JP2019078601A - Flowmeter monitoring device and flowmeter monitoring method - Google Patents

Abstract

To provide a device with which it is possible, when using a flowmeter such as an oxygen flowmeter, to make it as being equipped with a monitoring function only when necessary.SOLUTION: A flowmeter monitoring device 10 is a device for monitoring the flow rate of a float type flowmeter 20, comprising: at least one critical value setting unit 3 for setting a flow rate range; a control unit 5 for controlling the display of a positional relationship between the flow rate range set by the critical value setting unit 3 and a float 21; and a display unit 8 for displaying the positional relationship under control of the control unit 5. The critical value setting unit 3 is provided with at least one light-emitting unit 1 and at least one light-receiving unit 2 that corresponds to the foregoing (light-emitting/receiving unit 12), the light-emitting unit 1 and the light-receiving unit 2 of the light-emitting/receiving unit 12 being arranged facing each other across a tube 23 of the flowmeter 20 when this device 10 is in use.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a flow meter monitoring apparatus and a flow meter monitoring method, and more particularly to a flow meter monitoring apparatus and the like in a field where flow rate monitoring and management are important such as an oxygen flow meter in a medical engine.

  In medical institutions, oxygen flowmeters are widely used from respiratory therapy to auxiliary circulation devices such as artificial heart and lungs. This may be used for critically ill patients suffering from cardiac or respiratory dysfunction such as cardiopulmonary bypass, and monitoring and control of the oxygen flow rate is important for use at such sites. Therefore, in addition to the oxygen supply, a device for measuring the flow rate and operating an alarm if the flow rate is dangerous is also commercially available.

  Conventionally, many technical proposals have been made regarding flow meter management techniques. For example, in Patent Document 1 listed below, as a flow meter capable of detecting whether the flow rate of fluid to be measured is within an arbitrary predetermined flow rate range, the upper and lower ends are each sealed by a lid, and the float An upper mechanical stopper is provided in the tapered pipe provided so as to be vertically movable through the upper lid, and a lower mechanical stopper is provided through the lower lid so as to be vertically movable, at an upper and lower position slightly lower than the lower end of the upper mechanical stopper The first optical sensor is provided close to the tapered tube, and the second optical sensor is provided close to the tapered tube at the upper and lower positions slightly higher than the upper end of the lower mechanical stopper.

Japanese Patent Laid-Open No. 2002-267511 "Flow-measuring device and substrate processing apparatus using the same"

  As mentioned above, although the flow measurement device which measures the flow rate in addition to the oxygen supply and activates the alarm if the flow rate is dangerous is also commercially available, this is a flow rate that is generally widely distributed and used It is expensive compared to the total. On the other hand, less expensive flow meters that are widely provided do not have a monitoring function, and are used mostly in light cases such as relatively light oxygen therapy. However, it is natural that this type of flowmeter needs to monitor and control its flow rate. However, covering all flow meters used in medical institutions with expensive alarm functions is not realistic from the economic point of view. It would be convenient if such an inexpensive flow meter could be equipped with a monitoring function only when needed. This is true not only in the medical field and the oxygen flow meter but also in the flow meter in general.

  Therefore, the problem to be solved by the present invention is to eliminate the problems of the prior art and to provide a technology capable of making the monitoring function only when necessary when using a flow meter such as an oxygen flow meter. It is.

  As a result of examining the above problems, the inventor of the present application has conceived of a configuration of a monitoring device that can be detached from an existing flow meter without a monitoring function. And, if necessary, it can be attached to a flowmeter such as an oxygen flowmeter to monitor the flow rate, and any allowable flow rate range can be set, and when it deviates from that range, an alarm can be displayed by visual or audible indication. It has been found that the problem can be solved by providing an apparatus capable of issuing a notification, and based on this, the present invention has been completed. That is, the invention claimed in the present application as means for solving the above-mentioned problems or at least the invention disclosed is as follows.

