KR100373954B1 - apparatus for driving guff for blood pressure machine - Google Patents

Abstract

The present invention relates to a arm drive of the blood pressure measuring device, in the blood pressure measuring device to measure the blood pressure wrapped around the lower arm, the arm 20 is moved while drawing a spiral curve in the hollow arm cylinder 18 And a band 66 of a predetermined length, a rack 68 provided on an outer surface of the band, and a bag portion 70 coupled to an inner surface of the band to pressurize and introduce air. The pinion is penetrated through the cylinder, and the pinion is directly coupled to the motor shaft of the drive motor 28, thereby reducing the size of the arm drive and significantly reducing the size of the product. Simplify and reduce the number of parts.

Description

Band drive of blood pressure meter {apparatus for driving guff for blood pressure machine}

The present invention relates to a blood pressure meter, and more particularly to a arm drive device of the blood pressure meter.

Blood pressure monitor is a device for measuring the systolic blood pressure and diastolic blood pressure of the arteries by wrapping the arm around the arm, pressurizing the arm by filling the air inside the arm, and slowly releasing the air. In such a blood pressure monitor, the arm is wound around the arm by the drive.

In the conventional blood pressure measuring device, the belt winding device has a structure in which the belt is wound or unwound through a belt. In other words, the wand is fixed to one side and bends the other end while drawing a spiral curve, and then pulls the other side of the wand in the tangential direction to meet the arm. While wrapping or loosening the band.

However, in the arm drive device of the conventional blood pressure measuring device configured as described above, the arm wound around the wheel is tangentially moved by the belt to meet or loosen the arm of the examinee. Therefore, the space for installing the belt must be secured and the structure is complicated. There was this.

That is, in the arm drive device of the conventional blood pressure measuring device has a problem that the size of the blood pressure measuring device is large because the case formed with a long space for installing the belt and the pulley to which the belt is to be formed. The control circuit board, pneumatic line, and pump should be installed inside the blood pressure monitor. The excessive size of the arm drive device makes the product coarse.

Therefore, the present invention has been made to solve the above problems, and an object of the present invention is to provide a blood pressure measuring device for the drive of the blood pressure measuring device to significantly reduce the size of the drive device.

Another object of the present invention is to provide a arm drive device of a blood pressure monitor, which simplifies the structure of the arm drive device and reduces the number of parts.

1 is a perspective view showing a blood pressure monitor coupled to the arm drive device according to the present invention,

FIG. 2 is a cross-sectional view of the arm cylinder of FIG. 1 cut radially; FIG.

3 is a cross-sectional view of the arm cylinder of Figure 1 cut in the longitudinal direction;

Figure 4 is a schematic plan view showing the interior of the blood pressure measuring instrument to which the arm drive device according to the present invention,

5 is a graph showing a change in the pressure of the arm over time at the time of blood pressure measurement of the blood pressure meter to which the present invention is applied.

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

10: case 12: cover

14 monitor 16 arm support

18: arm cylinder 20: arm

28: drive motor 34: pinion

68: rack 70: bag

72: base bracket 74: fixed guide roller

76: rotating guide roller

The arm drive device of the blood pressure measuring device according to the present invention is a blood pressure measuring device for measuring blood pressure by wrapping the arm around the upper arm, wherein the arm is moved while drawing a spiral curve in the hollow arm cylinder, the band having a predetermined length and the A rack provided on an outer surface of the band, and a bag portion coupled to the inner surface of the band to pressurize air by inflow, wherein the rack is held by a pinion penetrating through the arm cylinder, and the pinion is connected to a motor shaft of a drive motor. It is characterized in that it is directly coupled.

The arm is slid while one end is fixed to the base bracket and the other end is guided by the guide roller, thereby increasing or decreasing the inner space of the arm.

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

As shown in FIG. 1, the blood pressure measuring device to which the arm drive device according to the present invention is applied is fixed by covering a cover 12 on an upper side of a case 10 in which a control circuit board and air access means are installed. One side of the rear edge of the cover 12 is hinged to the monitor 14, which displays the blood pressure measurement value, can be folded to the upper surface of the cover 12, the other side of the rear edge of the cover 12, the lower arm of the examinee An arm rest 16 is installed to comfortably support, and a hollow arm cylinder 18 is coupled to the front of the arm rest 16 to align with the arm rest 16, and inside the arm cylinder 18. There is a structure coupled to the arm 20 wound around the examiner's upper arm.

As shown in Fig. 4, inside the case 10, power supply means 22 for supplying power and control means 24 for controlling a blood pressure meter are provided on each circuit board. Printing means 26 for printing the output data output by the control means 24 is provided. In addition, a drive motor 28 for generating power for driving the arm 20 is installed inside the case 10, while an air entry means 30 for introducing air into and out of the arm 20 is provided. It is installed.

The front motor shaft 32 of the drive motor 28 is provided with a pinion 34 snapped to a rack tooth, which will be described later, of the arm 20. The rear motor shaft 36 of the drive motor 28 has a hanger. 38 is provided, and the solenoid ball 42 which has the plunger 40 which catches the said latch 38 is provided in the case 10. As shown in FIG. The drive motor 28 is a forward and reverse motor capable of forward and reverse rotation.

The air access means 30, the air pump 44 for pumping air is connected to the distributor 48 through the supply line 46, the test line 49 for testing the air pressure on one side of the distributor 48 ) Is connected, and the other side of the distributor 48 is connected to a rapid exhaust line for rapidly exhausting air, and the other side of the distributor 48 is a supply line for guiding air to the arm 20. The structure 52 is connected. In addition, the supply line 46 is branched into the fine exhaust line 54, which gradually exhausts the air after supplying air to the arm 20, the air supply line 52 for detecting the air pressure (line) 56 is branched.

