DE19518846A1 - Expansion screw for correcting tooth misalignments - Google Patents

Abstract

The invention concerns a jackscrew for use in correcting misalignments of teeth. It comprises two main bodies (1, 2) whose mutual separation can be adjusted by means of a spindle (3) provided with an operating part (5) and, continuous with that part, one or two screw-thread sections (7, 11), the operating part (5) being mounted in one body (1) so as to rotate and one screw-thread section (11) being mounted so as to rotate in the other body. The jackscrew further comprises straight-line guide elements (22, 23) which engage with both bodies (1, 2) and guide them in a straight line while also preventing any relative rotation when the separation between the bodies is altered; and a threaded sleeve (13, 14) on each of the screw-thread sections (7, 11) of the spindle (3), the threaded sleeve (13, 14) being guided inside a recess (6, 10) in the body in question (1, 2) and along the spindle (3) so as not to rotate and transmitting its sliding motion to the bodies (1, 2) via a spring (18, 19) which determines the expansion force. The spring (18, 19) is made from a memory alloy which is pseudo-elastic at temperatures prevailing inside the mouth.

Description

The invention is based on an expansion screw with the in the preamble of Claim 1 specified features. Such an expansion screw is known from DE-PS 8 24 832. The known expansion screw is used in conjunction with a split palate plate, with incorrect tooth position, e.g. B. in the Oral cavity protruding or laterally shifted teeth in the Correct the upper or lower jaw in the correct tooth position to take. The two parts of the palate plate are through the expansion screw bridged and separated by adjusting the expansion screw. To For this purpose, the well-known expansion screw has two bodies through one Double spindle can be changed in their mutual distance. Each of these  Body is usually embedded in one of the palate plates. The pressure, which is built up by actuating the spindle, is by Druckfe those that have to be driven apart between the spindle and the two Bodies are effective, cushioned. The springs are in the well-known Dehn screw coil springs that hold the two threaded sections of the spin del surrounded and with one end supported on a lid, wel cher closes a recess in the respective body in order to engage with her the other end against an abutment in the form of a threaded sleeve zen, which is screwed onto the relevant threaded section of the spindle and - secured against rotation - when actuating the spindle in the concerned opening of the body is moved. The disadvantage here is that due to Hooke's law, the spring force with increasing loading progress decreases. This also leaves the effectiveness of the strain screw during the treatment period, the correction of the tooth lung slows down and eventually comes to a complete standstill when the Expansion screw is not adjusted. To avoid the expansion screw too often to readjust, one is easily tempted to put the springs in to tighten the expansion screw more than for the teeth and the tooth position good is.

Furthermore, deposits of food could be found in the known expansion screw Remnants and tartar penetrate into the expansion screw and jam and lock the screw.

The present invention has for its object to identify a way how to make working with such expansion screws easier, the wish is there, the expansion screw on the one hand not so Often having to readjust, but also no shavings risk of teeth spikes.

This object is achieved by an expansion screw with the in claim 1 specified features. Advantageous developments of the invention are  Subject of the dependent claims. The new expansion screw is used as a spring not a conventional steel spring, but a spring made of a Shape memory alloy, which under the temperatu prevailing in the mouth ren is pseudoelastic. Preferred shape memory alloys are alloys on the basis of nickel and titanium, in which nickel and titanium in approximately the same atomic percentages are included. Such alloys can depending on the selected temperature - either in austenitic or in a martensitic state. Martensite is at a lower temperature temperature, austenite at a higher temperature. The temperature at which the alloy can be converted to martensite when cooling from austenite starts, is also referred to as the Ms point. In martensitic condition and Such alloys can show shape memory below the Ms point: Plastic deformation in the martensitic state can be caused by Warming to temperatures above the Ms point reversible again be made. In a tempe following the Ms point upwards Such a shape memory alloy can be pseudoelastic Show behavior. The peusoelastic behavior is characterized by that the force required for increasing elongation is initially as for egg Austenite is expected to increase significantly, but then after reaching unung for 1 to 2% stretch with progressive stretch only slight increases rapidly and only after reaching greater strains of 6 to 8% rises steeply again. The middle stretch range is called the "martensite Plateau ". The name comes from the fact that in the alloy un The effect of tensile stress forms martensite. If the material from Relieved of tension, it returns to the austenitic state. This pseudoe Elastic strains are to a large extent, up to strains over 6 to 8 %, reversible. The pseudo-elasticity obeys because of the pronounced Mar tensite plateaus not Hooke's law. That makes feathers stand out behave in a pseudo-elastic manner for the purposes of the present invention particularly suitable, because with spring travel in the area of the martensite pla teaus the restoring force of the spring is almost independent of the spring travel. A  Expansion screw according to the invention therefore has the great advantage that the Tension is almost unchanged during the treatment period.

