KR20210001805U - Slot variable orthodontic self-locking bracket - Google Patents

Abstract

In the slot variable orthodontic self-locking bracket of the present invention, a bracket base in contact with the teeth is formed on the lower portion of the bracket body, a slot for installing a wire is formed in the body of the bracket, and the wire is formed with a first wire and a second wire. a bracket body including two wires, wherein the dimension of the first wire in the vertical direction is smaller than the dimension of the second wire in the vertical direction; an elastic platen formed on one end wall portion of the slot, wherein a dimensionally variable passage is formed between the elastic platen and the slot wall portion, the passage is formed so that the wire enters and leaves the slot, and the vertical dimension of the first wire is the passage It is characterized in that it comprises an interdental initiator self-locking unit which is formed smaller than the maximum passage dimension of the second wire and the dimension in the vertical direction of the second wire is formed larger than the maximum passage dimension of the passage. The present invention has the effect of fully utilizing the advantages of orthodontic treatment step by step and compensating for the disadvantages. When the tooth is subjected to excessive tensile force, the first wire of the first stage of orthodontic treatment is automatically released from the limit of the elastic platen and separated from the slot.

Description

Slot variable orthodontic self-locking bracket

The present invention relates to the field of orthodontic brackets, and more particularly, to a slot variable orthodontic self-locking bracket.

Conventional orthodontic brackets are divided into two types of conventional ligation-type brackets and self-locking brackets according to the clinical treatment ligation type. The self-locking bracket can reduce the friction between the slot and the wire by replacing the conventional ligation-type structure with the self-locking structure of the bracket. etc. have advantages.

However, the conventional self-locking bracket has several problems as follows. 1. The self-locking bracket is a thin wire used in the first stage to correct uneven teeth. When a severely misaligned tooth is inserted with a wire and the cover is closed, the tooth receives great force and the tooth shakes, the musculature is adhered, and external resorption occurs. There is a problem that causes pain in the patient. 2. For the self-locking bracket, the size of the wire had to be smaller than the size of the slot because the wire was inserted into the slot when the tooth was fixed using a thick square wire in the second step (full-size wire cannot be inserted into the slot or Excessive corrective power). Therefore, a gap had to be created between the inner wall of the slot and the thick wire, and even the conventional self-locking cover cannot fix the thick wire in the slot, that is, since the gap between the wire and the slot cannot be removed, the bracket's provisional setting data ( There are problems that affect the precision of the torque, shaft inclination, etc.) and the effectiveness of orthodontic treatment. 3. The self-locking structure of the bracket is cumbersome and requires a large space, and the size and volume of the entire bracket are limited and the self-locking structure occupies a large space. There is a problem in that it is difficult to ligate the recognition loop, which causes inconvenience to the use of the product in the future. 4. The relatively complicated self-locking structure is difficult to produce and has problems in that the self-locking structure is loosened and hard or easily damaged during use.

Also, in the second step, after inserting a relatively hard wire (including the case of using a square wire and a round wire) into the slot of the bracket, the teeth are moved by using the wire as a rail while receiving orthodontic force. When a relatively thick rectangular wire is used, the gap between the square wire and the slot is small and the frictional force is large, so a large orthodontic force is required to move the teeth. Therefore, while the crown and the root have the advantage that the crown and the root move almost at the same time, there is a disadvantage that the fixed source consumed is relatively large (the unwanted tooth moves easily). On the other hand, when a relatively thin circular wire is used, the orthodontic force required for tooth movement is small because the gap between the circular wire and the slot is large and the frictional force is small. Therefore, while it has the advantage of a small consumed anchorage (unwanted teeth move easily), the crown moves more than the root, so it has a disadvantage in that it can be moved as a whole only when the root is erected in the future. These two technologies have their own advantages and disadvantages in orthodontic-related clinical treatment. The representative technology of the former is straight wire orthodontic technology, which has the advantage of being able to easily control the movement of teeth. teeth do not move), this method is widely used in clinical treatment. The representative technique of the latter is the Tip-Edge technique, which moves the entire tooth by tilting the crown first and then vertically moving the tooth root. Although this technique does not require a separate anchorage, it is not widely used in clinical treatment because it is cumbersome in setting up the root vertically and managing torque in the future.

The present invention has been devised to solve the above problems, and it is designed to have a suitable structure and forms an elastic pressure plate in the slot of the bracket to fully utilize the advantages and compensate for the disadvantages when using various wires and stages of orthodontic treatment. An object of the present invention is to provide a self-locking bracket with a slot variable type orthodontic brace.

