JP2018023546A - Droplet detector and drip counter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a droplet detector and a drip counter dispensing with a mechanical configuration for holding a drip tube when they are mounted on the drip tube.SOLUTION: A droplet detector includes: a sensor 12 that responds to a droplet 9 dripping in a drip tube 7; and a housing 14 having a base part 142, a first arm part 144 extending from the base part 142, and a second arm part 146 facing the first arm part 144 with a space S in between, in which the sensor 12 is incorporated. The first arm part 144 and the second arm part 146 are put on the top face of the drip tube 7 disposed in the space S, and hooked on the drip tube 7 by the self-weight. A drip counter 10 includes the droplet detector and a display 20 which is an information output part for outputting information on the droplet 9 in response to a detection signal of the sensor 12.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a droplet detector and an infusion counter equipped with the droplet detector, and more particularly to a technique for mounting these devices on an infusion tube.

  There is known a treatment method called “infusion” in which a liquid (hereinafter referred to as “infusion agent”) containing components such as moisture, electrolytes and nutrients is infused into a patient's body by, for example, intravenous drip injection. An infusion set, which is a medical instrument for connecting a container in which an infusion solution is sealed and an infusion needle punctured into a patient's blood vessel, is used for intravenous infusion. As an infusion set, an infusion set including a drip tube and a clamp in the middle of a conduit including a soft tube connecting a container and a drip needle is widely used.

  When performing infusion, the amount of infusion and the time for infusion are determined by a doctor. In accordance with this, a medical staff such as a nurse adjusts the number of drops of the infusion solution in the infusion tube per unit time (hereinafter referred to as “the number of drops”) with a clamp, and adjusts the infusion rate of the infusion agent. Set. The general-purpose infusion set is for adults, and has a predetermined number of drops (nominal number of drops) corresponding to 1 ml of infusion, such as 20 drops per ml of infusion. For example, when the infusion set for adults is used to inject 500 ml of infusion solution in 4 hours, the number of drops is about 42 drops per minute.

  An infusion counter is used as an auxiliary device for adjusting the number of drops (Patent Documents 1 and 2). A photoelectric sensor is provided in the drip counter. The photoelectric sensor includes a light emitting unit that emits light and a light receiving unit that receives the emitted light (emitted light). The light emitting unit and the light receiving unit are arranged to face each other with an infusion tube interposed therebetween. When the emitted light is blocked by the droplets dropping in the drip tube, the amount of light received by the light receiving unit varies. The drip counter is configured to detect the presence of a droplet by detecting the variation in the amount of received light with a photoelectric sensor.

  The drip counter is also provided with a display. The number of drops per unit time (for example, per minute) is displayed on the display unit. The number of drops is calculated based on the interval of detection signals output from the light receiving unit. According to the drip counter having the above-described configuration, the number of drops is displayed on the display unit, so it is easy to check the number of drops. This eliminates the need for conventional complicated adjustments such as visually counting the number of droplets dropped in the drip tube while the healthcare worker looks at the watch. As a result, the workload of the healthcare worker is reduced. Is done.

  When the above-described infusion counter is used, it is necessary to mount the infusion counter at an appropriate position with respect to the infusion cylinder in order to accurately detect the droplet by the photoelectric sensor. Specifically, it is necessary to mount the drip counter on the drip tube in a state where the emission direction of the emitted light is positioned so as to intersect with the trajectory of the droplet to be dropped in the drip tube. Therefore, in Patent Documents 1 and 2, an infusion counter is attached to the infusion tube so as to sandwich the body portion of the infusion tube.

  However, in order to maintain the state in which the infusion counter is mounted on the infusion tube, a mechanical configuration is required in which the infusion tube (body portion) is clamped using a restoring force such as a torsion spring or a leaf spring. Although this configuration has the advantage of excellent workability when mounting the drip counter on the drip tube and adjusting the mounting position, it increases the number of components and assembly steps of the drip counter. As a result, the cost increases.

