RU2176526C1 - Device for metered drip infusion - Google Patents

Abstract

FIELD: medical equipment, particularly, disposable system for intravenous infusions. SUBSTANCE: device has flow chamber and discharge pipeline. Chamber accommodates hydrodynamic drip indicator in the form of body with flow-through channel whose one end has inlet communicating directly or through additional hole with chamber cavity, its other ends has outlet made as hydrodynamic seal in the form of hole flow-through under definite pressure with preset minimal hydrostatic working level. In this case, outlet may be made in the form of slit-like or longitudinal hole at channel outlet, and part of discharge pipeline is bent in the form of spiral. EFFECT: simplification of device design with simultaneous increasing of resolving power of registration of minor volumes of fluid and higher accuracy of indication of flow rate of drip infusion. 6 cl, 6 dwg

Description

 The invention relates to medical equipment, namely to disposable systems for intravenous infusion.

 A device for intravenous drip infusion, including longitudinally moving rods to change the rate of expiration of the liquid drug to obtain a certain concentration of the solution [1].

 A device is also known that includes a fluid flow regulator for installation using visual or chronometric control of the required rate of drip infusion [2]. The disadvantages of the known designs of drip infusion regulators are the low resolution in the registration of small volumes of liquid, the complexity of the chronometric control and the complexity of the design.

 The objective of the invention is to create a simple to use, high-resolution registration of small volumes of fluid structures, with convenient and accurate indication on a measuring scale of the rate of drip infusion per unit time.

 This problem is solved in that the device for a metered drip infusion, including a flow chamber 1 and a discharge pipe 5, has a hydrodynamic drip pointer 7 in the chamber lumen in the form of an extended body with a flow channel 8, at one end having an input 9 communicating directly or via an additional hole 14 with a clearance 4 of chamber 1, and at the other end, exit 10, which is a hole with a specified minimum hydrostatic working level only under a certain hydrostatic pressure 17 and is a hydrodynamic shutter. In this case, the output 10 can be made in the form of a slit-like hole 13, a longitudinal hole in the housing of the hydrodynamic pointer at the outlet of the channel 8, or the holes are made in a reciprocating material at the exit of the channel 8.

 In FIG. 1 shows a device for dosed drip infusion in section. In FIG. Figures 2 and 3 show cross-sectional variations of a hydrodynamic drip indicator. In FIG. 4, 5 shows the principle of operation of the hydrodynamic drip indicator in the system for intravenous infusion, in the context. In FIG. 6 shows a variant of a movable hydrodynamic drip pointer, made in the form of a "float" with a "float reservoir", in section.

 The device for dosed drip administration (Fig. 1) is made in a standard device for drip administration, which has a flow chamber 1 or a reservoir with an inlet pipe 2, made also in the form of a perforating needle with a drip tube 3 extended into the lumen 4 of the chamber 1 for the formation of a drop or an inlet pipeline, with an outlet pipeline 5 and a fluid flow regulator 6. This device is the main element of intravenous infusion systems and is designed to visually control the speed of the drip in maintaining, filtering the solution when appropriate filters are introduced into the chamber lumen.

 For fast and accurate dosing per unit time of the rate of drip infusion, the device for infusion is equipped (Fig. 1, 2, 3) with a hydrodynamic drip indicator 7, made in the lumen 4 of chamber 1. This device is intended for installation and visual control of the rate of drip infusion per unit time on a calibrated measuring scale. The functional purpose of the drip indicator 7 is realized by creating a movable hydrostatic column of liquid, the height or level of which characterizes and determines with high accuracy the number of solution drops or small volumes of flowing solution per unit time in the range from one drop per minute or more until the moment of jet injection.

