KR20090056519A - Testing jig for total knee-joint replacement - Google Patents

Abstract

A testing jig for an artificial knee-joint is provided to evaluate physical performance until the artificial knee-joint is dislocated by measuring twisting, bending, and binding power of the artificial knee-joint according to load in order to measure the durability of the artificial knee-joint. A testing jig(100) for an artificial knee-joint comprises: a base(10); a support(20) in which a first fixture(21) for supporting the tibia bone tissue(61) is connected to the front; a supporting plate(30) which is hinge-coupled in a connecting bar(40) to face the support; a weight(50) connected to the supporting plate; and a cartilage tissue(63) interposed between the tibia bone tissue and thighbone tissue(62). The second fixture is connected to the inside of the supporting plate. The second fixture supports the thighbone tissue adhering closely to the tibia bone tissue. The weight artificially gives the load applied to the knee joint of the human body by pulling the supporting plate.

Description

Testing Jig For Total Knee-Joint Replacement}

The present invention relates to an artificial knee joint test jig having a structure that can provide various types of environments such as bending and torsion of the artificial knee joint according to load conditions in order to evaluate the physical performance until the artificial knee joint is dislocated.

In general, the knee joint is composed of two bones consisting of the femur and tibia of the human body is in close contact. At this time, each bone is intercalated with cartilage to withstand external forces or severe pressure. The cartilage is cushioned and allows the bones to move well without pain, preventing joints from rubbing or fraying.

Artificial knee joints to replace these knee joints are very important to wear resistance, chemical resistance, bending strength, tensile strength, durability, corrosion resistance, flexibility hardness.

These artificial knee joints should be processed inside the acetabular cup and the acetabular cup to prevent dislocation due to wear and fatigue and to be used for a long time without failure.

Therefore, the artificial knee joint is replaced with artificial joint if the patient's knee joint is damaged and cannot be used to maintain normal activity or dislocation due to abrasion, strong physical force from outside, and structural defect of the artificial joint. This occurred and there was a problem that should be performed re-replacement surgery.

This phenomenon is that the artificial knee joint has a significant difference depending on the endurance has been studied continuously.

However, there is no device capable of evaluating the physical performance until dislocation to measure the durability of the artificial knee joint.

Therefore, there is a need for a device of a device that can provide various types of conditions such as bending and torsion of an artificial knee joint to evaluate physical performance until dislocation to measure durability of the artificial knee joint.

The present invention has been made in view of the above problems, the present invention has a structure that can provide a variety of environments, such as bending and torsion of the artificial knee joint to evaluate the physical performance until the artificial knee joint dislocated In the artificial knee joint test jig of the base, and fixed to the base, the first support for supporting the tibial tissue in front of the support post connected to the support post, and facing the support post through the hinge bar connected to the upper end of the support post It is hinged to the connecting bar, and the support plate is connected to the second support for supporting the femoral tissue that is in close contact with the support and the tibial tissue, and the load applied to the knee joint of the human body by pulling the support plate Weight weight connected with the support plate to be artificially applied; Made, including, the tibia tissue, femur tissue In between the cartilage tissue is provided to provide an artificial knee joint test jig characterized in having the same conditions as the knee joint of the human body.

Artificial knee joint test jig according to the present invention can adjust the angle of the femur up / down / left / right in the state in which the tibia is fixed to evaluate the physical performance until the artificial knee joint dislocated artificial knee joint according to the load There is a characteristic that can provide various types of conditions such as bending, torsion and restraint force.

Hereinafter, with reference to the accompanying drawings for the artificial knee joint test jig according to the present invention will be described in detail.

1A is a perspective view of an artificial knee joint test jig according to the present invention, and FIG. 1B is a plan view of FIG.

As shown in Figure 1a and Figure 1b, the present invention the angle of the femoral tissue up / down / left / right with the tibia tissue fixed in order to evaluate the physical performance until the artificial knee joint 60 dislocation It relates to the artificial knee joint test jig 100 of the structure that can provide various types of environment, such as bending and twisting, restraint force of the artificial knee joint 60 according to the load conditions.

The artificial knee joint test jig 100 is largely composed of five parts, which are the base 10, the support base 20, the support plate 30, the connecting bar 40 and the weight 50 It is composed.

Here, the holding stand 20 is fixed to the upper surface of the base 10, and is configured to be connected to the first fixing stand 21 for supporting the tibial tissue 61 in the front.

