KR102038359B1 - Assembly method for bone plate - Google Patents

Abstract

The present invention relates to a method for manufacturing a variable locking type bone plate assembly, which comprises: a first step of preparing a bone plate (110) having a through-hole (H′) formed therein; and a second step of preparing a bone screw (120′) having a head part (121′) formed with a protrusion part and a depression part (121′) and fastened to the through-hole (H′). The first step includes a (1-1)^th step of forming a plurality of latch grooves recessed to correspond to the protrusion part of the head part (121′) on an inner wall of a first region of an entrance part of the through-hole (H′). The second step is a step of finally fastening the bone screw (120′) to the bone plate (110) to allow the protrusion part to be positioned in the latch grooves, separately. The bone plate (110) which is a pair of structures hinge-coupled by a hinge shaft (H0), is horizontally rotated to be deviated from the same line. Therefore, the variable locking type bone plate assembly which can be more effectively and stably applied to various types of fracture parts, can be provided.

Description

Assembly method for bone plate assembly variable {Assembly method for bone plate}

The present invention relates to a modified lockable bone plate assembly, and more particularly, to a method of manufacturing a variable lockable bone plate assembly which can be more effectively and stably applied to various types of fractures.

The bone plate is placed over the bone piece and the support and joins the broken bone by securing the respective bone piece and the support and the bone plate through the bone screws. Such bone plates have been developed and applied in various forms. However, there is a problem in that the means that can be flexibly responded to the shape of the bone fragment and the type of fracture present. Therefore, there is a disadvantage that it is not easy to provide a variable lockable bone plate assembly that can be more effectively and stably applied to various types of fractures.

Korea Patent Registration No. 10-0424088

An object of the present invention is to provide a variable lockable bone plate assembly manufacturing method that can be more effectively and stably applied to fractures of various forms.

The present invention provides a method of assembling a variable locking bone plate assembly, comprising: a first step of preparing a bone plate (110) having a through hole (H '); And a second step of preparing a bone screw (120 ') for fastening to the through hole (H') having a head (121 ') having a protrusion and a recess (121b') formed therein. The method may include a first-first step of forming a plurality of latch grooves recessed to correspond to the protruding portion of the head portion 121 'on an inner wall of the first region of the through hole H ′. The second step is to final tighten the bone screw 120 'to the bone plate 110 so that the protrusions are positioned in the latch grooves, and the bone plate 110 is connected to the hinge shaft H0. Provides a method of assembling a variable lockable bone plate assembly which is provided as a hinge-paired structure to be left and right pivoted so as to deviate from the same line with each other.

According to the present invention there is an effect that can provide a variable locking bone plate assembly that can be more effectively and stably applied to various types of fracture.

1 and 2 are perspective views showing a variable locking bone plate assembly according to an embodiment of the present invention.
3 is a plan view of a bone plate of the configurations of the variable lockable bone plate assembly according to FIG. 1.
4 is a perspective view of the bone screw of the configurations of the variable lockable bone plate assembly according to FIG. 1.
5 is a cross-sectional view showing a state in which the bone screw according to Figure 1 is fastened to the bone plate.
6 is a cross-sectional view showing a state in which the bone screw according to Figure 1 is fastened to the bone plate at a set angle.
7 is a flowchart sequentially illustrating a method of assembling a variable lockable bone plate assembly according to an embodiment of the present invention.
8 to 16 are views showing the variable lockable bone plate assembly according to another embodiment of the present invention.
17 is a view showing a variable locking bone plate assembly according to another embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In this process, the thickness of the lines shown in the drawings, the size, ratio, etc. of the components may be exaggerated or schematically illustrated for clarity and convenience of description, and the same reference numerals are used to refer to the same components. .