In the first stage of orthodontic treatment, the process of inserting the first wire into the slot by the doctor pressing the first wire is very convenient, and when the tooth receives excessive tensile force, the first wire can be transmitted to the doctor to inform the doctor that the wire should not be completely inserted into the slot automatically escapes from the limit of the elastic platen and avoids unnecessary damage by escaping from the slot In addition to being able to move more in the direction, the teeth can be tilted to some extent in the mesial and distal direction, which prevents incisor protrusion and overbite, and requires relatively few anchors (no unwanted tooth movement). . At the same time, by using a compensating element at the beginning of orthodontic treatment, the depth of the slot becomes smaller and the wire moves less in the direction of the depth of the slot, so that the tooth can be easily corrected.

In the second stage of orthodontic treatment, the second wire is inserted into the slot by directly pressing the elastic platen, and the elastic platen is positioned between the wire and the slot to reduce the width of the slot, and the teeth have an appropriate tote, axial inclination angle and position. By removing the gap in the width direction between the wire and the slot, the effect of orthodontic treatment can be greatly improved by accurately controlling the inclination angle and torque angle of the tooth axis.

In addition, the self-locking structure of the present invention does not require a large space, and since the ligation wing structure of the present invention is not differentiated from the conventional ligation bracket, the ligation wire and the sieve recognition loop can be easily seated in place in clinical treatment. . The overall structure of the self-locking bracket does not have high demands on the production process, the self-locking structure is very stable, and the cost-effectiveness is high, so this design can solve the problems of the conventional self-locking bracket and orthodontic treatment technology.

In the slot variable orthodontic self-locking bracket of the present invention for solving such a problem, a bracket base in contact with the teeth is formed in the lower portion of the bracket body, and a slot for installing a wire is formed in the body of the bracket, , wherein the wire includes a first wire and a second wire, and a vertical dimension of the first wire is smaller than a vertical dimension of the second wire; an elastic platen formed on one end wall portion of the slot, wherein a dimensionally variable passage is formed between the elastic platen and the slot wall portion, the passage is formed so that the wire enters and exits the slot; an interdental initiator self-locking unit, wherein the directional dimension is smaller than the maximum passage dimension of the passage, and the vertical dimension of the second wire is greater than the maximum passage dimension of the passage; the elastic platen includes a first operating state and a second operating state; in the first operating state, the first wire is inserted into the slot through the passage to achieve a self-locking state; In the second operating state, the second wire presses the elastic pressure plate to approach the slot wall to form a non-self-locking state; characterized by including.

In addition, the elastic platen has a first pressure limiting the movement of the first wire to the outside, and the first wire is installed so that the elastic platen can receive the first pressure, and then presses the elastic platen in a direction spaced apart from the slot, , Tensile force is formed on the teeth through the second pressure received by the elastic platen, and when the second pressure exceeds the safety limit of the tensile force received by the teeth, the second pressure applied to the elastic platen by the first wire is the second pressure. It is formed to be greater than 1 pressure, and the first wire is separated from the slot.

In addition, a concave groove is formed in the wall portion of the slot, and the concave groove serves to enlarge the dimension in the slot width direction so that the movement range of the first wire in the slot width direction can be increased.

a compensating element is formed under the elastic platen, and when the elastic platen is in a first operating state, the compensating element is used for the purpose of reducing a dimension in which the first wire moves along the depth direction of the slot; When the elastic platen is in the second operating state, the compensating element is engaged with the concave groove to compensate for the increased dimension of the concave groove with respect to the width direction of the slot, thereby limiting movement of the second wire along the width direction of the slot. do.

In addition, the compensating element is made of an elastic compensating element, and when the elastic pressure plate is positioned above the slot, the elastic compensating element is configured such that a dimension of the first wire moving in the depth direction of the slot can be changed. It is elastically deformed after being compressed.

In addition, when the elastic compensating element and the concave groove contact each other and do not elastically deform, an angle is formed between the elastic platen and the wall portion of the slot, and when the elastic platen receives compression of the second wire, the elastic compensating element is elastically deformed so that the elastic platen is in close contact with the wall portion of the slot.

In addition, the elastic compensating element includes an elastic bending plate, one end of the elastic bending plate and the elastic platen are connected to each other, and the other end is formed across the elastic bending plate and the elastic platen to form an angle.

In addition, both ends of the elastic banding plate are respectively connected to the elastic platen, and a portion between the both ends to which the elastic banding plate and the elastic platen are connected is formed in a bending state.

