RU212684U1 - drip chamber - Google Patents

Abstract

The device relates to medical technology and can be used for drip chambers in drip infusion systems. The required technical result, which consists in increasing the reliability with respect to protection against air ingress through the injection port into the patient's vein, is achieved in a device in the form of a drip chamber containing a cylindrical body, the upper wall of which is configured to be connected with a spike into a container with medicinal liquid, and the lower wall is made with the possibility of connection with a polymer tube for supplying a medicinal liquid to the injection port, as well as a trapezoidal inverted valve on the stem and a float in the form of a cylinder with a diameter corresponding to the inner diameter of the cylindrical body, and a saddle-shaped protrusion is made in the middle part of the drip chamber , the upper surface of which is made in the form of the lower surface of the valve, and the stem is connected in the lower part to the float, which has vertical channels. 1 ill.

Description

The device relates to medical technology and can be used for drip chambers in drip infusion systems.

Known drip chamber device for receiving and introducing infusion solutions into the body [RU 2120310 C1, A61M 5/14, 2010.1998], made in the form of a reservoir forming a flow cavity with a dry medicinal substance, a means for filtering the solution is made in the form of at least one milliporous membrane filter blocking the flow cavity from the outlet side, the outlet of the drip chamber is connected to a plastic container, made with the possibility of changing the volume as it is filled up to a given working value, and the lower end of the container has an outlet pipeline, on which a liquid flow rate regulator is installed, and at the inlet the drip chamber is connected through a sealed connection with elastic fixing sliding ledges to a sealed elastic elastic reservoir containing the solution.

The disadvantage of this device is the relatively low reliability, which does not exclude the ingress of air into the lower part of the drip chamber to its lower wall and its flow through the polymer tube and the injection port into the patient's vein.

The closest in technical essence to the proposed one is a drip chamber containing a cylindrical body, the upper wall of which is configured to be connected with a spike into a container with medicinal liquid, and the lower wall is configured to enter the injection port [V.B. Petrova, A.I. Petrova, E.S. Laptev. Parenteral administration of drugs. Intravenous drip infusion. Taking venous blood. Postinjection complications. (Part 2). Teaching aid. St. Petersburg: ed. SZGMU them. I.I. Mechnikova, 2013. - 44 p.].

Medicinal liquid from the container drips through the spike into the container with medicinal liquid into the lower part of the drip chamber, from where it enters through the polymer tube and the injection port into the patient's vein. In this case, the lower part of the drip chamber must always be filled with medicinal liquid, which ensures that air does not enter the patient's vein. Entry of air leads to air embolism and death of the patient. Therefore, when the drug liquid in the container runs out, the polymer tube is closed using an infusion rate regulator.

This means that the patient must monitor the fluid level and be able to promptly report that the fluid has run out. But this is impossible if the patient is unconscious, and the medical worker has many patients at the same time and he is not able to monitor all of them at the same time, and if several medicinal liquids are poured in succession, and the liquid in the lower part of the drip chamber is drained, and after reinstalling the drip chamber to a new container it is necessary to drive the air that has got there through the polymer tube, i.e. drain all the drug liquid remaining in the polymer tube.

Thus, the disadvantage of the known drip chamber is relatively low reliability, which does not exclude air from entering the lower part of the drip chamber to its lower wall and entering through the polymer tube and the injection port into the patient's vein.

The objective of the utility model is to create a drip chamber, which has increased reliability with respect to protection against air entering the lower part of the drip chamber to its lower wall and its flow through a polymer tube and injection port into the patient's vein.

The required technical result is to increase the reliability with respect to protection against air ingress into the lower part of the drip chamber to its lower wall and its entry through the polymer tube and injection port into the patient's vein.

