KR20210146016A - Blood test apparatus - Google Patents

Abstract

The present invention provides a blood test apparatus capable of miniaturizing a product and simply testing blood within a very short time when testing blood through coagulation and melting process of blood according to generation and melting of blood clot. The blood test apparatus comprises: a test chamber in which blood is sprayed; a first disc rotatively installed inside the test chamber based on a first rotation axis; a second disc rotatively installed inside the test chamber based on a second rotation axis of the same direction as the first rotation axis, and facing the first disc to be spaced apart from each other; a disc driver to rotate the first disc based on the first rotation axis; and a rotation sensor to detect rotation of the second disc. The second disc is rotated through the blood according to the rotation of the first disc. A rotation characteristic of the blood is changed according to coagulation and melting process of the blood. Therefore, a product may be miniaturized and blood may simply tested within a very short time when testing blood through coagulation and melting process of blood according to generation and melting of blood clot.

Description

Hemostasis test device {BLOOD TEST APPARATUS}

The present invention relates to a hemostasis test apparatus, and more particularly, to a hemostasis test apparatus capable of inspecting blood coagulation and dissolution processes through Thromoelastography (TEG).

The formation and dissolution of thrombus is a decisive phenomenon in cardiovascular and cerebrovascular diseases, and if there is a technology that can be tested in vitro in advance, it can be used as a breakthrough clinical technology.

The key to this technology will be the ability to self-dissolve again when blood clots are formed, as well as hyperreactivity and thrombus formation of platelets in the issue of blood vessel clogging and death. In other words, even if a blood clot is formed in the body, a person who has the ability to dissolve it will live for a long time without vascular disease without being aware of this phenomenon. It suggests that you may be exposed to fatal situations.

The most widely known technology in existence is Thromoelastography (TEG) technology, which was proposed in the 1940s and has been rapidly expanded in recent years.

In this technique, as in the setup shown in Fig. 1 (a), a pin is attached to a torsion wire, and the pin is deposited inside the whole blood while the whole blood is accommodated in a cup. Then, when the cup is rotated forward and backward within a certain angle range, a thrombus is generated and coagulated in the whole blood accommodated in the cup, and when a certain time elapses, it undergoes a process of dissolving again.

At this time, the pin deposited on the whole blood does not rotate at the initial stage of the forward and reverse rotation of the cup, but rotates along with the forward and reverse rotation of the cup due to friction with the whole blood while the whole blood is coagulated. will do And, in the process of re-dissolving whole blood, the opposite phenomenon is exhibited. If this is graphed by measuring the torque or rotation radius of the torsion spring, the graph as shown in FIG. (TEG, Thromoelastography) can be measured.

However, as shown in (a) of FIG. 1 , when the cup-shaped chamber is opened in a state where blood is accommodated therein and the cup is manufactured to rotate, there is a limit to downsizing the test equipment.

Accordingly, the present invention has been devised to solve the above problems, and in performing a hemostasis test of blood through the clotting and dissolution process of blood according to the generation and dissolution of a thrombus, the product can be miniaturized and very short An object of the present invention is to provide a new hemostasis test device that can be easily tested within a short period of time.

According to the present invention, in the hemostasis test apparatus, a test chamber into which blood is injected, a first disk installed in the test chamber rotatably about a first rotational axis, and the first rotational axis in the same direction a second disk installed inside the test chamber to be rotatably rotatable about a second rotational axis of a disk driving unit rotating around The second disk rotates through the blood according to the rotation of the first disk, and is achieved by a hemostasis test apparatus, characterized in that the rotational characteristics change according to the clotting process and dissolution process of the blood.

Here, the disk driving unit may rotate the first disk forward and reverse within a preset angle range with respect to the first rotation axis.

In addition, the first disk is provided with a material that has a magnetic force or can be magnetized by magnetism; The disk driving unit may include a rotating magnet installed outside the test chamber to face the first disk, and a driving motor for rotating the rotating magnet forward and reverse so that the first disk rotates by a magnetic force of the rotating magnet. .

And, the first disk is provided with a material having a magnetic force; The disk driving unit may include a rotary type voice coil actuator that rotates the first disk forward and reverse.

And, a first rotation shaft support for rotatably supporting the first disk with respect to the test chamber; It may further include a second rotation shaft support for rotatably supporting the second disk with respect to the test chamber.

In addition, the first rotation shaft and the second rotation shaft are formed along a vertical direction so that the first disk and the second disk are vertically spaced apart from each other in the chamber, and the first disk is the second disk. located at the bottom of the disc; The first rotation shaft support portion includes a first pin type support portion including a rotation pin extending downward from the first disk and a first pin insertion hole formed on the bottom surface of the test chamber and into which the rotation pin is rotatably inserted; , a first bearing type support having a first rotation shaft extending downwardly from the first disk, and a first bearing module installed in the inspection chamber to rotatably support the first rotation shaft; It may include any one of a plurality of guide holes formed along the rotational direction of the first disk on the bottom surface, and a ball-type support having a guide ball seated in each of the guide holes to guide the rotation of the first disk have.

In addition, the second rotation shaft support portion includes a suspension type support portion having a connection portion for hanging the second disk from the ceiling inside the test chamber so that the second disk is rotatable, and an upper pin extending upwardly from the second disk; An upper insertion hole formed in the ceiling of the test chamber and into which the upper pin is rotatably inserted; A second pin-type support part having a lower insertion hole into which a pin is rotatably inserted, a second rotation shaft extending upwardly from the second disk, and installed in the test chamber to rotatably support the second rotation shaft It may include any one of the second bearing type support having a second bearing module.