[1] An apparatus for monitoring the flow rate of a float type flow meter, comprising: at least one limit value setting unit for setting a flow rate range; a flow rate range set by the limit value setting unit; And a display unit controlled by the control unit to display the positional relationship, the limit value setting unit including at least one light emitting unit and one light emitting unit At least one light receiving unit (hereinafter referred to as "light receiving / emitting unit") corresponding to the light emitting / receiving unit, the light emitting unit and the light receiving unit of the light emitting / receiving unit sandwich the tube of the flow meter when using this device The flow meter monitoring device, wherein the flow meter monitoring device is disposed to face each other.
[2] The light emitting and receiving unit transmits the light blocking occurrence as a signal to the control unit as a signal, and the control unit performs control to operate the display unit by receiving the light blocking occurrence signal. The flowmeter monitoring device according to [1].
[3] The flowmeter monitoring device according to [1] or [2], wherein the limit value setting unit is formed so as to be able to slide and be fixed in the longitudinal direction of the flowmeter.
[4] The limit value setting unit according to any one of [1] to [3], wherein two of the light receiving units are provided in the longitudinal direction of the pipe of the flow meter in use. Flow meter monitoring device.

[5] The control unit is characterized by comprising: a pattern determination unit that determines a light blocking occurrence pattern in the two light receiving units; and a display control unit that performs operation control of the display unit based on the determination. The flowmeter monitoring device according to [4].
[6] The pattern determination unit is formed to determine that light shielding occurs in one of the two light receiving units closer to the flow rate range and light shielding occurs in the other after that as a pattern requiring alarm display. The flowmeter monitoring device according to [5], characterized in that
[7] The flowmeter monitor according to any one of [1] to [6], wherein the light emitting and receiving unit is formed by pairing one light emitting unit and one light receiving unit. apparatus.
[8] The flowmeter monitoring device according to any one of [1] to [6], wherein the light emitting and receiving unit is formed of one light emitting unit and two or more light receiving units.

[9] The flow meter according to any one of [1] to [8], wherein two limit value setting units are provided to set the flow rate range by the upper limit value and the lower limit value. Monitoring device.
[10] The flowmeter monitoring device according to any one of [1] to [9], wherein the display unit performs visual display, auditory display, or both of them.
[11] The display unit performs visual display and / or auditory display, and displays when the upper limit is exceeded and display when the lower limit is exceeded are distinguished from each other. And [9].

[12] The flowmeter monitoring device according to any one of [1] to [11], wherein the limit value setting unit, the control unit, and the display unit are integrally formed by a housing. .
[13] The flowmeter monitoring device according to [12], including a mounting structure that can be mounted to two or more flowmeters of different specifications.
[14] The flowmeter monitoring device according to any one of [1] to [13], which is for measuring an oxygen flow rate.
[15] A flowmeter monitoring apparatus according to any one of [1] to [14] is attached to the flowmeter, and the limit value setting unit is slid and fixed at a desired position on the pipe. How to monitor the flow meter.

  Since the flowmeter monitoring device and the flowmeter monitoring method of the present invention are configured as described above, according to these, when using a flowmeter such as an oxygen flowmeter, the monitoring function is provided only when necessary. be able to. In other words, the device according to the present invention can be easily installed in an inexpensive existing flow meter which has already been distributed in large numbers so as to be easily removable, and the flow rate of the flow meter is monitored, and the flow rate exceeds the set range. In that case, it can be displayed and alerted. Therefore, it is not necessary to use an expensive flowmeter with a monitoring and alarm function, and the monitoring and display (alarm) function can be realized using an existing inexpensive flowmeter. Although the main application field is assumed to be the medical field, it is not limited to this, and the present invention can be applied to any flow meter for which flow monitoring and alarm are desired.

  As an example of use of the present invention in the medical field, a flowmeter such as an oxygen flowmeter is replaced with an expensive one with an alarm in response to a particularly intensively monitoring period or a target patient requiring intensive monitoring. Instead, it can be used simply by installing the existing flow meter for the required period of time. The ability to use the monitoring alarm device of the present invention in combination with the oxygen flow meter frequently used in medical institutions greatly contributes to medical safety.

  For example, when performing cardiopulmonary support with ICU, etc., oxygen is supplied to the artificial lung for a long period of time, but the flow rate change is appropriately monitored by using the device of the present invention, and a constant flow rate range is provided. If you deviate from the above, you can get an alert and take action. In most critically ill patients, most of the respiratory circulation is reliant on cardiopulmonary bypass, and the significance of flow monitoring is also very important for life maintenance purposes.

  Furthermore, the device according to the present invention can be installed not only on the flow rate monitoring at the time of oxygen supply to artificial heart and lung, etc., but also on an oxygen cylinder used at the time of movement etc. be able to.

