JP3980589B2 - Non-mercury analog sphygmomanometer - Google Patents

Description

  The present invention relates to a non-mercury analog sphygmomanometer, and in particular, it is possible to display a maximum blood pressure value and a minimum blood pressure value without using a mercury column for blood pressure display while performing a manual blood pressure measurement operation similar to a mercury sphygmomanometer. It relates to an ecological sphygmomanometer that is environmentally friendly.

  Conventionally, blood pressure measurement has been widely adopted for grasping the physical health of the body and for preventing, diagnosing, treating, etc. diseases. Various types of sphygmomanometers have been proposed and put into practical use, such as a manual type, a manual type and an automatic type (see Non-Patent Document 1 and Non-Patent Document 2).

  Among these sphygmomanometers, mercury sphygmomanometers have been used for a long time, and in particular, when a doctor examines a patient at a medical site, the mercury sphygmomanometer is still an essential instrument, With such a mercury sphygmomanometer, a patient's blood pressure is measured using a stethoscope. Specifically, the pressure of the cuff (arm band) wrapped around the patient's upper arm is displayed on the mercury column of the mercury sphygmomanometer, while the Korotkoff sound that accompanies the pressure of the cuff being gradually reduced. When the doctor listens to the appearance and disappearance of the sound with a stethoscope, the height of the mercury column when the Korotkoff sound appears is read as the maximum blood pressure, and the height of the mercury column when the Korotkoff sound disappears is read from the scale. The blood pressure is measured by recognizing it as the minimum blood pressure value.

  By the way, since the mercury sphygmomanometer used in such a medical field shows the pressure in the cuff as the height of the mercury column, the use of mercury is an indispensable condition. Because it is a toxic metal, it is desirable to avoid its use, especially in the medical field. However, in the unlikely event that mercury leaks due to damage such as damage to the mercury sphygmomanometer, it may be scattered in the air as mercury vapor and contaminate the medical site. When such a mercury sphygmomanometer is disposed of, there is a risk of causing difficult problems and causing social problems such as polluting the environment.

  For this reason, Patent Document 1 discloses a sphygmomanometer that does not use a mercury column for measuring pressure, in which the cuff pressure is displayed in a row of LEDs, while the systolic pressure and the diastolic pressure are displayed. The doctor listens to the Korotkoff sound that indicates the pressure and turns on the switch to output an infrared signal or a high-frequency signal for display on the LED display. In addition to being complicated and expensive and cumbersome to operate, the LED display is difficult to display pressure in such a manner that it can be easily read like a mercury column.

  In Patent Document 2, as a hybrid sphygmomanometer having the advantages of a mercury sphygmomanometer and an electronic device, a cuff provided with an inflatable air bag, and a pump device (rubber ball) for inflating the air bag, An air discharge valve for extracting air from the air bag, an air pressure converter having a function of receiving the pressure in the air bag and generating an electric signal indicating the pressure, and an interrupt signal for contraction and expansion A manually operated switch for generating, a first electronic display for displaying a momentary pressure measurement in the bladder as a bar graph, and a first electronic display for displaying systolic and diastolic pressures A sphygmomanometer comprising two electronic displays and an electrical circuit for controlling the pressure transducer and the first and second displays connected to the switch is disclosed, In this case, it is necessary to perform the instantaneous operation of the contraction / expansion switch in parallel with listening to the Korotkoff sound by the stethoscope and lowering (lowering) the pressure in the cuff, which causes an operation delay. However, problems such as a decrease in measurement accuracy and a need for skill in blood pressure measurement operations are inherent.