The first disk has a first blade extending toward the second disk and a plate surface facing the first rotation axis, and the second disk extends toward the first disk and is spaced apart from the first blade. It may further include a second blade facing.

And, any one of the first blade and the second blade is provided as a pair spaced apart toward the first rotation shaft or the second rotation shaft; The other one of the first blade and the second blade may be positioned between any one of the pair.

In addition, the rotation detection unit includes a light type detection unit having a light irradiator for irradiating light toward the second disk, and a light detection unit for detecting light passing through or reflected from the second disk; An interlocking type detection unit having an interlocking rotation unit rotating in association with the rotation of the second disk, an interlocking detection unit sensing the rotation of the interlocking rotation unit, a displacement sensing magnet installed on the second disk, and the test chamber outside The second disk may include any one of a magnetic type detection unit having a magnetic field displacement sensor for detecting the displacement of the displacement detection magnet according to the rotation of the disk.

On the other hand, according to another embodiment of the present invention, in a hemostasis test apparatus, a test chamber into which blood is injected, a disk installed in the test chamber rotatably about a rotational axis, and the disk are disposed on the rotational shaft a disk driving unit rotating around the , and a rotation sensing unit sensing rotation of the disk; The disk is also achieved by a hemostasis test device, characterized in that the rotational characteristics change according to the clotting process and the dissolution process of the blood.

Here, the disk driving unit may rotate the disk forward and reverse within a preset angle range with respect to the rotation axis.

In addition, the disk is provided with a material that has a magnetic force or can be magnetized by magnetism; The disk driving unit may include a rotating magnet installed outside the test chamber to face the disk, and a driving motor configured to rotate the rotating magnet forward and reverse so that the disk rotates by a magnetic force of the rotating magnet.

And, the disk is provided with a material having a magnetic force; The disk driving unit may include a rotary type voice coil actuator that rotates the disk forward and reverse.

And, it may further include a rotation shaft support for rotatably supporting the disk with respect to the test chamber.

In addition, the rotation shaft support part is formed on the ceiling of the test chamber, the suspension type support having a connection part for hanging the disk to the inner ceiling of the test chamber so that the disk is rotatable, an upper pin extending upwardly from the disk, and the A pin-type support part having an upper insertion hole into which the upper pin is rotatably inserted, a lower pin extending downward from the disk, and a lower insertion hole formed on the bottom surface of the test chamber and into which the lower pin is rotatably inserted. and a rotating shaft extending upward or downward from the disk, and a bearing-type support having a bearing module installed in the test chamber to rotatably support the rotating shaft.

In addition, the disk may further include at least one blade extending in at least one of the upper and lower directions and the plate surface facing the rotation axis.

In addition, the rotation detection unit includes a light irradiator for irradiating light toward the disk, a light type detection unit having a light detection unit for detecting light passing through or reflected from the disk; It may include any one of an interlocking type detection unit having an interlocking rotation unit rotating in association with the rotation and an interlocking sensing unit sensing the rotation of the interlocking rotation unit.

According to the above configuration, according to the present invention, in performing a hemostasis test of blood through the coagulation and dissolution process of blood according to the generation and dissolution of a thrombus, the product can be miniaturized and the test can be conveniently performed within a very short time A new hemostasis test device is provided.

1 is a view showing a conventional thromboelastography (TEG, Thromoelastography) measuring device,
2 is a view showing a hemostasis test apparatus according to a first embodiment of the present invention,
3 is a view showing a hemostasis test apparatus according to a second embodiment of the present invention,
4 is a view showing other examples of the disk drive unit of the hemostasis test apparatus according to the second embodiment of the present invention,
5 is a view showing examples of a first rotation shaft support part and a second rotation shaft support part according to an embodiment of the present invention,
6 is a view showing an example of the first through hole and the second through hole formed in the first disk and the second disk according to an embodiment of the present invention,
7 and 8 are views showing other examples of a rotation sensor according to an embodiment of the present invention,
9 is a view showing a hemostasis test apparatus according to a third embodiment of the present invention,
10 is a view showing examples of disks of a hemostasis test apparatus according to a third embodiment of the present invention;
11 is a view showing examples of the rotation shaft support of the hemostasis test apparatus according to the third embodiment of the present invention.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a view showing the hemostasis test apparatus 10 according to the first embodiment of the present invention. Referring to FIG. 2 , the hemostasis test apparatus 10 according to the first embodiment of the present invention includes a test chamber 110 , a first disk 120 , a second disk 130 , a disk drive unit 140 , and It includes a rotation sensor 150 .

In the test chamber 110 , blood to be tested is injected. Here, the test chamber 110 may be manufactured in the form of a microchip, and is preferably made of a transparent material that can be seen inside, for example, an acrylic material.

The first disk 120 is installed inside the test chamber 110 to be rotatable about a first rotational axis. Similarly, the second disk 130 is installed inside the test chamber 110 to be rotatable about a second rotational axis in the same direction as the first rotational axis. Here, the first disk 120 and the second disk 130 are installed inside the test chamber 110 in a state where the plate surfaces face each other and are spaced apart from each other.