  According to the present invention, the deviation of the float from the set flow rate range is displayed as an audible or visual display, so that it is not necessary to visually check the position of the float, and it takes more quickly. An alert can be recognized. Further, according to the flow meter monitoring apparatus of the present invention in which two light receiving units are provided in the limit value setting unit, malfunction is reduced by using two pairs of light emitting and receiving units, which deviates from the flow rate setting range. It is possible to detect with high accuracy whether or not to display / alarm.

  Further, in the device of the present invention, monitoring can be performed only by attaching from the outside without invading the inside of the existing flow meter to be attached. Thus, since it does not intrude into the flow meter main body, the flow can be monitored and displayed without any loss of the function as the flow meter. Here, the function as a flow meter is, for example, oxygen supply in the case of an oxygen flow meter.

  Further, according to the flow meter monitoring apparatus of the present invention having a mounting structure capable of mounting to two or more types of flow meters having different specifications, the flow meter is mounted to a plurality of flow meters having different specifications due to differences in manufacturers. It is possible, versatile and convenient.

  In the present invention device having a configuration in which two limit value setting units are provided to set the flow rate range by the upper limit value and the lower limit value, display when exceeding the upper limit value and display when exceeding the lower limit value ( According to the device of the present invention in which the alarm sound or the like is distinguished, it is extremely easy to determine which one of the upper limit value and the lower limit value has deviated from the range.

BRIEF DESCRIPTION OF THE DRAWINGS It is explanatory drawing which shows notionally the basic composition of the flow meter monitoring apparatus of this invention. It is explanatory drawing which shows notionally for slide operation of the limit value setting part of the flow meter monitoring apparatus of this invention. It is explanatory drawing which shows notionally the light-shielding signal production | generation effect | action in the flow meter monitoring apparatus of this invention. It is explanatory drawing which shows notionally the structure of this invention flowmeter monitoring apparatus with which two light reception parts are provided. FIG. 5 is an explanatory view conceptually showing an example of a flow meter monitoring device of the present invention including an internal configuration of a control unit using the configuration example shown in (a) of FIG. 4. It is explanatory drawing which shows notionally the state of light-shielding generation | occurrence | production in the flow meter monitoring apparatus shown in FIG. It is explanatory drawing which shows the example of a pattern of light-shielding generation in a table. It is explanatory drawing which shows notionally the structure of this invention flow meter monitoring apparatus provided with two limit value setting parts. It is explanatory drawing which shows the housing | casing structure of an Example oxygen flowmeter monitoring apparatus (state which removed the front cover). It is explanatory drawing which shows the housing | casing structure of an Example oxygen flowmeter monitoring apparatus (state with front lid filled). BRIEF DESCRIPTION OF THE DRAWINGS It is a photograph figure which shows the external appearance of an Example oxygen flowmeter monitoring apparatus. It is a photograph figure which shows the attachment state to the oxygen flow meter of the Example oxygen flow meter monitoring apparatus. It is a photograph figure which shows the alarm alerting | reporting state of an Example oxygen flowmeter monitoring apparatus. 1 is a control circuit diagram of an oxygen flow meter monitoring device according to an embodiment. FIG. 6 is a circuit diagram of a float sensor of the embodiment of the oxygen flow meter monitoring device. FIG. 6 is a circuit diagram of a display unit of the oxygen flowmeter monitoring device according to the embodiment. It is a regular six-sided view of the appearance of an example oxygen flowmeter monitor.

Hereinafter, the present invention will be described in detail with reference to the drawings.
FIG. 1 is an explanatory view conceptually showing the basic structure of a flow meter monitoring device of the present invention. As illustrated, the flow meter monitoring device 10 is a device for monitoring the flow rate of the float type flow meter 20, and includes at least one limit value setting unit 3 for setting the flow rate range, and the limit value setting. The control unit 5 controls display of the positional relationship between the flow rate range set by the unit 3 and the float 21 and the display unit 8 controlled by the control unit 5 to display the positional relationship The value setting unit 3 is provided with at least one light emitting unit 1 and at least one light receiving unit 2 (light emitting / receiving unit 12) corresponding thereto, and the light emitting unit 1 and the light receiving unit 2 of the light emitting / receiving unit 12 The main configuration is to be disposed so as to face each other across the pipe 23 of the flow meter 20 when 10 is used.