1 and 2 are perspective views of the variable lockable bone plate assembly 100 'according to one embodiment of the invention, and FIG. 3 is a view of the variable lockable bone plate assembly 100' according to FIG. A plan view of the bone plate 110 'of the configurations. 4 is a perspective view of the bone screw 120 'of the configurations of the variable lockable bone plate assembly 100' according to FIG. 5 is a cross-sectional view illustrating a state in which the bone screw 120 'is fastened to the bone rate 110' of FIG. 1, and FIG. 6 is a bone screw 120 'of the bone plate 110' of FIG. It is sectional drawing which shows the state fastened by the setting angle. 1 and 2, the variable lockable bone plate assembly 100 ′ includes a bone plate 110 ′ and a bone screw 120 ′. Here, the bone plate 110 ′ is a panel having a plurality of through holes H ′, as shown in FIG. 3, and may preferably be formed in a rectangular panel shape.

The bone plate 110 ′ may have various lengths and widths depending on the fracture site. The inner wall of the first region S1 ', which is the first entry portion of the through hole H' of the bone plate 110 ', corresponds to the protrusion 121a' of the head portion 121 'of the bone screw 120' described later. A plurality of embedded latch grooves 111 'may be formed. The through hole H 'of the bone plate 110' may be formed such that the first region S1 'is rounded or tapered upwardly and downward, and the first region S1' of the through hole H 'is formed. A thread may be formed from at least a portion over the second region S2 ′ under the first entrance portion. In this case, the latch groove 111 ′ on the first region S1 ′ may be formed to overlap the thread pitch to block the thread pitch, or may be formed to be independent of the thread pitch. As shown in FIG. 4, the bone screw 120 ′ may have a head portion 121 ′ alternately formed with the protrusion 121 a ′ and the recess 121 b ′ and a shaft 122 ′ formed with a thread. have. As shown in FIG. 5, the bone screw 120 ′ may be fastened to pass through the first region S1 ′ and the second region S2 ′ through the through hole H ′ through reverse rotation or forward rotation. Can be. In this case, the bone screw 120 'may be finally tightened and fastened to the bone plate 110' such that the protrusion 121a 'is positioned in the latch groove 111'. Therefore, there is an effect that the bone screw 120 'fastened to the bone plate 110' can be prevented from being separated from the bone plate 110 'by flowing in the disengaging direction rather than the tightening direction due to external impact. Meanwhile, referring to FIG. 6, in the bone plate 110 ′, the thread on the first region S1 ′ and the second region S2 ′ is inclined at a predetermined angle in at least one of the through holes H ′. It can be formed to tilt.

Accordingly, in fixing the bone plate 110 'and the bone screw 120' with respect to the bone fragments, since the bone screws 120 'can be fastened at various angles according to the fracture types of the bone fragments, a more effective and stable procedure is possible. There is a possible effect. 7 is a flowchart illustrating a method (S100 ') of assembling a variable lockable bone plate assembly 100' according to an embodiment of the present invention. Hereinafter, different points from the bone plate assembly 100 ′ according to the exemplary embodiment will be described. Referring to FIG. 7, in the method of assembling the variable lockable bone plate assembly 100 ′ (S100 ′), a bone plate having a panel shape having a plurality of through holes H ′ is formed in a first step S110 ′. 110 '). More specifically, the first step may include the first-first step S111 'to the first-third step S113'.

First, in step 1-1 (S111 ′), a plurality of recesses recessed to correspond to the protrusion 121a ′ of the head portion 121 ′ on the inner wall of the first hole S ′ of the through hole H ′. The latch groove 111 ′ may be formed. Here, the bone plate 110 ′ may be formed by rounding or tapering the first region S1 ′ of the through hole H ′ from above to below. Next, in the first step S120 ′, the bone plate 110 ′ extends from at least a portion of the first area S1 ′ of the through hole H 'to the second area S2 ′ under the entry portion. Threads may be formed. Next, in the first step S113 ′, the threads on the first area S1 ′ and the second area S2 ′ are inserted into at least one of the through holes H ′ of the bone plate 110 ′. It can be formed to be inclined at a predetermined angle slope. Here, although the first-first step S111 'to the first-third step S113' are described as being sequentially performed, the present invention is not limited thereto and may be sufficiently performed out of order. The second step S120 ′ has a head portion 121 ′ in which the protrusion 121 a ′ and the recess 121 b ′ are alternately formed, and are fastened to the through hole H ′ through reverse rotation or forward rotation. Prepare a bone screw (120 '). In the second step S120 ′, the bone screw 120 ′ may be final tightened to the bone plate 110 ′ such that the protrusion 121 a ′ is positioned in the latch groove 111 ′, respectively. In more detail, the second step S120 ′ may include steps 2-1 S121 ′ and steps 2-2 S122 ′.