The first rotational axis, which is the rotation center of the first disk 120 , is formed by a first rotational shaft supporter 160 to be described later, and the second rotational shaft that is the rotational center of the second disk 130 is a second rotational shaft supporter 170 to be described later. ), the first rotation shaft and the second rotation shaft may be located on the same line, but may not be on the same line. Here, various embodiments of the first rotation shaft support part 160 and the second rotation shaft support part 170 will be described later.

The disk driving unit 140 rotates the first disk 120 about the first rotation axis. In the present invention, it is exemplified that the disk driving unit 140 rotates the first disk 120 forward and backward in a preset angular range, for example, 4.75° with respect to the first rotation axis.

As described above, while the first disk 120 is rotated forward and backward by the disk driving unit 140 , a thrombus is generated in the blood inside the test chamber 110 and the blood is coagulated. In the process, the second disk 130 does not rotate because the viscosity of the blood inside the test chamber 110 is low. ) is transferred to

Accordingly, when a predetermined time elapses, the forward and reverse rotation of the second disk 130 starts, and the forward and reverse rotation radius of the second disk 130 increases as the blood coagulates, that is, the viscosity increases.

During this process, when the dissolution of the thrombus starts, the viscosity of the blood is lowered again, and the normal and reverse rotation radius of the second disk 130 also decreases. As a result, the forward and reverse rotation of the second disk 130 is It has the same aspect as the thrombus elasticity diagram shown in Fig. 1 (a). That is, the rotational characteristics of the second disk 130 are changed according to the coagulation and dissolution process of the test target blood.

Here, the rotation detection unit 150 detects the rotation of the second disk 130, and the rotation characteristic of the second disk 130 sensed by the rotation detection unit 150 is shown in FIG. It can be detected by the rotation sensor 150 in the same form as the illustrated thrombus elasticity diagram.

As described above, in a state in which the first disk 120 and the second disk 130 are disposed to face each other in a simple structure in the microchip type test chamber 110, the rotation of the first disk 120 is It is transferred to the second disk 130 through blood, and at this time, the change in viscosity during the clotting process and dissolution process of the blood changes the radius of rotation of the second disk 130, so that the coagulation and dissolution properties of the blood are changed. detection is possible.

The disk driving unit 140 of the thrombus test apparatus according to the first embodiment of the present invention rotates the first disk 120 by magnetic force outside the test chamber 110 as shown in FIG. 2 . . To this end, the first disk 120 may be made of a magnetic material or a magnetizable material.

And, as shown in FIG. 2 , the disk driving unit 140 includes a rotating magnet 141 and a driving motor 142 .

The rotating magnet 141 is installed to face the first disk 120 outside the test chamber 110 , and rotates in the same direction as the first rotation axis as the first disk 120 . In addition, the driving motor 142 rotates the rotating magnet 141 forward and reverse in a predetermined angular range as described above, so that the first disk 120 rotates forward and reverse according to a change in the magnetic field according to the rotation of the rotating magnet 141 . do.

As described above, the first disk 120 having a magnetic force or made of a magnetizable material is installed inside the test chamber 110, and is produced by the magnetic force of the rotating magnet 141 rotating outside the test chamber 110. 1 By rotating the disk 120 , the structure of the inspection chamber 110 is simplified, and thus the product can be miniaturized.

Meanwhile, as shown in FIG. 2 , the rotation detection unit 150 of the hemostasis test apparatus 10 according to the first embodiment of the present invention includes an optical type detection unit as an example. The light type detector includes a light irradiator 151 for irradiating light toward the second disk 130 and a photodetector 152 for detecting light passing through or reflected from the second disk 130 . ) may be included.

In the embodiment shown in FIG. 2 , the second light passing hole 131 formed in the second disk 130 through which the light irradiated from the light irradiation unit 151 is formed, and the first light passing hole formed in the first disk 120 ( For example, it is sensed by the light sensing unit 152 after passing through 121 .

6 is a view showing an example of the first light passing hole 121 and the second light passing hole 131 formed in the first disk 120 and the second disk 130 according to an embodiment of the present invention. In the present invention, as described above, the rotation detecting unit 150 detects the rotation of the second disk 130 , and the second disk 130 has a plurality of second light passing holes 131 along the circumferential direction. is formed In addition, the first light passage hole 121 is formed in the first disk 120 at a predetermined angle in the circumferential direction corresponding to the radius of the forward and reverse rotation of the first disk 120 .

Through this, when the second disk 130 rotates, the light passes through the plurality of second light passage holes 131 or is blocked therebetween, so that the rotation radius of the second disk 130 can be detected.

3 is a view showing a hemostasis test apparatus 20 according to a second embodiment of the present invention. As in the first embodiment, the hemostasis test apparatus 20 according to the second embodiment includes a test chamber 210 , a first disk 220 , a second disk 230 , a disk drive unit 240 , and a rotation detection unit ( 250) may be included. In addition, the hemostasis test apparatus 20 may include a first rotation shaft support part 260 and a second rotation shaft support part 270 .

As in the first embodiment, the first disk 220 and the second disk 230 face each other, and are respectively rotatably installed in the test chamber 210 about the first and second rotation axes. Here, the basic configuration of the first disk 220 and the second disk 230 corresponds to the first embodiment, and a detailed description thereof will be omitted.

