KR100886416B1 - Ultrasonic bone density measurement device having waterproof means - Google Patents

Abstract

An ultrasonic bone density measurement device having waterproof means is provided to prevent intrusion of medium by installing a first and a second ultrasonic probe unit on both side of a mounting unit. In an ultrasonic bone density measurement device, the foot of a subject is settled on the mounting unit. A first ultrasonic probe unit(300) is arranged in one side of the mounting unit. A second ultrasonic probe unit(400) is arranged in the other side of the mounting unit. A first ultrasonic probe unit radiates an ultrasonic wave, and the second ultrasonic probe receives ultra sonic wave from the first ultrasonic wave. Each ultrasonic probe unit includes connecting parts(310,410), and the waterproofing part and probe housing. A connecting unit is mounted inside one side and the other side of the mounting unit. The waterproofing is arranged on one side and the other side of the mounting unit. Each waterproofing part has a head, receiving units(323,423) and insertion parts(325,425). A head is combined to the connection part, and The receiving part is extended from the head in direction of ultrasonic probe by predetermined length. The insertion unit is extended from the receiving unit in direction of the ultrasonic probe by predetermined length.

Description

Ultrasonic Bone Density Measurement Device with Waterproof Means {Ultrasonic Bone Density Measurement Device having Waterproof Means}

The present invention relates to an ultrasonic bone density measuring apparatus equipped with a waterproof means, and in particular, when correcting the measuring apparatus using a medium, the ultrasonic bone mineral density measuring apparatus having waterproof means for preventing the medium from flowing into the measuring apparatus. It is about.

Osteoporosis is a disease in which bone fractures become thin and weak due to bone loss, and fractures occur easily even with a small impact. In addition, osteoporosis comes first without symptoms and progresses slowly, eventually leading to severe pain and fractures. At this time, osteoporosis is an irreversible disease that cannot be returned to its normal state once it is developed. As a preventive diagnosis is important, as long as the bone loss is found early, it can be sufficiently prevented.

In addition, fractures frequently caused by osteoporosis are the spine, thighs, wrists, etc. In the case of the elderly, fractures of these areas may pose a risk to life. Today osteoporosis is a serious social problem. It is estimated that more than 2 million people in Korea are suffering from osteoporosis, and in the United States, 7 to 8 million people already have osteoporosis, and 17 million people are at risk of developing osteoporosis with low bone mass. Due to the risk of fracture. Accordingly, there is an increasing demand for the development of an osteoporosis diagnostic apparatus that can accurately diagnose osteoporosis in advance.

Recently, the research of the bone density measuring instrument using the ultrasonic wave which is harmless to the human body has been actively conducted. Ultrasonic Bone Density Meter is based on the time of flight (TOF) and the change in the amplitude of the ultrasonic wave due to the energy loss caused by the characteristics of the medium to be transmitted (elastic, density, porosity, homogeneity). A device for evaluating bone density using attenuation due to a difference in acoustic impedance at an incident interface and attenuation due to scattering and absorption in a medium to be transmitted.

The ultrasonic bone density meter is largely divided into wet and dry by the medium of the contact area between the calcaneal part of the subject and the ultrasonic probe, and the wet measuring device uses ultrasonic water to penetrate the heated water between the ultrasonic probe and the heel. That's the way. On the other hand, the dry measuring device is a method in which ultrasonic permeation is performed by applying a balloon containing water to the front of the ultrasonic probe and applying an ultrasonic gel between the balloon and the heel.

However, the above-described wet or dry method is used to calibrate the ultrasonic measuring apparatus using a medium. At this time, the medium used to calibrate is introduced into the ultrasonic measuring apparatus, thereby causing the ultrasonic measuring apparatus to fail.

An object of the present invention for solving the above-described problems, each of which is provided with an ultrasonic probe mechanism part including a waterproof portion having excellent flexibility to one side and the other side of the seating portion accommodated the feet of the subject, when correcting the measuring device using a medium It is to provide an ultrasonic bone density measuring apparatus having a waterproof means for preventing the medium from flowing into the measuring apparatus.