  The above-described problem is not limited to the drip counter, and for example, a droplet detector for detecting a droplet dropped in the drip cylinder, such as a drip number control type infusion pump (Patent Document 3), is used. It is common to medical equipment.

Japanese Patent Laid-Open No. 10-80482 JP 2011-206082 A JP 2010-145334 A

  In view of the above problems, a first object of the present invention is to provide a droplet detector that eliminates the need for a mechanical configuration for sandwiching the drip tube when mounted on the drip tube.

  The second object of the present invention is to provide an infusion counter equipped with such a droplet detector.

  In order to achieve the first object, a droplet detector according to the present invention includes a sensor that reacts to a droplet dropped in a drip tube, a base, a first arm that extends from the base, and the first A housing having a second arm portion opposed to the one arm portion across a space and incorporating the sensor, and the first arm on the top surface of the drip tube disposed in the space The second arm and the second arm are hooked on the drip tube by their own weight.

  In addition, each of the first arm portion and the second arm portion is bent in a direction in which the tip portions thereof are close to each other, and each of the tip portions is hooked on the upper surface of the drip tube. It is characterized by that.

  Furthermore, each of the first arm part and the second arm part has an outer peripheral edge of the upper surface of the infusion cylinder around the first peripheral edge part and the first peripheral edge part when being attached to the infusion pipe. Dividing into a short second peripheral edge, the first point and the second point on the outer peripheral edge are respectively hooked, and a line segment connecting the first point and the second point is seen in a plan view. The center of gravity is located on the first peripheral edge side.

  In addition, the base portion is in contact with the body of the drip tube when it is hooked on the drip tube, and the center of gravity is located below the contacted portion.

  In order to achieve the second object, an infusion counter of the present invention includes a droplet detector having any one of the above-described configurations and an information output for outputting information on the droplet according to a detection signal of the sensor. And a section.

  Further, the information output unit is provided in the housing.

  According to the droplet detector according to the present invention, the first arm portion and the second arm portion, which are part of the casing, are simply hooked on the top surface of the drip tube, respectively, and the drip tube is caused by its own weight. Therefore, when the droplet detector is attached to the drip tube, a mechanical configuration for holding the drip tube as in the prior art can be eliminated.

  In addition, the drip counter according to the present invention uses the casing constituting the droplet detector as a common component. Therefore, like the above-described droplet detector, the first arm and the second arm, which are part of the housing, are simply hooked on the top surface of the drip tube, and the drip tube is formed by its own weight. Since it is configured to be hooked, it is possible to eliminate the need for a mechanical configuration for sandwiching the drip tube as in the prior art when mounting on the drip tube.

It is a figure which shows the state by which the drip counter which concerns on embodiment was attached to the drip pipe | tube. (A) is the front side perspective view of the drip counter concerning an embodiment, and (b) is the back side perspective view. (A) is a front view of the drip counter, (b) is a rear view thereof, (c) is a top view thereof, (d) is a cross-sectional view taken along line AA, (e) is a partially enlarged view of a tip portion, Each is shown. It is a side view which shows the state with which the said drip counter was attached to the drip pipe | tube. It is a schematic plan view which shows the force which acts on an infusion tube, and the gravity center position of an infusion counter.

  About each embodiment of the droplet detector which concerns on this invention, and the drip counter which concerns on this invention, use with the natural drip-type drip intravenous injection (henceforth only "drip") which is a kind of infusion therapy. An example will be described below with reference to the drawings.

  An infusion set 1 shown in FIG. 1 is a medical instrument that connects a container 3 in which an infusion solution 2 is sealed and an infusion needle (not shown) punctured into a blood vessel of a patient. The container 3 is suspended from an infusion stand (not shown). The container 3 and a drip needle (not shown) are connected by a conduit 6 including soft tubes 4 and 5. In the middle of the conduit 6, an infusion tube 7 is provided on the upstream side near the container 3, and a clamp 8 is provided further downstream than the infusion tube 7.

