JP2007135715A - Electronic blood pressure manometer with analog display - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To analogically display the range between the maximal blood pressure and the minimal blood pressure allowing intuitive and easy recognition. <P>SOLUTION: The electronic blood pressure manometer comprises: a cuff; a means for pressurizing the cuff; a means for depressurizing the cuff; a pressure sensor for detecting the pressure of the cuff; an external input switch for generating an external input signal by the manual operation; a blood pressure determining means for determining the detection values of the pressure sensor, corresponding to the time of input of a first external input signal from an external input switch, in the process of depressurizing the cuff and the time of input of a second external input signal thereafter respectively, as the maximal blood pressure and the minimal blood pressure; an analog display 15 for displaying the pressure values detected by the pressure sensor based on the length of an indicator 15B electronically displayed along a scale 15A or the point of the display; and a display control means for displaying the range between the maximal blood pressure and the minimal blood pressure as the length H of the indicator 15B between the maximal blood pressure and the minimal blood pressure on the scale 15A. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an electronic sphygmomanometer including an analog display capable of electronic bar graph display imitating a mercury column, for example.

  Conventionally, a mercury column type sphygmomanometer has been generally used in the medical field. A mercury column type sphygmomanometer is composed of a mercury column type pressure gauge, a cuff wound around the upper arm, a pressurizing means (generally a rubber ball) for pressurizing the cuff, and a decompression means (exhaust valve) for depressurizing the cuff. When measuring the blood pressure of the measurement subject, the maximum blood pressure and the minimum blood pressure are determined by reading the mercury column while listening to the pulse of the arm with a stethoscope.

  Specifically, after pressurizing the cuff wrapped around the upper arm above the maximum blood pressure, gradually reduce the pressure, listen to Korotkoff sounds with a stethoscope during the decompression process, and listen to the systole and diastole separately At the timing, the scale at the upper end of the mercury column is read, and the systolic timing reading is detected as the maximum blood pressure, and the diastolic timing reading is detected as the minimum blood pressure.

  By the way, although a mercury column type sphygmomanometer has been used for a long time in the medical field, a sphygmomanometer that replaces the mercury column type sphygmomanometer has been desired in response to recent environmental problems.

  Recently, digital display electronic sphygmomanometers have been developed as an alternative to mercury column sphygmomanometers, but for those who have long been familiar with mercury sphygmomanometers, digital displays that are far from mercury columns are There was a situation that it was difficult to get used to.

  In response to such circumstances, an electronic sphygmomanometer has been developed that can display the cuff pressure value as an analog bar graph simulating a mercury column (see, for example, Patent Document 1).

  The electronic sphygmomanometer described in Patent Document 1 includes a cuff, a pressurizing unit, a decompressing unit, a pressure sensor, an interrupt switch for giving an interrupt signal to the systolic and diastolic timings detected by a stethoscope, a mercury column And a digital display capable of digitally displaying the maximum blood pressure and the minimum blood pressure as the pressure values detected by the pressure sensor and the measurement results.

  According to this electronic sphygmomanometer, you can listen to Korotkoff sounds with a stethoscope while looking at the bar graph on the analog display, and operate the interrupt switch at the timing judged to be systole and diastole. Blood pressure can be displayed on a digital display.

JP 2000-70231 A

  By the way, like the electronic sphygmomanometer described in Patent Document 1, there has been a problem that it cannot be said that the commercial value is very high if only digital display is performed to display electronically. In other words, the digital display is perfect for recognizing numerical values with the head, but for example, when it is desired to grasp the “maximum blood pressure and minimum blood pressure width” as an analog quantity, the read numerical values are not calculated once in the head. There was a problem that it was difficult to recognize and it was difficult to grasp intuitively.

  In consideration of the above circumstances, the present invention is an analog sphygmomanometer having a display function for displaying a pressure value in an analog form so that the "maximum blood pressure and the minimum blood pressure width" can be intuitively easily recognized. An object of the present invention is to provide an electronic blood pressure monitor that can be displayed on the screen.

