KR101603014B1 - Diagnostic Tester for Pulse of Both Hands - Google Patents

Abstract

The present invention relates to a two-handed pulsator, comprising two pulse machines for worn on both sides of an examinee, and one air pump for simultaneously supplying air pressure to the two pulse machines, Since the air pressure is simultaneously supplied through one air pump and the pressure sensor is in contact with the both hands of the examinee at the same time, a separate air pump is not required, so that the entire structure can be simplified, It is possible to simultaneously form the pressure contact force and more precisely measure the pulse waves of both the sagittal parts and to independently adjust the pneumatic pressure to be supplied to the two pulsation units by attaching the air pressure control valve, The pressing contact forces of the pulse-guiding unit with respect to the both-handedness parts of the examinee are different from each other And provides a two-handed pulse-wave device capable of more accurately measuring pulse waves on both hand parts in more various ways.

Description

[0001] The present invention relates to a two-

The present invention relates to a two-handed pulse device. More specifically, it is provided with two pulse machines for individually worn on both examinee's hands, and one air pump for simultaneously supplying air pressure to the two pulse machines, so that two pulse machines can be driven by one air pump The air pressure is simultaneously supplied to both the examinee's hands and the pressure points of the examinee at the same time. Therefore, the separate structure of the air pump is not required, so that the entire structure can be simplified, It is possible to simultaneously measure the pulse waves of both the sagittal parts and the pneumatic pressure control valve to independently adjust the pneumatic pressure to be supplied to the two pulsation units so that the sphygmomanometer The pressure contact force of the pulse unit can be made different from each other. More precisely in such a way it relates to a hands pulse taking device capable of measuring the pulse wave of the yangsonmok region.

Generally, one of the diagnostic methods in Oriental medicine is to perform the method of detecting the pulse wave of the examinee by promoting the radial artery in the wrist area of the examinee's wrist.

The pulse wave from the arterial blood vessel, which is a three-dimensional structure, is not only a time series signal but also has a three-dimensional characteristic. That is, the intensity of the pulse wave due to pressurization, the width of the pulse wave (width of the transverse side where the pulse wave is detected), and the length of the pulse wave (length of the longitudinal axis of the blood vessel where the pulse wave is detected). In order to accurately detect these characteristics, it is necessary to measure the three-dimensional characteristics of the reproducible pulse waves by appropriately fixing the blood vessels in the atypical peripheral shape constituted by the ligaments, muscles, and skin. There was a problem that it was very difficult for the doctors who did not have many, and the accuracy was not high.

In recent years, to solve the inaccuracies of such a vein, a pulsation device has been developed which objectifies the senses of the examinee and sets the standard as a standard.

The conventional pulse wave device includes a fixing band that wraps around the wrist of a examinee, an air bag that is mounted inside the fixing band, and a pressure sensor that is mounted on the inner surface of the air bag and presses the skin of the examinee by the air pressure of the air bag. The pulse wave sensor detects the pulse wave of the examinee and processes the detected signal through the pulse wave sensor to measure the pulse wave of the examinee.

Such a pulse wave device is generally configured to be worn on one of the wrists of the examinee, and is configured to measure a pulse wave of one of the wrists of the examinee. Therefore, in order to measure the pulse wave on both wrists, the pulse waves on the left and right wrists must be separately measured.

The various characteristics of the pulse wave have a medicinal significance as well as an absolute value. Among these, the difference of the left and right pulse wave has various physiological meanings of oriental medicine. Therefore, considering that the temporal variation of the pulse wave is large, the accuracy of the measurement is limited by sequentially detecting the relative difference between the left and right without simultaneously measuring the pulse waves of both hands.

In this way, if the left and right wrists are separately measured, the pulse waves on the left and right wrists are measured with a time difference, so that the pulse waves of both the wrists can not be measured at the same time, And there is a problem that it is impossible to measure pulse waves of various methods. In addition, even if the two pulse devices are used to simultaneously measure the pulse waves of both the sagittal parts, since the method of measuring the pulse waves of the both sagittal parts is a separate device, the pressing force to the wrist part may be different, Not only the accuracy of the apparatus is degraded, but also the apparatus is also operated as a separate apparatus, so that there is a problem that the structure and the operation method are very inconvenient.

