RU2089224C1 - Monitor for dropping infusion systems - Google Patents

Abstract

FIELD: medicine; medical engineering. SUBSTANCE: proposed monitor comprises indicator of optimum position of drop fall transducer. With help of this indicator user must set drop fall transducer in required position in relation to orifice of dropping tube of drop-dispensing bottle by directly placing monitor on drop-dispensing bottle. Next user must make sure, whether drop fall transducer reliably fixes moment of drop fall. Proposed monitor comprises casing, electronic circuit including, enclosed by casing, drop fall transducer and drop fall indicator. There are also provided device for securing monitor on drop-dispensing bottle and indicator of required position of drop fall transducer in relation to dropping tube orifice of drop-dispensing bottle. Said monitor securing device is structurally designed in such manner as to enable fixation of monitor on drop-dispensing bottle in any desired position and to make possible direct observation of drop fall in drop-dispensing bottle. Proposed monitor can be fitted into any existing dropping infusion systems for monitoring liquid administration rate, for calculating other infusion parameters, and for issuing warning signals as soon as prescribed infusion parameters transgress prescribed limits. EFFECT: proposed monitor ensures safer and more reliable use of dropping infusion systems. 7 cl, 6 dwg

Description

 The invention relates to medical equipment and can be used in conjunction with drip infusion systems to monitor the rate of fluid injection, calculate other parameters of the infusion, and also to give warning signals when certain infusion parameters go beyond the specified limits.

 A known monitor for drip infusion systems containing a drop sensor and an electronic circuit located in the housing, a monitor mounting device on an external support, and also a device for fixing the dropper, the design of the device for fixing the dropper provides a rigid fixation of the dropper in a predetermined position relative to the drop sensor (US Pat. U.S. N4525163, A 61 M 5/16, publ. 06/25/85).

 The disadvantage of such a monitor for drip infusion systems is the need for external support, which makes it difficult to use such a monitor with drip infusion systems in which a dropper is used rigidly connected to the needle. In addition, rigid fixation of the dropper in a predetermined position relative to the droplet sensor due to the design of the device for fixing the dropper limits the number of design options for droppers, which can be used together with such a monitor, because if the dropper design deviates from the set, the droplet sensor will not be installed in optimal position relative to the dropper and will not provide reliable registration of droplets in the dropper.

 A known monitor for drip infusion systems, containing a droplet sensor and a device for securing a droplet sensor on a dropper located in the first housing, as well as an electronic circuit and a monitor mounting device on an external support; located in the second case, the design of the device for securing the drop sensor on the dropper provides a rigid fixation of the drop sensor in a predetermined position relative to the dropper, and the drop sensor located in the second case (US Pat. No. 4,718,896, class A 61 M 5/00, G 01 F 1/00, publ. 12.01.88 g.).

 The disadvantage of such a monitor for drip infusion systems is the presence of a flexible cable between the first and second buildings, which makes it difficult to access the infusion system itself, especially when simultaneously infusing several fluids to one patient. In addition, the rigid fixation of the droplet sensor in a predetermined position relative to the dropper, due to the design of the device for securing the droplet sensor on the dropper, limits the number of design options for droppers, which can be used together with such a monitor, since if the dropper design deviates from the set, the droplet sensor does not will be installed in the optimal position relative to the dropper and will not provide reliable registration of droplets in the dropper.

 Closest to the claimed prototype is a monitor for drip infusion systems containing a drop drop sensor and an electronic circuit located in the housing, as well as a device for fixing the monitor on a dropper, the design of the device for fixing the monitor on a dropper provides a rigid fixation of the drop sensor in a predetermined position relative to droppers (US Pat. US N 4507112, A 61 M 5/00, publ. 02.26.85).

 The disadvantage of the prototype is the rigid fixation of the droplet sensor in a predetermined position relative to the dropper due to the design of the device for securing the monitor on the dropper, which limits the number of design options for droppers, which can be used together with such a monitor, since, if the dropper design differs from the set, the droplet sensor will not be installed in the optimal position relative to the dropper and will not provide reliable registration of droplets in the dropper.

 The claimed monitor for drip infusion systems provides high reliability for measuring infusion parameters when working together with droppers having various designs.