In addition, the compensating element is composed of a hard compensating element, the hard compensating element is not elastically deformed after being compressed from the first wire or the second wire, and after the second wire is installed in the slot, the elastic platen and the The hard compensating element is formed in engagement with the concave groove so that the position between the slot walls can be relatively fixed.

In addition, the length of the elastic platen is formed to be the same as the length of the slot to prevent the second wire from moving in the slot.

In addition, the elastic platen has a third operating state, and when in the third operating state, the elastic platen is spaced apart from the slot so that the dimension passing through the passage can be formed to be larger than the dimension in the vertical direction of the second wire. direction, and after the second wire is inserted into the slot, the elastic platen is restored to a position above the slot to self-lock to the second wire, and a gap is formed between the second wire and the slot.

In addition, the elastic platen has a fourth operating state, and the elastic platen in the fourth operating state is bent in a direction spaced apart from the slot so that the elastic platen and the slot do not overlap each other in the vertical direction.

In addition, a vertical part connected to the bracket body is formed on the elastic platen, and a connection part is formed between the elastic platen and the vertical part, and the shear strength of the connection part is smaller than the shear strength of the elastic platen and the vertical part.

In addition, a ligation wing is formed on the bracket body, the elastic platen is formed at an intermediate position between the two ligation wings on the same side, and the elastic platen is formed so that the elastic platen can be in close contact with the trench outer surfaces of the two ligation wings. It is bent in a direction spaced apart from the slot along the connection part.

In addition, an arc is formed on the elastic platen to face the slot and protrude to the outside, and the arc of the elastic platen has a force for adhering the second wire in the second operating state so that the second wire can be caught in the slot. A gap between the second wire and the slot can be eliminated.

In addition, an installation groove is formed in the slot wall portion, the installation groove is located at one end opposite to the concave groove, and the installation groove is formed for the purpose of reducing a dimension in which the first wire moves in the width direction of the slot. and the size of the groove portion of the installation groove is formed smaller than the dimension in the vertical direction of the depth of the slot when the second wire is inserted into the slot, thereby limiting the insertion of the second wire into the installation groove.

The present invention is designed to have a suitable structure and forms an elastic platen in the slot of the bracket to fully utilize the advantages and compensate for the disadvantages when using various wires and stages of orthodontic treatment.

In the first stage of orthodontic treatment, the process of inserting the first wire into the slot by pressing the first wire by the doctor is very convenient, and when the tooth receives excessive tension, the first wire can be transmitted to the doctor to inform the doctor that the wire should not be completely inserted into the slot automatically escapes from the limit of the elastic platen and avoids unnecessary damage by escaping from the slot In addition to being able to move more in the direction, the teeth can be tilted to some extent in the mesial and distal direction, which prevents incisor protrusion and overbite, and requires relatively few anchors (no unwanted tooth movement). . At the same time, by using a compensating element at the beginning of orthodontic treatment, the depth of the slot becomes smaller and the wire moves less in the direction of the depth of the slot, so that the tooth can be easily corrected.

In the second stage of orthodontic treatment, the second wire is inserted into the slot by directly pressing the elastic platen, and the elastic platen is positioned between the wire and the slot to reduce the width of the slot, and the teeth can have an appropriate tote, axial inclination angle and position. By removing the gap in the width direction of the wire and the slot, the orthodontic treatment effect can be greatly improved by accurately controlling the inclination angle and torque angle of the tooth axis.

In addition, the self-locking structure of the present invention does not require a large space, and since the ligation wing structure of the present invention is not differentiated from the conventional ligation bracket, the ligation wire and the chain-type loop can be easily seated in place in clinical treatment. . The structure of the entire self-locking bracket does not require high production process, the self-locking structure is very stable, and the cost-effectiveness is high, so this design can solve the problems of the conventional self-locking bracket and orthodontic treatment technology.

1 is a perspective view showing the structure of the present invention;
Figure 2 is a left side view of Figure 1;
3 is a structural diagram showing a first operating state of the elastic pressure plate of the present invention;
4 is a structural diagram showing a second operating state of the elastic pressure plate of the present invention;
5 is a structural diagram showing a third operating state of the elastic platen of the present invention;
6 is a structural diagram showing a state in which an arc is formed on the elastic platen of the present invention;
7 is a structure in which the present invention is optimized;
8 is a structural diagram in which a first wire is installed in the structure of FIG. 7;
9 is a structural diagram in which a second wire is installed in the structure of FIG. 7;
10 is a first wire installation structure diagram of the present invention;
11 is a structural diagram in which the hard compensation element of the present invention is installed on a second wire;

In order to describe the technical features of the present invention in detail, the present invention will be described in detail below with reference to specific embodiments to which the drawings are attached.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to various descriptions, but the present invention may be practiced in other various ways. Accordingly, the scope of the present invention is not limited by the specific examples disclosed below.