 The hydrodynamic drip indicator 7 (Fig. 1, 2, 3) is a housing, fixed or fixed in the lumen of chamber 1, with a flow channel 8 open at one end in the form of an entrance 9 into the air or lumen 4 of chamber 1, and having at the other end output 10 in the form of a hydrodynamic shutter. The body of the pointer with the channel 8 passing inside it is made as an extended device, where the length exceeds the diameter for the possibility of visual registration of the increased level or height of the water column in its lumen with the introduction of minimal and small volumes of liquid comparable to the volume of a hanging drop. The inlet 9 of the drip indicator 7 is designed to supply a solution to the channel 8 and at the same time communicating the lumen of the channel 8 with the air or the lumen 4 of the chamber 1. When the inlet 9 is tightly connected to the drip tube 3 or the punch needle, the drip pointer is supplied (Fig. 4, 5) an additional separate hole 14, which opens the lumen of the channel 8 into the internal environment of the chamber 1. In all cases, a necessary condition is a message at the entrance or from one end of the lumen of the channel 8 and the lumen 4 of the chamber 1, which ensures independent hydrostatic movement cally liquid column in the upright channel 8 during operation. For visual control of the height of the liquid column (Fig. 2), the drip pointer 7 is equipped with a calibrated measuring scale 11 of the drip infusion rate per unit time, or the speed can be recorded (Fig. 6) according to the level of the moving hydrodynamic drip pointer 7 relative to the fixed parts of the device. Fixed to the wall of the drip tube or the needle-punch of the chamber 1, the drip pointer 7 is made of a transparent malleable or rigid material (glass, plastic, polymer) and may have a hydrophobic coating to increase the sensitivity of the device. The case of the droplet pointer 7 itself can be made as a hydrodynamic device, where differences in the diameter of the device or the diameter of the channel 8 over time disproportionately change the height of the water column in the channel’s lumen from the same droplets of solution, which reduces to a reasonable extent the length of the channel 8 and the length of the droplet pointer 7, which changes the sensitivity of the method in any range of drip feed rate. One of the options for such a hydrodynamic device is a drip indicator 7 (Fig. 3), the part of the wall of which at the outlet is made of a porous membrane that is permeable only under pressure with differences in diameter along the channel 8. This also gives a not directly proportional dependence of the fluid flow on the column height due to differences in the area of the filtering membrane over, moreover, the membrane itself with compression pores functions as a hydrodynamic shutter.

 The working element of the device 7, providing the occurrence and change in the level or height of the water column in the extended channel 8 (Fig. 2, 4, 5) of the drip pointer 7, is the output 10 of the hydrodynamic drip pointer, made as a hydrodynamic shutter at the outlet of channel 8. This an element of the device provides the formation of a mobile hydrostatic column of liquid in channel 8 and a direct highly sensitive dependence of its level or height to small volumes in the form of a drop or small volumes with a continuous flow of liquid, falling or passing through the drip pointer 7. This enables the quantitative registration of the drip infusion rates through the system. In addition, the output 10 is designed as a device that provides a dependence of the flow rate at the outlet on the height of the hydrostatic column of liquid. A simple output device in the form of a hydrodynamic shutter is a flow tank with an open entrance, a bottom and an exit, made as a series of holes in the wall of an extended tank, and it is possible with different diameter of the holes, where at least one of the holes creates a minimum hydrostatic level of the liquid, due to, for example, surface tension films. With an increasing rate of infusion and an increase in the height of the water column of liquid in the tank, the liquid will discharge or exit sequentially from holes made at different levels until the total area of the holes corresponds to the incoming volume of liquid, which will correspond to a certain visible level of water column. This is a scaled water level and will roughly reflect the fluid flow rate.

 For accurate registration of small volumes of liquid, taking into account surface tension forces at such small volumes, the output 10 of channel 8 (Figs. 2, 4, 5) can be made in the form of a slit-like opening, which can be in the form of an open slot-like opening in the device’s body opposite to the entrance to the end of the housing and a closed hole in the form of a sliding hole in the reciprocating material 12 (Fig. 4) at the outlet of the housing. So, with an open slotted hole, the liquid level in channel 8 is maintained by the surface tension force at the interface, and the hydrostatic pressure is distributed over a large area of the retained surface tension film, which allows you to change the fluid flow depending on the level of the hydrostatic column. In the embodiment of a closed hole that holds the liquid column due to the closed edges of the hole, the main characteristic of the slit-like hole in the reciprocating material 12 is the property to increase the size of the hole due to the extension of the edges depending on the hydrostatic pressure of the liquid column, which increases the output throughput with increasing flow liquids. Thus, these types of holes, made in the form of an exit from channel 8, have the ability to hold a minimum certain level of water column (level of hydrostatic pressure) due to surface tension forces with an open hole and the elastic properties of the material with closed (closed) hole edges. The resulting liquid column 18 in channel 8 is the minimum hydrostatic working level of the hydrodynamic shutter.