  The invention of claim 1 is an electronic sphygmomanometer having an analog display capable of manually measuring blood pressure, a cuff wound around a blood pressure measurement site, a pressurizing means for pressurizing the cuff, and a decompression for depressurizing the cuff. Means, a pressure sensor that detects the pressure of the cuff and generates an electrical output, an external input switch that generates an external input signal by manual operation, and the cuff decompression process for blood pressure measurement by the external input switch, Blood pressure determination means for determining the detected value of the pressure sensor corresponding to the timing when the first external input signal is input and the timing when the second external input signal is input thereafter as the maximum blood pressure and the minimum blood pressure. An analog display for displaying the pressure value detected by the pressure sensor according to the length of the display body or the position of the display point electronically displayed along the scale, and the blood After the determination means determines the systolic blood pressure and the diastolic blood pressure, for the analog display, the range of the systolic blood pressure and the diastolic blood pressure is set as the length of the display body between the systolic blood pressure and the diastolic blood pressure on the scale, or Display control means for displaying the interval between two display points of maximum blood pressure and minimum blood pressure.

  The invention of claim 2 is an electronic sphygmomanometer having an analog display capable of automatically measuring blood pressure, a cuff wound around the blood pressure measurement site, a pressurizing means for pressurizing the cuff, and a decompression for depressurizing the cuff. Means, a pressure sensor that detects the pressure of the cuff and generates an electrical output, a blood pressure determination means that determines a maximum blood pressure and a minimum blood pressure by performing arithmetic processing based on detection data of the pressure sensor, and an electronic device along the scale An analog display for displaying the pressure value detected by the pressure sensor according to the length of the display body displayed or the position of the display point, and the analog display after the blood pressure determination means determines the maximum blood pressure and the minimum blood pressure. For the display, the range of the maximum blood pressure and the minimum blood pressure on the scale is set as the length of the display body between the maximum blood pressure and the minimum blood pressure, or the interval between the two display points of the maximum blood pressure and the minimum blood pressure. It is characterized by comprising a display control means for displaying Te.

  According to a third aspect of the present invention, there is provided an electronic sphygmomanometer comprising the analog display according to the first or second aspect, wherein the pressure value detected by the pressure sensor is digitally displayed separately from the analog display. The display control means displays the maximum blood pressure and the minimum blood pressure numerically on the digital display after the blood pressure determination means determines the maximum blood pressure and the minimum blood pressure.

  The invention of claim 4 is an electronic sphygmomanometer comprising the analog display according to any one of claims 1 to 3, wherein a light emitting means is provided at a position of the scale of the analog display, and the display The control means is characterized in that, when displaying the width of the systolic blood pressure and the systolic blood pressure on the analog display, the light emitting means at a position corresponding to the systolic blood pressure and the systolic blood pressure is caused to emit light.

  A fifth aspect of the present invention is an electronic sphygmomanometer including the analog display according to any one of the first to fourth aspects, wherein the display control means displays the width of the maximum blood pressure and the minimum blood pressure in an analog manner. When the display is performed on the display, the entire display body having a length between the maximum blood pressure and the minimum blood pressure, or only the position corresponding to the maximum blood pressure and the minimum blood pressure of the display body is displayed in a blinking manner.

  The invention of claim 6 is an electronic sphygmomanometer comprising the analog display according to any one of claims 1 to 5, wherein the display control means determines the maximum blood pressure by the blood pressure determination means. Then, the display body is displayed as a point at the position of the maximum blood pressure, and then the detected value of the pressure sensor is maintained while the point display of the maximum blood pressure is maintained until the blood pressure determination means determines the minimum blood pressure. It is characterized by being displayed with the length of the display body.

  According to the first aspect of the present invention, blood pressure can be manually measured by performing substantially the same operation as that of a conventional mercury column type sphygmomanometer. That is, the measurer listens to the Korotkoff sound with a stethoscope while observing the pressure display (for example, bar graph display or pointer display) on the analog display, and inputs externally at the timing determined as the systole based on the Korotkoff sound. Operate the switch. Then, a first external input signal is generated, and the blood pressure determination means determines the blood pressure display value (pressure value) at that timing as the maximum blood pressure. Thereafter, the external input switch is operated at the timing determined as the expansion period based on the Korotkoff sound. Then, a second external input signal is generated, and the blood pressure determination means determines the blood pressure display value (pressure value) at that timing as the minimum blood pressure.