The conventional pulse wave device according to the related art is constructed in such a manner that the fixed band is worn on the wrist of the examinee as described above. At this time, in the process of wearing the fixed band on the wrist of the examinee, In particular, there has been a problem that it is very difficult and inconvenient to detect the pulse wave at the accurate venous point because the venous sensor is twisted or moved due to the motion of the examinee during the process of detecting the pulse wave of the examinee.

Korean Patent No. 10-1365230

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art, and an object of the present invention is to provide a blood pressure monitor which comprises two pulse- Since the two pulsation units are supplied with the air pressure through one air pump at the same time and brought into pressure contact with the both sides of the examinee at the same time by providing the pump, a separate air pump is not necessary, The present invention also provides a two-handed pulse-wave device capable of accurately measuring the pulse waves of both the sagittal parts simultaneously by forming the same pressure contact force on the examinee of each pulse unit.

Another object of the present invention is to provide a pneumatic pressure regulating valve capable of independently controlling the size of pneumatic pressure supplied to the two pulsation units so that the pressure contact force of the pulsation unit relative to both siblings of the examinee And to measure the pulse wave with respect to both of the sagittal parts in a more various manner.

Yet another object of the present invention is to provide a method and apparatus for adjusting the position of a venous sensor by moving a venous sensor in a state of wrapping a wrist portion of the examinee through a cuff member and an air bag, The position of the venous sensor can be easily moved to the correct venous point using the position adjusting means even if the position of the venous sensor is changed during the wrapping process or the position of the venous sensor is changed by the movement of the examinee during the venous process, Accordingly, it is a further object of the present invention to provide a two-handed beating device capable of more convenient and accurately performing a beating process.

The present invention relates to a pulse wave detecting apparatus comprising two pulse wave detecting units which are formed so as to cover both of the examinee's squeeze units, And an air pump for supplying air pressure to the pulse-wave unit so that the pulse-wave unit can be in pressure contact with both of the examinee's hands and the air-pump unit is configured to simultaneously supply air pressure to the two pulse- Handed beating device.

At this time, a main connection hose is connected to the air pump so as to supply air pressure, and the main connection hose may be branched into two sub connection hoses and connected to the two pulsating units.

In addition, the main connection hose and the sub connection hose may be configured so that the air pressures supplied from the air pump to the two pulsation units are all the same.

In addition, the sub connection hose may be equipped with a sub air pressure regulating valve so as to control the air pressure passing through the sub connection hose.

The two-hand beating device may further include a controller for controlling an opening amount of the sub air pressure regulating valve and an operation state of the air pump.

In addition, the above-mentioned two-handed pulse device may further include a pressure measuring sensor capable of measuring the pressing force of each pulse unit generated by the air pressure of the air pump to the examinee.

The pulsating unit may include a cuff member configured to wrap around the wrist of the examinee; An air bag formed to be able to receive air pressure from the air pump and mounted on an inner surface of the cuff member; And a sensor module for detecting a pulse wave of the examinee, and a sensor module mounted on an inner surface of the air bag.

The pulse wave unit may further include position adjusting means for adjusting the position of the pulse wave sensor by moving the pulse wave sensor at a predetermined interval.

The sensor module may include a fixed plate fixedly mounted on an inner surface of the air bag and having a guide rail formed on one side thereof. And a movable plate movably coupled along the guide rail, wherein the venous sensor can be coupled to the movable plate to move with the movable plate.

Further, the pulse-

And a cover member coupled to the air bag and surrounding the outer exposed surface of the sensor module, wherein the venous sensor is capable of being pressed against the skin of the examinee through the cover member.

The position adjusting means may include a pulling wire, one end of which is coupled to both ends of the moving plate in the moving direction, and the other end of which is pulled out through the cuff member and pulled out from the cuff member; And a guide ring for guiding an arrangement path of the traction wire so that a traction movement direction of the traction wire is parallel to a moving direction of the movable plate or an angle therebetween is at least 45 degrees, It is possible to move the venous sensor by a predetermined distance by pulling it from the outside of the cuff member.

According to the present invention, by providing the two pulse machines and the air pump simultaneously supplying the air pressure to the two pulse machines so as to be worn on both the examinee's hands and the two pulse machines, So that the entire structure can be simplified and the pressure contact force to the examinee of each pulse unit can be made equal to the pressure applied to the examinee of the examinee at the same time So that it is possible to simultaneously measure the pulse waves of both the sagittal parts at the same time.