The terms “center”, “top”, “bottom”, “tip”, “rear”, “left”, “right”, “vertical”, “horizontal”, “top”, “ The direction or positional relationship such as “bottom”, “inside”, “outside”, “axial direction”, “vertical direction”, “circumferential direction”, etc. is a direction or positional relationship indicated based on the accompanying drawings, so that it is easy to explain the present invention. It should not be construed as limiting the present invention, because it is used only for the purpose of the present invention, and this device or element does not necessarily have a specific orientation or a specific orientation.

In addition, the terms “first”, “second”, etc. are used for the purpose of explaining the purpose, and should not be construed as indicating or implying the relative importance or indicating the quantity of the indicated technical features. Accordingly, having a “first” or “second” feature is understood to include one or more of those features, either expressly or implicitly. In this case, "many" refers to two or more than two, unless otherwise specified.

Unless otherwise specified and limited in the description of the present invention, the terms “installation”, “connection to each other”, “connection”, and “fixed” will be understood from a wide range, for example, fixed connection, detachable connection or may be construed as an integral connection; shall be construed as a mechanical or electrical connection or communication; It will be interpreted as a direct connection or an indirect connection through an intermediary, or a penetration inside the two elements. By those of ordinary skill in the art to which the present invention pertains, the above terms in the present invention will be interpreted according to the relevant case.

Unless otherwise specified or limited in the description of the present invention, the first feature is in direct contact with the first and second features in the “upper” or “lower” of the second feature, or the first and second features are intermediary. understood as indirect contact. The terms “preferred embodiments”, “important things”, “examples”, “specific examples” or “some examples” used in the description of the present specification refer to specific features, structures, materials or It is said that a feature is included in at least one embodiment or illustration of the present invention. Exemplary expressions for the above terms herein are not limited to the same embodiment or illustration. In addition, specific features, structures, materials, or features of the description may be combined in any suitable manner in one or multiple embodiments or examples.

1-11, in the slot variable orthodontic self-locking bracket of the present invention, a bracket base (2) in contact with teeth is formed at the lower portion of the bracket body, and a wire is installed on the body (1) of the bracket. A slot 3 that can be formed is formed, and the wire includes a first wire 4 and a second wire 5, and the vertical dimension of the first wire 4 is the second wire 5 vertical direction. a bracket body (1) formed smaller than the dimension of; and an elastic platen 6 formed on one end wall portion of the slot 3, wherein a dimensionally variable passage 7 is formed between the elastic platen 6 and the wall portion of the slot 3, and the passage 7 includes the slot In (3), the wire is formed for the purpose of entering and leaving, the vertical dimension of the first wire 4 is formed smaller than the maximum passage dimension of the passage 7, and the vertical dimension of the second wire 5 a self-locking unit (6) for interdental discrepancy formed to be larger than the maximum passage dimension of the passage (7); The elastic platen 6 has a first operating state and a second operating state; In the first operating state, the first wire 4 is inserted into the slot 3 through the passage 7 to achieve a self-locking state; In the second operating state, the second wire 5 presses the elastic platen 6 to approach the slot 3 wall portion to form a non-self-locking state; characterized by including.

3 and 4, the elastic platen 6 includes a first operating state and a second operating state; In the first operating state, the first wire 4 having a dimension in the vertical direction formed smaller than the maximum passing dimension of the passage 7 is inserted into the slot 3 through the passage 7 to form a self-locking state, ; In the second operating state, the second wire 5 having a dimension in the vertical direction formed to be larger than the maximum passing dimension of the passage 7 is compressed by the other end of the elastic platen 6 and the slot 3 to remove the gap. After the non-self-locking state is formed, the wire in this state is fixed by ligation. Because the provisional torque of the bracket cannot be accurately expressed, the orthodontist has no choice but to adjust the torque by bending the wire. such risks may arise. As shown in Figure 4, the elastic pressure plate 6 in the second operating state is inserted into the slot 3 so that the torque expressed from the second wire 5 can achieve a smoother, safer, and more efficient state. By directly fixing the second wire 5 through 3), it is possible to reduce the patient's pain and side effects.

