to claim 1, characterized in that each guide (16.6) has an adhesive channel (28) for introducing adhesive for gluing the support element (17.6) in the guide. 5. Support device according to claim 1, characterized in that the support element (17.5; 17.6) is elastic (26).

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