Further, since the air pressure regulating valve can be mounted to independently adjust the air pressure magnitude to be supplied to the two pulsation units, the pressure contact force of the pulsation unit with respect to both the examinee's two-sided part can be made different according to the needs of the examiner, It is possible to more accurately measure the pulse wave on both the sagittal part.

In addition, the position of the venous sensor can be adjusted by moving the venous sensor while the wrist of the examinee is wrapped around the cuff member and the air bag. Thus, in the process of wrapping the wrist of the examinee using the cuff member or the like, The position of the venous sensor can be easily moved to the correct venous point by using the position adjusting means even if the position of the venous sensor is changed by the movement of the examinee during the course of the venipuncture, There is an effect that can precisely carry out the course procedure.

Figure 1 schematically illustrates the use of a two-handed beating device according to one embodiment of the present invention,
FIG. 2 is a schematic view of a configuration of a two-handed pulse-track apparatus according to an embodiment of the present invention;
Figure 3 schematically illustrates the configuration for each pulse unit according to one embodiment of the present invention;
Fig. 4 is a partially exploded perspective view schematically showing the configuration of the pulse-train unit shown in Fig. 3,
Fig. 5 is a sectional view schematically showing the internal structure of the pulse tube unit shown in Fig. 3,
6 is an operational state diagram schematically showing the operation state of the pulse-train unit shown in Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a view schematically showing the use of a two-handed beating device according to one embodiment of the present invention, and FIG. 2 is a view schematically showing a configuration of a two-handed beating device according to an embodiment of the present invention.

The two-handed pulse-wave apparatus according to an embodiment of the present invention is capable of simultaneously detecting pulse waves of both the examinee's hands. The apparatus includes two pulse-wave units 20 and one air pump 230.

Two pulsation units 20 are provided, each of which is formed so as to cover the regions of both sutures 10 of the examinee, and are configured to respectively detect pulse waves of the examinee from both of the sutures. Each of the pulsation units 20 may include a cuff member 100 capable of wrapping around a part of the examinee's wrist 10 and a pair of upper and lower parts of the cuff member 100, An air bag 200 mounted on the inner side of the air bag 200 and a sensor module 300 mounted on the inner side of the air bag 200 to detect a pulse wave. In particular, the pulse-tube unit 20 is configured to move the pulse-tube sensor at a predetermined interval so that the pulse-tube unit 20 can be accurately positioned. Will be described later.

The air pump 230 is configured to supply air pressure to the pulse tube unit 20 so that the pulse tube unit 20 can come into pressure contact with the region of both hands 10 of the examinee. At this time, the air pump 230 is formed to simultaneously supply the air pressure to the two pulse units 20.

A main connection hose 210 is connected to the air pump 230 so as to supply air pressure and the main connection hose 210 is branched into two sub connection hoses 220 to be connected to the two pulsating units 20 Respectively.

According to this configuration, the two pulse-wave units 20 are supplied with the air pressure through the air pump 230 at the same time and come into pressure contact with the both sides of the examinee at the same time, so that the entire structure can be simplified, It is possible to form the pressure contact force on the examinee of the pulse-tube unit 20 equally, and more precisely, the pulse waves of both the sagittal parts can be measured simultaneously.

1 and 2, two pulsation units 20 are provided and one air pump 230 is provided. In the air pump 230, a main connection hose 210 is connected to the air pump 230, And the main connection hose 210 branches to two sub connection hoses 220 and is connected to each of the two pulsation units 20.

It is preferable that the main connection hose 210 and the sub connection hose 220 are formed so that the air pressures supplied from the air pump 230 to the two pulsation units 20 are the same. That is, as shown in FIG. 2, the two sub connection hoses 220 are all formed to have the same inner diameter, so that the air pressure supplied from the air pump 230 through the main connection hose 210 is divided into two sub- And is equally supplied to each of the pulsation units 20, as shown in FIG.

In other words, the air pressure generated by one air pump 230 is supplied to the two pulse units 20 through the main connection hose 210 and the sub connection hose 220, Are supplied with the same air pressure, they are brought into pressure contact with the respective sore portions of the examinee with the same contact pressure.

Therefore, in the two-hand pulse device according to the embodiment of the present invention, in the process of measuring the pulse wave with respect to both the examinee's two-sided pulse, the two pulse wave units 20 measure the pulse wave with respect to both of the slack parts , It is possible to improve the accuracy of the pulse wave measurement results on both the sagittal and sagittal regions.