In addition, the elastic platen 6 has a first pressure that limits the movement of the first wire 4 to the outside, and the first wire 4 is installed so that the elastic platen 6 can receive the second pressure. The elastic platen 6 is pressed in a direction spaced from the slot 3, and a tensile force is formed on the teeth through the second pressure that the elastic platen 6 receives, and the second pressure exceeds the safe range of the tensile force that the teeth receive. In this case, the second pressure applied to the elastic platen 6 by the first wire 4 is greater than the first pressure, and the first wire 4 is separated from the slot 3 . After the first wire 4 is installed, while moving in the slot 3, a force to adhere the slot 3 is formed or a second pressure to apply the elastic pressure plate 6 is formed, and these forces Therefore, the second pressure receives a tensile force corresponding to the teeth, and when the second pressure exceeds the safe range of the tensile force received by the teeth, the force applied to the first wire 4 and the bracket body 1 is adjusted. The first wire 4 automatically escapes from the limit of the elastic platen 6 and disengages from the slot 3 so as to convey the information to the doctor that it should be done, so that the patient does not suffer unnecessary damage and pain.

In a preferred embodiment, an installation groove 8 is formed in the wall portion of the slot 3 , and the concave groove 8 is formed to increase the movement range of the first wire 4 toward the width direction of the slot 3 . The slot 3 is formed for the purpose of increasing the dimension in the width direction.

A compensating element 9 is formed in the lower portion of the elastic platen 6, and when the elastic platen 6 is in the first operating state, the compensating element 9 determines that the first wire 4 is connected to the depth of the slot 3 formed for the purpose of reducing the dimension moving in the direction; When the resilient platen 6 is in the second operative state, the compensating element 9 engages with the recess 8 so that the recess 8 compensates for the increased dimension in the width direction of the slot 3 so that the 2 Limits the movement of the wire (5) along the width direction of the slot (3). In use, when the elastic platen 6 is in the first operating state (ie, orthodontic initial stage), the width of the slot 3 increases and the gap between the first wire 4 and the slot 3 increases as the first wire (4) can move more in the width direction of the slot (3), and since the teeth can be inclined to some extent in the mesiodistal direction, protrusion of the incisors and overbite can be prevented, and the fixation source required is relatively small (Unwanted teeth do not move). At the same time, when the elastic platen 6 is in the first operating state, by using the compensating element 9, the depth of the slot 3 becomes smaller and the wire moves less in the depth direction of the slot, so that the tooth can be easily corrected. there is. When the elastic platen 6 is in the second operating state (late orthodontic treatment), in the second stage of orthodontic treatment, the width of the slot 3 is reduced and the second wire ( 5) and the slot 3, by removing the gap in the width direction, the tooth axis inclination angle and the torque angle can be accurately controlled, and the orthodontic treatment effect can be greatly improved.

In addition, as long as the first wire 4 can be moved along the width direction of the slot 3 , the shape of the concave groove 8 can be arbitrarily set according to the actually processed and used state, and the concave groove 8 is The shape of the compensating element 9 may be formed by being coupled according to the state of the concave groove 8 as long as it is possible to compensate for the increased dimension in the width direction of the slot 3 .

In a preferred embodiment, the compensating element 9 consists of an elastic compensating element 901 , and when the elastic pressure plate 6 is located above the slot 3 , the first wire 4 is connected to the depth of the slot 3 . The elastic compensating element 901 is elastically deformed after being compressed by the first wire 4 so that the dimension moving in the direction can be changed. After using the elastic compensating element 901 , the dimension in which the first wire 4 moves along the depth direction of the slot 3 is reduced and movement is limited, and the elastic compensating element 901 is the first wire 4 . The force applied to the teeth is safe and soft because the elastic deformation under compression, that is, the tensile force on the first wire 4 acts as a buffer, and the first wire 4 in the depth direction of the slot 3 Since the moving dimension can be changed, it can give a better effect.

Further, when the elastic compensating element 901 and the concave groove 8 come into contact with each other and are not elastically deformed, an angle is formed between the elastic pressure plate 6 and the wall portion of the slot 3; When the elastic platen 6 receives the compression of the second wire 5 , the elastic compensation element 901 is elastically deformed so that the elastic platen 6 is in close contact with the wall portion of the slot 3 . In the prior art, since the hypothetical torque angle of the bracket cannot be accurately expressed, in general, the orthodontic treatment doctor adjusts the torque by bending the wire. As a result, risks such as root resorption may occur. 9, when the elastic pressure plate 6 of the present invention is in the second operating state, the torque expressed from the second wire 5 is smoother, safer, and a second wire ( After the 5) is inserted into the slot 3, the elastic compensating element 901 is inserted into the concave groove 8, and the elastic pressure plate 6 is coupled with the wall portion of the slot 3 to hold the second wire 5. By direct fixation, the patient's pain and side effects can be reduced.