In the second step S121 ′, the bone screw 120 ′ may be fastened to the through hole H 'via the first region S1 ′ and the second region S2 ′. In the second step S122 ′, at least one of the protrusions 121a ′ of the head portion 121 ′ is directed toward at least one of the latch grooves 111 ′ according to the inclination of the thread. The bone screw 120 'may be fastened to an inclination corresponding to the inclined threads on the first region S1' and the second region S2 '. As described above, the first step S110 ′ and the second step S120 ′ are described as being sequentially performed with each other. However, the present invention is not limited thereto and may be sufficiently performed out of order.

8 to 16 are views illustrating a variable lockable bone plate assembly according to another embodiment of the present invention. Hereinafter, the same or similar parts as those described above will be omitted and the following description will be given based on technical features. Shall be.

8 to 16, the variable locking bone plate assembly includes a panel plate bone plate 110 having a plurality of through holes H formed therein; And a bone screw 120 having a head portion 121 in which the protrusion 121a and the recess 121b are alternately formed, and fastened to the through hole H through reverse rotation or forward rotation. Here, the bone plate 110 is a pair of structures hinged to the hinge axis (H0) is provided to be able to rotate left and right so as to deviate from the same line with each other.

The inner wall of the first region S1, which is the first entry portion of the through hole H, has a plurality of latch grooves 111 recessed to correspond to the protrusion 121a of the head portion 121, and the bone screw 120 is the final tightening and fastening to the bone plate 110 so that the protrusion 121a is located in the latch groove 111, the bone plate 110 is the first region of the through hole (H) S1 is formed to be rounded or tapered from above to below.

The bone plate 110 is formed with a thread from at least a portion of the first region S1 of the through hole H to a second region below the entry portion, and the screw is formed on the through hole H. It is fastened so as to pass through the first area S1 and the second area.

At least one of the through-holes H of the bone plate 110 is formed such that the threads on the first region S1 and the second region are inclined at a predetermined angle. The screw is fastened to be inclined at an inclination corresponding to the inclined screw thread on the first area S1 and the second area, and among the protrusions 121a of the head part 121 according to the inclination of the screw. At least one of the latch grooves 111 is provided to face the inside of at least one of the latch grooves 111.

The bone plate 110 includes a first bone plate 111 and a second bone plate 112 that is rotated in conjunction with the first bone plate 111 and the first bone plate 111. The first bone plate is provided on one side of the central axis with respect to the central axis in the longitudinal direction of the second bone plate 112, and the first bone plate 111 and the second bone plate 112 are rotated when the first bone plate 112 is rotated. A first restoration module 120 is provided to generate a restoring force so that the bone plate 111 and the second bone plate 112 are coaxially repositioned.

It is provided on the other side of the central axis, when the first bone plate 111 and the second bone plate 112, in the coaxial line of the first bone plate 111 and the second bone plate 112 The second restoration module 130 for generating a restoring force to be repositioned is provided.

At least one of the first restoration module 120 and the second restoration module 130 may include a first binding part 141 embedded in the first bone plate 111 and the second bone plate 112. The second binding unit 142 embedded in the) and the restoring force generating unit 143 for interlocking the first binding unit 141 and the second binding unit 142 is provided.

The restoring force generating unit is provided between the first binding unit 141 and the second binding unit 142 such that the tubular body 144 of a transparent material (eg, plastic) is extrapolated to block the inside and the outside. The first bone plate 111 and the second bone plate 112, when the second bone plate 112 is rotated at an angle from the first bone plate 111, the first bone plate 111. ) And a fixing module 150 for fixing the second bone plate 112 rotated with each other.