As shown in FIG. 2, the sub connection hose 220 may be equipped with a sub air pressure regulating valve 240 to adjust the air pressure passing through the sub connection hose 220. The sub air pressure regulating valve 240 can be regulated in its opening amount through a separate controller 250. In this way, the size of the air pressure supplied to each pulse unit 20 can be adjusted and the operation state of the air pump 230 can be controlled by the control unit 250, May be adjusted.

That is, by mounting the sub air pressure regulating valve 240 on the sub connection hose 220, the sub air pressure regulating valve 240 is independently controlled according to the user's needs, Can be adjusted differently. In this case, the sub air pressure regulating valve 240 may be independently controlled so that each of the pulse wave measuring units 20 is provided with a plurality of pulsating units 20, It is possible to operate such that another air pressure is supplied. In addition, by controlling the operation of the air pump 230 by the control unit 250, the magnitude of the air pressure supplied to the pulse-train unit 20 can be increased or decreased as a whole.

The two-handed pulse-wave apparatus according to an embodiment of the present invention may further include a separate pressure measuring sensor 260 (not shown) capable of measuring the pressing force applied to the examinee of each pulse unit 20 generated by the air pressure of the air pump 230 ). ≪ / RTI >

The pressure measurement sensor 260 may be mounted on the inner side of the air bag 200 of the pulse tube unit 20 as shown in FIGS. 1 and 2, and may be supplied to the air bag 200 using a piezoelectric element or the like And a method of measuring the change in the pressing force transmitted to the wrist of the examinee according to the air pressure.

The control unit 250 may be configured to adjust the opening amount of the sub air pressure regulating valve 240 or adjust the operating state of the air pump 230 according to the value measured by the pressure measuring sensor 260 have. That is, the contact pressure of the pulse tube unit 20 can be measured by the pressure measurement sensor 260, and the sub air pressure regulating valve 240 or the air pump 230 is controlled to have an appropriate contact pressure according to the measured value .

Next, the detailed configuration of each pulse unit 20 will be described in detail with reference to FIGS. 3 to 6. FIG.

FIG. 3 is a view schematically showing the configuration of each pulse unit according to an embodiment of the present invention, FIG. 4 is a partially exploded perspective view schematically showing the configuration of the pulse unit shown in FIG. 3, and FIG. 3 is a schematic sectional view showing the internal structure of the pulse tube unit shown in Fig. 3, and Fig. 6 is an operational state diagram schematically showing an operation state of the pulse tube unit shown in Fig.

The pulsator unit 20 according to an embodiment of the present invention is configured to surround the wrist of the examinee. In this state, the position of the pulse sensor for detecting the pulse wave of the examinee can be adjusted, The air bag 200 and the sensor module 300 and may further include a position adjusting means 400. The cuff member 100 may include a cuff member 100,

The cuff member 100 is formed so as to wrap around the part of the examinee's wrist 10 and may be formed by winding the wrist 10 around one or more turns or wrapping a part of the wrist 10 And the like. The cuff member 100 is not a simple rubber band, but may be configured to be freely changed in shape by applying an external force of a predetermined size or more according to an embodiment of the present invention, ≪ / RTI > For example, it can be composed of a soft resin product of a soft material or a thin sheet metal product, and the process of wrapping the wrist part of the examinee through the free shape changing structure can be performed more easily, It is possible to carry out the work of the podium.

The air bag 200 is formed to be able to receive air pressure from the air pump 230 through the main connection hose 210 and the sub connection hose 220. The air bag 200 may include an entire inner side surface of the cuff member 100, . The air bag 200 is inflated by the air pressure to press the sensor module 300 to be pressed against the wrist of the examinee, and at the same time, the entire device including the sensor module 300 is pressed by the wrist Thereby stably fixing the liquid to the site.

The sensor module 300 is mounted on the inner surface of the bladder 200 and includes a vein sensor 330 for detecting a pulse wave of the examinee. That is, the sensor module 300 is pressed toward the wrist of the examinee by the air pressure of the air bag 200 on the arrangement structure. At this time, the venous sensor 330 of the sensor module 300 presses the skin of the examinee . Of course, the quick axis sensor 330 may directly contact the skin of the examinee, but may indirectly contact the skin of the examinee through a separate cover member 500. [

Since the sensor module 300 has a different pressing force on the wrist of the examinee according to the air pressure of the air bag 200, the examiner can adjust the air pressure of the air bag 200 as described above, The pressurized state can be adjusted differently.

