JPS6125384B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a flow control device for use, for example, in a device for intravenous infusion of liquids.

Known intravenous infusion devices include a container for the liquid to be injected, a tube connected to the container, a hollow needle at the end of the tube for introduction into the patient's blood vessel, and a container for the liquid to flow by gravity from the container to the hollow needle. A gravity device is also known as a gravity device.

In use, a liquid-filled container, such as a bottle or plastic bag, is connected by a flexible tube to a hollow needle or cannula that is introduced into a blood vessel.

The container is located at a height above the patient. The flow rate of the liquid is regulated with a control device in the form of an adjustable clamp on the flexible tube, the supply tube being equipped with a drip chamber so as to give an indication of the rate at which the liquid is being injected.

This gravity device is used for intravenous drips and blood transfusions.
In the case of an intravenous drip, a liquid such as a solution of glucose and saline with or without added drugs is injected, whereas a blood transfusion is the infusion of blood. There is no major difference in injection technique, so unless otherwise specified below, infusion also includes blood transfusion.

Infusion duration can vary from hours to days or even longer. The amount of fluid injected per unit time is important, especially when certain drugs are added to the infusion fluid.

In the case of current gravity devices, the amount of liquid injected per unit time is not very stable due to the principle and construction of these devices. The main sources of variation in the regulated flow rate are: a. flow resistance in the tube near the regulating clamp and the hollow needle within the blood vessel; b. resistance to exit flow near the end of the needle; and c. the infusion device. d depends on the height of the fluid column and the back pressure of the blood in the blood vessel at the perforation site.

Gravity devices require constant attention from the nursing staff to control the flow rate and to readjust and timely replace the liquid container to prevent air from entering the device when the container is empty. do.

In particular, the cause of the above-mentioned fluctuations in the regulated flow rate is
It is as follows.

a In gravity devices, there are two restrictions, one near the adjustment clamp on the tube and the other on the hollow needle. When equipped with a micropore filter, a third diaphragm is present.

The flow area adjacent to the control device depends on the adjustment of this device and has a value of 0 to approximately 0.1 mm ² . The flow area shape of this flow channel region is an elongated or circular slot with average pores on the order of microns. The injection liquid may contain very small solid components that may occlude the control opening, thereby reducing the flow rate. If a filter is used, the same effect can occur on the filter.

Partial occlusion of the needle can also occur, especially when the delivery of infusion fluid is too slow or there is blood backpressure.

The latter cause results in unintentional readjustment of the control device. Some devices use rolling clamps and others use folding clamps that make sharp bends in the tube. External causes, such as patient movement or the viscoelastic properties of the tubing material, can change the opening of the slot.

b The hollow needle introduced into the blood vessel has a beveled end, so that the outlet is oval-shaped. The outlet surface lies at an acute angle to the wall of the blood vessel. Patient movement can cause the outlet to become constricted by the vessel wall.

c The height of the liquid column in a gravity device affects the flow rate. Changes in the height of the liquid column are caused by a decrease in the amount of liquid in the container and any change in the patient's position. The height of the liquid column is determined by the height at which the static pressure in the device above the control clamp equals atmospheric pressure and the relative height of the needle or cannula outlet.

The maximum pressure fluctuation that can occur due to a drop in the water level of a liquid in a bottle or bag with a content of 500 c.c.
15 cm, and the variation that can occur with changes in patient position is approximately 35 cm of water column. The total pressure fluctuation that can occur is therefore approximately 50 cm of water.

The change in height of the liquid column is estimated to be approximately 50 cm of water column. As a result, the liquid pressure can be reduced by 33 to 50% for heights starting from 100 to 150 cm, resulting in a significant reduction in liquid flow rate.

d Vascular blood pressure is 0 to 5 cm water column. Any fluctuations in blood pressure will not significantly affect fluid flow. However, when a child is crying, peripheral vascular pressures can reach peak values of 100 cm of water column. Therefore, the average value of the back surface can vary significantly. Additionally, the infusion device can become occluded with vascular backflow into the gravity device.

The aim of the invention is to provide a device in which the above-mentioned drawbacks are eliminated.