  Although only one limit value setting unit 3 for setting the flow rate range is shown in the figure, a plurality of limit value setting units 3 may be provided. The example in which only one is provided corresponds to the case where either the upper limit or the lower limit of the flow rate may be set. Further, an example of providing two (described later, FIG. 8) corresponds to the case where both the upper limit and the lower limit of the flow rate should be set. This applies to the latter case where the device of the present invention is applied to an oxygen flowmeter used in the medical field. 1 to 7 will be described based on an example in which only one limit value setting unit is provided, but the present invention is not limited to this and a plurality of limit value settings are set. This also applies to the case where a department is provided.

  As the control unit 5 that controls the display of the positional relationship between the flow rate range set by the limit value setting unit 3 and the float 21, an appropriate arithmetic processing means can be used. Further, as the display unit 8 controlled by the control unit 5 to display the positional relationship, at least one of visual display (display recognized by visual sense) and auditory display (display recognized by auditory sense) is suitably used. be able to. This is because these displays are convenient means for recognition. Note that both types of display may be used in combination.

  The light emitting / receiving unit 12 provided in the limit value setting unit 3 includes at least one light emitting unit 1 and at least one light receiving unit 2 corresponding thereto. That is, each of the light emitting unit 1 and the light receiving unit 2 may be only one or plural. Further, the number of light emitting units and light receiving units need not be the same. For example, only one light emitting unit 1 and two or more light receiving units 2 corresponding thereto are provided, the light emitting unit 1 and a corresponding light receiving unit 2 are both one, Certain configurations, that is, two pairs, and configurations having three or more pairs are all within the scope of the present invention. A configuration example of the light emitting and receiving unit will be described later (after FIG. 4).

  In the case of using the flow monitor 10 of the present invention with this configuration for the float type flow meter 20, the light emitting unit 1 and the light receiving unit 2 are the tubes of the flow meter 20 in which the float 21 is housed. It will be in the state arrange | positioned so as to oppose on both sides of 23. FIG. The limit value setting unit 3 provided with the light emitting / receiving unit 12 is used to set at least one of the upper limit position and the lower limit position of the float 21. By this setting, the flow rate range is set. In order to perform such setting, the limit value setting unit 3 is formed so as to be able to slide and be fixed in the longitudinal direction of the pipe 23 of the flow meter 20. With this configuration, the limit value setting unit 3 can be slid to a desired set position on the pipe 23 and fixed thereto, and the flow rate range and the limit point at which the alarm display by the display unit 8 should be performed can be freely set. . In addition, FIG. 2 is explanatory drawing which shows notionally the thing for slip operation of the limit value setting part of this invention flowmeter monitoring apparatus. In the figure, the slide is indicated by the symbol S.

  The positional relationship between the flow rate range set by the limit value setting unit 3 and the float 21 is detected by the action of the light emitting / receiving unit 12 described in detail later, and is emitted as a signal. The signal is processed in the control unit 5, and control of display of the positional relationship between the flow rate range set by the limit value setting unit 3 and the float 21 is performed, and display of the positional relationship is performed in the display unit 8 by such control. Is done. Although the present apparatus 10 is characterized by the display specially made when it deviates from the set limit, the state where such a special display is not made indicates that it does not deviate from the set limit. Do. Therefore, it can be said that the state where the above special display is not made is also made.

  FIG. 3 is an explanatory view conceptually showing the light blocking generation signal generating operation in the flow meter monitoring device of the present invention. As shown in the figure, the device 10 sends the presence or absence of light blocking in the light emitting / receiving unit (12) by the float 21 as a signal to a control unit (not shown), and the control unit receives the light blocking occurrence signal and displays the display unit (figure Control can be performed to operate (not shown). That is, the presence or absence of the light shielding based on the positional relationship between the light emitting / receiving unit (12) and the float 23 is the basis of the operation of the present apparatus 10.

  In the illustrated example, the limit value setting unit 3 is provided with one light emitting unit 1 and one light receiving unit 2 (a light receiving and emitting unit 12 corresponding to the light emitting and receiving unit 12) with the tube 23 interposed therebetween. When the float 23 shown in a) is not interposed between the light emitting unit 1 and the light receiving unit 2, the light L emitted from the light emitting unit 1 reaches the light receiving unit 2 without being blocked and is received. That is, at this time, the light shielding occurrence signal is not generated. Therefore, the control unit does not perform control to operate the display unit, such as visual display, and the display unit does not display visual display or the like.