Meanwhile, the information detected by the sensor module 300, more specifically, the chamfer sensor 330 is transmitted to a separate data processing device (not shown) through the data cable 340, And output information of the examiner to the examiner.

The position adjusting unit 400 is configured to adjust the position of the venous sensor 330 of the sensor module 300 by moving the venous sensor 330 by a predetermined distance. At this time, the position adjusting means 400 can adjust the position of the sensor module 300 even when the sensor module 300 is in contact with the wrist of the examinee due to the air pressure of the air bag 200.

According to this structure, the pulsation unit according to an embodiment of the present invention can be used in combination with the cuff member 100, even when the air bag 200 and the sensor module 300 are wound around the examinee's wrist, It is possible to adjust the position of the minute hand sensor 330 and to perform more accurate chin work.

That is, in the conventional pulse wave devices, the position of the pulse signal sensor is changed in the course of winding a separate rubber band or the like around the wrist part of the examinee, or the pulse sensor is moved by the motion of the examinee. Since the cuff member 100 and the air bladder 200 can not be accurately positioned with respect to the examinee's wrist 200, The position of the angular sensor 330 can be adjusted through the position adjusting means 400 while the cuff member 100 and the air bag 200 are wound around the wrist. Even if the position of the venous sensor 330 is changed by the movement of the examinee or the position of the venous sensor 330 through the position adjusting means 400, Values can be re-adjusted to the correct jinmaek point. Therefore, the accuracy of the work can be improved.

As shown in FIGS. 4 and 5, the sensor module 300 and the position adjusting unit 400 are fixedly mounted on the inner surface of the air bag 200 A fixed plate 310 having a guide rail 311 formed on one side thereof and a movable plate 320 movably coupled along a guide rail 311 of the fixed plate 310. At this time, the venous sensor 330 may be coupled to one surface of the movable plate 320 and move along the guide rail 311 along with the movable plate 320 for a predetermined interval.

While the movable plate 320 and the venous sensor 330 are moving as described above, the movable plate 320 and the venous sensor 330 may move as they are in contact with the skin of the examinee. In this case, A separate cover member 500 surrounding the outer exposed surface of the sensor module 300 may be disposed on the inner surface of the air bag 200 to prevent the pain. According to this structure, since the movable plate 320 and the venous sensor 330 come into contact with the skin of the examinee through the cover member 500, the movement of the movable plate 320 and the venous sensor 330 can be performed more smoothly. It is possible to prevent the occurrence of pain that may occur to the examinee.

In addition, since the movable plate 320 is moved by the position adjusting means 400 in a state in which the movable plate 320 is pressed, the area where the movable plate 320 moves is the skin of the wrist region of the examinee. Is not flat and has irregular shape. Accordingly, when the movable plate 320 is made of a rigid material, the examinee may cause pain and the movement of the movable plate 320 may not be smooth even if the cover member 500 is interposed between the movable plate 320 and the movable plate 320. Therefore, And can be formed of a flexible material capable of bending deformation such that the pressure contact state with the examinee can be favorably maintained.

The position adjusting means 400 is configured to move the movable plate 320 of the sensor module 300 so that the immersion sensor 330 moves together with the movable plate 320. The movable plate 320 is coupled to both ends of the moving plate 320 And a pulling wire 410 through which the other end passes through the cuff member 100 and is drawn out to the outside. The other end of the pulling wire 410 located at the outside of the cuff member 100 is provided with a separate handle band 410 for facilitating the pulling out operation of the pulling wire 410 and preventing the pulling wire 410 from being twisted. 420 may be combined.

When the pulling wire 410 is pulled out and moved to move the movable plate 320, it is most advantageous that the pulling direction of the pulling wire 410 is formed parallel to the moving direction of the movable plate 320 For this purpose, a separate guide ring 430 may be disposed inside the air bag 200.

The guide ring 430 may be formed in the form of a simple ring through which the pulling wire 410 can penetrate. As shown in FIG. 5, when the traction direction of the pulling wire 410 is moved Direction or an angle [alpha] therebetween is guided to be less than or equal to 45 [deg.].