According to the present invention, a supply chamber, a filter chamber, an outlet chamber, a supply channel having an outlet opening opening in a wall of the supply chamber, and a supply channel opening in the wall of the supply chamber, a first passage connecting the filter chamber; a second passage opening in the wall of the outlet chamber and connecting the filter chamber and the outlet chamber;
a first diaphragm provided in the supply chamber so as to be able to close the outlet opening of the supply channel and the opening of the first passage; a second diaphragm dividing into two separate parts connected by a channel and an adjustment device for adjusting the flow area of the bias channel; downstream of the bias channel, one part of the outlet chamber; It is characterized by having an outlet channel that opens in a side where the second channel is not open, and a closing device that adjustably closes the supply channel and the first channel. A flow control device is provided that controls the flow rate of a liquid.

The flow control device allows adjustment of the liquid flow rate and automatically maintains the adjusted value within a narrow range. Further, the flow control device is configured such that when the pressure of the liquid in the supply chamber becomes too low, e.g. when the supply container is empty, the pressure on the first diaphragm separates from the passage between the supply chamber and the filter chamber. The diaphragm operates to automatically shut off liquid flow when the diaphragm is insufficient to retain the diaphragm. This is important if this supply must be continued and empty containers need to be replaced.

This automatic closure prevents air from entering the device since it is filled with liquid. Replacing an empty container can be carried out some time after the liquid flowing from the container has stopped, which simplifies the task of controlling and replacing the liquid container.

In a preferred embodiment, the closure device is arranged to connect the outlet opening of the supply channel and the opening of the first passageway to walls facing each other with the wall of the supply chamber and the first diaphragm interposed therebetween. and a plurality of elements insertable into the holes. By inserting the element into the hole, it is possible to press the first septum and close the outlet opening and the opening.

This element may be a pin or a remotely controlled pressure pin. Furthermore, this element may be an air tube which can be connected to the hole, so that the diaphragm is pushed with compressed air towards the passage between the feed chamber and the filter chamber.

Preferably, the device includes a plurality of supply channels having separate outlet ends and a corresponding number of holes in the opposite wall of the supply chamber, and a plurality of holes inserted into the holes to selectively open and close the inlet channels. It has possible elements. Furthermore, multiple liquid containers can be connected to the flow control device at the same time. The containers may contain the same liquid, making it possible to extend the supply of liquid without changing the containers. or may contain different liquids. In that case, the liquids supplied can be mixed.

When the outlet opening of the supply channel is open and the first passage between the supply chamber and the filter chamber is closed, the supply channel may be used to mix or meter a predetermined amount of liquid. A communicating container device is formed. The elements can be operated by hand as well as by a remote control device that can be easily worn. A particular advantage is that this element does not come into contact with liquid and therefore
There are no joints to disassemble and a sterile liquid circuit is created. This element may be constructed as described above. When an air tube is used, pulsating pressure is applied to the first diaphragm so that the diaphragm can act as a pump.

Preferably, the adjustment device comprises a cylindrical member rotatable about its axis and having a groove extending around a part of its circumference, the bottom of the groove being eccentric with respect to the axis of the member. The groove extends along an arc, and the depth of the groove varies from 0 at one end to 0.5 at the other end.
Increases to mm.

This allows for reliable and easily adjustable control of the flow rate. This groove is preferably V-shaped in cross-section, so that at all positions of the cylindrical member the relationship between the flow area and the groove profile is as favorable as possible. The best shape for the flow area is circular, but the closest approximation is triangular, preferably with a 90° angle.

Almost all known control devices have an elongated or circular flow control slot. If the flow area is, for example, 0.1 mm ² , the opening of the slot is very small (0.01 mm or less) and therefore solid particles in the liquid will lead to partial blockage of the slot and the flow rate will be reduced. Disturbed.

An advantage of the preferred embodiment of the invention is that the passageway for the solid components is at least 10 times larger than in other designs.

In cross section, this groove is semicircular and its center is eccentric with respect to the axis of the cylindrical member. Experimentally, it has been constructed such that the flow resistance varies exponentially with rotation of the cylindrical member, allowing very precise control at small flow rates.

Certain regulations require flow control devices that allow a specified amount of liquid to flow per unit of time (British Standard 24631962, section 33). To meet this requirement, it is preferred that, adjacent to the end of said groove, the cylindrical member has another groove with a flow area at least equal to the area of the bias channel.

A flow control device embodying the invention will be described in detail below by way of example with reference to the accompanying drawings.

The illustrated device consists of two approximately rectangular parts (2.5×
casing 1) of dimensions within the range of 5 cm;
A rubber membrane 3 having a thickness of 0.30 mm is provided between these plates. Casing 1
and the lid body 2 is a screw 4 passing through a hole in the rubber membrane 3.
The rubber membrane seals between the edge 5 of the casing and the lid plate, forming two septa 6, 7.