 This goal is achieved by the fact that in the monitor for drip infusion systems, containing a drop drop sensor and an electronic circuit located in the housing, as well as a device for fixing the monitor on a dropper, an indicator is also introduced for the optimal position of the drop drop sensor relative to the cut of the dropper tube, the design of the fixation device the monitor on the dropper provides a constant opportunity to fix the drop drop sensor in the desired position relative to the cut of the drip tube, regardless of t the design of the dropper, as well as the ability to directly observe the droplets in the dropper, after installing a monitor for the drip infusion systems on the dropper, the electronic circuit including a droplet drop indicator that is installed so that the user can simultaneously observe the droplet drop in the dropper and indicate the drop signal drops.

 The essence of the invention consists in installing, using an indicator of the optimal position of the drop drop sensor, the drop drop sensor in the position required to reliably fix the moment of drop drop relative to the cut of the dropper tube of the dropper directly by the user when fixing the monitor for drip infusion systems on the dropper, as well as to control the reliability of fixation by the user drop drop sensor of the moment of drop drop.

 The presence of the specified set of features of the claimed invention provides reliable detection of droplet drops in a dropper, regardless of the design of a specific dropper, in conjunction with which a monitor for drip infusion systems is used, by installing a droplet drop sensor in the position required to reliably record the moment of dropping, relative to the cut of the dropper dropper tube directly by the user before starting the monitor. Thus, the reliability of recording drop drops, and, accordingly, the reliability of the measured parameters, corresponds to the reliability and reliability achieved in monitors for drip infusion systems having a drop drop sensor, the design of which is designed to work with droppers having a certain design. The ability of the user to control the reliability of the fixation by the drop sensor of the drop moment of the drop of the drop increases the reliability of the measurement of the infusion parameters for the drip infusion systems when working with droppers of various designs.

 The monitor for drip infusion systems contains (Fig. 1, 2) an electronic circuit 1, (Fig. 3) located in the housing 2, a device 3 for fixing the monitor on a dropper and a pointer 4 for the desired position of the housing relative to the dropper, and the device 3 for fixing the monitor on a dropper contains a recess 5, to accommodate a dropper in the housing 2, a part of the surface of which is formed by support planes 6 located at an angle α to each other, and the surface 7 of the support planes 6 has a high coefficient of friction, a spring 8 fixed by a hinge 9 in the housing 2, as well as the latch 10, mounted on the housing 2 with rivets 11. The electronic circuit 1 contains a series-connected keyboard 12, a microcomputer 13 and a display 14, an audio signal 15, a timer 16, and a drop sensor 17, including an LED 18, a photodiode 19 and a cover 20, wherein the input of the audio signal 15 is connected to the second output of the microcomputer 13, the output of the drop drop sensor 17 is connected to the second input of the microcomputer 13, the LED 18 and the photodiode 19 are installed in the recess 5 in the plane 21 passing through the angle bisector oporn alpha mi 6 planes, and the cover 20 mounted on the housing 2 by a hinge 22, has a shape and reflectance of the inner surface 23, which in the closed position provides the optical channel transmitter circuit 17 drops fall between the LED 18 and the photodiode 19.

 The pointer 4 of the desired position of the housing relative to the dropper can, for example, be made in the form of risks on the housing 2 calibrated relative to the cut of the dropping tube of the dropper.

 On supporting surfaces 6, for example, a soft rubber layer 24 may be glued, the thickness of this layer compensating for the conical shape of the dropper.

 The cover 20, for example, may have a shape that, ensuring the operability of the drop drop sensor 17, leaves a portion of the dropper closed, through which the user can directly observe the drop of droplets in the dropper.

 All monitor elements for drip infusor systems can, for example, be so structurally placed in case 2 that the center of gravity of the monitor will be located on the axis of the dropper having the expected diameter when installing the monitor for drip infusion systems on such a dropper, as low as possible.

 Keypad 12 contains a digital dialing field 50, as well as buttons 51, 52, 53, 54, 55, 56, 57 for controlling the modes "INFUSION SPEED", "DECLINE INFUSION SPEED", "INFUSION TIME", "TOTAL AMOUNT OF SPILLED LIQUID", " ENTERING ALLOWABLE PARAMETERS "," START OF MONITORING "," END OF MONITORING "respectively.

 The display 14 contains a multi-digit indicator 62, as well as mnemonic indicators 63, 64, 65, 66, 67, 68, 69 "INFUSION SPEED", "DECLINE INFUSION SPEED", "INFUSION TIME", "TOTAL AMOUNT OF SPILLED LIQUID", "INPUT PARAMETERS "," FALLING DROPS "," ACCIDENT "respectively.