  The drip tube 7 includes a hollow cylindrical body 71. The body 71 is made of a plastic material and has translucency. The upper opening on the container 3 side of the body 71 is sealed with a cap 72. A lower end portion 4 </ b> L of the soft tube 4 is connected to the upper connection port 73 provided in the upper center portion of the cap 72. On the other hand, an infusion opening 74 is provided at the center lower portion of the cap 72. An upper end portion 5U of the flexible tube 5 is connected to a lower connection port 75 that is directly below the drip port 74 of the body 71.

  A clamp 8 is attached below the upper end 5U of the soft tube 5. The clamp 8 includes a main body 81 that holds a fixed length portion of the soft tube 5. The main body 81 is provided with a roller 82 that rolls up and down along the fixed length portion. The clamp 8 is configured such that the space between the roller 82 and the main body 81 portion facing the outer peripheral curved surface of the roller 82 gradually becomes narrower as the roller 82 moves to the lower side of the main body 81.

  The infusion agent 2 in the container 3 flows down the soft tube 4 due to its own weight, and then becomes a droplet 9, which is dropped inside the infusion tube 7 (the hollow portion of the body 71) from the infusion port 74. At this time, the clamp 8 is operated and a part of the soft tube 5 existing between the main body 81 and the roller 82 is crushed to deform the flow path cross section of the infusion solution 2. Then, along with the deformation, the time interval at which the droplet 9 drops from the drip port 74 varies. Thus, by adjusting the number of droplets 9 dropped per unit time, the infusion rate of the infusate 2 by infusion (hereinafter referred to as “infusion rate”) is set so as to conform to the instruction from the doctor.

  The drip counter 10 according to the embodiment is an auxiliary device for adjusting the number of drops described above. The drip counter 10 is used by being attached to the drip tube 7. Hereinafter, the configuration of the drip counter 10 will be described with reference to FIGS.

  As shown in FIGS. 1 and 2, the drip counter 10 includes a sensor 12 that reacts to a droplet 9 that drops in the drip tube 7. The sensor 12 is incorporated in a general-purpose plastic casing 14. The housing 14 also accommodates a central processing unit (hereinafter referred to as “CPU”), a board (not shown) on which electronic components such as a memory are mounted, and a battery (not shown). The memory stores a program for controlling the overall operation of the drip counter 10. The drip counter 10 is operated by causing the CPU to execute this program with the power supplied from the battery. The operation of the drip counter 10 will be described later.

  The housing 14 has a base 142. The substrate portion and the battery on which the above-described CPU, memory, etc. (not shown) are mounted are accommodated in the base portion 142. From the base part 142, the 1st arm part 144 and the 2nd arm part 146 are each extended. The first arm portion 144 and the second arm portion 146 are opposed to each other with a space S between them. Each of the first arm portion 144 and the second arm portion 146 is bent in a direction in which the respective distal end portions 144F and 146F are close to each other. A gap G is provided between the distal end portion 144F and the distal end portion 146, as shown in FIGS.

  As shown in FIGS. 2 and 3A, the lower surfaces of the tip portions 144F and 146F include flat surfaces 144P and 146P, respectively. As shown in FIG. 3E, the flat surface 144P is an inclined surface inclined at an angle θ with respect to a virtual plane VP parallel to the upper surface of the distal end portion 144F. Further, on the back side of the tip portion 144F, a protruding portion 144S is formed in which a portion adjacent to the gap G protrudes downward toward the base 142 side. Although not shown in the drawing, the flat surface 146P is also an inclined surface inclined at an angle θ with respect to a virtual plane VP parallel to the upper surface of the distal end portion 146F, similarly to the flat surface 144P described above. Similarly, a protruding portion 146S in which a portion adjacent to the gap G protrudes downward toward the base 142 side is formed on the back surface side of the tip portion 146F.