 Thus, the value of the hydrostatic column can be set by changing the nature of the hole or the properties of the material in which the hole is made, which becomes flowing with an increase in the minimum hydrostatic working level, for example, when a small volume of liquid is supplied. The use of an outlet that creates a hydrodynamic barrier and a visible minimum hydrostatic operating level allows with high accuracy, at least 1-5 drops per minute, to set the rate of drip infusion. The volume of the minimum hydrostatic level itself can be 1-3 drops of a solution that create a visible column of liquid in the channel 8. This is the resistance to the flow of liquid at the outlet that does not allow this volume to pass through. The next property of the hole options at the outlet of the channel 8 is the possibility of changing the fluid flow depending on the size of the hydrostatic column of liquid 18. Thus, with an open slit-like opening, the increase in fluid flow obeys the physical law of the direct dependence of the speed of passage and, accordingly, the volume of liquid through the hole on the pressure value of the hydrostatic column . With increasing pressure, the flow rate of the liquid at the outlet increases, including due to greater pressure on the film of surface tension in the slit-like opening. An increase in the fluid flow through the hole in the reciprocating material is achieved by expanding the hole from increased pressure on the compliant walls, which allows the use of an opening with sliding walls to create a water column level dependent on the fluid flow rate.

 Thus, the output 9 of the hydrodynamic indicator 7, made in the form of a slit-shaped or longitudinal hole (as an option in the return-deforming material at the outlet of the channel 8 in the form of a sliding hole), allows to accurately register various modes and rates of drip infusion per unit time and in a wide range. To choose the best option, you can use the geometric properties of the holes to select the surface area of the film of surface tension, in a different form, combine this with the reciprocating properties of the material at the output of channel 8, which allows you to use a variety of options for output 9 to create a hydrodynamic shutter. To exclude the "drop droplet effect" (Fig. 4), the drip pointer 7 can be made outside of the continued drip tube 3 or the supply pipe in the form of a perforating needle at the inlet, the exit of which can be below the minimum hydrostatic working level of the pointer. The principle of operation of the device is as follows (Fig. 4, 5). The device 1 is connected to the container 15 with the initial solution 16 through a punch needle, the regulator 6 opens, and the liquid begins to flow through the input pipe 2 or the drop tube 3 into the channel 8 of the drip indicator 7. After filling the system and equalizing the pressure in the lumen 4 in the channel 8 of the drip pointer 7 remains only the visible level of the water column 17, which is held either by a film of surface tension, or closed pliable edges of the hole. These few drops 17 (1-3 drops are optimal) of the solution make up the minimum hydrostatic working level, which is held at the outlet, which works as a hydrodynamic shutter. After the start of infusion and the introduction of another drop of liquid or a small volume during continuous infusion, in case of using an internal pipeline, the level of the water column increases in proportion to the entered volume, and the hydrostatic pressure at the outlet 10 is successive. In this case, either the surface tension force is overcome or the slit-like opening is opened 13 in the back-deforming material 12 and the liquid begins to pass through the drip indicator 7. After the exit of a part of the volume at a certain time interval fluid from the lumen 8 of the device 7, the hydrostatic pressure decreases and the output 10 again becomes stagnant until the next injection. With an increased rate of drip infusion, the increasing level of the water column increases the rate of fluid passage through the hole or exerts greater pressure on the walls of the sliding hole, increasing the degree of opening of the hole for increased fluid flow. At the same time, there is always a mismatch between the throughput of the hole and the volume of the fluid flow, which keeps the water column at a certain level. At a low rate of drip infusion, the leading one is the acceleration of the flow through the hole due to the increase in pressure, which allows the use of only a slit-like hole and a barrier in the form of a surface tension film. With large pressure figures, it is advisable to use output 10 in the variant of the sliding hole. After equilibrium is established, this value of the hydrostatic column of liquid in channel 8 makes up the conditional value of the rate of drop infusion or the flow rate of small volumes of liquid, calibrated in the form of a measuring scale. Thus, the output 10 of the device 7, made in the form of a hydrodynamic shutter, allows you to quickly and relatively stably balance the output flow rate and the corresponding fluid flow rate due to autonomous predetermined self-regulation using several physical factors.