  On the other hand, when the float 23 shown in (b) in the figure is interposed between the light emitting unit 1 and the light receiving unit 2, the light L emitted from the light emitting unit 1 is blocked and does not reach the light receiving unit 2. It is not received. That is, at this time, a light blocking occurrence signal is generated. Therefore, the control unit performs control to operate the display unit such as visual display, and the display unit performs display such as visual display. It is needless to say that the light emitting unit 1 and the light receiving unit 2 are configured in such a specification that light shielding occurs due to the presence of the float 23 therebetween.

  FIG. 4 is an explanatory view conceptually showing the structure of the flowmeter monitoring device of the present invention in which two light receiving portions are provided. As shown by the flow meter monitoring devices 310 ((a) in the figure) and 410 ((b) in the figure), the flow meter monitoring device of the flow meter monitoring device according to the present invention Two light receivers can be provided in the longitudinal direction of the tube 21. In the example of (a), two light emitting parts are also provided, and the light emitting / receiving part 312 is configured by the light emitting part 31a and the light receiving part 32a, the light emitting part 31b and the light receiving part 32b, and two pairs of light emitting part-light receiving part. That is, in the light emitting / receiving unit 312, one light emitting unit 31a etc. and one light receiving unit 32a etc. are formed as a pair, and a light blocking occurrence signal can be generated in each pair 31a-32a, 31b-32b. This will be further described later with reference to FIGS.

  On the other hand, in the example of (b), the light emission / reception part 412 is comprised from one light emission part 41 and two light reception parts 42a and 42b. That is, in the light emitting / receiving unit 412, one light emitting unit 41 functions as a light source for the two light receiving units 42a and 42b. Also in this example, it can be said that two pairs of light emitting unit 41-light receiving unit 42 a and light emitting unit 41-light receiving unit 42 b are provided. For the light emitting unit 41, a light source of a specification capable of irradiating any light receiving unit may be used. In order to detect the deviation of the limit of the flow rate range as the light blocking occurrence signal more accurately, the type (a) is desirable, but the type (b) is not excluded from the present invention.

  FIG. 5 is an explanatory view conceptually showing an example of the flow meter monitoring device of the present invention including the internal configuration of the control unit using the configuration example shown in FIG. 4 (a). As shown in the drawing, the apparatus 310 of this example is a display unit based on the pattern discrimination unit 36 in which the control unit 35 discriminates the pattern of light blocking occurrence in the two light receiving units 32a and 32b, and the discrimination of the pattern of light blocking occurrence by this. And a display control unit 37 configured to perform the operation control of 38. The present example device 310 has a configuration in which two pairs or more of a light emitting unit and a light receiving unit are provided in the light emitting and receiving unit 312. Although a configuration in which three or more pairs are provided is not excluded, a sufficient effect can be obtained with two pairs for the purpose of the present invention, and it is not necessary to have three or more pairs.

  With this configuration, in the present example device 310, the pattern indicating the presence or absence of light blocking by the float 21 in each of the two light receiving portions 32a and 32b, that is, the pattern of light blocking occurrence is determined by the pattern determining portion 36 of the control portion 35. At 37, it is determined whether to operate the display unit 38 based on the determination result, and control of the operation of the display unit 38 is executed.

  FIG. 6 is an explanatory view conceptually showing the state of light blocking occurrence in the flow meter monitoring device shown in FIG. In (a) in the figure, the float 21 is at a position interposed between the lower light emitting portion 31a and the light receiving portion 32a, and the light La emitted from the light emitting portion 31a is shielded by the float 21 and is received by the light receiving portion 32a. There is no light reception, and therefore a light shielding occurrence signal is generated. On the other hand, between the light emitting portion 31b and the light receiving portion 32b in the upper stage, no light blocking by the float 21 occurs, and the light Lb is received by the light receiving portion 32b.

  Further, in (b) of the figure, the float 21 is located between the light emitting portion 31b and the light receiving portion 32b in the upper stage, and the light Lb emitted from the light emitting portion 31b is shielded by the float 21 and the light receiving portion 32b Light is not received, so that a light blocking occurrence signal is generated. On the other hand, light blocking by the float 21 does not occur between the light emitting portion 31a and the light receiving portion 32a in the lower stage, and the light La is received by the light receiving portion 32a. The control of the display control unit 37 is determined by the light shielding occurrence patterns in the upper and lower two pairs of light emitting units and light receiving units, which will be described next.