A monitor for drip infusion systems operates as follows, FIG. 4. Using the button 55 "ENTER ADMISSIBLE PARAMETERS" put the monitor into the mode of permissible infusion parameters, block 81, FIG. 4, and using the buttons of the digital dialing field 50 and the buttons 51, 52, 53, 54 for controlling the "INFUSION SPEED", "DECLINE INFUSION SPEED", "INFUSION TIME", "TOTAL AMOUNT OF SPILLED LIQUID" modes, enter the desired allowable values v _D , Δv _D , T _D , Σ _D, respectively, block 82, FIG. 4. When entering these values, the microcomputer 13 provides an indication of the entered values on the display 14 using a multi-digit indicator 62 and mnemonic indicators 63, 64, 65, 66, respectively. Next, the infusion drip system is filled with medicinal fluid and a monitor for drip infusion systems is installed on the dropper 110 of this infusion drip system using the monitor fixing device 3 on the dropper. At the same time, using the hinges 9, 22, the spring 8 and the cover 20 are removed to the side, a dropper 110 is inserted into the recess 5 and the cut 111 of the droplet tube 112 of the dropper 110 is combined with the pointer 4 of the desired monitor position relative to the dropper. Then, with a spring 8, a dropper 110 is pressed against the supporting planes 6 of the recess 5 and the spring 8 is fixed in this position with a latch 10 fixed to the housing 2 with rivets 11. Thus, the monitor for drip infusion systems can be mounted on droppers having different designs . After that, the monitor for drip infusion systems is held on a dropper 110 due to friction between the surface 7 of the supporting planes 6, which has a high coefficient of friction, and the side surface 113 of the dropper 110. If the dropper 110 has conical side surfaces 113, then the taper of the side surfaces 113 of the dropper 110 compensated by elastic deformation of the soft rubber layer 24 deposited on the supporting surfaces 6 of the recess 5. After installing the monitor for the drip infusion systems on the dropper 110, the cover 20 is closed. Since the supporting planes 6 of the recess 5 are located at an angle to each other, then, given that the dropper 110 is located in the plane 21 which is the bisector of the angle. Accordingly, in this case, the optical channel between the LED 18 and the photodiode 19, closed by the inner surface 23 of the cover 20, passes through the axis 114 and the dropper 110. Thus, the LED 18 and the photodiode 19 of the drop drop sensor 17 are installed relative to the cut 111 of the droplet tube 112 of the dropper 110 in such the position required to reliably fix the moment of drop 115 dropping in the dropper 110. Accordingly, this provides the same probability of fixing the moment of dropping 115 drops in the dropper 110 as with the sensor drop drops, the design of which is associated with the design of this dropper 110. After installing the monitor for the drip infusion systems on the dropper 110, press the 56 "START MONITORING" button. The appearance of the “START” signal generated by pressing the “START MONITORING” button 56 is analyzed by block 83, FIG. 4. When the "START" signal appears, the values V ₁ Δv, T, Σ are stored that are stored in the main memory of the microcomputer 13 from the previous infusion, the "WORK" flag is set, and the timer 16 is remembered, after which the "START" flag is reset, block 84, FIG. 4. In the absence of the “STOP” signal, which is generated when the “MONITORING END” button 57 is pressed, and if the “OPERATION” flag is present, the signal from the drop drop sensor 17 is analyzed, blocks 85, 87, 88, FIG. 4. When droplet 115 falls in the dropper 110, it blocks the optical channel between the LED 18 and the photodiode 19, as a result of which a “DROP” signal is generated at the output of the droplet drop sensor 17. When the signal “DROP” appears, the microcomputer 