US Pat. No. 5,464,017 JP 2000-70231 A Hironori Kubota "Introduction to Vital Sign Monitor"-From electrocardiograph to pulse oximeter (published by Shujunsha, July 1, 2000), pp. 33-43 Yuji Kimura “Introduction to Medical Engineering” (September 10, 2003, issued by Corona Co., Ltd.), pp. 36-41

  Here, the present invention has been made in the background of such circumstances, and the solution to the problem is a sphygmomanometer that does not use a mercury column for measuring pressure at all. Another object of the present invention is to provide a non-mercury analog sphygmomanometer that is as simple and easy as a conventional mercury sphygmomanometer and that is extremely easy to read the maximum and minimum blood pressure values.

  In order to solve the above problems, the present invention provides (a) pressure display means for displaying pressure in a bar graph along the blood pressure display scale, and the pressure display means is provided at each scale position. An analog blood pressure display device configured to emit light in a dotted or linear manner, and (b) a cuff wound around the arm of a patient whose blood pressure is to be measured and tightening the arm, c) Supplying air to the cuff to increase the pressure in the cuff, and pressurizing rubber balls for tightening the arm, and (d) detecting the fluctuating pressure in the cuff, And (e) detecting the reversal of the change in the cuff pressure caused by the pressure rubber balls being compressed in response to the appearance and disappearance of the Korotkoff sound, respectively, Maximum blood pressure signal and maximum A pressure inversion detection means for outputting as a blood pressure signal, and (f) a bar graph having a length corresponding to the pressure in the cuff in the pressure display means of the analog blood pressure display device according to the pressure signal in the cuff from the pressure detector. While pressure is displayed by emitting light, the pressure reversal detection is performed when the pressure display means is extinguished so that the length of the emitted bar graph is shortened as the pressure in the cuff decreases during blood pressure measurement. And a control device that controls the pressure display means so that only point-like or linear light emission at the scale position corresponding to the signals is present by inputting the systolic blood pressure signal and the diastolic blood pressure signal from the means. The gist of the present invention is a non-mercury analog sphygmomanometer.

  In the non-mercury analog sphygmomanometer according to the present invention, advantageously, the pressure reversal detection means is realized in an embodiment in which the pressure reversal detection means is integrally incorporated in the control device. .

  Further, according to one of the desirable embodiments of the non-mercury analog blood pressure monitor according to the present invention, the generator includes a generator that can be driven by a pressing operation of the rubber ball for pressurization, and the electric power generated by driving the generator is This is advantageously used for the operation of at least one of the control device, the analog blood pressure display device, the pressure detector, and the pressure reversal detection means.

  According to another desirable aspect of the non-mercury analog blood pressure monitor according to the present invention, a digital display device that digitally displays the pulse rate together with the measured maximum blood pressure value and the minimum blood pressure value is further provided, It is controlled by a control device.

  In addition, according to still another desirable aspect of the non-mercury analog sphygmomanometer according to the present invention, a large number of independent light emitters are in a bar graph shape so that the pressure display means corresponds to each scale position of the blood pressure display scale. Are arranged and configured.

  Therefore, in the non-mercury analog sphygmomanometer according to the present invention as described above, a bar graph shape that emits light in a dotted or linear manner at each scale position of the blood pressure display scale without using a mercury column for blood pressure display. Since an analog blood pressure display device having a pressure display means is used, it is no longer necessary to consider the problem of mercury contamination as in conventional mercury sphygmomanometers. In addition, in such an analog blood pressure display device, the maximum blood pressure value and the minimum blood pressure value are respectively dotted or lined at the corresponding scale positions. In the state where the light is emitted in a shape, the pressure is displayed by the pressure display means. As in the conventional mercury sphygmomanometer, the upper end of the mercury column is There is no need for skilled techniques that must be instantaneously read and memorized at the time of disappearance and at the time of disappearance. Even after the blood pressure measurement operation is completed by completely reducing the pressure in the cuff, the pressure display means The maximum blood pressure value and the minimum blood pressure value can be read from the punctiform or linear light emission positions in the blood pressure measurement, so even blood pressure measurement operations can be performed easily and accurately even for medical personnel unfamiliar with blood pressure measurement operations. It can be done.

