KR100977465B1 - Jig for probe of blood flow meter - Google Patents

Abstract

PURPOSE: A probe holder is provided to improve the accuracy of a blood flow measurement by stably fixing a measuring position and the angle of a probe. CONSTITUTION: A probe holder comprises a fixture(110), a rotating block(120), a moving block(130), and a probe fixing part(140). The fixture is fixed to the body part of a subject. The fixture is made of an elastic material. The rotating block is rotatably assembled in the bracket part(111) of the fixture in order to control the angle of a probe. The moving block is movably assembled in the rotating block in order to control the location of the probe. The probe fixing part is assembled in the moving block.

Description

Probe holder {Jig for probe of blood flow meter}

The present invention relates to a probe holder for a blood flow measuring device, and more particularly, to a probe holder for fixing a probe having an ultrasonic probe of a blood flow measuring device to a body part of a subject such as an arm during blood flow measurement.

In general, the measurement of the velocity of blood flow in the blood vessel is widely used for the diagnosis of diseases, and the ultrasonic diagnostic system using the Doppler effect is widely used for the detection of the velocity of blood flow.

The blood flow measurement method using the Doppler effect of ultrasound has a feature of non-invasive measurement of blood flow rate in real time, and is widely used in the diagnosis of modern medicine.

In the ultrasonic diagnostic system using the Doppler effect, the ultrasonic transducer transmits an ultrasonic signal to a target such as red blood cells, receives a signal reflected from the target, and detects the frequency shift of the received signal due to the movement of the target to determine the speed of the target.

That is, an ultrasonic wave having a specific frequency is incident on the human body and the ultrasonic wave reflected by the red blood cells flowing through the blood vessel is detected. The frequency of the detected ultrasonic wave has a different frequency from that of the incident ultrasonic wave. To measure the rate of blood flow.

Briefly describing the principle of measuring the blood flow rate using the ultrasonic signal, the ultrasonic transducer transmits the ultrasonic signal to the target and acquires the ultrasonic signal reflected from the target through the ultrasonic transducer.

At this time, if the target moves, the center frequency of the reflected signal is changed from the center frequency of the transmitted signal, the moving speed V of the target can be calculated according to Equation 1 from the change in the center frequency of the reflected signal.

Here, f _d is the amount of change in the center frequency of the ultrasonic waves reflected from the center frequency of the transmitted ultrasonic waves, defined as doppler shift, c is the ultrasonic velocity in the medium to be transmitted and received ultrasonic waves, f is the center of the transmitted ultrasonic waves Frequency. θ is the angle between the traveling direction of the ultrasonic wave and the traveling direction of the blood flow. As can be seen in Equation 1, the moving speed of the target is proportional to the Doppler movement of the signal reflected from the target.

In addition, a conventional ultrasonic diagnostic system using the Doppler effect generates an ultrasonic probe that contacts the human body to inject an ultrasonic signal into a sample (blood blood) and obtains the reflected signal, and generates a high frequency signal for driving the ultrasonic probe. And a signal processing and control unit which calculates blood flow rate data by processing the reflected signal, and transmits the acquired blood flow rate data to the display unit, and a display unit which displays the measurement result including the blood flow rate data for the user to check. Consists of.

On the other hand, there is a need for a system that is simple to carry and use in ultrasound diagnosis, and various studies have been conducted to reduce the size of a probe having an ultrasonic probe in order to increase mobility, availability, and convenience.

In addition, in order to improve the reliability of the measurement results due to the characteristics of the diagnostic system for human body, various studies such as process improvement and algorithm improvement for signal processing and result calculation have been conducted.

However, the above-mentioned improvement of the device alone does not improve the accuracy of the measurement result entirely, and in order to maximize the accuracy of the measurement result, the use of the correct device by the measurer is important.

For example, in order to inject ultrasound into the human body during the blood flow measurement, the ultrasonic probe contacts the skin surface. In order to reduce measurement errors, the angle of incidence between the ultrasonic probe and the skin surface must be kept constant.