  FIG. 7 is an explanatory view showing an example of a light shielding occurrence pattern in a table. In each of (a) and (b), the first line indicates the elapsed time to the right with Seq 1 and 2. The second and third lines indicate the presence or absence of light blocking in each of the light receiving sections 32a and 32b. Indicates the presence or absence of display at 38. As shown in (a), in the case of a light blocking occurrence pattern in the order in which light shielding occurs in the upper light receiving unit 32a and light shielding occurs in the lower light receiving unit 32b, the lower light receiving unit 32b In accordance with the occurrence of light shielding at the time, the pattern determination unit 36 determines that the pattern is the pattern, and the display control unit 37 operates to display on the display unit 38. This pattern occurs when the float 21 moves from within the set flow rate range to outside the range. That is, when the flow rate changes out of the set flow rate range, such an operation is performed.

  On the other hand, as shown in (b), in the case of a light blocking occurrence pattern in the order of light blocking occurring in the lower light receiving portion 32b and light blocking occurring in the light receiving portion 32a further upward thereafter This is determined by the pattern determination unit 36, and after processing by the display control unit 37, display on the display unit 38 is not performed. This pattern occurs when the float 21 moves from the outside of the set flow rate range into the range. That is, when the flow rate changes in the direction toward the set flow rate range, such an operation is performed. As a result, when the flow rate which has once deviated from the limit returns to the normal range, the display unit 38 does not display it, and therefore it is not mistaken for occurrence of flow rate abnormality.

  That is, in the flow meter monitoring device 310 of the present invention, when the pattern determination unit 36 generates light shielding in one of the two light receiving units 32a and 32b closer to the flow rate range and then generates light shielding in the other, the display unit It may be configured to determine the required pattern of the alarm display at 38. Although the example which set the flow volume upper limit by the limit value setting part 33 was demonstrated in FIG. 6, this is the same also when the flow volume lower limit is set. As described above, according to the present invention, not only the flow rate at a certain point in time but also the change with time of the flow rate can be detected, whereby more appropriate flow rate monitoring and display in the case of deviation can be made.

  FIG. 8 is an explanatory view conceptually showing the structure of the flowmeter monitoring device of the present invention in which two limit value setting units are provided. As shown in the drawing, the flowmeter monitoring device 510 may be provided with two limit value setting units 53 and 54 in order to set the flow rate range by the upper limit value and the lower limit value in addition to the configuration described above. it can. Although the light emitting and receiving units 512B and 512T provided in the limit value setting units 53 and 54 are shown in the same manner as FIG. 1 in the drawing, the configuration of the light emitting and receiving units may be any of the examples described above.

  With this configuration, the operation and the effect in the limit value setting unit described above can be obtained in any of the upper and lower limit value setting units 53 and 54. As in the case of an oxygen flow meter, the limit value setting unit may be set to either the upper limit or the lower limit for the purpose of monitoring a flow meter that causes problems even if the flow rate range is excessive or excessive. The embodiment described later is also of this type.

  Also in the case of a flow meter monitoring device provided with two limit value setting units, as described above, the display unit may be a visual display, an auditory display, or a display by both of them. In either method, the display when the upper limit is exceeded and the display when the lower limit is exceeded can be distinguished. As a result, it is possible to instantly identify whether the abnormality has occurred at the upper limit or the lower limit of the flow rate range, and when the correspondence differs depending on the case, it is possible to respond promptly to it. For example, in the case of red display, the deviation of the lower limit value is set, and in the case of yellow display, the deviation of the upper limit value is set.

  As will be described later in the embodiment, in the flow meter monitoring device of the present invention, the limit value setting unit, the control unit, and the display unit can be configured integrally with a housing. Use as an integral structure can enhance usability and commercialization. Moreover, it can also be set as the structure provided with the mounting structure which can be mounted | worn with respect to two or more flow meters from which a specification differs. According to such a configuration, the flowmeter monitoring device can be attached to two or more applicable commercially available flowmeters, which is versatile and convenient.