In a preferred embodiment, the elastic compensating element 901 includes an elastic banding plate, one end of the elastic banding plate is connected to the elastic platen 6 and the other end is formed by the elastic banding plate and the elastic platen 6 forming an angle. It is formed so as to be able to, and one end of the elastic banding plate is connected to the elastic platen 6 and similarly serves to limit the first wire 4 and to compensate for the concave groove 8 .

In a preferred embodiment, both ends of the elastic banding plate are respectively connected to the elastic platen 6, and a portion between the elastic banding plate and the both ends to which the elastic platen 6 is connected is formed in a bending state. When the elastic banding plate is compressed, its appearance is elastically deformed, that is, the shape of the elastic compensating element is changed. Both ends of the elastic banding plate are fixed and connected to each other with the elastic platen 6 so as to be formed. The structure connected to both ends of the elastic banding plate is a more reliable optimization method than the structure in which the one end is fixed and the one end is over.

In addition, the connection position of the elastic banding plate and the elastic platen 6 is spaced apart from the connection portion of the elastic platen 6 and the bracket body (1). By gently applying the force applied to the elastic banding plate connected to one end, the connection position of the elastic banding plate and the elastic platen 6 is deliberately set at a position spaced apart from the connection part of the elastic platen 6 and the bracket body 1; At this time, the elastic banding plate not only limits and serves as a buffer for the first wire 4, but also has a concave groove 8 so that the position of the elastic platen 6 can be determined when the elastic platen 6 is in the second operating state. ) is effectively compensated.

In an alternative method, the compensating element 9 is composed of a hard compensating element 902, and the hard compensating element 902 is not elastically deformed after being compressed from the first wire 4 or the second wire 5. After the second wire 5 is installed in the slot, the rigid compensating element 902 is coupled to the concave groove 8 so that the position between the elastic platen 6 and the wall portion of the slot 3 can be relatively fixed. is formed When the elastic platen 6 is in the second operating state as shown in FIG. 10, the second wire 5 is slotted so that the torque expressed from the second wire 5 is smoother, safer, and more efficient. After being inserted in (3), the elastic compensating element 902 is inserted into the concave groove (8) so that the elastic pressure plate (6) is coupled to the wall portion of the slot (3) to directly fix the second wire (5).

In a preferred embodiment, the length of the resilient platen 6 is formed equal to the length of the slot 3 to limit the movement of the second wire 5 within the slot. In this embodiment, the length of the elastic platen 6 cannot cover the longitudinal direction of the slot 3, so that the second wire 5 is not covered between the longitudinal direction of the elastic platen 6 and the slot 3, so the position It is possible to prevent the inability to accurately express the torque angle by being distorted; Since the elastic platen 6 can completely cover the slot 3 in the longitudinal direction, it is possible to effectively limit the movement of the second wire 5 in the width direction of the slot 3 to accurately express the torque angle.

In addition, the elastic pressure plate 6 has a third operating state, and when in the third operating state, the dimension passing through the passage 7 can be formed to be larger than the dimension in the vertical direction of the second wire 5 . The elastic platen 6 is bent in a direction spaced apart from the slot 3, and after the second wire 5 is inserted into the slot 3, the elastic platen 6 is restored to the upper position of the slot 3 and made The second wire 5 is self-locking, and a gap is formed between the second wire 5 and the slot 3 .

In an alternative embodiment that can be replaced in comparison with the third operating state of the elastic platen 6 , the elastic platen 6 has a fourth operating state, and the elastic platen 6 in the fourth operating state includes the elastic platen 6 and The slots 3 are bent in a direction spaced apart from the slots 3 so that they do not overlap each other in the vertical direction. The elastic platen 6 is separated from the slot 3 in the vertical direction to ensure a non-self-locking state in the future.

In a preferred embodiment, the elastic platen 6 includes the bracket body 1 and the elastic platen 6 so that the elastic platen 6 can be easily moved to the fourth operating state and the connection stability between the elastic platen 6 and the bracket body 1 can be improved. A connected vertical part 10 is formed, a connection part 11 is formed between the elastic platen 6 and the vertical part 10, and the shear strength of the connection part 11 is the elastic platen 6 and the vertical part 10. is formed less than the shear strength of The elastic platen 6 and the vertical part 10 are integrally formed, and the vertical part 10 is connected to the bracket body 1 so that the elastic platen 6 can be set more stably and accurately. The vertical portion 10 is integrally formed with the bracket body 1; Alternatively, the vertical portion 10 and the bracket body are connected to each other by welding.