  When the maximum blood pressure and the minimum blood pressure are determined, the display control means displays the width of the maximum blood pressure and the minimum blood pressure on the analog display, and the length of the display body between the maximum blood pressure and the minimum blood pressure on the scale. Or, it is displayed as an interval between two display points of maximum blood pressure and minimum blood pressure. In this way, since the “maximum blood pressure and minimum blood pressure range” can be displayed in an analog manner, the measurer can easily recognize the “maximum blood pressure and minimum blood pressure range” intuitively and simply digitally. Product value is higher than what is displayed.

  According to the second aspect of the present invention, blood pressure can be automatically measured, and “maximum blood pressure and minimum blood pressure width”, which is the measurement result, can be displayed in an analog manner. Accordingly, the measurer can easily and intuitively recognize the “width of the maximum blood pressure and the minimum blood pressure”, and the commercial value is increased as compared with the digital display.

  According to the invention of claim 3, since the maximum blood pressure and the minimum blood pressure are digitally displayed on the digital display provided separately from the analog display, the numerical values of the maximum blood pressure and the minimum blood pressure can be easily recognized intuitively. be able to.

  According to the invention of claim 4, since the position of the scale corresponding to the systolic blood pressure and the diastolic blood pressure is emitted, it becomes easier to recognize the “width between the systolic blood pressure and the diastolic blood pressure”.

  According to the invention of claim 5, since all of the display body having a length between the systolic blood pressure and the diastolic blood pressure or only the position corresponding to the systolic blood pressure and the diastolic blood pressure of the display body is displayed in a blinking manner. It becomes easier to recognize the “maximum blood pressure and minimum blood pressure range”.

  According to the invention of claim 6, when the blood pressure determination means determines the maximum blood pressure, the display body is point-displayed at the position of the maximum blood pressure, and thereafter, until the blood pressure determination means determines the minimum blood pressure, The detection value of the pressure sensor is displayed with the length of the display body while maintaining the point display of the maximum blood pressure, so that the maximum blood pressure value can be immediately recognized in the middle of measurement where the minimum blood pressure is still determined.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a configuration diagram of an electronic sphygmomanometer according to an embodiment, in which (a) is an external view and (b) is a block diagram. FIG. 2 is a front view of the sphygmomanometer body.

  This electronic sphygmomanometer includes a sphygmomanometer body 1, a cuff 2 wound around a blood pressure measurement site, and a tube 3 that connects the tube connection port 19 of the sphygmomanometer body 1 and the cuff 2.

  The sphygmomanometer body 1 includes a pressurizing unit (pressurizing pump) 11 that pressurizes the cuff 2, a decompressing unit (depressurizing valve) 12 that depressurizes the cuff 2, and detects the pressure of the cuff 2 to generate an electrical output. Pressure sensor 13, start switch 17 for starting blood pressure measurement, external input switch (set switch) 18 for giving an external input signal by manual operation, and length of display body 15B electronically displayed along scale 15A Thus, the analog display 15 that displays the pressure value detected by the pressure sensor 13, the digital display 16 that displays the pressure value detected by the pressure sensor 13, the power switch 20, the power lamp 22, and the manual measurement mode. A mode changeover switch 21 for switching the automatic measurement mode, a dial switch 23 for adjusting the upper limit of pressure applied to the cuff 2 by the pressurizing means 11, And a control unit 14 for controlling, is provided.

  The switches 17, 18, 20, 21, 22, 23, and the power lamp 22 are mounted on the outer surface of the main body case 10. Further, the pressurizing means 11, the decompression means 12, the pressure sensor 13, and the control device 14 are provided inside the main body case 10. In addition, the analog display 15 and the digital display 16 are installed at easy-to-see positions on the front wall of the main body case 10. The set switch 18 and the start switch 17 are provided on the lower side of the analog display 15 and the digital display 16 at positions where they can be easily operated while viewing the display.