  The flowmeter monitoring device of the present invention is mounted and used from the outside of the flowmeter by a fitting type or other suitable mounting method. On the other hand, the specifications of the flow meter are not uniform due to differences among manufacturers, starting with the housing shape of the flow rate display unit. Providing a mounting structure that can meet two or more specifications is a desirable configuration in the present invention based on mounting on an existing flow meter. As a specific example of the mounting structure, a spacer fitted between the flow meter and the present device, an elastic spacer fitted between the flow meter and the present device, etc. can be used, but it is not limited thereto.

  In addition, the flowmeter monitoring method performed by attaching one of the flowmeter monitoring devices described above to the flowmeter, sliding the limit value setting unit, and fixing it at a desired on-pipe position is also within the scope of the present invention. It is inside. If the flowmeter is operated with the device fixed to the flowmeter, then, if the flow rate deviates from the set limit value, the device displays that in a predetermined display method.

Examples of the present invention will be described below, but the present invention is not limited thereto. The outline of the research and development process leading to the completion of the present invention will be replaced by the explanation of the embodiment.
[1] Research and development theme Development of flow rate monitoring and alarming device (oxygen flowmeter monitoring and alarming device) that is versatile for each oxygen flowmeter equipped with a new sensor

[2] Outline of development device We developed a sensor to monitor the behavior of floats in the flow meter.
The apparatus was provided with a limit value setting unit in which two sensors (four in total) at the upper limit and the lower limit were provided with a pair of sensors of the light emitting unit and the light receiving unit. As a result, even if monitoring is started with no float in the measurement range (flow rate range) between the upper limit and the lower limit, the float passes through the set value and enters the set range Then, the alarm was not activated and the alarm was activated only when the float deviated from the set value range.

  That is, by setting two pairs at one monitoring position, for example, in the case of the lower limit sensor, when detecting in the order from the bottom of the two pairs, an alarm is activated to indicate that the float has entered the set range Instead of this, it was decided that it deviated from within the range when sensing from top to bottom sensor in order, and it was considered as a system to activate an alarm. The alarm was a combination of visual display and auditory display. That is, when the flow rate was abnormal, light of a specific color was emitted. Specifically, red light was displayed when abnormal, and green light was displayed when normal. In addition, a specific sound is generated. In addition, different buzzer sounds were used for the upper limit and the lower limit.

  The setting of the measurement range is performed by moving the upper and lower limit value setting units to an arbitrary position on the flow meter tube and fixing it. The light emitting part and the light receiving part of the sensor just sandwich the tube in which the float which shows the flow value is incorporated. The position set in this way is the upper limit position and the lower limit position of the alarm generation. Then, a state where the signal (light) of the light emitting unit is received by the light receiving unit is regarded as a normal flow rate, and the float deviates from each measurement range, and light reception in the light receiving unit, that is, a signal from the light emitting unit When the)) is interrupted, the sensor recognizes that it has passed through the float and activates an alarm.

  In addition, two oxygen flowmeters, which have a particularly high market share, were identified through research, and a versatile device structure that can be attached to any of these flowmeters and used. Specifically, a push type mounting structure operated by a button is provided at two lower parts of the apparatus. By pressing both buttons so that the area of the lower surface of the device into which the flow meter is inserted can be adjusted, and a spring can interlock and hold the tube of the flow meter in a pinched manner and fix it. In addition, attachment to the flowmeter main body of a monitoring apparatus is performed so that a flowmeter may be covered from the apparatus main body lower surface side. FIGS. 9 and 10 are explanatory views showing the case structure of the oxygen flowmeter monitoring device of the embodiment, where the former shows a state in which the front lid is removed and the latter shows a state in which the front lid is filled. In the figure, reference numeral 67 denotes the mounting structure of this embodiment.

[3] Evaluation of Development Device FIGS. 9, 10 and 11 are photographs showing the appearance of the oxygen flowmeter monitoring device according to the embodiment, the attachment state to the oxygen flowmeter, and the alarm notification state, respectively. 12, 13, and 14 are a control circuit diagram, a float sensor circuit diagram, and a circuit diagram of the display unit of the oxygen flow meter monitor of the embodiment, respectively, and FIG. 15 is an appearance of the oxygen flow meter monitor of the embodiment. It is an orthographic view of In the present apparatus 610, malfunction can be eliminated by using two pairs of sensors. In addition, it was possible to easily determine whether it deviated from the upper limit value or the lower limit value without visually checking the position of the float by changing the alarm sound of the upper limit value and the lower limit value.