However, in the related art, it is practically difficult to maintain a constant angle of incidence when the ultrasonic transducer is in contact with a blood flow measuring apparatus such as a Doppler ultrasonic apparatus for measuring a blood flow rate, which may cause an error in the result of blood flow measurement.

In addition, in the case where the measurer maintains the measurement position and the measurement angle (ultrasound incident angle) of the probe in which the ultrasonic probe is built, there is a difficulty and inconvenience, such as the need to fix the probe by hand directly during the measurement time.

Therefore, the present invention has been invented to solve the above problems, and as an auxiliary device for fixing the probe (probe) with an ultrasonic probe when measuring blood flow, which can more accurately and conveniently fix the probe during human contact. It is an object of the present invention to provide a probe holder for blood flow measurement apparatus.

In order to achieve the above object, the present invention, in one embodiment, a fixing stationary fixed to the body part of the subject; A rotatable block assembled up and down and fixed to the bracket part integrally formed with the fixing stand, and allowing a vertical angle adjustment of the probe to the body surface according to the rotated angle; A moving block which is assembled to the front and rear movement of the rotary block and enables the front and rear positioning of the probe with respect to the body surface according to the moved back and forth position; Provides a probe holder for blood flow measurement device comprising a; probe fixing unit is assembled to the moving block and the probe is fixed.

In a preferred embodiment, the rotating block is fastened by the bracket portion and the fastening bolt and the tightening nut of the fixing unit can be rotated about the fastening bolt and can be fixed by the fastening bolt and the fastening nut.

In addition, a slot is formed up and down long in the bracket portion of the fixture, the fastening bolt is assembled through the slot, the rotation block may be configured to adjust the vertical position along the slot in the bracket portion of the fixture.

In addition, the probe fixing unit may be configured to be rotatable and fixed to the rotating block so that the left and right directions of the probe with respect to the body surface may be adjusted according to the rotated angle.

Accordingly, the following effects can be obtained through the problem solving means described above.

According to the probe holder according to the present invention, a more accurate and convenient measurement can be made by fixing the measurement position and the measurement angle of the probe during the measurement.

In particular, according to the probe holder of the present invention, the position and angle of the probe, and more specifically, the up and down angle, up and down position, front and rear position, left and right angle of the probe with respect to the body surface can be easily adjusted while holding the position of the probe before measurement. Will be.

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

The present invention relates to a probe holder for fixing the probe embedded in the ultrasonic probe of the blood flow measuring device to the body part of the subject, such as an arm. The measurement position and the measurement angle of the probe are fixed during the measurement to make a more accurate and convenient measurement. I would have to.

In particular, the probe holder of the present invention can easily position and angle the probe, and more specifically, the up and down angle, up and down position, front and rear position, left and right angle of the probe with respect to the body surface, as described below while holding the position of the probe before measurement Configured to adjust.

1 is a perspective view showing a probe holder according to a preferred embodiment of the present invention, Figure 2 is an exploded perspective view of the probe holder according to a preferred embodiment of the present invention.

In addition, Figure 3 is a state diagram showing the up and down position adjustment and the vertical angle adjustment of the rotary block in the probe holder according to a preferred embodiment of the present invention, Figures 4 and 5 are views showing the front and rear position adjustment of the moving block. 6 is a state diagram used.

As shown, the probe holder 100 of the present invention, the holder 110 is fixed to the body part 1, such as the arm of the measurement target, and the bracket portion 111 formed integrally with the bracket 110, the rotation After the assembly is assembled to be fixed to the rotating block 120 to be able to adjust the angle of the probe (2) according to the rotated angle, and assembled so as to be moved back and forth to the rotary block 120, the probe according to the position moved back and forth It comprises a moving block 130 that is capable of adjusting the front and rear positions of (2), and the probe fixing unit 140 is assembled to the moving block 130 is fixed to the probe (2).

Here, the fixing stand 110 is a part that is fitted to the body part 1, such as the arm is fixed, has a long and rounded band shape to surround the body part 1, the opening 112 is formed on one side of the opening Through 112, it is possible to fit the body part 1 such as the arm.