  The analog display 15 includes a scale 15A that is swung so that the pressure value increases from the lower side toward the upper side, and a display body 15B that is disposed along the scale 15A. The scale 15A is composed of a scale line in which a pressure of 0 mmHg to 300 mmHg is cut at intervals of 2 mmHg, and a scale value assigned to the scale line every 10 mmHg. As shown in FIG. 3, the display body 15 </ b> B is configured by an alignment body of a large number of segments 15 s that are aligned in the vertical direction and are each defined by a pressure amount having a constant width. In this case, one segment 15s has a bar shape elongated in the horizontal direction perpendicular to the length direction (vertical direction) of the display body 15B, and is defined to correspond to a pressure amount of 1 mmHg or 2 mmHg. The segment 15s is composed of an LCD, an LED, or the like. Further, a backlight for making the display easy to see is incorporated behind the analog display 15.

  In the example of FIG. 3, one segment 15s is set to correspond to “2 mmHg”. That is, the pressure display resolution is “2 mmHg”. When the pressure display resolution is increased, the number of segments 15s must be increased accordingly. If the pressure display resolution is “1 mmHg”, the number of segments 15 s is twice as many as the pressure display resolution of “2 mmHg”, which may increase the cost accordingly. However, when the pressure display value is actually read with the eyes, it is difficult to read between the scale lines. Therefore, if there is a pressure display resolution of “2 mmHg”, there is no problem in reading the pressure value. However, when the pressure fluctuation due to the pulse is to be displayed as accurately as possible, the amplitude of the pulse wave in the vicinity of the maximum blood pressure and the minimum blood pressure is about 0.5 to 2.0 mmHg.

  By the way, the sampling interval of pressure detection by the pressure sensor 13 is on the order of 10 ms (milliseconds) (for example, 30 ms), and the resolution of pressure detection is “0.05 mmHg” level. That is, the resolution is 2 mmHg intervals on the display, but the pressure is detected quite fine internally.

  The analog display 15 is configured such that the segment 15s of the display body 15B is continuously turned on (lighted) from the lower side (position of 0 mmHg), that is, the first segment, the second segment, ... By turning on all of the detected pressure values such as the nth segment, the pressure values can be displayed in a bar graph as shown in FIG. Accordingly, the measurer can intuitively grasp the pressure value by actually reading the length (upper end position) of the display body 15A on the scale 15A rather than the number of the lit segments 15s. it can.

  On the other hand, the digital display 16 is of a segment type that numerically displays a pressure value and a pulse, and has mainly three display portions 16A, 16B, and 16C as shown in FIG. The upper display unit 16A displays a real-time pressure detection value and displays a maximum blood pressure (SYS = systolic blood pressure value) when displaying the measurement result, and the lower display unit 16B displays the measurement result. A portion that sometimes displays the minimum blood pressure (DIA = diastolic blood pressure value), and the lower display portion 16C is a portion that displays the pulse. The upper two display portions 16A and 16B are each constituted by a three-digit 7-segment electrode, and the unit is mmHg. The lower pulse display unit 16C is configured such that the first digit of the three digits is composed of a two-segment electrode, and the last two digits are composed of a seven-segment electrode. The unit is Pul / min. It has become. In addition, the digital display unit 16 is provided with a display unit 16D for displaying the measurement number (number of times).

  Each of these display units 16A to 16D can display numbers from 0 to 9 by selectively causing each segment to emit light. However, only one digit can be displayed in the hundreds digit of the pulse display 16C. Therefore, the measurement result can be directly read by those numerical values.