The pump 44 has two and the air outlets are connected to each other and to the supply line 46.

At the end of the test line 49, a connector is coupled to open the test tube when necessary and is normally closed by a cap. The solenoid valve 58 is provided at the end of the rapid exhaust line 50, and the micro holes are provided at the end of the fine exhaust line 54 so that air is discharged at a rate at which air pressure of 3 to 4 mmHg per second is reduced. It is formed, the end of the air pressure detection line 56 is connected to the pressure sensor 60 installed in the control means 24 to detect the pressure of the supply line.

As shown in FIG. 1, an operation unit 62 having a plurality of keys is provided on one side of the cover 12, and a tape printed by the printing means 26 is provided on the right side of the operation unit 62. The tape outflow hole 64 is formed so that a paper may come out.

FIG. 2 is a cross-sectional view showing a cut cylinder in a radial direction, and FIG. 3 is a cross-sectional view showing a cut cylinder in a longitudinal direction. As shown, the arm 20 is a spiral curve inside the hollow arm cylinder 18, the end is moved, the rack 68 is formed on the outer surface of the band 66 having a predetermined width and length And a bag portion 70 through which air is introduced through the supply line 52 is tightly coupled along the inner surface of the band 66.

The arm 20 is installed in the form of a spiral curved stone whose one end is fixed to the base bracket 72 and is rotated clockwise to increase the radius, the inner surface of the other end is fixed guide roller 74 and the rotation guide roller Sliding while guided by (76) to increase or decrease the inner space (S) of the armband. At this time, the rack formed on the outer surface of the arm 20 is bitten by the pinion 34 of FIG.

Through holes 78 are formed in the arm cylinder 18 and the cover 12 so that the pinion 34 is snapped to the rack 68.

The fixed guide roller 74 and the rotary guide roller 76 are installed in the base bracket 72 and are coupled to each shaft 77. The base bracket 72 is formed with a through hole through which the other end of the arm 20 passes.

In the arm drive device of the blood pressure measuring device configured as described above, the arm of the examinee is pushed into the inner space S of the arm, the lower arm is placed in the arm rest 16, and the upper arm stays in the arm cylinder 18. When the start key is pressed, the drive motor 28 is operated in the forward rotation, and the pinion 34 coupled to the drive motor 28 is bitten by the rack 68 of the arm 20 to wind the arm 20. Therefore, the end of the arm 20 is wound clockwise along the inner surface of the arm cylinder 18 to press the upper arm of the subject.

Next, the drive motor 28 is stopped and the plunger 40 of the solenoid valve 42 is advanced to be caught by the latch 38 so that the reverse rotation of the drive motor 28 is prevented. Subsequently, the solenoid valve 58 is operated to block the rapid exhaust line 50 and the pump 44 is operated.

By the operation of the pump 44, the outside air is sequentially passed through the supply line 46, the distributor 48 and the supply line 52 to enter the bag portion 70 of the armband 20 in the bag portion 70 Pressure rises. At this time, the pressure value is transmitted to the pressure sensor 60 by the air pressure sensing line 56, the electrical signal of the air pressure by the pressure sensor 60 is transmitted to the control means 24 and displayed on the screen of the monitor 24 do. At this time, since the pressure drop due to air flowing out through the fine exhaust line 54 is 3 to 4 mmHg per second, it does not affect the pressurization. Pressurization of the bag portion 70 continues until the pressure in the bag portion 70 reaches a predetermined pressure (185 mmHg).

When the pressure inside the bag 70 reaches a predetermined pressure, the operation of the pump 44 is stopped, and air flows out through the fine exhaust line 54, resulting in a pressure drop at a rate of 3 to 4 mmHg per second. Decompression

This pressure change in the bag is shown graphically in FIG. That is, the pressure is reduced to a maximum pressure of 185 mmHg and then gradually depressurized. The pulse P appearing during the decompression becomes a pressure fluctuation due to the pulse. This pressure fluctuation is transmitted to the control means 24 through the pressure sensor 60 and displayed in real time on the monitor 14, and finally the highest blood pressure (contractor blood pressure) and the lowest blood pressure (diastolic blood pressure) are displayed on the monitor 14. do.

When the stop key is pressed after the measurement, the solenoid valve 58 is turned off, the air is rapidly exhausted, the solenoid 42 is operated, the plunger 40 is retracted, the drive motor 28 is operated in reverse rotation, and the armature 20 is operated. Unlocked

In the driving device of the blood pressure measuring device according to the present invention, since the arm 20 is wound and unwound inside the arm cylinder 18, the driving device may be simple and the space occupied by the driving device may be small. Therefore, the size of the case may be small.

The present invention is not limited to the above embodiment and can be modified in various ways.

According to the arm drive device of the blood pressure measuring device according to the present invention, by reducing the size of the arm drive device it can significantly reduce the size of the product, simplify the structure of the arm drive device and reduce the number of parts.

Claims (2)

In the blood pressure measuring device to measure the blood pressure wrapped around the upper arm, The wand moves while drawing a spiral curve in a hollow wand cylinder, having a band of a predetermined length, a rack provided on the outer surface of the band, and a bag portion coupled to the inner surface of the band to pressurize air into the band. , The rack is held by a pinion penetrating the arm cylinder, The pinion is the arm drive of the blood pressure monitor, characterized in that directly coupled to the motor shaft of the drive motor. The method of claim 1, The arm, the one end is fixed to the base bracket and the other end of the inner surface is guided by the guide rollers and sliding, so as to increase or decrease the inner space of the arm, the arm drive device of the blood pressure monitor.