Further, by using the above-described push type mounting structure, the present device 610 can be mounted without any problem on any of the following two models having particularly high share as an oxygen flow meter, and can be used.
Supported models 1. Koike Medical Safety Flow 2. New industrial oxygen flowmeter N-102

  According to the flowmeter monitoring apparatus and the flowmeter monitoring method of the present invention, it can be easily installed in an inexpensive existing flowmeter in a detachable manner, and the flow rate of the flowmeter is monitored, and the flow rate exceeds the set range. In that case, it can be displayed and alerted. Thus, there is no need to use an expensive flow meter with a monitoring and alarm function. Therefore, it is an invention of high industrial applicability in the medical field including oxygen flow rate measurement, other industrial / technical fields requiring flow rate management, and all related fields.

1, 31a, 31b, 41, 51B, 51T ... light emitting unit 2, 32a, 32b, 42a, 42b, 52B, 52T ... light receiving unit 3, 33, 43, 53, 54, 63, 64 ... limit value setting unit 5, 35, 55 ... control unit 8, 38, 58, 68 ... display unit 10, 310, 410, 510, 610 ... flow meter monitoring device 12, 312, 412, 512T, 512B ... light emitting / receiving unit 20, 620 ... float type Flow meter 21: Floating element 23: Flow meter tube 36: Pattern discrimination section 37: Display control section 65: Window section 66 ... Front lid 67 ... Mounting structure 69 ... Housing L, La, Lb ... Light from light emitting section Irradiation)
S: Slide

Claims (15)

An apparatus for monitoring the flow rate of a float type flow meter, comprising at least one limit value setting unit for setting a flow rate range, the position of the flow rate range set by the limit value setting unit, and the float A control unit that controls display of a relationship, and a display unit that is controlled by the control unit to display the positional relationship, and the limit value setting unit corresponds to at least one light emitting unit and the same. At least one light receiving unit (hereinafter also referred to as "light receiving / emitting unit") is provided, and the light emitting unit and the light receiving unit of the light emitting / receiving unit face each other across the tube of the flow meter when using this device. Flow meter monitoring device, characterized in that it is arranged. The light emitting and receiving unit sends a signal indicating the occurrence of light blocking by a float as a signal to the control unit, and the control unit performs control to operate the display unit by receiving the light blocking occurrence signal. Flow meter monitoring device according to. The flow meter monitoring device according to claim 1 or 2, wherein the limit value setting unit is formed slidably and fixed in a longitudinal direction of a flow meter tube. The flow meter monitoring apparatus according to any one of claims 1 to 3, wherein two of the light receiving units are provided in the longitudinal direction of the flow meter at the time of use in the limit value setting unit. The control unit includes a pattern determination unit that determines a light blocking occurrence pattern in the two light receiving units, and a display control unit that controls the operation of the display unit based on the determination. The flowmeter monitoring device according to claim 4. The pattern determination unit is configured to determine that light shielding occurs in one of the two light receiving units closer to the flow rate range and light shielding occurs in the other after that as a pattern required for alarm display. The flowmeter monitoring device according to claim 5, characterized in that: The flowmeter monitoring device according to any one of claims 1 to 6, wherein the light emitting / receiving unit is formed by pairing one light emitting unit and one light receiving unit. The flowmeter monitoring device according to any one of claims 1 to 6, wherein the light emitting and receiving unit is formed of one light emitting unit and two or more light receiving units. 9. The flowmeter monitoring device according to claim 1, wherein two limit value setting units are provided to set the flow rate range by the upper limit value and the lower limit value. The flowmeter monitoring device according to any one of claims 1 to 9, wherein the display unit performs visual display, auditory display, or both. In the display unit, visual display and / or auditory display are performed, and display when the upper limit is exceeded and display when the lower limit is exceeded are distinguished. The flowmeter monitoring device according to 9. The flow meter monitoring device according to any one of claims 1 to 11, wherein the limit value setting unit, the control unit, and the display unit are integrally formed by a housing. The flowmeter monitoring device according to claim 12, further comprising a mounting structure mountable to two or more flowmeters of different specifications. 14. A flowmeter monitor according to any of the preceding claims, characterized in that it is for oxygen flow measurement. A flowmeter monitor characterized in that the flowmeter monitor according to any one of claims 1 to 14 is attached to the flowmeter and the limit value setting unit is slid and fixed at a desired position on a pipe. Method.