  Moreover, in the non-mercury analog sphygmomanometer according to the present invention, the rubber balls for pressurization for supplying air to the cuff correspond to the time of appearance and disappearance of the Korotkoff sound observed (listened) by the stethoscope, respectively. Based on the fact that the pressure causes a change from a decrease in the cuff pressure to an increase, the reversal of such a pressure change is detected, and the systolic blood pressure signal and the diastolic blood pressure signal are respectively extracted. Therefore, a medical worker who measures blood pressure gradually grasps the rubber ball from the operation process of repeatedly pressing the rubber ball for pressurization in order to increase the pressure in the cuff for blood pressure measurement. The cuff pressure is lowered, and when the Korotkoff sound appears and disappears, the rubber ball is strongly pressed to output a systolic blood pressure signal and a diastolic blood pressure signal, respectively. A than Rukoto can, any way, since it is not necessary to a special switch operation, the blood pressure measuring operation also, it's becomes more easy.

  In the present invention, the pressure reversal detection means advantageously outputs the systolic blood pressure signal and the diastolic blood pressure signal by using the in-cuff pressure signal output from the pressure detector and reversing the pressure change therein. Therefore, the detection / determination can be easily realized by an electronic circuit. Therefore, according to a desirable aspect of the present invention, such a pressure reversal detection means is integrated with the control device. By adopting a configuration that is built in, it is possible to greatly contribute to simplification and compactness of the device configuration as a sphygmomanometer.

  Further, according to a desirable mode of the present invention, if the generator is driven by the pressing operation of the rubber ball for pressurization, and the electric power obtained thereby is used as the power source of the constituent devices of the sphygmomanometer according to the present invention, This makes it possible to bring the blood pressure monitor according to the invention closer to the ultimate ecological device.

  In the present invention, in addition to the analog blood pressure display device described above, a digital display device that digitally displays the maximum blood pressure value, the minimum blood pressure value, and further the pulse rate can be provided. In addition to the fact that the accuracy can be further improved, there is an advantage that it can be advantageously used as information for medical personnel.

  Further, according to another desirable aspect of the present invention, if the pressure display means in the analog blood pressure display device is constituted by a bar graph-like arrangement of a large number of independent light emitters, it corresponds to each scale position of the blood pressure display scale. Thus, only the illuminating body that emits light can be emitted, so that the maximum blood pressure value and the minimum blood pressure value can be more effectively read.

  Hereinafter, in order to clarify the configuration of the present invention more specifically, representative embodiments of the present invention will be described in detail with reference to the drawings.

  First, FIG. 1 shows an example of a non-mercury type analog blood pressure monitor according to the present invention, that is, not using mercury. Therefore, the sphygmomanometer according to the present invention includes an analog blood pressure display device 2, a cuff 4, a pressurizing rubber ball 6, a pressure detector 8, a pressure reversal detection device 10, a control device 12, and a digital display. Including the device 14.

  Specifically, the analog blood pressure display device 2 is for reading a maximum blood pressure value and a minimum blood pressure value by a medical worker such as a doctor who measures blood pressure instead of the mercury column in a conventional mercury blood pressure monitor. A blood pressure display scale 20 with a scale within a range to be measured, for example, a scale within a range of 0 to 300 mmHg, and a pressure for displaying pressure in a bar graph form along the blood pressure display scale 20 And a display device 22. The pressure display device 22 is composed of an LED (light emitting diode), an LCD (liquid crystal), or the like so that it can emit light (light) in a dotted or linear manner at each scale position on the blood pressure display scale 20. A large number of the luminous bodies 30 arranged in correspondence with each scale position are formed in a bar graph shape, and pressure can be displayed by the height (length) emitted in the bar graph shape. On the other hand, only the light emitters located at predetermined scale positions of the light emitters arranged in a bar graph shape can emit light.