When the body part 1 is to be inserted into the fixing part 110, the body part 1 passes through the opening part 112, and the inner part 1 is inserted into the body part 1 or inserted into the band shape of the fixing part 110. The arm may be inserted directly without passing through the opening 112.

The fixing unit 110 may be made of a material having a certain amount of elasticity, for example, plastic having elasticity so as to be elastically opened at the opening 112 in order to insert the body part 1, and the body part 1 When the fitting is to be inserted through the opening 112, the measurer opens the opening 112 slightly and passes the body part 1 from the opening 112 into the fixing unit 110.

Reference numeral 113 denotes a reinforcing rib protruding from the outer surface of the holder 110, which is formed long along the longitudinal direction of the holder 110.

In addition, reference numeral 114 is a support portion, which may be formed to protrude from both the left and right sides of the lower surface of the fixing stand 110, respectively, so that the supporter 114 to measure more stably and more easily after taking a posture. The body part (1) such as the desk top surface is supported on the surface to be raised, and then the body part (1) is inserted into the holder (110) inside the upright 110. In this state, the measurement is performed after adjusting the position and angle of the probe 2.

The rotating block 120 is assembled to be vertically rotated and fixed to the bracket portion 111 formed on the fixing unit 110, and configured to enable the vertical angle adjustment of the probe 2 to the body surface during rotation. It is wealth.

In a preferred embodiment, the slot 115 is formed up and down in the bracket portion 111 of the fixing unit 110, the fastening bolt 116 and the fastening bolt 116 to be assembled through the slot 115 The rotating block 120 is assembled to the bracket part 111 of the holder 110 by the fastening nut 117 to be fastened.

At this time, the fastening part 120a which is fastened by the bracket part 111 and the fastening bolt 116 is integrally formed in the lower part of the rotating block 120, and the fastening bolt 116 penetrates through the fastening part 120a. The through hole 120b is formed, and the fastening bolt 116 is inserted into the through hole 120b of the fastening part 120a and the slot 115 of the bracket part 111, and then ends of the fastening bolt 116. The fastening nut 117 is fastened to the rotating block 120 and the brackets 111 of the fixing base 110 to be assembled with each other.

The rotating block 120 is rotated about the fastening bolt 116 in the bracket portion 111 of the fixing unit 110, the angle is adjusted and then the angle is fixed after the tightening nut 117 is fully fastened, the rotating block When the tightening nut 117 is completely tightened after adjusting the angle of the 120, the fastening bolt 116 and the fastening nut 117 are connected to the fastening part 120a of the rotary block 120 and the bracket part 111 of the fixing base 110. It is fixed by pressing on both sides.

The vertical angle adjustment of the rotary block 120 is ultimately for adjusting the vertical angle of the probe 2, and in the preferred embodiment, the slot formed with the rotary block 120 vertically long in the bracket portion 111 of the holder 110 is provided. Since it is assembled to the 115 to move the rotation block 120 is fixed along the slot 115 can be adjusted together with the vertical position of the rotation block 120. Of course, the vertical position adjustment of the rotary block 120 is ultimately for the vertical position adjustment of the probe (2) relative to the body surface (see Figure 3).

In addition, in a preferred embodiment, the upper surface of the bracket portion 111 of the fixing unit 110 may be formed with a scale portion 119 of the scale form indicating the angle, the scale portion 119 on the side of the rotary block 120 A reference point 120c in the form of a groove or protrusion may be formed at a corresponding position of the groove.

Accordingly, by measuring the position of the reference point (120c) in the scale unit 119 at the time of rotation of the rotary block 120, the measurer can easily know the amount of rotation and the current angle of the rotary block 120, the angle adjustment more easily Will be able to.

In Figures 1 to 4, 6 can be seen that the reference point (120c) is provided on the side of the rotary block 120, the same shape in the same position on the opposite side of the rotary block 120 (invisible side) It is provided that the reference point of, which is not shown in the figure (note that the reference point is formed at the same position on both sides of the rotary block).