Ultrasonic bone density measuring apparatus equipped with a waterproof means of the present invention for achieving the above object, the first ultrasonic transducer mechanism and the seat for emitting ultrasonic waves having a seating portion on which the subject's feet are seated, a waterproofing portion on one side of the seating portion; It provides an ultrasonic bone density measuring apparatus having a waterproof means including a second ultrasonic transducer mechanism for receiving the ultrasonic wave emitted from the first ultrasonic transducer mechanism provided on the other side of the unit.

The first ultrasonic transducer mechanism portion and the second ultrasonic transducer mechanism portion, the coupling portion is respectively mounted on one side and the other inside of the seating portion, one end of the coupling portion is respectively coupled to one side and the other side of the seating portion are respectively provided It may be configured of a waterproof unit, an ultrasonic probe coupled to the other end of the waterproof unit, and a transducer housing to which the ultrasonic probe is coupled.

The waterproof portion has a head coupled to the fastening portion, has a circumferential length smaller than the head, and a receiving portion is formed in a cylindrical shape by a predetermined length in the direction of the ultrasonic probe from the head, and smaller than the receiving portion. It has a circumferential length, the insertion portion may be formed in a cylindrical shape by a predetermined length in the direction of the ultrasonic probe from the receiving portion.

The waterproof part may be inserted while the head is coupled to the fastening part and the ultrasonic probe moves while the ultrasonic probe is coupled to the lower part of the insertion part so as to protrude into the seating part. Can be.

In the ultrasonic bone density measuring apparatus, when the medium is filled in the seating portion for correction, the inflow of the medium into the seating portion may be prevented by the waterproof portion.

The waterproof part may be a material having excellent flexibility, such as rubber or silicone.

As described above, according to the present invention, each of the ultrasonic transducer mechanism including a waterproof portion having excellent flexibility to one side and the other side of the seating portion in which the feet of the subject are accommodated, respectively, to the inside of the measuring device when calibrating the measuring device using a medium. It is possible to provide an ultrasonic bone density measuring apparatus having a waterproof means for preventing the medium from flowing.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention.

1 is a perspective view showing an ultrasonic bone density measuring apparatus equipped with a waterproof means according to an embodiment of the present invention, Figure 2 is a perspective view showing the internal structure of the ultrasonic bone density measuring apparatus equipped with a waterproof means according to an embodiment of the present invention 3 is a perspective view showing an operating state of the ultrasonic bone density measuring apparatus equipped with a waterproof means according to an embodiment of the present invention.

Ultrasonic bone density measuring apparatus having a waterproof means according to an embodiment of the present invention, as shown in Figures 1 to 3, the central portion of the housing 100, the bone density of the foot (not shown) of the subject (patient) In order to measure, a seating unit 200 which is a space in which the feet of the subject can be accommodated is formed, and one side of the seating unit 200 is provided with a first ultrasonic probe mechanism unit 300 for emitting an ultrasonic wave, The other side of the 200 is provided with a second ultrasonic transducer mechanism 400 so as to face the first ultrasonic transducer mechanism 300 to receive the ultrasonic wave emitted from the first ultrasonic transducer mechanism 300.

The first ultrasonic probe mechanism part 300 serves to emit ultrasonic waves by being in close contact with one side of the heel of the subject accommodated in the seating part 200, and as shown in FIGS. 2 and 3, one side inside the housing 100. It is coupled to the first bracket 500 provided in.

Similarly, the second ultrasonic transducer mechanism 400 is mounted to face the other of the first ultrasonic transducer mechanism 300 so as to be in close contact with the other side of the heel of the subject accommodated in the seating part 200, and the first ultrasonic transducer mechanism 300 ), And then receives the ultrasound that passed through the heel of the subject.

2 and 3, the second ultrasonic transducer mechanism 400 is coupled to the second bracket 600 provided on the other side of the housing 100.

In addition, the first bracket 500 and the second bracket 600 may be connected to the linear transfer path 900 provided on the inner bottom of the housing 100 to reciprocate a predetermined distance.

Therefore, as shown in FIG. 3, the first fastening portion 310 and the second fastening portion 410 are fixed, and the first bracket 500 and the second bracket 600 are along the linear transport path 900. Move in the direction facing each other.