At this time, the first fixing part 21 is transmitted to the artificial knee joint 60 through the support plate 30 through the first rotating part 211 and the weight 50 to rotate the combined tibial tissue 61. It further comprises a load cell 212 for measuring the load.

In addition, the connecting bar 40 is hinged to the upper end of the support stand 20 to separate the support plate 30 from the base 10, while supporting the support plate 30 facing the support stand 20 Function. At this time, the support plate 30 is also provided with a structure that can be hinged with the connection bar 40, the freedom to move in the forward / backward direction is provided.

In addition, the connection bar 40 is divided into two so as to adjust the length to the central portion, it is configured to be connected to each other through the length adjusting screw (41).

In addition, the support plate 30 is configured to be connected to the second fixing stand 31 for supporting the femoral tissue 62 in close contact with the tibial tissue 61 on the inner side facing the holding table 20.

Here, the second fixing stand 31 has a structure further including a second rotating part 311 for rotating the femoral tissue 62 and a joint part 312 that bends the femoral tissue 62 up and down.

In addition, the support plate 30 has a structure in which a coupling cross 313 of a crisscross shape is formed so as to be bolted and coupled in an up / down / left / right direction according to the rotation direction of the second fixing stand 31.

Here, the structure of the femoral tissue 62 is determined in advance through the coupling hole 313 and then fixed. At this time, the angle of the femoral tissue 62 can be easily adjusted through the joint portion 312 bending the femur tissue 62 to the upper and lower parts.

In addition, the weight 50 is a structure that is connected to the support plate 30 so as to artificially apply a load applied to the knee joint of the human body by pulling the support plate 30.

The weight 50 is a load transfer through the wire 51 is connected to the support plate 30, the wire 51 is a structure that is supported through the pulley 52 is coupled to the back of the strut 20.

Meanwhile, the cartilage tissue 63 is interposed between the tibia tissue 61 and the femur tissue 62 to have the same conditions as the knee joints of the human body.

Hereinafter, with reference to the accompanying drawings with respect to the operation of the artificial knee joint test jig according to the present invention will be described in detail.

FIG. 1C is an operating state diagram of FIG. 1B, and FIG. 1D is a right side view of FIG. 1C.

1C and 1D, first, the artificial knee joint 60 is installed on the test jig 100, and the angle of the femoral tissue 62 connected to the second fixation table 31 is connected to the joint 312. After adjusting vertically, it is fixed to the coupling hole 313 of the support plate 30 (shown in FIG. 1D).

Thereafter, the artificial knee joint 60 is fixed to the test jig 100 through the length adjusting screw 41 of the connecting bar 40.

The weight of the weight 50 connected to the wire 51 is adjusted to a force (for example, 710N) applied when a person bends the knee or when the person stands on the knee. At this time, it is necessary to check the load applied to the artificial knee joint 60 through the load cell 212.

In this case, when the weight of the weight 50 is increased, the wire 51 pulls the support plate 30, and as the support plate 30 is pulled to the inner side, a load is transmitted to the second fixing table 31 to artificial knees. A load is applied to the entire joint 60 (shown in FIG. 1C).

Thus, the artificial knee joint test jig 100 of the present invention can provide various types of conditions (environment) such as bending, torsion, and restraint force before dislocation of the artificial knee joint 60 according to the load condition of the human body. .

Meanwhile, after providing various types of environments through the artificial knee joint test jig 100, a force is applied to the femoral tissue 62 through a separate tensile tester (not shown) in the direction of the arrow of FIG. 1C, and the tensile force is measured. It can provide an environment where it can be done.

 In addition, the restraint force of the artificial knee joint 60 may provide an environment that can be measured by using a tensile tester and software associated with a Chetillon gauge (Chatillon gauge) (not shown).

Figure 2a is a perspective view of the artificial knee joint test jig with the artificial knee joint rotated 90 °, Figure 2b is a plan view of Figure 2a, Figure 2c is an operating state of Figure 2b, Figure 2d is a right side view of Figure 2c to be.

As shown in Figure 2a to 2d, the artificial knee joint test jig 100 of the present invention can provide an environment that can measure the side twist and side bending and side restraint force of the artificial knee joint (60).

To this end, first, the artificial knee joint 60 is installed in the test jig 100.

And when the first rotating part 211 provided in the first fixing station 21 rotates about 90 degrees, the second rotating unit 311 provided in the second fixing unit 31 is also rotated together to tibial tissue 61, femoral bone tissue (62), the artificial knee joint (60) consisting of cartilage tissue (63) is rotated by 90 °. This provides an environment in which side torsion and side bending and side restraint force of the artificial knee joint 60 can be measured.