In a preferred embodiment, the ligating wing 13 is formed on the bracket body 1, the elastic platen 6 is formed at an intermediate position between the two ligating wings 13 on the same side, and the elastic platen 6 is provided with two The elastic pressure plate 6 is bent in a direction spaced apart from the slot 3 along the connecting portion so as to be in close contact with the outer surface of the trench 14 of the ligation wing 13 of the . It is possible to prevent the elastic platen 6 from being cut during use, and the elastic platen is bent so that it can be in close contact with the position of the trench 14 in the middle portion of the ligation wing 13 . The ligation wing 10 is designed so that the wire can be easily ligated and fixed. The connecting portion 11 is made of a material having a shear strength smaller than that of the elastic platen 6 and the vertical portion 10; Alternatively, by reducing the amount of material used in the connection part 11 so that the thickness of the connection part 11 can be formed smaller than the thickness of the elastic platen 6 and the vertical part 10, the elastic platen 4 operates normally and the connection part 11 It can give a banding effect.

In another bending alternative method of the elastic platen 6, a method of directly cutting the elastic platen 6 can be used, and a plurality of holes can be formed in the connection part 11, and the connection part 11 position through the design of the hole It is possible to cut the elastic platen 6 bent upward by reducing the shear strength of the.

In a preferred embodiment, the elastic platen 6 is formed with an arc protruding outwardly facing the slot 3 so that the first wire 5 can be compressed and limited in the slot 3 through the elastic platen 6 and , a force to adhere the second wire 5 in the second operating state is formed in the arc of the elastic pressure plate 6 so that the second wire 5 can be caught in the slot 3, so that the second wire 5 ) and the gap in the slot 3 can be eliminated.

In a preferred embodiment, an installation groove 12 is formed in the wall portion of the slot 3 , the installation groove 12 is located at one end opposite to the concave groove 8 , and the installation groove 12 is the first wire 4 ) is used to increase the dimension moving in the width direction of the slot 3, and the dimension of the groove part of the installation groove 12 is smaller than the dimension in the vertical direction of the slot depth when the second wire 5 is inserted into the slot 3 is formed to limit the insertion of the second wire 5 into the installation groove. The installation groove 12 and the concave groove 8 face each other to further increase the dimension at which the first wire 4 moves in the width direction of the slot 3 so that the teeth can be inclined to some extent in the mesio-distal direction. Therefore, protrusion of the incisors and overbite can be prevented.

Although preferred embodiments of the present invention have been described above, the scope of the present invention is not limited thereto, and it is easily changed by those of ordinary skill in the art to which the present invention pertains and all within the range recognized as equivalent. Includes changes and modifications.

Parts that are not described in detail in the present invention are techniques known to those skilled in the art to which the present invention pertains.

1: Bracket body 2: Bracket base 3: Slot
4: first wire 5: second wire 6: elastic platen
7: Passage 8: Concave groove 9: Compensation factor
901: elastic compensation element 902: hard compensation element
10: vertical part 11: connection part 12: installation groove
13: ligation wing 14: trench

Claims (15)