Because of the constant spring tension, the teeth are straightened faster than before, with readjustment of the expansion screw not as often as in the prior art. Since the spring force, as long as you move on the martensite plateau, hardly changes, it can also be reliably prevented using the invention that a treating orthodontist accidentally sets too high clamping forces, because by simply adjusting the spring travel to the expansion clamps the expansion screw can be prevented that an adjustment beyond the martensite plateau takes place, and therefore in the expansion screw according to the invention, the clamping force is approximately only by the choice of pseudo-elastic
Spring determined, but not by the adjustment path of the spindle. The adjustment away from the spindle only determines the end of the tooth correction, but not the force used for it.

The comfort and safety of using the expansion screw are ensured by the Invention significantly increased.

Pseudo-elastic springs are already known per se, but were in Expansion screws for orthodontic purposes have not been used so far open up a substantially broadened field of application according to the invention, in which they face with the dangers (harmful voltage peaks!) the technology with the necessary frequent readjustment of the expansion screw go along, break up once and for all.

Depending on the choice of the arrangement of the spring in the body of the expansion screw the spring can be used as a tension spring or as a compression spring. There With regard to the structure of the expansion screw, use as a compression spring is favorable ger and therefore preferred.  

The expansion screw could be a spindle with a head and a threaded part have, with the head in one body and the threaded part itself extends into the other body. However, the spindle preferably has two Thread parts, which are arranged in the middle of an actuating part of the Spindle extend in opposite directions and reverse thread de have. Such a structure enables longer adjustment paths.

In order to be effective, the spring must attack the body on the one hand and others on the other hand on the threaded sleeve located on the spindle. To this end is the recess in the body in which the threaded part of the spindle, the threaded sleeve and the spring are closed by a cover sen, the assembly of which ends the expansion screw assembly. This lid can be welded or soldered to the respective body the, but it can also be pressed or inserted and egg by flanging nes provided on the body. This lid serves then not only as an abutment for the spring, but also closes it in the body provided recess at one end, so that no food from there penetrate residues, harden and thereby the function of the expansion screw can impair. To penetrate from the other side as well To prevent food residues, a seal is preferably provided there, in particular an O-ring, which is in the vicinity of the actuating part the spindle is arranged on this and from this end the in each sealing recess leading to the body leading access. If on this is due to leftovers, tartar and plaque accumulation deposits in the recess in which the threaded sleeve is located and the pseudo-elastic spring are prevented, then one is perfect functioning of the expansion screw during the entire treatment duration ensured without intermittent cleaning processes must.  

The straight guide means are advantageously pins, which in one of the both bodies are attached and he bores in the other body stretch. There is also a certain amount of straight guide means risk of crusting, but it is lower than in the area of the spindle because the Pins in the course of the expansion of the expansion screw from the holes, in wel if they are guided, slide out but do not have to drive in; only over the pins travel back into the holes. Nevertheless it may be advantageous to also provide sealing rings there, which hold the pins surrounded and penetration of initially liquid food residues into the Boh prevent one body from struggling.

An embodiment of the invention is in the accompanying drawings shown.

Fig. 1 shows a longitudinal section through an expansion screw,

Fig. 2 shows an end view of the expansion screw, and

Fig. 3 shows a typical tension-strain diagram for a pseudoelastic wire.

The expansion screw shown in Figs. 1 and 2 has two mutually variable in their mutual distance, approximately cuboid body 1 and 2 , which can be adjusted by a spindle 3 . For this purpose, the larger body 1 has a first recess 4 for receiving an actuation supply part 5 of the spindle and a second recess 6 for receiving a first threaded portion 7 of the spindle. The first recess 4 is located on the side facing the second body 2 and is open to there. The second recess 6 is located on the opposite side of the body 1 and is closed by a cover 8 . The two recesses 4 and 6 are connected by a cylindrical bore 9 through which a threaded part 7 of the spindle is passed.