The first disk 220 is rotatably supported with respect to the test chamber 210 by the first rotation shaft support 260 . In the second embodiment of the present invention, as shown in FIG. 3 , it is assumed that the second rotating shaft support 270 is supported by the first bearing type support. Here, the first bearing type support may include a first rotation shaft 261 and a first bearing module 262 .

A first rotational shaft 261 extends downwardly from the first disk 220 . The first rotation shaft 261 may be manufactured integrally with the first disk 220 , or a separate first rotation shaft 261 may be provided in a form coupled to the first disk 220 .

The first bearing module 262 rotatably supports the first rotation shaft while installed inside or outside the test chamber 210 , so that the first disk 220 is rotatable inside the test chamber 210 .

Here, in the second embodiment of the present invention, the first rotation shaft 261 is rotatably supported by the first bearing module 262 and extends to the outside of the test chamber 210 as an example, and the disk drive unit 240 . As an example, the first rotation shaft 261 is rotated forward and reverse to rotate the first disk 220 forward and reverse.

3 , it is exemplified that the disk driving unit 240 includes a first gear 241 , a second gear 242 , and a driving motor 243 .

The first gear 241 is axially connected to the first rotation shaft 261 so that forward and reverse rotation of the first gear 241 is transmitted to the first disk 220 through the first rotation shaft. In addition, the first gear 241 is rotated by meshing with the second gear 242 . As the second gear 242 rotates through the rotation of the driving motor 243 , the rotation of the driving motor 243 is the second By being transmitted to the first disk 220 through the gear 242 , the first gear 241 , and the first rotation shaft 261 , the first disk 220 is capable of forward and reverse rotation.

Meanwhile, the second rotation shaft support 270 rotatably supports the second disk 230 with respect to the test chamber 210 . In the exemplary embodiment of the present invention, the second disk 230 is disposed in a spaced apart state on the upper portion of the first disk 220 inside the test chamber 210 , and the second rotation shaft support 270 is a suspension type support. For example, including

More specifically, the second disk 230 is disposed on the upper portion of the first disk 220 in a spaced apart state, and the connection part moves the second disk 230 so that the second disk 230 is rotatable inside the examination chamber. For example, to rotatably support the second disk 230 in the form of hanging from the ceiling of the.

In the present invention, as described above, the second disk 230 also rotates forward and reverse according to the forward and reverse rotation of the first disk 220, and the second disk 230 through a connection portion such as a torsion wire, a torsion spring, or a general wire. ) It is possible to install in the test chamber 210 in the form of hanging. Accordingly, it is possible to install the second disk 230 with a simpler structure.

On the other hand, the first disk 220 according to the second embodiment of the present invention may include a first blade 222 extending toward the second disk 230, the second disk 230 is the first disk It may include second blades 232a and 232b extending toward 220 . In addition, the first blade 222 and the second blade (232a, 232b) may be disposed to face each other in a spaced apart state.

3 is a cross-sectional view of the hemostasis test apparatus 20 according to the present invention, the first blade 222 and the second blades 232a and 232b are the first disk 220 and the second disk 230, respectively. ) may be formed along the circumferential direction or may be formed at regular intervals.

In the present invention, it is exemplified that the second blades 232a and 232b are provided as a pair spaced apart from each other toward the rotation axis, and the first blade 222 is disposed between the pair of first blades 222, but Of course, the first blade 222 may be provided as a pair and the second blades 232a and 232b may be provided to be disposed between the pair of first blades 222 .

Through this configuration, the mutually facing areas of the first disk 220 and the second disk 230 are increased, and when the second disk 230 rotates according to the rotation of the first disk 220 , the first The frictional force between the disk 220 and the blood and the frictional force between the second disk 230 and the blood increase, so that the rotational force of the first disk 220 is more effectively transmitted to the second disk 230, so that the blood is coagulated or dissolved. Accordingly, the rotation response of the second disk 230 becomes sensitive, and more precise measurement is possible.

Meanwhile, it is assumed that the rotation sensing unit 250 according to the second embodiment of the present invention is provided in the form of detecting a change in a magnetic field. As shown in FIG. 3 , a displacement sensing magnet 252 is installed on the second disk 230 , and an electromotive force that changes according to the displacement of the magnet according to the rotation of the second disk 230 is measured by a magnetic field displacement sensor 251 . For example, the magnetic type sensing unit detected by is. Here, the magnetic field displacement sensor 251 can be applied in various forms, such as a magnetoresistive type, an inductive resistance type, of course.

4 is a view showing other examples of the disk driving units 240a and 240b of the hemostasis test apparatus 20 according to the second embodiment of the present invention.

As an example, the disk driving unit 240a according to the embodiment shown in FIG. 4A includes an operation lever 241a and a linear motor 242a.

The actuating lever 241a is a first rotational shaft ( 261a).

Then, the linear motor 242a reciprocates the actuating lever 241a in the forward and reverse direction so that the first rotation shaft 261a rotates forward and reverse within a predetermined angle range as described above, thereby rotating the first disk 220 forward and reverse. make it

As an example, the disk driving unit 240b according to the embodiment shown in FIG. 4B includes a magnet lever 241b and a voice coil actuator 242b.

The magnetic lever 241b is connected to the first rotational shaft 261b so as to be radially outwardly directed to the first rotational shaft 261b inside the test chamber 210 . Here, the first rotation shaft 261b is rotatably installed by the first bearing module 262b.