 When the infusion rate decreases, the hydrostatic pressure decreases and, accordingly, the size of the sliding opening decreases, the flow rate decreases from the pressure decrease, and finally, the outlet 10 closes when the minimum operating level is reached. The principle of operation of the membrane drip pointer is similar, where one of the factors includes the increase in the area of the filtering membrane with an increase in the liquid column, which well compensates for the increase in the liquid flow.

 Thus, the output 10, made as a hydrodynamic shutter in the form of a slit-like closed or sliding opening in the device 7, stabilizes the ratio of the inflow and outflow under any infusion regimes depending on the height of the hydrostatic column of liquid, which can be an indicator of the rate of drip infusion. Alternatively, the drip pointer can be movable (Fig. 6) in the form of a float with buoyancy properties even with maximum filling of the tank. The movable drip pointer 7, made in the form of a float, is equipped with a float chamber 20, which is filled to the upper edge through the outlet of the drip pointer and is constantly maintained at this level 21. The principle of operation of the movable pointer is the same, with the only difference being that an increased water column in channel 8 increases the mass of the device and the drip pointer is more immersed in the liquid, and due to buoyancy and buoyancy, the hydrostatic level 22 of the water column in channel 8 is always preserved in comparison with a liquid level of 21 in the float chamber. This working hydrostatic level is the factor that opens output 10 and tends to equalize fluid levels by the type of communicating vessels. In this case, only the output 10 in the form of a sliding hole can be used in this device. The degree of immersion of the drip pointer and is used as a conditional scale for the rate of drip infusion. An additional device that creates convenience in work and prevents complications associated with disconnecting the system from the patient is a portion of the outlet pipe that is curved in the form of a reciprocating deformable figure 19 of a spiral type. In case of unintentional tension of the system, the bent outlet pipe is stretched due to the back-deformable bend and prevents the system from disconnecting.

 This is especially important when transporting the patient. This device in the form of a system with a hydrodynamic drip pointer and a spiral bent outlet pipe is a simple technical device that is convenient to use for estimating the rate of drip infusion over a wide range and with high accuracy, which can be widely used in clinical practice.

Sources of information
1. A.S. N 1741807, EP 59694.

 2. A.S. N, 121571.

Claims (6)

 1. A device for a metered drip infusion, including a flow chamber and an outlet pipe, characterized in that in the chamber lumen a hydrodynamic drip pointer is made in the form of a housing with a flow channel having an entrance in communication with the chamber lumen and an exit in the form of a hydrodynamic shutter, which is a hole flowing under a certain hydrostatic pressure with a given minimum hydrostatic operating level.  2. The device according to claim 1, the device characterized in that the output of the hydrodynamic drip pointer is made in the form of a slit-like open hole.  3. The device according to claim 1, the device characterized in that the output of the hydrodynamic drip pointer is made in the form of a slit-like closed sliding opening in a reciprocating material.  4. The device according to claim 1, characterized in that part of the wall of the housing is made of a permeable membrane under pressure.  5. The device according to claims 1 to 3, characterized in that the hydrodynamic drip pointer is made outside the drip tube or input pipe equipped with a device in the form of a perforating needle, the output of which is made below the level of the minimum hydrostatic liquid column in the channel with a given value of 1 - 5 drops of liquid, where the hydrodynamic pointer is made with a difference in diameter throughout.  6. The device according to claims 1 to 5, characterized in that a part of the outlet pipe is curved in the form of a reciprocating deformable spiral shape.

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