  The cuff 4 has the same structure as that of the prior art, and an air bag (not shown) is disposed inside a belt-like body having a predetermined width so that the upper arm of a blood pressure measurement subject (patient) is provided. It can be wound and fixed, and the inner air bag is inflated by the supplied air, tightening such an arm and compressing the blood vessel, so that the appearance of Korotkoff sounds and Disappearance can be realized.

  The rubber ball 6 for pressurization is connected to the air bag of the cuff 4 via the air tube 24, and is guided from the atmosphere by the pumping action by the compression (compression) of the rubber ball 6. Air is supplied to the air bag of the cuff 4 by the air tube 24 through the valve 26, so that the pressure in the cuff 4 can be increased and the patient's arm can be tightened and compressed. It is. The valve 26 provided on the air tube 24 is the same as the air discharge valve attached to the rubber ball in the conventional blood pressure measuring device, and these conventional ones can be used as they are. Yes, for example, by supplying the air in the rubber ball 6 to the cuff 4 through the air tube 24 by such a valve 26, by manually operating the knob 28, the button or the like of the valve 26, The air in the cuff 4 can be discharged from the valve 26 to the outside through the air tube 24.

  The pressure detector 8 is a pressure transducer that detects a fluctuating pressure in the cuff 4, specifically, a pressure in an air bag disposed inside, and outputs it as a cuff pressure signal. The cuff pressure signal is output as an electrical signal that is electrically detected by an integrated sensor. Here, the pressure detector 8 is shown in the form of being taken out to the outside, but it can generally be arranged inside the cuff 4.

  Further, the in-cuff pressure signal output from the pressure detector 8 is input to the pressure reversal detection device 10 and the control device 12, respectively. In the pressure reversal detection device 10, the reversal point of the change in the cuff pressure existing in the input cuff pressure signal, in other words, the cuff pressure that is gradually lowered (decreased) rapidly increases. The point of rolling can be detected and output as a systolic blood pressure signal or a diastolic blood pressure signal. In addition, such reversal of the change in the cuff pressure occurs when the Korotkoff sound heard by the stethoscope appears and disappears with the decrease (decrease) in the cuff pressure during blood pressure measurement, respectively. When the medical staff who measures the blood pressure presses the rubber ball 6 for pressurization, the decrease in the cuff pressure is suddenly turned to the increase, and this causes the Korotkoff sound to appear. The inversion point of the cuff pressure is output as a systolic blood pressure signal, while the inversion point of the change in the cuff pressure when the Korotkoff sound disappears is output as the diastolic blood pressure signal.

  In the control device 12, in accordance with the cuff pressure signal from the pressure detector 8, the pressure display device 22 of the analog blood pressure display device 2 emits light as a bar graph having a length corresponding to the cuff pressure. The pressure is displayed at the height (length) of the emitted light. In addition, the control device 12 can receive a systolic blood pressure signal and a diastolic blood pressure signal from the pressure reversal detection device 10, and by inputting these signals, the bar graph of light emitted from the pressure display device 22 is displayed. The analog blood pressure display device 2 (specifically, in order to keep only point-like or line-like light emission at the scale position corresponding to these signals when extinguishing the light so that the length is shortened) The pressure display device 22) is controlled by the control device 12.

  A digital display device 14 is also connected to the control device 12, and the systolic blood pressure obtained based on the systolic blood pressure signal and the diastolic blood pressure signal input from the pressure reversal detection device 10 in the control device 12. A value (SYS) and a diastolic blood pressure value (DIA) are respectively displayed, and a pulse rate (Pulse) detected by a detector (not shown) provided in the cuff 4 is determined by the control device 12. Under the control, digital display is performed on the digital display device 14.