The voice coil actuator 242b reciprocates the magnetic lever 241b in a forward and reverse direction through a change in a magnetic field from the outside of the test chamber 210 to rotate the first rotation shaft 261b forward and reverse within a predetermined angular range. The disk 220 is rotated forward and reverse.

Meanwhile, FIG. 5 is a view showing examples of the first rotation shaft support parts 260c, 260d, and 260e and the second rotation shaft support parts 270c and 270d according to an embodiment of the present invention.

Referring to FIG. 5A , the first rotation shaft support part 260c may be provided in the form of a first pin type support part including a rotation pin 161c and a first pin insertion hole 262c. The rotation pin 161c extends downward from the first disk 220 . In addition, the first pin insertion hole 262c is formed in the bottom surface of the test chamber 210 and the rotation pin 161c is rotatably inserted therein. Through this, the first disk 220 is rotatably installed in the test chamber 210 using the rotation pin 161c inserted into the first pin insertion hole 262c as the first rotation axis.

The second rotation shaft support part 270c shown in FIG. 5A is a second pin type support part composed of an upper pin 271c, an upper insertion hole 272c, a lower pin 273c, and a lower insertion hole (not shown). may be provided in the form.

The upper fin 271c extends upward from the first disk 220 , and the lower fin 273c extends downward from the second disk 230 . In the embodiment shown in FIG. 5A , the upper pin 271c and the lower pin 273c are integrally installed through the second disk 230 as an example, but are separately provided and each second disk Of course, it can be installed on the upper plate surface and the lower plate surface of the 230, respectively.

The upper insertion hole 272c is formed in the ceiling of the test chamber 210 and the upper pin 271c is rotatably inserted therein. And, the lower insertion hole is formed in the upper plate surface of the first disk 220, the lower pin 273c is rotatably inserted. Through this, the second disk 230 may be rotatably installed between the first disk 220 and the ceiling of the test chamber 210 using the upper pin 271c and the lower pin 273c as a second rotation axis. .

The first rotating shaft support 260d according to the embodiment shown in FIG. 5B is a first bearing type support having a first rotating shaft 261d and a first bearing module 262d as described above. Having it is an example. And, the second rotation shaft support 270d according to the embodiment shown in FIG. 5B has an upper pin 271d, a lower pin 273d, an upper insertion hole 272d and a lower insertion hole 274d. It is exemplified that the second pin type support has a shape.

Here, unlike in the embodiment shown in FIG. 5A , the lower pin 273d passes through the through hole 224d through the first disk 220 and the first rotation shaft 261d to the test chamber ( As an example, it is rotatably inserted into the lower insertion hole 274d formed in the bottom surface of the 210 . In the embodiment shown in Fig. 5 (b), the first bearing module 262d is installed inside the test chamber 210, and the lower pin passed through the first rotation shaft 261d in the first bearing module 262d. It is exemplified that the 273c is rotatably inserted into the lower insertion hole 274d formed in the bottom surface of the test chamber 210 .

On the other hand, the first rotation shaft support 260e according to the embodiment shown in Fig. 5 (c) includes a plurality of guide holes 261e, and guide balls 262e seated in each guide hole 261e. For example, having a ball-type support shape.

Each guide hole 261e is formed on the bottom surface of the test chamber 210 along the rotational direction of the first disk 220 . Then, the rotation of the first disk 220 is guided while the first disk 220 is seated on the upper end of the guide ball 262e seated in each guide hole 261e. The second rotation shaft support according to the embodiment shown in FIG. 5 ( c ) has the shape of the second pin type support shown in FIG. 5 ( a ), and a detailed description thereof will be omitted.

7 and 8 are views showing other examples of the rotation sensor 150a according to an embodiment of the present invention.

The rotation detection unit 150a according to the embodiment shown in FIG. 7A has the form of a light type detection unit, and includes a light irradiation unit 151a and a light sensing unit 152a as an example. The light irradiation unit 151a irradiates light toward the first disk 220 .

Unlike the above-described embodiment, the light irradiated from the light emitter 151a is reflected from the first reflector 153a attached to the upper plate surface of the second disk 230 and is sensed by the light detector 152a. Here, a plurality of the first reflecting plate 153a may be attached to be spaced apart within a predetermined angular range along the rotational direction of the second disk 230 to detect the rotational radius of the second disk 230 .

In the rotation detecting unit 150b according to the embodiment shown in FIG. 7B , the light irradiation unit 151b irradiates light from the side surface of the second disk 230 , and the light reflected from the second reflecting plate 153b It is a view showing an example in which the light sensing unit 152b detects it from the side. Similarly, a plurality of second reflection plates 153b may be attached within a predetermined interval and a predetermined angle range along the rotational direction.

The rotation detecting unit 250a according to the embodiment shown in FIG. 7C is similar to the embodiment shown in FIG. 2 , including a displacement sensing magnet 252a and a magnetic field displacement sensor 251a take as an example Unlike the embodiment shown in FIG. 2 , the displacement sensing magnet 252a is installed on the side surface of the second disk 230 , and the magnetic field displacement sensor 251a detects it from the side surface of the test chamber 210 . taking as an example

The rotation sensing units 250c and 250d according to the embodiment shown in FIG. 8 are exemplified in the form of an interlocking type sensing unit.