13 calculates the diffusion parameters, blocks 89, 90, FIG. 4 and provides an indication of the results obtained, as well as the moment the drop falls, on the display 14 using a multi-bit indicator 62 and mnemonic indicators 63, 64, 65, 66 and 68, and the choice of the infusion parameter displayed on the multi-bit indicator 62 is provided by pressing one of the buttons 51, 52, 53, 54 "INFUSION SPEED", "DECLINE INFUSION SPEED", "INFUSION TIME", "TOTAL AMOUNT OF SPILLED LIQUID, respectively. The algorithm of operation of the microcomputer 13 with the display 14 was determined by the construction of specific microcomputers 13 and the display 14, widely used in practice, and therefore not shown. Since the cover 20 of the drop drop sensor 17 leaves part of the dropper 110 open, the user can directly observe the drop of drop 115 in the dropper 110 and, by comparing the moments of drop 115 falling in the dropper 110 and the “FALL DROP” signal appearing on the mnemonic display 68, monitor the operation of the monitor for drip infusion systems. If necessary, an audible alarm for dropping 115 in the dropper 110 can be entered using the sound signal 15. Then, the calculated infusion parameters Dv, T, Σ are compared with the permissible infusion parameters Dv _D , T _D , Σ _D blocks 91, 92 in the microcomputer 13. 93, FIG. 4. In the event that at least one of the monitored infusion parameters exceeds the permissible value, the ALARM flag is set, block 95, FIG. 4. If all monitored infusion parameters do not exceed the permissible values, then the ALARM flag is cleared, block 94, FIG. 4. Then the algorithm returns to its original point. If the “DROP” signal did not appear, then the microcomputer 13 calculates the infusion rate V _A relative to the last moment the “DROP” signal appears and calculates the deviation of the infusion rate Δv _A from the permissible value of the infusion speed V _D , blocks 96, 97, FIG. 4. If the calculated deviation of the infusion rate Δv _A exceeds the permissible deviation of the infusion rate Δv _D then the "ALARM" flag is set, block 99, FIG. 4. According to this flag, the microcomputer 13 provides an indication on the display 14 of the signal "EMERGENCY" using the mnemonic indicator 69 "EMERGENCY" and an audible alarm using the audible signal 15. The algorithm of operation of the microcomputer 13 with the display 14 and the audible signal 15 is not shown. In this case, the audio signal 15 may generate an audio signal "ALARM" different from the audio signal "ALARM", for example, by the frequency of the sound or the duration of the audio signals. If the calculated deviation of the infusion rate Δv _A does not exceed the permissible deviation of the infusion rate Δv _D, then the "ALARM" flag is cleared, block 100, FIG. 4. This ensures the termination of the indication of the "EMERGENCY" signal, for example, when the liquid flow in the dropper 110 is restored. Next, the algorithm returns to the starting point. When the button 57 "END OF MONITORING" is pressed, the signal "STOP" is generated, which is analyzed in the microcomputer, block 85, FIG. 4. When the “STOP” signal appears, the “OPERATION”, “ALARM” and “ALARM” flags are removed, block 86, FIG. 4. Thus, when the button 57 "END OF MONITORING" is pressed, the last calculated values of the infusion parameters are stored in the main memory of the microcomputer 13, which allows the user to view them on the display 14 using the buttons 51, 52, 53, 54 "INFUSION SPEED", "DISCONNECT SPEED INFUSIONS "," TIME OF INFUSIONS "," TOTAL AMOUNT OF SPILLED LIQUID ", respectively, and the alarm about the parameters beyond the permissible limits is removed. To remove the monitor for drip infusion systems, release the latch 10 and remove the spring 8, as well as the cover 20. Then remove the monitor for drip infusion systems from the dropper 110.