The other body 2 has on its side facing away from the first body 1 a recess 10, which is the same as the recess 6, for receiving a second threaded part 11 of the spindle. The recess 10 is also closed by a cover 8 ; on the opposite side of the body 2 has a cylindrical bore 12 through which the threaded part 11 is inserted into the recess 10 . In the recesses 6 and 10 is on the threaded parts 7 and 11 , a threaded sleeve 13 and 14 , respectively, which has a collar 15 with diagonal extensions 15 a, which in corresponding, longitudinal guide grooves in the recesses 6 and 10 limiting wall 16 or 17 engage and prevent rotation of the threaded sleeves 13 and 14 . Between the collar 15 and the cover 8 each egg ne pseudo-elastic coil spring 18 and 19 is clamped.

As a straight guide means two guide pins 20 and 21 are provided, which che are pressed at one end into holes in the body 2 and extend in the other holes 22 and 23 of the body 1 and are displaceable therein.

The expansion screw is adjusted by engaging with a pin from the open top 24 or from the open bottom 25 in one of the holes 26 of the actuating part and rotating it. As a result, the threaded sleeves 13 and 14 are moved away from one another and thereby tension the coil springs 18 and 19 , which in turn move the bodies 1 and 2 away from one another with the spring force available to them. O-rings 28 to 30 prevent food residues from penetrating into the bores 22 and 23 and into the recesses 6 and 10 .

Fig. 3 shows a typical tension-strain diagram for a pseudoelastic nickel-titanium wire. If such a wire is stretched by tension, you first need a moderately steep pulling force in order to stretch the wire progressively. From an elongation of approximately 2%, the tensile force required for a progressive elongation increases only very slightly, until it begins to increase again at about 8% elongation (upper branch A of the curve.) If the wire is then relieved, it forms the stretch back along the lower branch B of the curve. The appearance shows a hysteresis. The flat part of the characteristic curve, in the example shown between 2% and 8%, the so-called martensite plateau, is used for the purposes of the invention. The less effective for a tooth correction to the increase range of the curve between 0 and about 2% elongation can be switched off for the purpose of tooth correction by installing the springs 18 and 19 with a corresponding preload in the recesses 6 and 10 and the recesses 6 and 10 then closes, e.g. B. by flanging or welding the cover 8th

Claims (7)

1. Expansion screw for correcting incorrect positions of teeth, with two bodies ( 1 , 2 ), the mutual distance between which can be changed by means of a spindle ( 3 ) which has an actuating part ( 5 ) and, starting therefrom, one or two threaded parts ( 7 , 11 ) , wherein the actuating part ( 5 ) is rotatably mounted in one body ( 1 ) and a threaded part ( 11 ) in the other body ( 2 ), with straight guide means ( 22 , 23 ) which with both bodies ( 1 , 2 ) engage and guide them straight while avoiding a relative rotation when changing their distance, and with a threaded sleeve ( 13 , 14 ) on each of the threaded parts ( 7 , 11 ) of the spindle ( 3 ), the threaded sleeve ( 13 , 14 ) in a recess ( 6 , 10 ) of the respective body ( 1 , 2 ) is secured against rotation along the spindle ( 3 ) and communicates its displacement movement to the bodies ( 1 , 2 ) via a spring ( 18 , 19 ) determining the tensile force, characterized by it et that the spring ( 18 , 19 ) consists of a shape memory alloy which is pseu doelastic under the temperatures prevailing in the mouth. 2. Expansion screw according to claim 1, characterized in that the spring ( 18 , 19 ) consists of an alloy based on nickel and titanium, in which nickel and titanium are kept in approximately the same atomic percentages. 3. Expansion screw according to one of the preceding claims, characterized in that the spring ( 18 , 19 ) is a compression spring. 4. Expansion screw according to one of the preceding claims, characterized in that the spindle ( 3 ) has two threaded parts ( 7 , 11 ) with opposite winding direction. 5. Expansion screw according to claim 3, characterized in that the spring ( 18 , 19 ) between a on the threaded sleeve ( 13 , 14 ) provided abutment ( 15 ) and one of the recess ( 6 , 10 ) in the body ( 1 , 2 ) is clamped at the outer end of the cover ( 8 ). 6. Expansion screw according to one of the preceding claims, characterized in that the threaded parts ( 7 , 11 ) of the spindle ( 3 ) are surrounded by a seal ( 28 , 29 ) which from the actuating part ( 5 ) into the respective recess ( 6 , 10 ) of the body ( 1 , 2 ) sealing leading access ( 9 , 12 ). 7. Expansion screw according to one of the preceding claims, characterized in that the straight guide means ( 20 , 21 ) are pins which are fixed in one of the bodies ( 2 ) and extend in bores ( 22 , 23 ) of the other body ( 1 ) which are sealed by sealing rings ( 31 , 32 ) which surround the pins ( 20 , 21 ).