  Therefore, when a medical staff such as a doctor measures the blood pressure of a patient using the sphygmomanometer shown in FIG. 1, first, the cuff 4 is wound around the upper arm of the patient's hand in the same manner as before. Then, by repeatedly compressing (compressing) the rubber balls 6 for pressurization, air is supplied into the air bag of the cuff 4 and pressurization is performed until the pressure in the cuff becomes sufficiently high for blood pressure measurement, The arm is tightened. At that time, the pressure in the cuff is detected by the pressure detector 8 and input to the control device 12 as a cuff pressure signal, and the light emitting body of the pressure display device 22 in the analog blood pressure display device 2 by the control device 12. 30 is emitted to the position of the blood pressure display scale 20 corresponding to the pressure in the cuff, and the pressure is displayed as a bar graph of a predetermined height (length).

  Then, in such a state that the pressure in the cuff is increased, by operating the knob 28 of the valve 26 and the like, the air supplied to the cuff is discharged to the outside, so that the pressure in the cuff is as shown in FIG. While the patient's arm is gradually lowered (decreased), a stethoscope is applied to the patient's arm as before, and whether or not the Korotkoff sound is heard is continuously observed over time. . When the appearance of the Korotkoff sound is grasped by a stethoscope, a medical worker such as a doctor immediately presses (shrinks) the rubber ball 6 grasped in the hand, thereby reducing the inside of the cuff that has been lowered. The pressure starts to rise, and this is detected by the pressure reversal detection device 10 based on the cuff internal pressure signal output from the pressure detector 8 as the reversal point of the change in the cuff internal pressure. The pressure reversal detection device 10 outputs the maximum blood pressure signal to the control device 12. The inversion point of the change in the cuff pressure that outputs such a systolic blood pressure signal is the position indicated by A in FIG.

  Next, when the systolic blood pressure signal is input from the pressure reversal detection device 10 to the control device 12, the analog blood pressure display device 2 controlled by the control device 12 is operated as shown in FIG. ), The light emitters 30 arranged in a bar graph so as to constitute the pressure display device 22 are sequentially extinguished (turned off), and the length of the emitted bar graph (cross-hatched portion in the figure) is The light emitter 30a at the highest position of the emitted bar graph, which is located when the systolic blood pressure signal is input as it is shortened, is held in the emitted state, as shown in FIG. 3 (b), and Each of the light emitters 30 below the light emitters 30a in which such light emission is retained is reversed after the reversal of the change in the cuff internal pressure due to the compression of the rubber balls 6. Falling in the cuff pressure is gradually, with the carried out sequentially, it is going to be made to quenching.

  Further, when the Korotkoff sound heard by the stethoscope disappears due to the pressure in the cuff 4 being lowered, the rubber ball 6 is compressed again, and the decrease in the pressure in the cuff is changed. The point of reversal is instantaneously reversed, and the reversal point is shown as B in FIG. As is well known, the pressure in the cuff at the time of disappearance of this Korotkoff sound is recognized as the minimum blood pressure value.

  Further, the reversal point B of the change in the cuff pressure corresponding to the diastolic blood pressure value as shown in FIG. 2 is based on the pressure signal in the cuff output from the pressure detector 8, and the pressure reversal detection device 10. When the diastolic blood pressure signal corresponding to the diastolic blood pressure signal is output, the control device 12 causes the pressure display device 22 of the analog blood pressure display device 2 to perform the same as when the systolic blood pressure signal is input. The light emission of the light emitter 30b at the scale position corresponding to the diastolic blood pressure signal is held as shown in FIG. Further, the light emitter 30 below the light emitter 30b in which such light emission is held is sequentially extinguished as the pressure in the cuff decreases, and is in a state shown in FIG. The extinguishing operation in the pressure display device 22 accompanying the decrease in the cuff pressure is terminated.

  As described above, when the light emission / quenching operation of the pressure display device 22 in the analog blood pressure display device 2 at the time of blood pressure measurement is completed, the blood pressure display scale 20 corresponding to the maximum blood pressure value and the minimum blood pressure value is respectively displayed in the pressure display device 22. In this position, in the state where only the light emitter 30a and the light emitter 30b are made to emit light, the respective blood pressure values are displayed in an analog manner, and therefore are in such a state. By reading the blood pressure display scale 20 corresponding thereto from the light emitters 30a and 30b, the patient's maximum blood pressure value and minimum blood pressure value can be easily and accurately read. Various problems inherent in recognizing systolic blood pressure and diastolic blood pressure by instantaneously reading It is becoming an be eliminated altogether.