  The drip tube 7 (FIG. 1) is disposed in the space S portion of the housing 14. Therefore, as shown in FIGS. 2 and 3, the base portion 142, the first arm portion 144, and the second arm portion 146 of the housing 14 are respectively opposed portions 142 </ b> O that face the infusion tube 7. , 144O, 146O. In this example, each of these facing portions 142O, 144O, 146O has a shape including a curved surface curved along the outer shape of the body 71 portion of the drip tube 7. In addition, the space S is designed to have a size that allows the body 71 to be accommodated with a certain margin, and can be mounted on another drip tube (not shown) having a different shape and size from the drip tube 7. Yes.

  As shown in FIG. 2A, the first arm portion 144 is provided with an emission window 16 that opens to the space S side. In this example, the exit window 16 is arranged in a line along the direction in which the first arm portion 144 extends, and the first exit window 161, the second exit window 162, the third exit window 163, and the fourth exit window. A window 164 is included. The first arm portion 144 also incorporates a light emitting element (not shown) that emits light through the emission window 16. In this example, four light emitting diodes (not shown) are provided as light emitting portions corresponding to the exit windows 161, 162, 163, and 164, respectively.

  On the other hand, as shown in FIG. 2B, the second arm portion 146 is provided with a light receiving window 18 that opens to the space S side, like the exit window 16. In this example, the light receiving window 18 is arranged in a line along the direction in which the second arm portion 146 extends, and the first light receiving window 181, the second light receiving window 182, the third light receiving window 183, and the fourth light receiving window. A window 184 is included. The second arm portion 146 also incorporates a light receiving element (not shown) that receives light emitted from the emission window 16 described above. In this example, four phototransistors (not shown) are provided as light receiving portions corresponding to the light receiving windows 181, 182, 183, and 184.

  The exit window 16 and the light receiving window 18 are provided at positions where the corresponding windows face each other with the space S therebetween. That is, the first emission window 161 faces the first light receiving window 181. Similarly, the second exit window 162 faces the second light receiving window 182, the third exit window 163 faces the third light receiving window 183, and the fourth exit window 164 faces the fourth light receiving window 184.

  When any of the light emitted from the light emitting diodes emitted from the emission windows 161, 162, 163, and 164 is blocked by the droplet 9 (FIG. 1), the phototransistor passes through the corresponding light receiving windows 181, 182, 183, and 184. The amount of light received by fluctuates. By detecting the change in the amount of received light into an electric signal, the presence of the droplet 9 is detected. That is, in this example, the sensor 12 is configured by each of the photoelectric sensors including the above-described four sets of light emitting diodes and phototransistors. Thus, in the drip counter 10, the sensor 12 incorporated in the housing 14 functions as a droplet detector.

  A display 20 that displays the number of drops per unit time as information about the droplets 9 is provided on the front surface of the base 142 of the housing 14. The number of drops is determined by calculating the time interval at which the droplet 9 drops from the drip inlet 74 (FIG. 1) from the electrical signal (detection signal of the sensor 12) indicating the variation in the amount of received light, for example, per minute. Calculated by converting to the number of drops. The calculation process for calculating the number of drops is automatically performed by causing the CPU to execute a calculation program stored in the memory in advance. Thus, in the drip counter 10, the display 20 functions as an information output unit that outputs information related to the droplet 9 according to the detection signal of the sensor 12.

  A switch 22 is provided below the display 20 in front of the base 142. The switch 22 is a known push button switch. The switch 22 is for performing a counting mode selection operation such as a power ON / OFF operation when using the drip counter 10 and a change of unit time (for example, 10 seconds, 30 seconds).

  As shown in FIGS. 3B and 3D, an illumination window 24 is provided in the facing portion 142O on the back side of the base portion 142. The base 142 incorporates an illumination light emitting diode (not shown) that emits light that illuminates the drip tube 7 from the bottom of the body 71 through the illumination window 24. The lighting light emitting diode can be turned on / off by the switch 22 described above. The lighting function is used, for example, during night patrols.