The casing 1 has a filter chamber 11 and a supply chamber 10.
and three feed channels 8 with outlet openings 9 opening into the walls. The filter element 12 has a chamber 11 which is closed with a removable filter lid 13 which allows it to be easily updated or replaced.
It is located inside.

Between the supply chamber 10 and the filter chamber 11 there is a first passage 14 with a projecting rim 15, and a second passage 16 connects the outlet chamber 17 to the filter chamber 11.

The cover plate 2 is provided with a hole 18 facing the outlet opening 9 of the supply channel 8 . Elements like pin 19 are
The first diaphragm 6 can be inserted into each of these holes.
By pressing the diaphragm 6 into the opening 9, the associated opening 9 is partially or completely closed; for example, when the diaphragm 6 is pressed into position a, the opening 9 is completely closed. The cover plate 2 also has a hole 20 on the side opposite the first passage 14 between the supply chamber 10 and the filter chamber 11, and one element has a hole 20 in the position a which completely closes the second passage 14. As if pressing the diaphragm 6 to
Insertable. In the rest position b, the diaphragm 6 lies under some tension against the edge 15 and when pressurized liquid (about 10-15 cm of water column) is fed from the supply channel 6 to the position c. Moving. At this time, the liquid is
It flows into the filter chamber 11 through the passage 14 as shown by the arrow 21, passes through the filter element 12 along the flow path formed by the ribs 11a as shown by the arrow 22,
It flows into the groove formed by the rib 23 of the filter lid 13 and then into the groove 27 in which the two passages 16, 28 open.

The outlet chamber 17 accommodates a diaphragm 7 which, when at rest, is in the position 25 shown in dotted lines and which is located in the closed part 1
7a and a portion 17b to which the outlet flow path 30 is connected.

As shown in FIG.
7 and to the section 17b of the chamber 17 by a passage 28, a hole 26 in the rubber membrane, and bias channels 31a, 31b.

A rim 31 is formed around the outlet channel 30. When the pressure of the liquid exiting the filter chamber is higher than the pressure in the outlet channel 30, the diaphragm 7 moves towards the rim 31 and partially or completely closes the channel 30.

The regulating device 29 connects the bypass flow path to the casing 3.
The casing 32 is divided into two parts 31a and 31b formed in
It is located so that it is sealed. The pin 33 has a groove 34 extending over part of its circumference in a plane perpendicular to the axis of the pin, and the bottom of the groove 34 is centered at a center 35 eccentric to the center 36 of the circular cross section of the pin 33. Draw an arc as . The cross-section of groove 34 is preferably triangular with a 90° apex angle. Another groove 37
is provided in the pin with a groove 34 at its deeper end.
Connect to.

The liquid leaving the filter chamber is divided into two parts (arrows 38, 39), as indicated by arrow 24.
A portion (arrow 38) is connected to the outlet flow path 30 (arrow 4
0), the other part (arrow 39) exerts pressure on the side of the diaphragm 7 opposite the outlet channel 30.

Groove 37 allows a specified amount of liquid to be
(Sec. 33 of 1962) guarantees circulation per unit of time. Similar requirements also apply in various other countries.

Adjustment of the groove 34 relative to the bypass channel section 31b is effected by a rotatable lever 41, as shown by arrow 42, attached to the pin 33.

One or more channels 8 are connected to the liquid container with flexible tubing. The outlet channel 30 connects to another flexible tube, the other end of which is equipped with a hollow needle or cannula that is introduced into the blood vessel of the person in which the liquid is to be injected. A drip chamber is interposed in this tube.

The liquid flowing into the supply channel 8, if its pressure is sufficient, moves the diaphragm 6 from position b to position c.
The liquid then flows through passage 14 to groove 27 as shown by arrows 21, 22, 24, where arrow 3
It is classified as shown in 8 and 39. The fluid flowing according to the arrow 38 flows through the first portion 31a of the bypass flow path.
The desired flow rate is adjusted by the position of groove 34 and then flows to outlet channel 30 as indicated by arrow 40. The liquid deflected as shown by the arrow 39 applies pressure to the diaphragm 7, thereby causing the diaphragm 7 to
moves toward the rim 31. As a result, the pressure drop across the partially closed hole in the flow path 30 is controlled so that the pressure drop across the regulating device 29 remains constant and thus the liquid flow rate remains constant. Provided that the device is sterilized before use, those parts through which liquid flows or emerges during use remain sterile because the device is completely sealed.