As an example, the rotation detecting unit 250c according to the embodiment shown in (a) of FIG. 8 includes an interlocking rotation unit 253c and interlocking sensing units 251c and 252c. The interlocking rotation unit 253c rotates in association with the rotation of the second disk 230 . In the embodiment shown in (a) of FIG. 8 , it is assumed that the interlocking rotation part 253c extends upward from the plate surface of the second disk 230 , and the upper edge of the interlocking rotation part 253c is located on the upper part of the test chamber 210 . A guide hole into which the region is inserted may be formed. Here, it is assumed that the interlocking rotation part 253c is formed within a predetermined angle range along the rotation direction of the second disk 230 .

In addition, the interlocking sensing units 251c and 252c include, for example, the light irradiation unit 251c and the light sensing unit 252c. By installing a plurality of reflective plates (not shown) on the plate surface of the interlocking rotating unit 253c, the light For example, it is assumed that the light irradiated by the irradiation unit 251c is reflected from the reflector and sensed by the light sensing unit 252c, and the rotation of the second disk 230 is sensed.

For example, the interlocking rotation unit 253d of the rotation sensing unit 250d according to the embodiment shown in FIG. 8B is provided in the form of a disk. Here, for example, the second rotation shaft support 270e according to the embodiment shown in FIG. 8 (b) is provided in the form of a second bearing type support corresponding to the first bearing type support of the first rotation shaft support 260e. do.

Here, the second bearing type support part includes a second rotation shaft 271e extending upwardly from the second disk 230 and a second rotation shaft 271e installed in the test chamber 210 to rotatably support the second rotation shaft 271e. It is exemplified by including the two bearing module 272e.

At this time, the second rotation shaft 271e passes through the second bearing module 272e and extends to the outside of the test chamber 210 , and the second rotation shaft 271e extended to the outside of the test chamber 210 is a disk ( 320) is connected to the axis of rotation of the interlocking rotation unit 253d of the form. Accordingly, when the second disk 230 rotates, the interlocking rotation unit 253d rotates according to the rotation of the second rotation shaft 271e.

Here, the interlocking sensing units 251d and 252d include, for example, the light irradiating unit 251d and the light sensing unit 252d. A plurality of reflecting plates (not shown) are installed on the plate surface of the interlocking rotating unit 253d, For example, it is assumed that the light irradiated by the irradiator 251d is reflected from the reflective plate and sensed by the photodetector 252d, and the rotation of the second disk 230 is sensed.

Hereinafter, a hemostasis test apparatus 30 according to a third embodiment of the present invention will be described with reference to FIG. 9 . The hemostasis test apparatus 30 according to the third embodiment of the present invention includes a test chamber 310 , a disk 320 , a disk drive unit 340 , and a rotation sensor 350 .

Blood is injected into the test chamber 310 . In addition, the disk 320 is rotatably installed around a rotational axis inside the test chamber 310 , and is rotatably supported by a rotational shaft supporter 360 to be described later.

As such, in the hemostasis test apparatus 30 according to the third embodiment of the present invention, one disk 320 is rotatably installed in the test chamber 310 as an example. Then, the disk driving unit 340 rotates the disk 320 about the rotation axis, and the rotation detecting unit 350 detects the rotation of the disk 320 .

At this time, the disk 320 changes in rotational characteristics according to the blood coagulation and dissolution process. As in the above-described embodiment, the disk driving unit 340 operates the disk 320 within a preset angle range with respect to the rotation axis. ) is rotated forward and reverse.

As described above, while the disk 320 is rotated forward and backward by the disk driving unit 340 , a blood clot is generated in the blood inside the test chamber 310 and the blood is coagulated. The turning radius is reduced, and the turning radius is increased again in the process of blood coagulation and then dissolution. When this characteristic is sensed by the rotation sensor 350, it is possible to measure the thrombus elasticity delineation.

Here, it is assumed that the disk driving unit 340 according to the third embodiment of the present invention includes a rotating magnet 341 and a driving motor 342 corresponding to the first embodiment.

The rotating magnet 341 is installed to face the disk 320 outside the test chamber 310 , and rotates in the same direction as the rotation axis direction as the disk 320 . In addition, the driving motor 342 rotates the rotating magnet 341 forward and reverse in a predetermined angular range, and the disk 320 rotates forward and reverse according to a change in the magnetic field according to the rotation of the rotating magnet 341 .

As described above, the disk 320 having a magnetic force or made of a magnetizable material is installed in the test chamber 310 , and the disk 320 is installed by the magnetic force of the rotating magnet 341 rotating outside the test chamber 310 . ), the structure of the inspection chamber 310 is simplified and the product can be miniaturized.

As shown in FIG. 9 , the rotation detection unit 350 of the hemostasis test apparatus 30 according to the third embodiment of the present invention includes a light type detection unit. The light type detector may include a light irradiator 351 for irradiating light toward the disk 320 and a photodetector 352 for detecting light passing through the disk 320 . Here, a light passage hole 321 through which the light irradiated from the light irradiator 351 passes is formed in the disk 320, and is formed as shown in (a) of FIG. 6 as an example.

10 is a view showing examples of disks 320a and 320b of the hemostasis test apparatus 30 according to the third embodiment of the present invention. The disk 320a according to the embodiment shown in FIG. 10A may include at least one blade 322a extending in upper and lower directions and having a plate surface facing the rotation axis direction.