A slot-variable orthodontic self-locking bracket, a bracket base in contact with teeth is formed on a lower portion of the bracket body, a slot for installing a wire is formed in the body of the bracket, and the wire is a first wire and a second wire Including, The vertical dimension of the first wire is a bracket body formed smaller than the dimension of the second wire in the vertical direction; an elastic platen formed on one end wall portion of the slot, wherein a dimensionally variable passage is formed between the elastic platen and the slot wall portion, the passage is formed so that the wire enters and exits the slot; an interdental initiator self-locking unit, the directional dimension being smaller than the maximum passage dimension of the passage, and the vertical dimension of the second wire being greater than the maximum passage dimension of the passage; the elastic platen includes a first operating state and a second operating state; in the first operating state, the first wire is inserted into the slot through the passage to achieve a self-locking state; In the second operating state, the second wire presses the elastic pressure plate to approach the slot wall portion to form a non-self-locking state. According to claim 1,
The elastic platen has a first pressure limiting the movement of the first wire to the outside, and the first wire is installed so that the elastic platen can receive the first pressure, and then presses the elastic platen in a direction spaced apart from the slot, Tensile force is formed on the teeth through the second pressure received by the elastic platen, and when the second pressure exceeds the safe range of the tensile force received by the teeth, the second pressure applied to the elastic platen by the first wire is the first Slot variable orthodontic self-locking bracket, characterized in that formed greater than the pressure, the first wire is separated from the slot. According to claim 1,
a concave groove is formed in the wall portion of the slot, and the concave groove serves to enlarge a dimension in the slot width direction so that a movement range of the first wire in the slot width direction can be increased;
a compensating element is formed under the elastic platen, and when the elastic platen is in a first operating state, the compensating element is used for the purpose of reducing a dimension in which the first wire moves along the depth direction of the slot;
When the elastic platen is in the second operating state, the compensating element is engaged with the concave groove to compensate for the increased dimension of the concave groove with respect to the width direction of the slot, thereby limiting movement of the second wire along the width direction of the slot. Slot variable orthodontic self-locking bracket, characterized in that. 4. The method of claim 3,
The compensating element is made of an elastic compensating element, and when the elastic pressure plate is positioned above the slot, the elastic compensating element is configured to change the dimension of the first wire in the depth direction of the slot. Slot variable orthodontic self-locking bracket, characterized in that it is elastically deformed after being compressed. 5. The method of claim 4,
When the elastic compensating element and the concave groove contact each other and do not elastically deform, an angle is formed between the elastic pressure plate and the wall portion of the slot, and when the elastic pressure plate receives compression of the second wire, the elastic compensating element becomes elastic Slot variable orthodontic self-locking bracket, characterized in that it is deformed and the elastic platen is in close contact with the wall portion of the slot. 6. The method according to claim 4 or 5,
The elastic compensating element includes an elastic banding plate, one end of the elastic banding plate and the elastic platen are connected to each other, and the other end is formed across the elastic banding plate and the elastic platen to form an angle. Slot variable orthodontic self-locking bracket. 7. The method of claim 6,
Both ends of the elastic banding plate are respectively connected to the elastic platen, and a portion between the elastic banding plate and the both ends connected to the elastic platen is formed in a bending state. 4. The method of claim 3,
The compensating element is composed of a hard compensating element, the hard compensating element is not elastically deformed after being compressed from the first wire or the second wire, and the elastic platen and the slot wall after the second wire is installed in the slot The slot-variable orthodontic self-locking bracket, characterized in that the hard compensating element is coupled to the concave groove so that the position therebetween can be relatively fixed. 9. The method according to claim 4 or 8,
A slot variable orthodontic self-locking bracket, characterized in that the length of the elastic platen is formed to be the same as the length of the slot to prevent the second wire from moving in the slot. 3. The method of claim 2,
The elastic platen has a third operating state, and when in the third operating state, the elastic platen is spaced apart from the slot so that the dimension passing through the passage can be formed to be larger than the dimension in the vertical direction of the second wire. is bent, and after the second wire is inserted into the slot, the elastic platen is restored to a position above the slot to self-lock to the second wire, and a gap is formed between the second wire and the slot. Adjustable orthodontic self-locking brackets. 3. The method of claim 2,
The elastic platen has a fourth operating state, and the elastic platen in the fourth operating state is a slot-variable orthodontic person, characterized in that the elastic platen and the slot are bent in a direction spaced apart from the slot so that the elastic platen and the slot do not overlap each other in the vertical direction. locking bracket. 12. The method of claim 11,
A vertical portion connected to the bracket body is formed on the elastic platen, and a connection portion is formed between the elastic platen and the vertical portion, and the shear strength of the connection portion is formed to be smaller than the shear strength of the elastic platen and the vertical portion. Orthodontic self-locking bracket. 13. The method of claim 12,
A ligation wing is formed on the bracket body, and the elastic platen is formed at an intermediate position between the two ligation wings on the same side, and the elastic platen is a connection part so that the elastic platen can be closely attached to the trench outer surfaces of the two ligation wings. A slot-variable orthodontic self-locking bracket, characterized in that it is bent in a direction spaced apart from the slot along the. 3. The method of claim 2,
An arc is formed on the elastic platen to face the slot and protrude to the outside, and a force for adhering the second wire in the second operating state is formed on the arc of the elastic platen so that the second wire can be caught in the slot. Slot variable orthodontic self-locking bracket, characterized in that it can remove the gap between the wire and the slot. 4. The method of claim 3,
An installation groove is formed in the slot wall portion, the installation groove is located at one end opposite to the concave groove, and the installation groove is formed for the purpose of reducing a dimension in which the first wire moves in the width direction of the slot, the The size of the groove portion of the installation groove is formed smaller than the dimension in the vertical direction of the depth of the slot when the second wire is inserted into the slot to limit the insertion of the second wire into the installation groove. expression bracket.

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