  Subsequently, a state in which the drip counter 10 is mounted on the drip cylinder 7 will be described with reference to FIGS. 1, 4, and 5. In order to avoid complexity, FIG. 4 shows only the first arm 144 side of the drip counter 10 and the base 142 shows a cross section. Further, in FIG. 5, the illustration of the drip counter 10 is omitted.

  The drip tube 7 is disposed in the space S of the housing 14. The top end portions 144F and 146F of the first arm portion 144 and the second arm portion 146 are respectively hooked on the upper surface of the cap 72 of the infusion tube 7.

  A T portion shown in FIG. 4 is a partially enlarged view of the distal end portion 144F hooked on the upper surface of the cap 72. As shown in the T section, in this example, the flat surface 144P on the lower surface of the tip portion 144F and the upper surface of the cap 72 are in surface contact. A protruding portion 144S located on the back side of the tip portion 144F is in contact with a part of the side surface of the cap 72. Here, the point where the protruding portion 144S is in contact with the outer peripheral edge of the upper surface of the cap 72 is referred to as a “first latching point P1”.

  Although not shown in FIG. 4, the flat surface 146P on the lower surface of the distal end portion 146F and the upper surface of the cap 72 are in surface contact with each other and the cap 72 is not illustrated, as in the above-described distal end portion 144F. A protruding portion 146S located on the back side of the tip end portion 146F is in contact with a part of the side surface. Here, the point where the protrusion 146S is in contact with the outer peripheral edge of the upper surface of the cap 72 is referred to as a “second latching point P2” (FIG. 5).

  In addition, as shown in FIG. 1, the connection portions such as the upper connection port 73 at the center upper portion of the cap 72 and the lower end portion 4 </ b> L of the soft tube 4 connected to the upper connection port 73 are located between the tip portions 144 </ b> F and 146 </ b> F. Will be disposed in the gap G. For this reason, when each front-end | tip part 144F and 146F is latched on the cap 72 upper surface, respectively, the said connection part does not cause any trouble.

  Returning to FIG. 4, since the base portion 142 of the casing 14 contains a board portion and a battery on which a CPU, a memory, etc. (not shown) are mounted, as described above, the center of gravity C of the drip counter 10 is The base portion 142 is located below the tip portions 144F and 146F. When each of the distal end portions 144F and 146F is hooked on the upper surface of the cap 72, a moment in a direction in which the base 142 approaches the infusion tube 7 is applied to the infusion counter 10 by its own weight. By this moment, the base 142 naturally comes into contact with a part of the drip tube 7 (body 71).

  A portion B shown in FIG. 4 is a partially enlarged view of a portion where the base portion 142 of the housing 14 is in contact with the drip tube 7. As shown in part B, in this example, the front portion of the base 142 where the illumination window 24 is opened is in contact with the lower connection port 75 at the bottom of the body 71. A point where the front portion is in contact with the lower connection port 75 will be referred to as a “contact T”.

  As described above, the drip counter 10 is in the state where the casing 14 and the drip cylinder 7 are in contact with each other at the first latching point P1, the second latching point P2, and the contact T. It will be hooked on the cylinder 7. The relationship between the forces acting on the three points in the hooked state will be described with reference to FIG.

  As shown in FIG. 5, the outer peripheral edge of the upper surface of the cap 72 of the drip tube 7 has a circular shape. The upper connection port 73 and the soft tube 4 are arranged concentrically with the upper surface of the cap 72, respectively. When the state shown in FIG. 4 is viewed in plan, the arrangement of the first latching point P1, the second latching point P2, the contact T, and the center of gravity C of the drip counter 10 is as follows. That is, the first latching point P1 and the second latching point P2 are respectively arranged at both end points of the dominant arc 72MA on the outer peripheral edge. Further, the contact point T and the center of gravity C with respect to the chord 72C indicated by a two-dot chain line connecting the first and second hooking points P1 and P2 which are both end points of the dominant arc 72MA are: Each is arranged on the dominant arc 72MA side.