Such a blade 322a increases the friction area with blood when it is rotated while being rotatably supported by the rotation shaft support 360a of the disk 320a, so that it is more sensitive to changes in viscosity due to the coagulation and dissolution of blood. By reacting more accurately, a more accurate examination becomes possible. In addition, by increasing the area facing the wall surface of the test chamber 310 as well as the increase in the friction area, the change in rotational characteristics according to the change in the viscosity of the blood positioned between the wall surface of the test chamber 310 is more sensitive. be able to react.

As an example, the disk 320b according to the embodiment shown in FIG. 10B has a cylindrical shape rather than a plate shape. In addition to the effect of increasing the friction area, this configuration increases the wall surface facing the test chamber 310b so that it can respond more sensitively to changes in the viscosity of blood.

Meanwhile, FIG. 11 is a view showing examples of the rotation shaft support parts 360c, 360d, and 360e of the hemostasis test apparatus 30 according to the third embodiment of the present invention.

The embodiment shown in (a) of FIG. 11 shows an example having the form of a pin-type support part, and the rotation shaft support part 360c is an upper pin 361c, a lower pin 362c, an upper insertion hole 363c, and a lower insertion part. For example, a hole 364c is included.

The upper fin 361c extends upward from the disk 320c, and the lower fin 362c extends downward from the disk 320c. Here, the upper pin 361c and the lower pin 362c form the center of rotation of the disk 320c, that is, the central axis.

The upper insertion hole 363c is formed in the ceiling inside the test chamber 310c, and the upper pin 361c is rotatably inserted therein. Similarly, the lower insertion hole 364c is formed in the bottom surface inside the test chamber 310c, and the lower pin 362c is rotatably inserted therein. Through this, the disk 320c is rotatably supported inside the test chamber 310c.

The embodiment shown in (b) of FIG. 11 shows an example having a bearing-type support part, and the rotation shaft support part 360d includes a rotation shaft 361d and a bearing module 362d as an example.

The rotating shaft 361d extends downwardly from the disk 320d. In addition, the bearing module 362d is installed in the test chamber 310d to rotatably support the rotation shaft 361d. Here, as described above, the bearing module 362d may be installed inside or outside the test chamber 310d.

Although the bearing-type support shown in FIG. 11B is installed on the bottom side of the test chamber 310d as an example, it may be installed on the ceiling side, of course.

11(c) shows an example of a suspension type support part, and the disk 320e is suspended from the ceiling of the test chamber 310e with a connection part 260e such as a wire. have.

The rotation detecting unit, the rotating shaft supporting unit, and the disk driving unit according to the third embodiment of the present invention have been described with the configuration shown in FIGS. 9 to 11 as an example, but the rotation detecting unit and the rotating shaft described in the first and third embodiments It goes without saying that the examples of the support part and the disk driving part are also applicable to the third embodiment, and the technical spirit of the present invention is not limited to the embodiments shown in FIGS. 9 to 11 .

In some embodiments described above, the disk driving unit is composed of a rotating magnet and a driving motor to rotate the first disk or disk outside the test chamber. Of course, it may be provided to rotate forward and reverse by installing a configuration having a , and using a rotary voice coil actuator outside the test chamber.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

10, 20, 30: hemostasis test device 110,210,310: test chamber
120,220: first disk 121: first light passing hole
222: first blade
320,320a.320b,320c,320d,320e : disk
321: light passing hole 322a: blade
130,230: second disk 131: second light passing hole
232a, 232b: second blade 140,240,340: disk drive unit
141,341: rotating magnet 142,243,342: driving motor
241: first gear 242: second gear
241a: actuation lever 242a: linear motor
241b: magnetic lever 242b: voice coil actuator
150,150a,150b,250,250a,250c,250d,350: rotation sensor
151,151a,150b,251c,251d,351: light irradiation unit
152,152a,150b,252c,251d,352: light sensing unit
251,251a: magnetic field displacement sensor 252,252a: magnet for displacement detection
160,260,260a,260b,260c,260d,260e: first rotating shaft support part
261,261a, 261b, 261d: first rotating shaft
262,262a, 262b, 262d: first bearing module
261c: rotary pin 262c: first pin insertion hole
261e: guide hole 262e: guide ball
360,360a,360b,360c,360d,360e: rotation shaft support
170,270c,270d: second rotation shaft support
271c, 271d: upper pin 272c, 272d: upper insertion hole
273c, 273d: lower pin 274d: lower insertion hole
271e: second rotation shaft 272e: second bearing module

Claims (18)