The fixing module 150 is fixed to the first bone plate 111 and the second bone plate 112 in a screwing manner, respectively.

The fixing module 150 may be provided in another type. For example, as shown in FIGS. 12 to 14, the first fixed body 151 provided on the side of the first bone plate 111 and the second fixed body provided on the side of the second bone plate 112 ( 152 is provided. The second fixing body 152 is fixed to the second bone plate 112 is fixed in the forward rotation or reverse rotation manner through the first fixing means (L1). The first fixing body 151 of the fixing module 150 has a first accommodating space H1 formed therein, and an upper region in which the second fixing body 152 is accommodated or roamed out in a rotational manner. A part UL is provided.

The second fixing body 152 is flowed to the second bone plate 112 is fixed position is fixed by the first fixing means (L1), the second fixing body 152, the first It is fixed to the fixed body 151 by the second fixing means (L2) rotatably.

Based on the forward rotation or reverse rotation of the second fixing means L2, the flow in the first fixing body 151 is limited. In the first fixing body 151 of the fixing module 150, a lower region portion Dl having a second receiving space therein is fitted to the side surface of the first bone plate 111 in a fitting manner. .

A magnetic protrusion MT protrudes from a side surface of the first bone plate 111 corresponding to the second receiving space H2, and a magnetic region corresponding to the magnetic protrusion is formed on an inner wall of the second receiving space H2. ML is formed, and the first bone plate 111, which is magnetically coupled to the magnetic protrusion MT and is accommodated in the second accommodation space, has a third fixing means from a lower portion of the lower region portion Dl. Through (H3), it binds in the forward or reverse rotation.

17 is a view showing a variable locking bone plate assembly according to another embodiment of the present invention. Referring to FIG. 17, the first bone plate 111 may include a first partition 111a, a second partition 111b, and a third partition 111c, and may be rotated by a predetermined radius in a torsional manner. It is possible.

First upper portions provided between the first partition portion 111a and the second partition portion 111b include first-first magnetic coupling parts 1621 and first-second magnetic coupling parts 1622, respectively. Magnetic coupling portion 162 is provided. At least one of the first-first magnetic coupling unit 1621 and the first-second magnetic coupling unit 1622 includes a first variable sensing unit 1623 for detecting a degree of position change based on the torsional rotation. It is provided.

A second side portion region between the first partition portion 111a and the second partition portion 111b includes a second-1 magnetic coupling portion 1631 and a second-2 magnetic coupling portion 1632, respectively. Magnetic coupling part 163 is provided. At least one of the 2-1 magnetic coupling unit 1631 and the 2-2 magnetic coupling unit 1632 includes a second variable sensing unit 1633 for detecting a degree of position change based on the torsional rotation. It is provided.

The third side portion region between the second partition portion 111b and the third partition portion 111c includes a 3-1 magnetic coupling portion 1611 and a 3-2 magnetic coupling portion 1612, respectively. Magnetic coupling part 161 is provided. At least one of the 3-1 magnetic coupling unit 1611 and the 3-2 magnetic coupling unit 1612 includes a third variable sensing unit 1613 for detecting a degree of position change based on the torsional rotation. It is provided.

The second bone plate 112 is provided with a fourth partition portion 112a, a fifth partition portion 112b, and a sixth partition portion 112c, and are provided to be rotatable by a predetermined radius in a torsion manner. The fourth region provided between the fourth compartment 112a and the fifth compartment 112b includes a 4-1 magnetic coupling unit 1651 and a 4-2 magnetic coupling unit 1652, respectively. Magnetic coupling portion 165 is provided.

At least one of the 4-1 magnetic coupling unit 1651 and the 4-2 magnetic coupling unit 1652 includes a fourth variable sensing unit 1653 for detecting a degree of position change based on the torsional rotation. It is provided. A fifth portion provided in the side region between the fourth partition portion 112a and the fifth partition portion 112b, respectively, as the 5-1 magnetic coupling part 1601 and the 5-2 magnetic coupling part 1662; Magnetic coupling portion 166 is provided.