This flow control device is completely automatic.
It is clear. If the liquid pressure in the container becomes too low, the diaphragm 6 engages the edge 15 and the supply of liquid is cut off. The flow rate of the liquid is regulated by a flow control device and automatically maintained constant by the diaphragm 7.

Several containers containing the liquid to be injected can be connected to this device. When the containers contain the same liquid, the infusion to the patient is carried out for an extended period of time without interruption. If the containers are filled with different liquids to be injected as a mixture into the patient, this injection can be carried out by means of a device actuated by a fixed device that can be manually adjusted with pin 19 or remotely controlled. is possible. The latter may be carried out automatically in a simple and programmed manner.

The device described above can be used in other fields besides injecting liquids into patients. The device can also be used in any application where small amounts of liquid are dispensed, such as, for example, chemical processes, drinking water preparation, etc.

The above-described control device provides the following advantages when used in setting up a blood transfusion or infusion.

a) saving in the labor of the nursing staff, in particular because the time interval for changing the liquid container may be 200% of that of the known device; b) an improvement based on a better controlled injection of the drug added to the liquid. and c) improved technical possibilities in the case of intravenous treatment. It also becomes possible to form a mixture of several liquids or liquid components during operation. This is carried out by controlling each element in a short periodic sequence at different times.
This allows any mixing ratio to be obtained. This mixing ratio can be constant or variable (programmed). Feedback to patients can also be considered from a technical standpoint.

[Brief explanation of the drawing]

Figure 1 is a front elevational view of the flow control device, Figure 2 is a rear elevational view of the flow rate controller with the filter chamber lid removed and only a portion of the filter shown, and Figure 3 is the same as in Figure 1. 4 shows a cross section taken along line - in FIG. 1, and FIG. 5 shows an end view of the flow control device. 6, 7...diaphragm, 8...supply channel, 9...outlet opening of supply channel, 10...supply chamber, 11...filter chamber, 14...passage, 17...exit chamber, 17
a... Closed part of the exit chamber, 17b... Flowing part of the exit chamber, 18... Hole in the lid, 19... Pin, 2
0... Hole on the opposite side of the passage, 29... Adjustment device, 3
0...Outlet flow path, 31a, 31b...Part of the bypass flow path, 33...Cylindrical pin, 34...Groove of the cylindrical pin, 36...Center of the cylindrical pin, 37...
Another groove.

Claims (1)

[Scope of Claims] 1: a supply chamber; a filter chamber; an outlet chamber; a supply channel having an outlet opening opened in the wall of the supply chamber; and the filter chamber; a second passage opening in the wall of the outlet chamber and connecting the filter chamber and the outlet chamber; and the outlet opening of the supply flow path. a first diaphragm provided in the supply chamber so as to be able to close the opening of the first passage; and two separate parts provided in the outlet chamber and connected to the outlet chamber by a bypass flow path. a second diaphragm dividing the bypass flow path into a second diaphragm; an adjustment device for adjusting the flow area of the bypass flow path; A flow rate control for controlling the flow rate of a liquid, characterized in that it has an outlet flow path that opens in a side portion, and a closing device that adjustably closes the supply flow path and the first passage. Device. 2. The closure device is connected to the outlet opening of the supply channel and the opening of the first passageway in a wall that faces the wall of the supply chamber with the first diaphragm interposed therebetween. It has a plurality of holes respectively formed at aligned positions and a plurality of elements that can be inserted into the holes, and by inserting the elements into the holes, the first diaphragm is opened. 2. A flow control device as claimed in claim 1, wherein said outlet opening and said opening are closed by pressing. 3. The flow rate control device according to claim 1, wherein the supply flow path is plural. 4. The adjusting device comprises a cylindrical member rotatable about its axis and having a groove extending around a part of its circumference, the bottom of the groove forming an arc eccentric with respect to the axis of the member. 2. The flow control device of claim 1, wherein the depth of the groove increases from 0 mm at one end to 0.5 mm at the other end. 5. The flow rate control device according to claim 4, wherein the groove has a V-shaped cross section. 6. A flow control device according to claim 4 or claim 5, wherein the cylindrical member is provided with another groove having a flow area at least equal to the area of the bias flow path.