The problem is solved, and the required technical result is achieved by the fact that, in a drip chamber containing a cylindrical hollow body, the upper wall of which is configured to be connected with a spike into a container with medicinal liquid, and the lower wall is configured to be connected to a polymer tube for supplying medicinal liquid into the injection port, according to the utility model, a trapezoidal inverted valve on the stem and a float in the form of a cylinder with a diameter corresponding to the inner diameter of the cylindrical body are introduced, moreover, in the middle part of the drip chamber, a saddle-shaped protrusion is made, the upper surface of which is made in the shape of the lower valve surface, and the stem is connected at the bottom with a float, which has vertical channels.

In addition, the required technical result is achieved by the fact that the float is made 12 mm high.

In addition, the required technical result is achieved by the fact that the vertical channels in the float are made with a diameter of 3 mm.

In addition, the required technical result is achieved by the fact that the rod is made with a cylindrical diameter of 6 mm, and longitudinal grooves with a depth of 1.5 mm are made on the outer surface of the rod.

The drawing shows a drip chamber together with a spike in the container and a polymer tube.

The drip chamber contains a cylindrical body 1, the upper wall of which is configured to be connected with a spike 2 to a container with a medicinal liquid, and the lower wall is configured to be connected to a polymer tube 3 for supplying a medicinal liquid to the injection port.

A trapezoidal inverted valve 4 is installed in the drip chamber on the stem 5 and a float 6 in the form of a cylinder with a diameter corresponding to the inner diameter of the cylindrical body 1.

In addition, in the middle part of the drip chamber, a saddle ledge 7 is made, the upper surface of which is made in the form of the lower surface of the valve 4, and the stem 5 is connected in the lower part to the float 6, which has vertical channels 8.

Valve 4 and stem 5 can be made of medical plastic or fluoroplastic, float 6 can be made of solid foam. In a particular case, the float is made 12 mm high, and the vertical channels in it have a diameter of 3 mm. Rod 5 is made cylindrical with a diameter of 6 mm, longitudinal grooves 1.5 mm deep are made on the outer surface of the rod to ensure free flow of the medicinal liquid.

The drip chamber is used as follows.

Medicinal liquid from the container (not shown in the drawing) drop by drop through the spike 2 into the container with the medicinal liquid enters the drip chamber, from where through the polymer tube (not shown in the drawing) and the injection port into the patient's vein. The bottom of the drip chamber should always be filled with medicinal liquid.

To increase protection against air ingress, a valve 4 is introduced into the drip chamber on a stem 5 with a float 6. When the liquid fills the lower part of the drip chamber, the float 6 lifts the valve 4 and the liquid flows freely from the upper part of the drip chamber to the bottom.

For reliable operation of the drop chamber, it is shaken before use, and under the action of inertia when the drop chamber moves down, the valve 4 comes off the saddle protrusion 7, and the medicinal liquid flows into the lower part of the drop chamber. Float 6 pops up and opens the valve.

If the liquid level in the lower part of the drip chamber decreases, the valve 4 blocks the air penetration into the lower part of the drip chamber. As a result, the air pressure in the lower part of the drop chamber rapidly decreases and no further decrease in the liquid level in the lower part of the drop chamber occurs.

This ensures the achievement of the required technical result, which is to increase the reliability with respect to protection against air entering the lower part of the drip chamber to its lower wall and its flow through the polymer tube and the injection port into the patient's vein.

Claims (1)

A drop chamber containing a cylindrical hollow body, the upper wall of which is configured to be connected with a spike into a container with medicinal liquid, and the lower wall is configured to be connected to a polymer tube for supplying medicinal liquid to the injection port, characterized in that a trapezoidal inverted in terms of the valve on the stem and a float in the form of a cylinder with a diameter corresponding to the inner diameter of the cylindrical body, and in the middle part of the drip chamber there is a saddle-shaped protrusion, the upper surface of which is made in the shape of the lower surface of the valve, and the stem is connected in the lower part to the float, which has vertical channels, wherein the float is made 12 mm high, the vertical channels in the float are made 3 mm in diameter, the stem is made cylindrical with a diameter of 6 mm, and longitudinal grooves 1.5 mm deep are made on the outer surface of the stem.

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