At least one of the 5-1 magnetic coupling unit 1661 and the 5-2 magnetic coupling unit 1662 includes a fifth variable sensing unit 1663 for detecting a degree of position change based on the torsional rotation. And a sixth-first magnetic coupling part 1641 and a sixth-second magnetic coupling part 1644 in the upper region between the fifth partition 112b and the sixth partition 112c, respectively. The sixth magnetic coupling portion 164 is provided.

At least one of the 6-1 magnetic coupling unit 1641 and the 6-2 magnetic coupling unit 1644 includes a sixth variable sensing unit 1643 for detecting a degree of position change based on the torsional rotation. It is provided.

The sixth partition portion 112c has an outer end portion having an upper first flange portion 112c1 and a lower second flange portion 112c2, and the first flange portion 112c1 through a predetermined pressing means 112c3. And presses an object inserted into and inserted into the second flange portion 112c2, wherein the object includes a first partition 111a of another variable lockable bone plate assembly provided separately. On the other hand, it is obvious to those skilled in the art based on the present specification that the embodiments described above can be applied to each other in combination.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

110 ': bone plate
120 ': Bone screw
121 ': head

Claims (6)

A method of assembling a variable lockable bone plate assembly,
A first step of preparing a bone plate 110 having a through hole H 'formed therein; And
And a second step of preparing a bone screw (120 ') for fastening to the through hole (H') having a head (121 ') formed with a protrusion and a recess (121b'),
The first step,
And a first-first step of forming a latch groove on an inner wall of the first region of the through hole (H ') to correspond to the protruding portion of the head portion 121',
In the second step, the bone screw 120 'is finally tightened to the bone plate 110 so that the protrusions are respectively positioned in the latch grooves.
The bone plate 110 is a pair of structures hinged to the hinge axis (H0) is provided to be able to rotate left and right so as to deviate from the same line with each other,
The bone plate 110,
The first bone plate 111,
It includes a second bone plate 112 is rotated in conjunction with the first bone plate 111,
The first bone plate 111 and the second bone plate 112 are provided on one side of the central axis with respect to the central axis in the longitudinal direction of the first bone plate 111 and the second bone plate ( When the rotation between the 112, the first bone plate 111 and the second bone plate 112 is provided with a first restoration module 120 for generating a restoring force to be repositioned coaxially,
The first bone plate 111 and the second bone plate 112,
When the second bone plate 112 is rotated at a predetermined angle from the first bone plate 111, the fixing module for fixing the first bone plate 111 and the second bone plate 112 rotated with each other 150 is provided,
The fixing module 150 is fixed to the first bone plate 111 and the second bone plate 112 by screwing, respectively.
The fixed module 150,
A first fixed body 151 provided on the first bone plate 111 side;
A second fixing body 152 is provided on the second bone plate 112 side,
The second fixing body 152 is a variable lockable bone plate assembly assembly method is fixed to the second bone plate 112 is fixed in the forward or reverse rotation manner through the first fixing means (L1). delete The method according to claim 1,
It is provided on the other side of the central axis, when the first bone plate 111 and the second bone plate 112, in the coaxial line of the first bone plate 111 and the second bone plate 112 Assembly method of the variable lockable bone plate assembly is provided with a second restoration module (130) for generating a restoring force to reposition. The method according to claim 3,
At least one of the first restoration module 120 and the second restoration module 130,
A first binding part 141 embedded in the first bone plate 111,
A second binding part 142 embedded in the second bone plate 112,
A restoring force generating unit 143 for interlocking the first binding unit 141 and the second binding unit 142 is provided.
The restoring force generating unit is provided with a tubular body (144) is extrapolated so that the interior and the outside is blocked between the first locking portion (141) and the second binding portion (142) assembly method of the variable lockable bone plate assembly.

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