  In addition, in order to detect the systolic blood pressure value and the diastolic blood pressure value from the process of increasing the cuff internal pressure, medical personnel such as doctors are required to pressurize during the process of gradually decreasing such cuff internal pressure. The rubber ball 6 can always be grasped, and the hand grasping the rubber ball 6 is released in order to operate other switch means for detection of the maximum blood pressure value and the minimum blood pressure value, or Since there is no need to perform a switching operation by shifting the hand, it is only necessary to compress (shrink) the rubber ball 6 in a state where the rubber ball 6 is grasped. The detection operation of the minimum blood pressure value can be performed easily and easily.

  By the way, in such a non-mercury analog sphygmomanometer according to the present invention, an appropriate power source is required for the operation of the equipment constituting the non-mercury analog sphygmomanometer. A more ecological sphygmomanometer can be obtained by using the electric power generated by the generator that can be driven by the pressing operation of the rubber ball 6 for pressurization as shown in FIG.

  Specifically, in FIG. 4A, the generator 32 that is driven to rotate by the circulation of air is disposed on the air tube 24 that is the air supply path from the rubber ball 6 to the cuff 4. In FIG. 4B, the air sent out by the compression of the rubber ball 6 is guided by the valve 26 so that the generator 32 is driven to rotate. In FIG. 4C, the operation lever 34 is grasped by the hand of the medical staff who measures the blood pressure together with the rubber ball 6, and the operation lever 34 is simultaneously operated with the rubber ball compression operation. By rotating as shown by an arrow, the drive shaft 38 of the generator 36 is rotated, so that the desired power generation can be performed. It should be noted that the generators 32 and 36 used here have a known and simple structure, and are used as they are, so that necessary power is generated. In addition, the electric power generated by the generators 32 and 36 can be stored in a necessary power storage device (not shown), and the generator 32 is previously measured prior to blood pressure measurement. , 36, and it is also possible to store it in a power storage device and use it for the operation of the electrical device of the sphygmomanometer according to the present invention.

  It should be understood that the present invention is not construed as being limited to the representative embodiments described so far, and the exemplary embodiments are merely illustrative. It is only a thing.

  For example, in the illustrated specific example, a structure in which the light emitters 30 are independently arranged for every 1 mmHg in the blood pressure display scale 20 is adopted. However, although inaccuracy increases in reading blood pressure, 2 mmHg Or it is also possible to arrange | position a light-emitting body (30) so that the pressure value of the range beyond it may be shown. Further, the light emitter 30 is not limited to an LED or an LCD, and any light emitter can be used as long as it can emit (light) in a bar graph shape. For example, a CRT (CRT) or a flat display It is also possible to use a bar graph with a display screen such as Even in the pressure display means, in addition to the pressure display device 22 having the configuration as illustrated, in addition to the first light emitting element that emits light in the form of a bar graph, the second light emitting element that emits light in the form of dots or lines is provided. It is also possible to extinguish the first element and to cause the second light emitting element to emit light in the form of dots or lines at the scale position corresponding to the systolic blood pressure signal and the systolic blood pressure signal. It is.

  Even in the pressure reversal detection means, in the illustrated specific example, the pressure reversal detection device 10 is configured separately from the control device 12, but the reversal of the change in the cuff pressure is detected. Since it can be realized by processing by an electric circuit based on the pressure signal in the cuff output from the pressure detector 8, a configuration in which it is integrated into a control device can be advantageously employed. It is. However, the detection of the reversal of the change in the pressure inside the cuff is most desirably performed by using the pressure signal in the cuff of the pressure detector 8, but is detected using another independent sensor, It is also possible to output a systolic blood pressure signal or a diastolic blood pressure signal.