Here, the first bracket 500 and the second bracket 600 is a driving force from the first driving unit 700 and the second driving unit 800, such as a motor provided on one side of the housing 100 through a predetermined mechanical device. It is preferable that each is transferred along the linear transport path 900.

4 is a perspective view showing an ultrasonic transducer mechanism according to an embodiment of the present invention, Figure 5 is a perspective view showing the operating state of the ultrasonic transducer mechanism according to an embodiment of the present invention.

The first ultrasonic transducer mechanism 300 is mounted to the first fastening part 310 inside one side of the seating part 200, and one end of the first waterproof part 320 is coupled to the first fastening part 310 to provide a housing. It is provided to the inside of the 100, that is, the outside of the mounting portion 200.

Then, the first ultrasonic transducer 350 for emitting ultrasonic waves is coupled to the other end of the first waterproofing unit 320, and the first ultrasonic transducer 350 is coupled to the inside of the first probe housing 360.

The first transducer housing 360 is fastened with the first ultrasonic transducer 350 and a fastening device (not shown), and is intended to protect the first ultrasonic transducer 350 coupled therein.

Meanwhile, the first coupling part 310 couples the first coupling 330 to the first coupling part 310 so that one end of the first waterproof part 320 is fixed to the first coupling part 310. Thus, one end of the first waterproof portion 320 is coupled between the first fastening portion 310 and the first coupling 330 is fixed.

In addition, in the first probe housing 360, the first waterproofing part 320 couples the first O-ring 340 to the first probe housing 360 so that the other end thereof is fixed to the first ultrasonic probe 350. Therefore, the other end of the first waterproofing part 320 is coupled and fixed between the first O-ring 340 and the first ultrasonic transducer 350.

Similarly, the second ultrasonic probe mechanism 400 has a second fastening part 410 mounted inside the other side of the seating part 200, and one end of the second waterproof part 420 is coupled to the second fastening part 410. It is provided inside the housing 100, that is, the outside of the seating portion 200.

Then, when the ultrasonic wave emitted by the first ultrasonic probe 350 to the other end of the second waterproof unit 420 passes through the heel of the subject, the second ultrasonic probe 450 receiving the coupled ultrasonic wave is coupled to the second ultrasonic wave. The transducer 450 is coupled to the second transducer housing 460.

The second transducer housing 460 is fastened by the second ultrasonic probe 450 and a fastening device (not shown), and is intended to protect the second ultrasonic probe 450 coupled therein.

Meanwhile, the second coupling part 410 is coupled to the second fastening part 410 so that one end of the second waterproof part 420 is fixed to the second fastening part 410. Thus, one end of the second waterproof portion 420 is coupled and fixed between the second fastening portion 410 and the second coupling 430.

In addition, the second waterproofing unit 420 couples the second O-ring 440 to the second transducer housing 460 so that the other end thereof is fixed to the second ultrasonic transducer 450. Accordingly, the other end of the second waterproof portion 420 is coupled and fixed between the second O-ring 440 and the second ultrasonic transducer 450.

Here, the first waterproof portion 320 has a circular first head 321 is coupled to the first fastening portion 310, has a smaller peripheral length than the first head 321, the first head 321 The first accommodating part 323 is formed in a cylindrical shape by a predetermined length in the direction of the first ultrasonic probe 350 from the.

Subsequently, the first insertion portion 325 has a circumferential length smaller than that of the first accommodating portion 323, and has a cylindrical shape from the first accommodating portion 323 to the first ultrasonic transducer 350 by a predetermined length. .

Accordingly, one end of the first waterproof portion 320 coupled to and fixed to the first fastening portion 310 becomes the first head 321 and the first waterproof portion 320 coupled to the first ultrasonic probe 350. The other end of) becomes the lower portion of the first inserting portion 325.

And, as shown in Figure 4 (a), when the first ultrasonic probe 350 is moved to the seating portion 200 for bone density measurement, the first head 321 and the first receiving portion 323 is fixed The first inserting portion 325 coupled to the first ultrasonic probe 350 is inserted while being folded into the first accommodating portion 323, as shown in FIG. 4 (b).