  The control device 14 has a function for controlling the pressurizing means 11 and the decompression means 12 according to a predetermined program, a function for controlling the display of the analog display 15 and the digital display 16 (corresponding to display control means), and mode switching. A function for switching between the manual measurement mode and the automatic measurement mode by operating the switch 21 and an arithmetic process based on the detection data of the pressure sensor 13 in the pressure reduction process of the cuff 2 for blood pressure measurement when the automatic measurement mode is selected. When the manual measurement mode is selected and the function for determining the systolic blood pressure and the systolic blood pressure and the manual measurement mode are selected, the external input switch 18 The timing at which the first external input signal is input and the timing at which the second external input signal is input thereafter are respectively paired. The function of determining the detected value of the pressure sensor 13 as the systolic blood pressure and the systolic blood pressure (corresponding to the blood pressure judging means), and after determining the systolic blood pressure and the systolic blood pressure, the analog display 15 is shown in FIG. In addition, a function (display control means) for displaying the range of the maximum blood pressure and the minimum blood pressure as the length H of the display body 15B between the maximum blood pressure and the minimum blood pressure on the scale 15A, and the maximum blood pressure and the minimum blood pressure are determined. Later, the digital display 16 is provided with a function of numerically displaying the maximum blood pressure and the minimum blood pressure.

Next, the operation will be described.
First, a case where the mode changeover switch 21 is switched to the “M (Manual)” side and blood pressure measurement is performed manually will be described. As a process common to both the manual and automatic modes, first, the cuff 2 is wound around the upper arm of the person to be measured, and the dial switch 23 for adjusting the pressurization upper limit value is set to an appropriate value higher than the subject's maximum blood pressure value. Then, the start switch 17 is pressed. Then, the operation proceeds according to a predetermined program. First, the pressurizing means 11 sends pressurized air to the cuff 2 and the cuff 2 gradually presses the upper arm. When the pressure is increased to the value set by the dial switch 23 for adjusting the pressure upper limit value, the pressurization is automatically stopped, and the decompression means 12 gradually starts the decompression of the cuff 2.

  In the manual mode, in this decompression process, the measurer listens to the Korotkoff sound by applying a stethoscope to the measurement subject's arm while observing the pressure display (bar graph display) of the analog display 15.

  Then, while reading the pressure display value of the analog indicator 15 at the timing when the heart systole is heard based on the Korotkoff sound (that is, the timing when the compression is weakened and the Korotkoff sound starts to be heard) This is a standard operation when using a sphygmomanometer, and is not necessarily a necessary action in the case of this embodiment), and an external input switch (set switch) 18 is pressed. Then, a first external input signal is generated, and the control device 14 determines and stores the blood pressure display value (pressure value) at that timing as “maximum blood pressure”.

  After that, while reading the pressure display value of the analog display 15 at the timing when it is determined as the diastole of the heart based on the Korotkoff sound (that is, when the Korotkoff sound is not heard again because the pressure is further weakened) This is a standard operation when using a mercury column type sphygmomanometer, and is not necessarily required in the case of this embodiment), and the external input switch (set switch) 18 is pressed. Then, a second external input signal is generated, and the control device 14 determines and stores the blood pressure display value (pressure value) at that timing as “minimum blood pressure”.

  Then, at the stage when the systolic blood pressure and the diastolic blood pressure are determined, the control device 14 gives the analog display 15 the range between the systolic blood pressure and the diastolic blood pressure on the scale 15A as shown in FIG. It is displayed as the length H of the display body 15B between the blood pressure. At the same time, the digital display 16 displays the maximum blood pressure and the minimum blood pressure numerically.

  On the other hand, in the automatic measurement mode in which the mode changeover switch 21 is switched to the “A (AUTO)” side, the detection data of the pressure sensor 13 is automatically generated by the control device 14 when the pressure reduction process is performed. Based on this, the systolic blood pressure and the diastolic blood pressure are calculated. The principle of blood pressure determination includes those based on pulse pressure and those based on Korotkoff sounds, both of which are well-known techniques, and are not specifically described here. Then, as in the manual mode, when the control device 14 determines the systolic blood pressure and the systolic blood pressure, as shown in FIG. It is displayed as the length H of the display body 15B between the maximum blood pressure and the minimum blood pressure on the scale 15A. At the same time, the digital display 16 displays the maximum blood pressure and the minimum blood pressure numerically.