  Here, the force acting on the first latching point P1 is represented as a first force F (P1), and the force acting on the second latching point P2 is represented as a second force F (P2). I will do it. In addition, the force acting on the contact T is represented as a third force F (T). At the first latching point P1 and the second latching point P2, the first force F (P1) in the direction in which each of the protrusions 144S and 146S presses the cap 72 (the left side in FIG. 5), The second force F (P2) is acting respectively. On the other hand, at the contact T, the third force F (T) acts in the direction in which the base portion 142 of the housing 14 presses the lower connection port 75 (right direction in FIG. 5).

  In this example, in the state shown in FIG. 4, the resultant force of the first force F (P1), the second force F (P2), and the third force F (T) is “0”. The moments of the first force F (P1), the second force F (P2), and the third force F (T) are balanced. As a result, the position of the drip counter 10 on the drip cylinder 7 is stabilized and maintained in a balanced state. Moreover, even if the balance is slightly lost, the protrusions 144S and 146S provided at the tip portions 144F and 146F function as hooks, so that the drip counter 10 can be easily detached from the drip tube 7. There is no.

  If the drip tube 7 is tilted clockwise from the state shown in FIG. 4, it seems that the tip portions 144F and 146F are likely to come off, but in this case, due to the weight of the drip counter 10, Since the moment of the third force F (T) is applied, unless the external force that tilts the drip tube 7 is too large, the drip tube 7 tilted by the moment returns to its original posture. Will be restored. In other words, if the drip counter 10 is engaged, the drip cylinder 7 is hardly inclined in the direction (the clockwise direction) in which the tip portions 144F and 146F are easily removed.

  In addition, in this example, as long as the tip portions 144F and 146F are latched at appropriate positions (first latch point P1 and second latch point P2) on the upper surface of the cap 72, the drip counter 10 is It will be naturally positioned by its own weight so that the above-mentioned hanging posture is stabilized. As described above, since the outer peripheral edge on the upper surface of the cap 72, the upper connection port 73, and the soft tube 4 are arranged concentrically, the first latching point P1 and the second hooking point can be placed at arbitrary positions on the outer peripheral edge. The latching point P2 can be determined. Therefore, there is no need to be particularly concerned about the position where the tip portions 144F and 146F are hooked on the upper surface of the cap 72.

  By the way, generally, the number of drops (nominal number of drops) corresponding to 1 ml of the infusion is predetermined for the drip tube. In recent years, the nominal number of drops has been standardized into two types: 20 drops per ml of infusion and 60 drops. When the nominal number of drops is different, the shape of the drip mouth may be different even if the shape, size, etc. of the drip tube are the same. For example, there are 60 drops per 1 ml of infusion, compared to 20 drops, the infusion opening has a smaller diameter, and the lower end surface of the infusion opening is located on the lower side. In this case, there is a possibility that the detection accuracy of the droplets varies due to the difference in the position of the lower end surface of the drip mouth.

  Therefore, in this example, as described above, the sensor 12 is made up of a plurality (four sets) of photoelectric sensors arranged along the direction in which each of the first arm portion 144 and the second arm portion 146 extends. It is going to be composed. By adopting this configuration, even if the lower end surface of the drip port 74 is on the lower side, it is sufficient to detect the droplet 9 by at least one set of the four photoelectric sensors. As much as possible, it is possible to prevent variations in detection accuracy of the droplets 9.

  As described above, according to the drip counter 10 having the above-described configuration, the first arm portion 144 and the second arm portion 146 are simply hooked on the upper surface of the cap 72, and the drip tube is formed by its own weight. 7 is attached. Therefore, when the infusion counter 10 is mounted on the infusion tube 7, it is possible to eliminate the need for a mechanical configuration for sandwiching the infusion tube as in the prior art.