On the other hand, the rotary block 120 is coupled to the movable block 130 adjustable forward and backward position, in the preferred embodiment the movable block 130 is assembled to the inside of the rotary block 120.

To this end, the moving block 130 is inserted into the inside of the rotary block 120, the guide groove 121 is guided back and forth is formed long before and after, the rear end of the rotary block 120 back and forth with the guide groove 121 A bolt hole 122 through which the true screw bolt 124 is inserted is formed.

The guide groove 121 guides the moving block 130 back and forth while constraining the rotation of the moving block 130 when the moving block 130 moves forward and backward in a state where the moving block 130 having a rectangular cross section is inserted. It serves as a passage, and is formed to have a rectangular cross section like the cross section of the moving block 130.

In addition, a stopper seating groove 123 into which a stopper 125 for restraining forward and backward movement of the screw bolt 124 is inserted is formed at one side of the inner circumferential surface of the bolt hole 122, and a rear end of the movable block 130 is provided. The screw hole 131 is formed on the inner peripheral surface so that the screw bolt 124 is screwed (screwed).

In addition, the head 126 of the screw bolt 124 is formed with a handle so that the measurer can hold and rotate by hand.

In this structure, the screw bolt 124 and the movable block 130 are assembled into the rotary block 120 with the end of the screw bolt 124 inserted into and fastened to the screw hole 131 of the movable block 130. The moving block 130 is inserted into the inner space of the rotary block 120, that is, the guide groove 121, and the screw bolt 124 is assembled to pass through the bolt hole 122 of the rotary block 120. .

At this time, the handle portion 126 of the screw bolt 124 is located outside the rear of the rotary block 120, the stopper 125 of the screw bolt 124 to the bolt hole 122 of the rotary block 120 It is fitted into the formed stopper mounting groove 123.

As a result, when the rotating block 120, the moving block 130, and the screw bolt 124 are all assembled, the grip bolt 124 is rotated while holding the handle 126 to rotate the screw bolt 124. Since the rotation of the movable block 130 is constrained in the state in which the forward and backward movements are constrained, the movable block 130 is moved back and forth along the guide groove 121 of the rotary block 120 by the rotation of the screw bolt 124. (The rotational force of the screw bolt is converted to the forward and backward force of the moving block).

Accordingly, the measurer can rotate the screw bolt 124 to adjust the forward and backward positions of the moving block 130 as desired, and ultimately, the forward and backward positions of the probe 2 can be adjusted (see FIGS. 4 and 5). ).

In addition, the probe fixing part 140 is assembled to the front end of the moving block 130, and the probe fixing part 140 includes a probe mounting part 141 to which the probe 2 is fitted and fixed inside, and the probe mounting part 141. It is formed integrally with) is composed of a fastening portion 142 coupled to the front end of the moving block (130).

Here, the fastening part 142 is coupled by the front end of the moving block 130 and the tightening bolt 145, in a preferred embodiment the fastening part 142 is assembled to be fixed after rotation in the moving block 130. .

That is, the fitting portion 143 is integrally formed to protrude from the lower end of the fastening portion 142, and the insertion portion 143 of the fastening portion 142 is inserted into and inserted into the upper end surface of the moving block 130. Grooves 132 are formed.

In addition, a bolt fastening hole 144 is formed at the position of the fitting part 143 in the fastening part 143 to the inside of the fastening part, and the insertion groove 132 passes through the movable block 130 up and down. A bolt hole 133 is formed, and the fastening bolt 145 is fastened to the bolt hole 133.

The tightening bolt 145 passes through the bolt hole 133 and is fastened to the bolt fastening hole 144 of the fastening part 142. The head 146 of the fastening bolt 145 may be rotated by a measurer by hand. The handle portion is formed to be.