  As described above, in any measurement mode, the range of the maximum blood pressure and the minimum blood pressure is displayed in an analog manner, so that the measurer can easily and intuitively recognize the width of the maximum blood pressure and the minimum blood pressure. Moreover, since the systolic blood pressure and the diastolic blood pressure are simultaneously displayed as numerical values on the digital display 16, the systolic blood pressure and the diastolic blood pressure can be easily recognized as numerical values. Therefore, the commercial value is increased as compared with a simple digital display.

  5 to 8 show other examples of how results are displayed.

  In the example illustrated in FIG. 5, the analog display 15 displays the maximum blood pressure and the minimum blood pressure as the interval H between two display points (the pointer-shaped display) of the maximum blood pressure and the minimum blood pressure on the scale 15A. I am doing so. In this case, the same effect as that of the above embodiment can be obtained.

  In the example shown in FIG. 6, the light emission means 15 h is provided at the position of the scale 15 </ b> A of the analog display 15, and the maximum blood pressure and the minimum blood pressure are supported when displaying the width of the maximum blood pressure and the minimum blood pressure on the analog display 15. The light emitting means 15h at the position to emit light is made to emit light. In this case, it becomes easier to recognize the maximum blood pressure and the minimum blood pressure than in the embodiment. 6 shows a case where the example of FIG. 4 is adopted to display the maximum blood pressure and the minimum blood pressure width in an analog manner, the display method of FIG. 5 may be adopted.

  In the example shown in FIG. 7, when displaying the range of the maximum blood pressure and the minimum blood pressure on the analog display 15, the display body 15 </ b> B having a length between the maximum blood pressure and the minimum blood pressure corresponds to the maximum blood pressure and the minimum blood pressure. Only the position to be flashed is displayed. In the example of FIG. 8, the entire display body 15B having a length between the maximum blood pressure and the minimum blood pressure is displayed in a blinking manner. In this case, it becomes easier to recognize the range between the systolic blood pressure and the systolic blood pressure than in the embodiment.

  FIG. 9 shows an example in which the past measurement results (maximum blood pressure and minimum blood pressure width) are set to be displayed in turn each time one of the switches is pressed, for example. In this way, by displaying the current systolic and diastolic blood pressure ranges in order from the past, it is possible to easily recognize temporal changes in the systolic and diastolic blood pressure ranges.

  In the example shown in FIG. 10, when the systolic blood pressure (120 mmHg in the illustrated example) is determined, the display body 15B is point-displayed at the position of the systolic blood pressure, and then the control device 14 determines the diastolic blood pressure. Until then, the detected value of the pressure sensor 13 is displayed in the length of the display body 15B while maintaining the point display of the maximum blood pressure. That is, the non-display portion 15m is formed above the upper end of the display body 15B displaying the pressure in real time. Then, when the minimum blood pressure is determined, it is displayed in the same manner as in FIG. In this way, the maximum blood pressure value can be recognized even in the middle of the measurement in which the minimum blood pressure is determined by displaying the maximum blood pressure value as a point immediately when the maximum blood pressure is determined.

  In the above embodiment, the case where the bar graph is displayed when the detection value of the pressure sensor 13 is displayed on the analog display 15 in real time has been described. However, the display body 15B of the position of the detection pressure value is displayed as a point. You may make it display (guideline display).

(A) is a schematic block diagram of the electronic blood pressure monitor of embodiment of this invention, (b) is a block diagram which shows a structure. It is a front view of the sphygmomanometer body 1 of the electronic sphygmomanometer of the embodiment. It is a block diagram of the analog display 15 in the electronic sphygmomanometer of the embodiment. It is a figure which shows the example of a display of the width | variety of the maximum blood pressure and the minimum blood pressure in the electronic blood pressure monitor of embodiment. It is a figure which shows another example of a display of the width | variety of a maximum blood pressure and a minimum blood pressure. It is a figure which shows another example of a display of the width | variety of the maximum blood pressure and the minimum blood pressure. It is a figure which shows another example of a display of the width | variety of the maximum blood pressure and the minimum blood pressure. It is a figure which shows another example of a display of the width | variety of the maximum blood pressure and the minimum blood pressure. It is a figure which shows displaying the measurement result of several times in order. It is a figure which shows the example of a display in the case of displaying only the maximum blood pressure value instantly at the stage which determined the maximum blood pressure.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Sphygmomanometer body 2 Cuff 11 Pressurizing means 12 Depressurizing means 13 Pressure sensor 14 Control device (control means)
15 Analog display 15A Scale 15B Display 16 Digital display 18 External input switch (set switch)