  The infusion counter 10 according to the embodiment has been described above, but the present invention is not limited to the above-described form, and may be implemented in the following form, for example. In the following description, components that are basically the same as those in the above embodiment are denoted by the same reference numerals. Further, the description will focus on the parts that are different from the above embodiment, and the description regarding matters common to the above embodiment will be simply referred to or omitted as appropriate.

[Modification]
(1) In the above embodiment, the distal end portions 144F and 146F of the first arm portion 144 and the second arm portion 146 are configured to be hooked on the upper surface of the drip tube 7, but the upper portion is hooked on the upper surface. The part to be stopped need not be the tip part. For example, a latching portion (not shown) having the same configuration as the distal end portions 144F and 146F at a portion from the distal end portion to the base portion such as the middle of the first arm portion 144 and the second arm portion 146 is provided. It may be provided.

  (2) In the above embodiment, each of the tip portions 144F and 146F hooked on the upper surface of the drip tube 7 includes the flat surfaces 144P and 146P on the lower surface thereof. The shape does not necessarily include a flat surface. That is, the housing portion does not necessarily have to be hooked in a state of surface contact with the upper surface of the drip tube 7. As long as the stability when hooked can be ensured, the casing portion and the top surface of the drip tube 7 may be configured to be in point contact or line contact. The same applies to the hooking portion (1).

  (3) In the above embodiment, the sensor 12 functioning as a droplet detector is a so-called transmissive photoelectric sensor, but a reflective photoelectric sensor may be used. In this case, since the light emitting element and the light receiving element do not need to be arranged to face each other across the space in which the drip tube 7 is disposed, the degree of freedom in designing the casing is increased.

  (4) In the above embodiment, the tip portions 144F and 146F are completely separated from each other by the gap G. However, as long as the connecting portion at the center upper portion of the cap 72 is arranged without any trouble, for example, “ A U-shaped notch may be provided. Further, the space S between the first arm portion 144 and the second arm portion 146 does not need to penetrate from the front side to the back side, and either one side may be a wall surface.

  As is clear from the above (1) to (4), in the embodiment of the drip counter according to the present invention, the shape of the housing in which the sensor is incorporated is particularly limited as long as it has at least the following configuration. It is not something. That is, the first part of the housing in which the sensor is incorporated is hooked on the upper surface of the drip tube, and the second part of the housing located below the first portion is opposed to the drip tube. In the state, it may be configured to be attached to the drip tube by its own weight.

  (5) In the above embodiment, the outer peripheral edge of the upper surface of the drip tube on which the casing of the droplet detector (infusion counter) is attached is circular, but the casing is attached. In the drip tube, the outer peripheral edge of the upper surface may have a shape other than a circle such as a polygonal shape.

  Specifically, in the above embodiment, since the outer peripheral edge of the upper surface of the drip tube 7 is circular, the distal end portions 144F and 146F of the arm portions 144 and 146, which are part of the casing, are dominant arcs at the outer peripheral edge. 72MA is hooked at two points of the first hook point P1 and the second hook point P2, which are both end points of the 72MA, and a superior arc in a plan view with respect to the string 72C connecting both the hook points P1 and P2. The center of gravity is located on the 72MA side.

  On the other hand, when the outer peripheral edge of the upper surface of the drip tube is a polygonal shape (for example, a regular hexagonal shape), the outer peripheral edge of the polygon is the first peripheral part and the first peripheral part has a shorter peripheral length than the first peripheral part. The first point and the second point on the outer peripheral edge divided into two peripheral parts are set as two points corresponding to the respective latching points P1 and P2 in the embodiment, and the center of gravity is on the first peripheral part side. It may be configured to be positioned. In short, it is only necessary that the arrangement in the plan view of the two points and the center of gravity held by the drip tube satisfy the above-described relationship.