Thus, when the examinee pulls the other end of the pulling wire 410 located outside the cuff member 100, that is, the pull band 420, the pulling wire 410 is pulled out from the movable plate 320, Even if the pulling out force on the pulling wire 410 is relatively small, the force of the movable plate 320 (i.e., the pulling force of the movable plate 320) Can move smoothly.

6 shows an operating state in which the movable plate 320 and the venous sensor 330 are moved according to the structure described above. As shown in FIG. 6 (a), the handle band 420 positioned on the right side is taken out The pulling wire 410 pulls the movable plate 320 in the right direction to move the movable plate 320 and the chamfer sensor 330 coupled thereto to the right. On the contrary, if the pull band 410 is pulled out on the left side as shown in FIG. 6 (b), the pulling wire 410 pulls the movable plate 320 in the left direction in the same manner, 320 and the chamfer sensor 330 coupled thereto move to the left.

Accordingly, the pulse tube unit according to an embodiment of the present invention can adjust the position of the pulse sensor 330 even when the pulse tube is wound around the examinee's wrist in this manner, so that the pulse tube can be accurately and conveniently operated.

The foregoing description is merely illustrative of the technical idea of the present invention and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents thereof should be construed as falling within the scope of the present invention.

10: Wrist 20: Pulse Unit
100: cuff member 200: air bag
210: main connection hose 220: sub connection hose
230: Air pump 240: Sub air pressure regulating valve
250: control unit 260: pressure measuring sensor
300: Sensor module 310: Fixing plate
311: guide rail 320: movable plate
330: centering sensor 400: position adjusting means
410: tow wire 420: handle band
430: guide ring 500: cover member

Claims (11)

delete Two pulse forming units formed to be able to wrap the both-handed parts of the examinee, respectively, and to detect pulse waves of the examinee at both of the two sore parts; And
An air pump for supplying air pressure to the pulse-wave unit so that the pulse-wave unit can be brought into pressure contact with the both-
Wherein the air pump is configured to simultaneously supply air pressure to the two pulsation units,
Wherein a main connection hose is connected to the air pump so as to supply air pressure, and the main connection hose is branched into two sub connection hoses and connected to the two pulsation units.
3. The method of claim 2,
Wherein the main connection hose and the sub connection hose are configured so that air pressure supplied from the air pump to the two pulsation units is the same.
3. The method of claim 2,
Wherein the sub connection hose is equipped with a sub air pressure regulating valve so as to adjust the air pressure passing through the sub connection hose.
5. The method of claim 4,
Further comprising a control unit for controlling operations of the auxiliary air pressure regulating valve and the operation state of the air pump.
6. The method of claim 5,
Further comprising a pressure measuring sensor capable of measuring the pressing force of each pulse unit generated by the air pressure of the air pump to the examinee.
7. The method according to any one of claims 2 to 6,
The pulse-
A cuff member formed to wrap around the wrist of the examinee;
An air bag formed to be able to receive air pressure from the air pump and mounted on an inner surface of the cuff member; And
A sensor module for detecting a pulse wave of an examinee, and a sensor module mounted on an inner surface of the air bag,
And a control unit for controlling the two-handed pulsator.
8. The method of claim 7,
The pulse-
A position adjusting means for adjusting the position of the venous sensor by moving the venous sensor by a predetermined interval;
Further comprising: a control unit for controlling the two-handed pulsating device.
9. The method of claim 8,
The sensor module
A fixing plate fixedly mounted on an inner surface of the air bag and having a guide rail formed on one side thereof; And
A movable plate movably coupled along the guide rail,
Wherein the venous sensor is coupled to the movable plate for movement with the movable plate.
10. The method of claim 9,
The pulse-
Further comprising a cover member coupled to the air bag and surrounding the outer exposed surface of the sensor module, wherein the venous sensor is in press contact with the skin of the examinee through the cover member.
11. The method of claim 10,
The position adjusting means
A pulling wire connected to both ends of one end in the moving direction of the movable plate, the other end being pulled out through the cuff member and pulled out from the outside of the cuff member; And
A guiding ring for guiding an arrangement path of the traction wire so that a traction movement direction of the traction wire is parallel to a moving direction of the movable plate or an angle therebetween is at least 45 degrees;
Wherein the traction wire is pulled from the outside of the cuff member to move the venous sensor for a predetermined interval.

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