 In the operation algorithm of the microcomputer 15 shown in FIG. 4, a check can be introduced in blocks 91, 92, 93, which the interpretation of an acceptable parameter equal to zero will be interpreted as removing this parameter from monitoring (control).

 Currently, the most widely used design is a dropper with a protruding belt at the junction of the upper and lower parts of the dropper, in which a fixing grid is fixed. In this case, the monitor for drip infusion systems comprises, FIG. 5, 6, electronic circuit 1, FIG. 3, located in the housing 2, the device 3 for fixing the monitor on a dropper and a pointer 29 for the desired position of the droplet drop sensor relative to the dropper, the device 3 for fixing the monitor on a dropper contains a recess 5, for placing the dropper 110 in the body 2, an additional recess 30, for placing the belt 116 droppers 110, in the upper part of the mounted stops 31, located on both sides of the recess 30, on the lower surfaces 32 of which there are supporting planes 33 located at an angle β to each other, so that the intersection line 35, 36 the supporting planes 33 lie in the same plane 37 and form the same angles g to the bottom surface 32 facing each other, and also contain elastic jaws 38 mounted in the recess 5 opposite each other, the supporting surfaces 39 of which are located at the same angle to each other symmetrically relative to each other a plane 37 passing through the intersection lines 35, 36 of the support planes 33, in FIG. 5, 6 are not shown. The electronic circuit 1 contains a keyboard 12, a microcomputer 13 and a display 14 connected in series, an audio signal 15, a timer 16, and a drop drop sensor 17 including an LED 18 and a photodiode 19, the audio signal 15 being connected to the second output of the microcomputer 13, the sensor output 17 drops falling is connected to the second input of the microcomputer 13, the output of the timer 16 is connected to the third input of the microcomputer 13, the LED 18 and the photodiode 19 are mounted in a ferrule 40, which can move relative to the housing 2 when additional force is applied to the protrusion 41 of the ferrule 40 per second even slides of the guides 42 along the grooves 43, the LED 18 and the photodiode 19, taking into account the installation of the holder 40 in the housing 2, are located in a plane 37 passing through the intersection lines 35, 36 of the supporting planes 33 on opposite sides of the recess 5. The fixation of the position of the holder 40 relative to the housing 2 is due to friction between the contacting surfaces of the guides 42 and the grooves 43.

 The pointer 29 of the desired position of the drop drop sensor relative to the dropper, for example, can be aligned with the upper surface of the holder 40 and calibrated relative to the cut 111 of the drip tube 112 of the dropper 110.

 Structurally, the monitor elements for drip infusion systems can be replaced in the housing so that the center of gravity of the monitor will be located on a line located in a plane 37 passing through the intersection lines 35, 36 of the reference planes 33 and symmetrically with respect to the opposite sides of the recess 5, as low as possible .

On the clip 40, elastic jaws 44 can be mounted opposite each other, the supporting surfaces 45 of which are located at the same angle g _{2 to} each other symmetrically with respect to the plane 37 passing through the intersection lines 35, 36 of the supporting planes 33, the LED 18 and the photodiode 19 being closed with jaws 44, at the same time, the design of the jaws 44 allows the user to observe a direct drop of the droplet 115 in the dropper 110.

 Keypad 12 contains a digital dialing field 50, as well as buttons 58, 59, 60, 61, 56, 57, 57 for controlling the modes "" ENTER THE REQUIRED INFUSION SPEED "," ENTER THE INFLUENCE SPECIFIC DECLINE "," ENTER THE INFUSION TIME LIMIT "," ENTER THE LIMIT TIME QUANTITIES OF SPILLED LIQUID "," START OF MONITORING "," END OF MONITORING "respectively.

 The display 14 contains digital multi-digit indicators 70, 71, 72, 73 "INFUSION SPEED", "DECLINE INFUSION SPEED", "INFUSION TIME", "TOTAL AMOUNT OF SPILLED LIQUID" responsibly, as well as mnemonic indicators 68, 69, 74, 75, 75 , 77 "DROP DROP", "EMERGENCY", "INPUT OF THE DESIRED INFUSION SPEED", "INPUT OF THE ACCEPTABLE DEVIATION OF THE INFUSION SPEED", "INPUT OF THE LIMIT TIME FOR INFUSION", "INPUT OF THE EXTENT QUANTITY OF SPILLED LIQUID.