As a result, in the state in which the fitting portion 143 formed on the fastening portion 142 of the probe fixing portion 140 is fitted into the insertion groove 132 of the moving block 130, the probe fixing portion 140 is properly rotated. Adjust the direction from side to side, and then tighten the fastening bolt 145 fastened to the probe fixing part 140 through the bolt hole 133 of the moving block 130, the probe fixing part 140 can be completely fixed. Will be.

At this time, when the head (knob) 146 of the tightening bolt 145 is squeezed to the maximum by rotating the tightening bolt 145 as much as possible, the probe fixing part 140 moves to the moving block ( 130 is not rotated and is completely fixed.

As described above, when the probe fixing part 140 is rotated from the moving block 130 to the left and right to adjust the direction, the direction of the probe 2 may be adjusted to the left and right with respect to the body surface (see FIG. 5).

In this way, the probe holder 100 of the present invention allows the measurer to easily adjust the measuring position and measuring angle of the probe 2 and stably fixes the measuring position and measuring angle of the adjusted probe 2 during the measurement. So that more accurate and convenient measurements can be made.

In particular, the probe holder 100 according to the present invention has the advantage that it can adjust both the vertical angle, vertical position, forward and backward position, left and right direction of the probe 2 with respect to the contact surface.

That is, the bracket 110 is fixed to the body part 1 of the measurement subject, for example, the arm, and the like, and the probe 2 is mounted on the probe fixing part 140. By rotating and rotating the rotary block 120 up and down around the fastening bolt 116, it is possible to adjust the vertical angle (ultrasound incident angle) of the probe (2), and also before the fixing of the rotary block 120 The upper and lower positions of the probe 2 may be adjusted by moving the rotating block 120 up and down along the slot 115 in the bracket portion 111 of the bracket 111.

And, by moving the moving block 130 back and forth in the rotary block 120 to adjust the forward and backward position of the probe (2), the probe fixing unit around the tightening bolt 145 in the moving block 130 The left and right directions of the probe 2 may be adjusted by rotating the 140 to the left and right.

If the angle adjustment of the probe by the rotation of the rotary block 120 is to adjust the vertical angle of the probe relative to the body surface, the direction adjustment of the probe by the rotation of the probe fixing unit 140 is the left and right direction of the probe relative to the body surface Angle adjustment is possible.

As described above, when the measuring position and the measuring angle of the probe 2 are precisely adjusted as desired by the user using the probe holder 100 of the present invention, the measurement is made easier and more convenient and more accurately. It becomes possible.

1 is a perspective view showing a probe holder according to a preferred embodiment of the present invention,

2 is an exploded perspective view of a probe holder according to a preferred embodiment of the present invention;

Figure 3 is a state diagram showing the vertical position adjustment and the vertical angle adjustment of the rotary block in the probe holder according to the preferred embodiment of the present invention,

4 and 5 is a view showing the front and rear position adjustment of the moving block in the probe holder according to an embodiment of the present invention,

Figure 6 is a state of use of the probe holder according to a preferred embodiment of the present invention.

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

1: body part 2: probe

100: holder 110: holder

120: rotation block 130: moving block

140: probe holding part

Claims (14)