  Further, the cuff 4, the rubber ball 6, the valve 26, and the knob 28 for gradually discharging air can be used as they are in the illustrated specific example. It is.

It is composition explanatory drawing which shows an example of the non-mercury type analog blood pressure meter according to this invention. It is a graph which shows the relationship between the cuff internal pressure at the time of blood-pressure measurement using the blood pressure meter according to this invention, and the elapsed time of blood-pressure measurement. FIG. 2 is an enlarged partial explanatory view showing one step of blood pressure measurement of the analog blood pressure display device in the sphygmomanometer shown in FIG. Moreover, (b) has shown the state by which the light-emitting body was made to light-emit in the shape of a dot or a line in the blood-pressure display scale position corresponding to a maximum blood pressure value and a minimum blood pressure value. It is explanatory drawing which shows the various examples which incorporate a simple generator in the blood pressure meter shown in FIG. 1, Comprising: (a) is an example with which the generator was provided on the air tube which sends air into a cuff. (B) shows an example in which power is generated by supplying air from the pressure rubber ball to the generator by switching the valve, and (c) shows the compression of the pressure rubber ball. At the same time, an example in which the generator is mechanically driven is shown.

Explanation of symbols

2 Analog blood pressure display device 4 Cuff 6 Rubber ball for pressurization 8 Pressure detector 10 Pressure reversal detection device 12 Control device 14 Digital display device 20 Blood pressure display scale 22 Pressure display device 24 Air tube 26 Valve 28 Knob 30 Luminescent body 32 36 Generator 34 Actuating lever 38 Drive shaft

Claims (5)

An analog type blood pressure provided with pressure display means for displaying pressure in the form of a bar graph along the blood pressure display scale and configured so that the pressure display means can emit light in a dotted or linear manner at each scale position. A display device;
A cuff wrapped around the arm of the patient whose blood pressure is to be measured and tightening the arm;
A pressure rubber ball for supplying air to the cuff to increase the pressure in the cuff and tighten the arm part;
A pressure detector for detecting the fluctuating pressure in the cuff and outputting it as a cuff pressure signal;
Pressure that detects the reversal of the change in the cuff pressure caused by the compression rubber balls being compressed in response to the appearance and disappearance of the Korotkoff sound, and outputs them as a systolic blood pressure signal and a diastolic blood pressure signal, respectively. Reversal detection means;
According to the pressure signal in the cuff from the pressure detector, the pressure display means of the analog type blood pressure display device emits light as a bar graph having a length corresponding to the pressure in the cuff and displays the pressure. When extinction of the pressure display means so that the length of the emitted bar graph becomes shorter as the pressure in the cuff decreases, by inputting the systolic blood pressure signal and the diastolic blood pressure signal from the pressure inversion detection means, In the pressure display means, a control device that controls so that only point-like or linear light emission at the scale position corresponding to these signals exists,
A non-mercury analog sphygmomanometer characterized by containing.   The non-mercury analog sphygmomanometer according to claim 1, wherein the pressure reversal detection means is integrally incorporated in the control device.   A generator that can be driven by a pressing operation of the rubber ball for pressurization is provided, and the electric power generated by driving the generator is the control device, the analog blood pressure display device, the pressure detector, and the pressure reversal detection means. The non-mercury analog sphygmomanometer according to claim 1 or 2, which is used for operating at least one of the above.   4. A digital display device that digitally displays the pulse rate together with the measured systolic blood pressure value and the diastolic blood pressure value is further provided and controlled by the control device. A non-mercury analog blood pressure monitor according to claim 1. The said pressure display means is comprised so that many independent light-emitting bodies may be arranged by bar graph shape so that it may respond | correspond to each scale position of the said blood-pressure display scale. Non-mercury analog sphygmomanometer.

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