Claims (6)

A cuff wrapped around the blood pressure measurement site;
A pressurizing means for pressurizing the cuff;
Decompression means for decompressing the cuff;
A pressure sensor that detects the pressure of the cuff and generates an electrical output;
An external input switch that generates an external input signal by manual operation;
In the decompression process of the cuff for blood pressure measurement, the timing corresponding to the timing at which the first external input signal is input by the external input switch and the timing at which the subsequent second external input signal is input, respectively. Blood pressure determination means for determining the detected value of the pressure sensor as the maximum blood pressure and the minimum blood pressure;
An analog display that displays the pressure value detected by the pressure sensor according to the length of the display body electronically displayed along the scale or the position of the display point;
After the blood pressure determining means determines the systolic blood pressure and the diastolic blood pressure, the analog indicator is displayed with a range of the systolic blood pressure and the diastolic blood pressure, and the length of the display body between the systolic blood pressure and the diastolic blood pressure on the scale. Or a display control means for displaying as an interval between two display points of systolic blood pressure and diastolic blood pressure,
An electronic sphygmomanometer equipped with an analog display. A cuff wrapped around the blood pressure measurement site;
A pressurizing means for pressurizing the cuff;
Decompression means for decompressing the cuff;
A pressure sensor that detects the pressure of the cuff and generates an electrical output;
Blood pressure determination means for determining the systolic blood pressure and the diastolic blood pressure by performing arithmetic processing based on the detection data of the pressure sensor;
An analog display that displays the pressure value detected by the pressure sensor according to the length of the display body electronically displayed along the scale or the position of the display point;
After the blood pressure determining means determines the systolic blood pressure and the diastolic blood pressure, the analog indicator is displayed with a range of the systolic blood pressure and the diastolic blood pressure, and the length of the display body between the systolic blood pressure and the diastolic blood pressure on the scale. Or a display control means for displaying as an interval between two display points of systolic blood pressure and diastolic blood pressure,
An electronic sphygmomanometer equipped with an analog display. An electronic sphygmomanometer comprising the analog indicator according to claim 1 or 2,
In addition to the analog indicator, a digital indicator for displaying the pressure value detected by the pressure sensor numerically,
An electronic apparatus comprising an analog display, wherein the display control means displays the maximum blood pressure and the minimum blood pressure numerically on the digital display after the blood pressure determination means determines the maximum blood pressure and the minimum blood pressure. Sphygmomanometer. An electronic sphygmomanometer comprising the analog display according to any one of claims 1 to 3,
A light emitting means is provided at the position of the scale of the analog display, and when the display control means displays the maximum blood pressure and the minimum blood pressure on the analog display, the position corresponding to the maximum blood pressure and the minimum blood pressure is displayed. An electronic sphygmomanometer having an analog display characterized in that the light emitting means emits light. An electronic sphygmomanometer comprising the analog indicator according to claim 1,
When the display control means displays the range of the systolic blood pressure and the systolic blood pressure on the analog display, the entire display body having a length between the systolic blood pressure and the systolic blood pressure, or the maximum of the display body. An electronic sphygmomanometer equipped with an analog display, wherein only the position corresponding to high blood pressure and minimum blood pressure blinks. An electronic sphygmomanometer comprising the analog indicator according to claim 1,
The display control means, when the blood pressure determination means determines the maximum blood pressure, causes the display body to display a point at the position of the maximum blood pressure, and thereafter until the blood pressure determination means determines the minimum blood pressure, An electronic sphygmomanometer comprising an analog display, wherein the detected value of the pressure sensor is displayed with the length of the display body while maintaining the maximum blood pressure point display.

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