Here, since the circumferential length of the first inserting portion 325 is smaller than the circumferential length of the first receiving portion 323, even if the first inserting portion 325 is inserted into the first accommodating portion 323 and folded, The first inserting portion 325 may be easily folded without being caught in the first accommodating portion 323.

When the bone density measurement is completed, the first ultrasonic probe 350 is moved back into the housing 100, and the first insertion part 325 folded into the first accommodating part 323 is opened.

Similarly, the second waterproof portion 420 also has a circular second head 421 coupled to the second fastening portion 410, has a smaller circumferential length than the second head 421, and the second head 421. The second accommodating part 423 is formed in a cylindrical shape by a predetermined length in the direction of the second ultrasonic probe 450.

Subsequently, the second insertion portion 425 has a circumferential length smaller than that of the second accommodating portion 423, and has a cylindrical shape from the second accommodating portion 423 in the direction of the second ultrasonic probe 450 by a predetermined length. .

Accordingly, one end of the second waterproof portion 420 coupled to the second fastening portion 410 is to be the second head 421, and the second waterproof portion 420 coupled to the second ultrasonic probe 450. The other end of) becomes a lower portion of the second inserting portion 425.

And, as shown in Figure 4 (a), when the second ultrasonic probe 450 is moved to the seating portion 200 to measure the bone density, the second head 421 and the second receiving portion 423 is fixed and The second insertion portion 425 coupled to the second ultrasonic probe 450 is inserted while being folded into the second accommodation portion 423, as shown in FIG. 4 (b).

Here, since the circumferential length of the second inserting portion 425 is smaller than the circumferential length of the second receiving portion 423, even if the second inserting portion 425 is folded into the second receiving portion 423, the second inserting portion is inserted. The part 425 may be folded without being caught in the second accommodating part 423.

When the bone density measurement is completed, the second ultrasonic probe 450 is moved back into the housing 100, and the second inserting part 425 folded into the second accommodating part 423 is unfolded.

Therefore, the first waterproof portion 320 and the second waterproof portion 420 is preferably made of a material having excellent flexibility, such as rubber, silicone, which does not tear or bend even when folded.

For reference, the ultrasound bone density measuring apparatus according to the embodiment of the present invention may include a user interface unit (not shown).

Thus, the interface unit allows the measurer to perform a key operation for measuring the bone density of the subject, and serves to display the bone density measurement results to the measurer. The user interface unit includes a direction key (not shown), a selection key (selection key), a power switch (not shown), and the like, and a keypad (not shown) for the measurer to select various functions and modes for measuring the bone density of the subject. And a monitor (not shown) for displaying the bone density measurement result of the subject on a screen, and a printer (not shown) for outputting the bone density measurement result of the subject in the form of a document to the measurer.

The operation process for measuring bone density using the ultrasonic bone density measuring apparatus configured as described above is as follows.

First, after turning on the power switch of the user interface unit accommodates the feet of the subject in the seating portion 200.

Subsequently, the measurer selects a bone density measurement mode using a selection key of the user interface unit.

Subsequently, the first electric motor 700 and the second electric motor 800 operate, respectively, and the first bracket 500 and the second bracket 600 face each other along the linear transport path 900. Move toward the part 200, respectively.

As the first bracket 500 and the second bracket 600 move, respectively, the first ultrasonic probe 350 and the second ultrasonic probe 450 also move to protrude into the seating part 200, respectively, and the heel of the subject is measured. One side and the other side of each touch.

In this case, since the first fastening part 310 is fixed to one side of the seating part 200, the first head 321 and the first head of the first waterproof part 320 coupled to the first fastening part 310. The accommodating part 323 is fixed and is inserted into the first accommodating part 323 while the first inserting part 325 coupled to the first ultrasonic probe 350 is folded.

Similarly, since the second fastening part 410 is fixed to one side inside the seating part 200, the second head 421 and the second head of the second waterproof part 420 coupled to the second fastening part 410. The accommodating part 423 is fixed and is inserted into the second accommodating part 423 while the second inserting part 425 coupled to the second ultrasonic probe 450 is folded.