In the hemostasis test apparatus,
a test chamber into which blood is injected;
a first disk installed in the test chamber to be rotatable about a first rotational axis;
a second disk installed inside the test chamber to be rotatable about a second axis of rotation in the same direction as the first axis of rotation, the second disk being spaced apart from the first disk and installed inside the test chamber;
a disk driving unit for rotating the first disk about the first rotation axis;
a rotation detection unit for detecting rotation of the second disk;
The second disk rotates with the blood as a medium according to the rotation of the first disk, but the hemostatic examination apparatus, characterized in that the rotational characteristics change according to the clotting process and the dissolution process of the blood. According to claim 1,
The hemostatic examination apparatus, characterized in that the disk driving unit rotates the first disk forward and reverse within a preset angle range with respect to the first rotation axis. 3. The method of claim 2,
the first disk is made of a material having a magnetic force or capable of being magnetized by magnetism;
The disk drive unit
a rotating magnet installed to face the first disk from the outside of the test chamber;
and a driving motor for rotating the rotating magnet forward and reverse so that the first disk rotates by the magnetic force of the rotating magnet. 3. The method of claim 2,
the first disk is made of a magnetic material;
The hemostatic examination apparatus, characterized in that the disk driving unit comprises a rotary type voice coil actuator for rotating the first disk forward and reverse. 3. The method of claim 2,
a first rotation shaft support part rotatably supporting the first disk with respect to the test chamber;
Hemostatic testing apparatus further comprising a second rotation shaft support for rotatably supporting the second disk with respect to the test chamber. 6. The method of claim 5,
The first rotation shaft and the second rotation shaft are formed along a vertical direction so that the first disk and the second disk are vertically spaced apart from each other in the chamber, and the first disk is the second disk. located at the bottom;
The first rotation shaft support portion
a first pin-type support part comprising a rotation pin extending downward from the first disk and a first pin insertion hole formed on a bottom surface of the test chamber and into which the rotation pin is rotatably inserted;
A first bearing type support part having a first rotation shaft extending downward from the first disk and a first bearing module installed in the test chamber to rotatably support the first rotation shaft;
Any one of a ball-type support having a plurality of guide holes formed along the rotational direction of the first disk on the bottom surface of the test chamber, and guide balls seated in each of the guide holes to guide the rotation of the first disk Hemostasis test device comprising a. 7. The method of claim 6,
The second rotation shaft support portion
a suspension type support part having a connection part for hanging the second disk from the ceiling inside the test chamber so that the second disk is rotatable;
an upper pin extending upwardly from the second disk, an upper insertion hole formed in the ceiling of the test chamber into which the upper pin is rotatably inserted, a lower pin extending downwardly from the second disk, and the first a second pin-type support part formed on the bottom surface of the first disk or the test chamber and having a lower insertion hole into which the lower pin is rotatably inserted;
including any one of a second bearing type support part having a second rotation shaft extending upwardly from the second disk and a second bearing module installed in the test chamber to rotatably support the second rotation shaft A hemostasis test device characterized. According to claim 1,
The first disk has a first blade extending toward the second disk and the plate surface faces the first rotational axis;
The second disk is extended toward the first disk, hemostatic examination apparatus, characterized in that it further comprises a second blade facing the first blade in a spaced apart state. 3. The method of claim 2,
any one of the first blade and the second blade is provided as a pair spaced apart from the first rotation shaft or the second rotation shaft;
The other one of the first blade and the second blade is a hemostasis test apparatus, characterized in that located between any one of the pair. According to claim 1,
The rotation sensor,
a light type detector having a light irradiator for irradiating light toward the second disk, and a photodetector for detecting light passing through or reflected from the second disk;
An interlocking type sensing unit having an interlocking rotation unit rotating in association with the rotation of the second disk, and an interlocking sensing unit sensing the rotation of the interlocking rotation unit;
A magnet for displacement detection installed on the second disk, and any one of a magnetic type detection unit having a magnetic field displacement sensor for detecting a displacement of the displacement detection magnet according to the rotation of the second disk outside the test chamber Hemostasis test device, characterized in that. In the hemostasis test apparatus,
a test chamber into which blood is injected;
a disk installed inside the test chamber to be rotatable about a rotation axis;
a disk drive unit for rotating the disk about the rotation shaft;
a rotation detection unit for detecting rotation of the disk;
The disk hemostasis test apparatus, characterized in that the rotational characteristic changes according to the clotting process and the dissolution process of the blood. 12. The method of claim 11,
The hemostatic examination apparatus, characterized in that the disk drive unit rotates the disk forward and reverse within a preset angle range with respect to the rotation axis. 13. The method of claim 12,
the disk is made of a material having a magnetic force or capable of being magnetized by magnetism;
The disk drive unit
a rotating magnet installed to face the disk from the outside of the test chamber;
and a driving motor for rotating the rotating magnet forward and reverse so that the disk rotates by the magnetic force of the rotating magnet. 13. The method of claim 12,
the disk is made of a magnetic material;
The hemostatic test apparatus, characterized in that the disk drive unit comprises a rotary type voice coil actuator for rotating the disk forward and reverse. 13. The method of claim 12,
Hemostatic testing apparatus, characterized in that it further comprises a rotation shaft support for rotatably supporting the disk with respect to the test chamber. 16. The method of claim 15,
The rotating shaft support
a suspension type support part having a connection part for suspending the disk from the ceiling inside the test chamber so that the disk is rotatable;
An upper pin extending upwardly from the disk, an upper insertion hole formed in the ceiling of the test chamber into which the upper pin is rotatably inserted, a lower pin extending downward from the disk, and a bottom surface of the test chamber a pin-type support portion formed in and having a lower insertion hole into which the lower pin is rotatably inserted;
The hemostatic test apparatus comprising: a rotation shaft extending upward or downward from the disk; and a bearing-type support part having a bearing module installed in the test chamber to rotatably support the rotation shaft. 12. The method of claim 11,
The disk is extended in at least one of the upper and lower directions, hemostasis test apparatus, characterized in that the plate surface further comprises at least one blade facing the rotation axis. 12. The method of claim 11,
The rotation sensor,
A light type detector having a light irradiator for irradiating light toward the disk, and a light detector for detecting light passing through or reflected from the disk;
and any one of an interlocking rotation unit rotating in association with the rotation of the disk outside the test chamber and an interlocking type sensing unit having an interlocking sensing unit sensing rotation of the interlocking rotation unit.

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