  (6) In the above embodiment, four sets of photoelectric sensors are used as the sensor 12 that reacts to the droplet 9, but five or more sets of sensors may be used as long as the design allows, or 3 It is also possible to use sensors of the set or less. In short, it is only necessary to have at least one set of sensors. Further, the sensor that reacts to the droplet is not limited to the photoelectric sensor, and for example, a sensor that detects the droplet by image processing using a camera may be employed.

  Further, in the above embodiment, four sets of photoelectric sensors are arranged along the direction in which each of the first arm portion 144 and the second arm portion 146 extends, but each arm portion 144, 146 is arranged. Alternatively, a plurality of sets of sensors may be arranged in parallel in the width direction. According to this configuration, since the detection region in the radial direction of the infusion tube can be expanded, even if the infusion tube is inclined or shaken, the detection accuracy of the liquid droplet is not reduced as much as possible. be able to.

  (7) In the above embodiment, the display 20 provided in the base 142 constitutes the information output unit. However, the present invention is not limited to this, and other configurations such as an LED lamp and an audio speaker may be adopted. Absent.

  (8) The infusion counter 10 of the above embodiment is used as an auxiliary instrument for medical personnel to adjust the number of drops when performing infusion, but the sensor 12 incorporated in the housing 14 is Of course, it is also possible to simply use it as a droplet detector that detects the droplet 9 that drops in the drip tube 7. When used as a droplet detector, the detection signal from the sensor 12 may be simply output. Such a droplet detector can be used, for example, as a component of a so-called dropping number control type infusion pump.

  Further, even when an infusion counter is configured, the above-described information output unit and droplet detector can be implemented separately. In short, the information output unit may be configured to output the detection of the droplet to a patient, a medical worker such as a doctor or a nurse, or a device used in cooperation.

  (9) In the above embodiment, the use of a natural drip-type drip was illustrated, but it can also be applied to other infusion therapies in which an infusion set including an infusion tube is used, such as a tube feeding method. Is possible.

  The present invention can be implemented in a mode in which various improvements, modifications, or variations are added based on the knowledge of those skilled in the art without departing from the spirit of the present invention. Moreover, you may implement with the form which substituted any invention specific matter to the other technique within the range which the same effect | action or effect produces.

7 Drip tube 9 Droplet 12 Sensor 14 Case 20 Display 71 Body 142 Base portion 144 First arm portion 146 Second arm portion S Space 144F, 146F Tip portion

Claims (6)

A sensor that reacts to droplets dripping in the drip tube;
A housing having a base, a first arm extending from the base, and a second arm facing the first arm across a space, the sensor being incorporated;
With
The first arm portion and the second arm portion are respectively hooked on the upper surface of the drip tube disposed in the space, and the droplet detection is performed on the drip tube by its own weight. vessel.   Each of the first arm portion and the second arm portion is bent in a direction in which the tip portions thereof are close to each other, and each of the tip portions is hooked on the top surface of the drip tube. The droplet detector according to claim 1.   When hooked on the drip tube, each of the first arm portion and the second arm portion has an outer peripheral edge of the upper surface of the drip tube that is longer than the first peripheral portion and the first peripheral portion. Dividing into a short second peripheral edge, the first and second points on the outer peripheral edge are respectively hooked, and the line segment connecting the first point and the second point is seen in a plan view, The droplet detector according to claim 1, wherein the center of gravity is located on the first peripheral edge side.   4. The device according to claim 1, wherein the base portion is in contact with the body of the drip tube when being attached to the drip tube, and the center of gravity is positioned below the contacted portion. The droplet detector according to item. The droplet detector according to any one of claims 1 to 4,
An information output unit that outputs information about the droplet according to a detection signal of the sensor;
An infusion counter characterized by comprising.   The infusion counter according to claim 5, wherein the information output unit is provided in the housing.

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