Then, the angle of the femoral tissue 62 connected to the second fixing table 31 is adjusted horizontally through the joint part 312 and then fixed to the coupling hole 313 of the support plate 30 (shown in FIG. 2D).

After that, the artificial knee joint 60 is fixed to the test jig 100 through the length adjusting screw of the connecting bar 40.

Here, the weight of the weight 50 connected to the wire 51 is matched to a force (for example, 710N) acting when the person bends the knee or when the person stands on the knee. At this time, it is necessary to check the load applied to the artificial knee joint 60 through the load cell 212.

In addition, when the weight of the weight 50 is increased, the wire 51 pulls the support plate 30, and as the support plate 30 is pulled to the inner side, the load is transferred to the second fixing table 31 to artificial knees. The load is applied to the entire joint 60 (shown in Fig. 2c).

Meanwhile, after providing the environment to measure the side of the artificial knee joint through the artificial knee joint test jig 100, the femoral tissue 62 through a separate tensile tester (not shown) in the direction of the arrow of Figure 2c. Forces can be applied to provide an environment in which tensile forces can be measured.

In addition, the restraint force of the artificial knee joint 60 may provide an environment that can be measured by using a tensile tester and software associated with a Chetillon gauge (Chatillon gauge) (not shown).

Although the present invention has been described in connection with the above-mentioned preferred embodiments, various other modifications and variations may be made without departing from the spirit and scope of the invention. Accordingly, it is intended that the appended claims cover such modifications and variations as fall within the true scope of the invention.

1A is a perspective view of an artificial knee joint test jig according to the present invention;

1B is a plan view of FIG. 1;

Figure 1c is an operating state of Figure 1b,

1D is a right side view of FIG. 1C;

Figure 2a is a perspective view of the artificial knee joint test jig in a state rotated 90 ° artificial knee joint,

Figure 2b is a plan view of Figure 2a,

Figure 2c is an operating state of Figure 2b,

FIG. 2D is a right side view of FIG. 2C;

<Detailed Description of Symbols for Drawings>

10: base

20: holding post 21: first fixing station 211: first rotating part 212: load cell

30: support plate 31: second fixing plate 311: second rotating part 312: joint portion

313: joiner

40: connecting bar 41: length adjusting screw

50: weight 51: wire 52: pulley

60: artificial knee joint 61: tibia tissue 62: femur tissue 63: cartilage tissue

100: artificial knee joint test jig

Claims (7)

In the artificial knee joint test jig 100 of the structure that can provide various types of conditions, such as bending and twisting of the artificial knee joint 60 to evaluate the physical performance until the artificial knee joint 60 dislocation , With the base 10, The support base 20 is fixed to the base 10 and connected to the first fixing base 21 for supporting the tibial tissue 61 in front, and It is hinged to the connecting bar 40 to face the support stand 20 through a connecting bar 40 hinged to the upper end of the support stand 20, the inner side facing the support stand 20 The support plate 30 is connected to the second fixing base 31 for supporting the femoral tissue 62 in close contact with the tibial tissue 61, A weight 50 connected to the support plate 30 to artificially apply a load applied to the knee joint of the human body by pulling the support plate 30; The knee joint test jig, characterized in that the cartilage tissue (63) is interposed between the tibia tissue (61) and the femur tissue (62) has the same conditions as the knee joint of the human body. The method of claim 1, The first stator 21 measures the load transmitted to the artificial knee joint 60 via the support plate 30 through the first rotation part 211 and the weight 50 to rotate the tibial tissue 61. Artificial knee joint test jig, characterized in that further comprises a load cell (212). The method of claim 1, The weight 50 is an artificial knee joint jig, characterized in that for transmitting the load through the wire 51 connected to the support plate (30). The method of claim 3, wherein The wire 51 is an artificial knee joint test jig, characterized in that supported through the pulley 52 is coupled to the back of the holding table (20). The method of claim 1, The second fixing stand 31 further includes a second rotation part 311 for rotating the femoral tissue 62 and a joint part 312 that bends the femoral tissue 62 in an upper / lower portion. Artificial knee joint test jig. The method of claim 1, The support plate 30 is a knee joint test jig, characterized in that the coupling hole of the cross-shaped form (313) is formed so as to be bolted to guide the second anchor 31 in the front / rear / left / right direction. The method of claim 1, The connecting bar 40 is divided into two so as to adjust the length, artificial knee joint test jig, characterized in that is configured to be connected to each other through the length adjustment screw (41).

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