In addition, when the first ultrasonic probe 350 and the second ultrasonic probe 450 each touch the heel of the subject, the first electric motor 700 and the second electric motor 800 stop operation, and the first The movement of the bracket 500, the second bracket 600, the first ultrasonic probe 350 and the second ultrasonic probe 450 also stops.

Subsequently, the first ultrasonic transducer 350 emits ultrasonic waves to the heel of the subject, and the second ultrasonic transducer 450 passes through the heel of the subject after being fired by the first ultrasonic transducer 350. Receive ultrasound.

On the other hand, after several times using the ultrasonic bone density measuring device, a little error occurs.

Therefore, the correction should be made in order to determine the reference of the measured value of the ultrasonic bone density measuring apparatus, and the correction is performed by filling a reference medium (distilled water, etc.) without putting a foot in the seating part 200.

Accordingly, the first head 321 of the first waterproof portion 320 is coupled to the first fastening portion 310, and the lower portion of the first insertion portion 325 of the first waterproof portion 320 is the first ultrasonic wave. Coupled to the probe 350, even if the medium is filled in the seating portion 200 to prevent the medium from flowing into the housing (100).

Similarly, the second head 421 of the second waterproof portion 420 is coupled to the second fastening portion 410, and the lower portion of the second insertion portion 425 of the second waterproof portion 420 is the second ultrasonic wave. Coupled to the probe 450, even if the medium is filled in the seating portion 200 to prevent the medium from flowing into the housing (100).

In the above description, the present invention has been described with reference to preferred embodiments, but the present invention is not necessarily limited thereto, and a person having ordinary skill in the art to which the present invention pertains does not depart from the technical spirit of the present invention. It will be readily appreciated that various substitutions, modifications and variations can be made.

1 is a perspective view showing an ultrasonic bone density measuring apparatus equipped with a waterproof means according to an embodiment of the present invention,

Figure 2 is a perspective view showing the internal structure of the ultrasonic bone density measurement apparatus equipped with a waterproof means according to an embodiment of the present invention,

Figure 3 is a perspective view showing the operating state of the ultrasonic bone density measuring apparatus equipped with a waterproof means according to an embodiment of the present invention,

4 is a perspective view showing a combined ultrasonic transducer mechanism according to an embodiment of the present invention,

Figure 5 is a perspective view showing the operating state of the ultrasonic transducer mechanism according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

200: seating unit 300: first ultrasonic transducer mechanism

320: waterproof portion 400: second ultrasonic transducer mechanism

420: waterproof

Claims (6)

A seating part on which a foot of a subject is seated; A first ultrasonic probe mechanism part having a waterproof part on one side of the seating part, and emitting ultrasonic waves by being in close contact with one side of the heel of the subject; And A second ultrasonic probe mechanism part provided with a waterproof part on the other side of the seating part and being in close contact with the other side of the heel of the subject to receive ultrasonic waves emitted from the first ultrasonic probe mechanism part; The first ultrasonic transducer mechanism portion and the second ultrasonic transducer mechanism portion, the fastening portion is respectively mounted on one side and the other side of the seating portion; One end is coupled to each of the fastening part and the waterproof part is provided to the outside of one side and the other side of the seating part, respectively; Ultrasonic probes respectively coupled to the other end of the waterproof portion; And a transducer housing to which the ultrasonic transducers are respectively coupled. The waterproof portion has a head coupled to the fastening portion, has a circumferential length smaller than the head, and a receiving portion is formed in a cylindrical shape by a predetermined length in the direction of the ultrasonic probe from the head, and a circumference smaller than the receiving portion. It has a length, the insertion portion is formed in a cylindrical shape by a predetermined length in the direction of the ultrasonic probe from the receiving portion, The waterproof part is inserted into the receiving portion folded into the receiving portion when the ultrasonic probe is moved and protrudes into the seating portion in the state that the head is coupled to the fastening portion and the lower portion of the insertion portion is coupled to the ultrasonic probe and , The waterproof portion is a flexible material, The ultrasonic bone density measuring apparatus is provided with a waterproof means, characterized in that the inlet of the medium is prevented from entering the mounting portion by the waterproof portion when the medium is filled in the seating portion for correction. delete delete delete delete delete

Images