With this design, the monitor for drip infusion systems works as follows. Using the buttons 58, 59, 60, 61 to control the modes "ENTER THE DESIRED INFUSION SPEED", "ENTER THE ACCESSIBLE DEVIATION OF THE INFUSION SPEED", "ENTER THE INFLUENCE TIME LIMIT", "ENTER THE LIMIT QUANTITY OF SPILLED LIQUID" and enter the desired dial values of v _D , Δv _D , T _D , Σ _D, respectively. In this case, the entered values are displayed on the display 14 using digital multi-digit indicators 70, 71, 72, 73 and mnemonic indicators 74, 75, 76, 77, respectively. The operation algorithm of the microcomputer 13 is the same as described above. Next, the drip infusion system is filled with drug liquid and a monitor for drip infusion systems is installed on the dropper 110 of this infusion system using the monitor fixing device 3 on the dropper. In this case, a monitor for drip infusion systems is put on the dropper 110 so that the belt 115 enters the recess 30, and its upper surface 117 symmetrically relative to the axis 114 of the dropper 110 abuts against the supporting surfaces 33 of the stops 31 located on both sides of the recess 30. In this case, the elastic the jaws 38, 44 encircle the lateral surface 117 of the dropper 110. Since the supporting planes 33 are located at an angle β to each other, and the intersection lines 35, 36 of the supporting planes 33 lie in the same plane 37, the axis 114 of the dropper 110, with the upper surface symmetrical in support The tee 117 of the belt 116 on the supporting plane 33, is located in the plane 37. The elastic lips 38, 44, the supporting surfaces 39, 45 of which are located at angles g ₁ , γ _2, respectively, to each other, symmetrically with respect to the plane 37, contribute to this. The scatter of the diameters of the belt 116 for droppers having various designs is compensated by the inclination of the lines 35, 36 of the intersection of the support planes 33 at an angle γ to the lower surface 32 of the stops 31. Thus, the monitor for drip infusion systems is mounted on the dropper 110 so that its axis 114 lies in the plane 37 along the recess 5 of the housing 2. Since the optical channel between the LED 18 and the photodiode 19, taking into account the installation of the holder 40 in the housing 2, is located in the plane 37, it turns out that the optical channel passes through the axis 114 of the dropper 110. Then moving the holder 40 over the protrusion 41 combine the upper surface 44 of the holder 40, which is an indicator 29 of the desired position of the drop drop sensor and calibrated relative to the cut 111 of the droplet tube 112 of the dropper 110, with a cut 111 of the droplet tube 112 of the dropper 110 Thus, the LED 18 and the photodiode 19 of the drop drop sensor 17 are installed relative to the cut 111 of the drop tube 112 of the dropper 110 in a position that is required to reliably fix the moment of drop 115 falling in the dropper 110, as with the drop drop sensor, the design of which coupled with the design of this dropper 110. Further, the monitor for drip infusion systems works in the same way as described above.

 The device 3 for fixing the monitor on a dropper may have a different design, for example, relying on the upper surface of the dropper 110, as shown in US Pat. U.S. N 4507112, CL A 61 M 5/00, publ. 03/26/85

 Microcomputer 13 may have a third output, FIG. 3, to which a fluid flow rate regulator in a drip infusion system, for example, as shown in US Pat. U.S. N 4507112, CL A 61 M 5/00, publ. 03/26/85 or as shown in US Pat. EPO N 0321996, class A 61 M 5/14, publ. 06/28/89

 The technical and economic effect of the use of the claimed invention consists in the convenience of operating the monitor for drip infusion systems in medical practice, since it provides the measurement of infusion parameters with the same reliability when working together with droppers having various designs. Moreover, the reliability of measuring infusion parameters in the proposed monitor for drip infusion systems corresponds to the reliability of measuring infusion parameters provided by monitors for drip infusion systems currently used in medical practice and designed to work together with a dropper having a certain design. At the same time, the claimed monitor for drip infusion systems has small dimensions and weight and easily fits in the pocket of a user's bathrobe. The possibility of operational monitoring by the user over the operation of the monitor for drip infusion systems, by simultaneously monitoring the direct drop of a drop in the dropper and indicating the signal from the drop drop sensor, significantly increases the credibility of the claimed monitor for drip infusion systems.

Claims (7)

 1. A monitor for drip infusion systems, made in the form of a housing with an electronic circuit located inside it, comprising a droplet drop sensor and provided with means for fixing the housing on a dropper, characterized in that the monitor housing is provided with a pointer to the position of the monitor housing relative to the cut of the dropper tube.  2. The monitor according to claim 1, characterized in that the window for visual observation of the drop falling is made in the monitor case.  3. The monitor according to claim 2, characterized in that the drop drop sensor has an indicator placed in front of the window for simultaneously monitoring the drop drop and the readings of the drop drop sensor.  4. The monitor according to claim 1, characterized in that the electronic circuit provides an electrical output for connecting to a fluid flow rate controller in a drip infusion system.  5. The monitor according to claim 1, characterized in that the means for fixing the housing on the dropper includes an elastic element for attaching the housing to the dropper due to the frictional force between them.  6. The monitor according to claim 1, characterized in that the drop drop sensor is enclosed in a separate housing and placed in the monitor body in the guides with the possibility of movement relative to it, and the monitor body position indicator relative to the cut of the dropper tube of the dropper is made on the drop drop sensor body.  7. The monitor according to claim 6, characterized in that the guides are provided with an elastic element for mounting the sensor housing due to the frictional force between it and the monitor body.

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