A fixed base 110 fixed to the body part 1 of the measurement target; Rotation to be assembled and rotated up and down to the bracket portion 111 integrally formed on the fixing unit 110 and to adjust the rotation angle of the probe 2 relative to the body surface according to the rotated angle. Block 120; A moving block (130) for assembling the front and rear movement of the rotary block (120) and enabling the front and rear positions of the probe (2) to the body surface according to the moved position back and forth; And a probe fixing part 140 assembled to the moving block 130 and to which the probe 2 is fixed. The moving block 130 is coupled to the screw bolt 124 in a state that the rotation is constrained to the rotation block 120 is assembled so that only forward and backward movement, The screw bolt 124 is coupled to the rotation block 120 to move forward and backward constrained and only rotation, Blood flow measurement device configured to be able to adjust the forward and backward position of the moving block 130 in the rotary block 120 while the rotational force is converted to the forward and backward force of the moving block 130 is screwed when the screw bolt 124 is rotated Probe holder for The method according to claim 1, The fixing unit 110 has a long and rounded band shape so as to surround the body part 1, and an opening 112 is formed at one side of the fixing unit 110 to open the body part 1 to the opening 112. Probe cradle for blood flow measurement device, characterized in that through the holder 110 can be put into. The method according to claim 2, The holder 110 is made of a material having elasticity to elastically open in the opening 112, characterized in that the reinforcing ribs 113 are formed long in the longitudinal direction on the outer surface of the holder 110. Probe holder for blood flow measuring apparatus. The method according to claim 2, Probe cradle for blood flow measurement device, characterized in that the lower surface of the support 110 is formed with a protruding portion 114 is supported on the surface on which the body portion (1) is raised. The method according to claim 1, The rotating block 120 is fastened by the bracket part 111 and the fastening bolt 116 and the fastening nut 117 of the fixing unit 110 is rotated around the fastening bolt 116 and fastening bolt 116 and tightening Probe holder for blood flow measurement, characterized in that fixed by the nut (117). The method according to claim 5, The fastening bolt 120a is formed integrally with the lower portion of the rotary block 120, and the fastening bolt penetrates the fastening portion 120a of the rotary block 120 and the bracket portion 111 of the fixing base 110. 116 and the probe block for blood flow measurement device, characterized in that the rotary block 120 is assembled by the tightening nut 117 is fastened to the fastening bolt 116. The method according to claim 5, The slot 115 is formed in the bracket portion 111 of the holder 110 up and down, the fastening bolt 116 is assembled through the slot 115, the rotating block 120 is fixed to the holder 110 Probe holder for blood flow measurement device, characterized in that the up and down position can be adjusted along the slot 115 in the bracket (111) of. The method according to claim 5, The bracket portion 111 of the fixing unit 110 is formed with a scale portion 119 of the scale form indicating the angle, the rotary block 120 is formed in the groove or protrusion form at the corresponding position of the scale portion 119. Probe holder for blood flow measurement, characterized in that the reference point (120c) is formed. delete The method according to claim 9, Guide grooves 121 are formed in the rotary block 120, The moving block 130 is inserted into the guide groove 121 of the rotary block 120 to move forward and backward, The screw bolt 124 is screwed with the moving block 130 inserted into the guide groove 121 in the state penetrating the bolt hole 122 of the rear end of the rotary block 120 for the blood flow measurement device Probe Cradle. The method according to claim 10, Probe cradle for blood flow measurement device, characterized in that the cross-section of the guide groove 121 and the moving block 130 in a square so that the rotation of the moving block 130 in the guide groove 121. The method according to claim 10, A stopper 125 is formed on the screw bolt 124, A stopper seating groove 123 into which the stopper 125 of the screw bolt 124 is inserted is formed at one side of the inner circumferential surface of the bolt hole 122, The stopper mounting groove 123 is inserted into the stopper 125, the cradle for the blood flow measurement device, characterized in that the forward and backward movement of the screw bolt 124 is restrained. The method according to claim 1, The probe fixing unit 140 is assembled to be rotated and fixed to the rotary block 120 so that the left and right directions of the probe 2 relative to the body surface can be adjusted according to the rotated angle Probe holder for measuring devices. 14. The method of claim 13, The fitting part 143 is integrally formed to protrude from the lower end of the probe fixing part 140, The moving block 130 is formed with an insertion groove 132 into which the fitting portion 143 of the probe fixing part 140 is inserted and fitted. A bolt fastening hole 144 is formed at the position of the fitting portion 143 in the probe fixing portion 140 to be formed long into the probe fixing portion 140. A bolt hole 133 penetrating the moving block 130 is formed at the position of the insertion groove 132 in the moving block 130, The fastening bolt 145 penetrating the bolt hole 133 of the moving block 130 is fastened to the bolt fastening hole 144 of the probe fixing part 140, The head 146 of the tightening bolt 145 is compressed by tightening the moving block 130, so that the probe fixing unit 140 is fixed to the moving block 130, the probe holder for blood flow measuring apparatus.

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