DK173857B1 - Hose connection for urine collection vessel - Google Patents

Description

in DK 173857 B1

The present invention relates to a hose connection adapted to transfer a liquid between a source of fluid and a point, and wherein the hose connection is arranged to allow a complete discharge of the hose connection for liquid and to prevent liquid flow back to liquid source. Such a hose connection may advantageously be used between a urinary catheter and a urine collection vessel.

For example, a traditional device for collecting urine, also called a urimeter, is described in the brochure "UnoMeter 500 - simple, safe and accurate urine measure-15 ment" (03-97 GB) published by Maersk Medical A / S. Such a urimeter is connected to a catheter, placed in a patient, by means of a tube with a circular inner diameter. Hose and catheter are connected to each other by means of a connecting element which may be an integral part of either the tube or the catheter. On the described urimeter the hose has an internal diameter of 7 mm.

This diameter is chosen so large that, in principle, one should be able to empty the hose by moving it so that the urine flows downward and into the chamber of the urimeter. A prerequisite for this, however, is that air from the chamber can flow up into the connecting element between catheter and tube, as the cavity in the connecting element is closed outwards. In practice, it is not possible or very difficult to empty the hose in this way. However, if one wishes to empty the hose what is needed for a precise measurement of the hourly duration, this is done by removing the hose from the catheter so that air is drawn into the hose from the now free end. This is bacteriologically unfortunate, as it opens direct access to the patient's urinary tract via the relatively short path through the catheter, and is also cumbersome, as can lead to urine flow.

The problem could be partially solved by a manually operated valve on the connector between the catheter and tubing, but this solution would cause the valve to draw contaminated air from the environment into the closed system, resulting in increased risk of infection.

10

The above problem has been solved with a urine collection device as disclosed in U.S. Patent No. 3,583,401 and as set forth in the preamble of claim 1.

Another problem with the known tubing devices is that urine can flow back to the bladder, increasing the risk of bacteria entering the bladder through the urinary catheter.

Therefore, there is a need for an improved device which partly ensures that a hose connection between, for example, a catheter and a urimeter can be completely emptied of liquid without the need to remove the hose or otherwise open it to it. closed 25 catheter / tube system, partly ensuring that bacteria cannot migrate into the bladder through the urinary catheter.

The present invention solves the above problem by partly using a hose connection with at least two channels between the two points, for example between a catheter and a ventilated urimeter, where the channels corresponding to the respective ends of the hose connection are interconnected, ie. "short-circuited", in part by connecting the tubing corresponding to the end which is adapted to be able to be coupled to a urinary catheter, is equipped with a one-way valve which prevents the return of urine to the bladder.

By a hose connection with more than two channels 5 is meant both multiple individual hoses and a single hose with at least two internal channels.

Hose connections with more than one lumen are very well known per se, for example from the medical field, but this has always been for the purpose of separating the flow of various fluids; a mixing of the fluids by "shorting" the channels at both ends has never been desirable or relevant.

When, for example, urine enters the tube from a catheter, the ducts will more or less be filled and direct the urine to the chamber of the ureter. Therefore, when the urine flow ceases, more urine will typically remain in one duct than in the other.

20

In practice, since no amount of urine ever flows into the ducts, the urine in one of the ducts by virtue of the present invention will be taken over and withdrawn in the second duct backwards and then out through the first duct. since the ducts are partly connected at one end via the connecting element between catheter and tube and partly that the other end of the ducts is ventilated via an opening in the ureter collection chamber.

The invention can, in principle, be realized in two different embodiments, one embodiment where the hose connection is an integral part of a collection unit, for example a urimeter, and an embodiment where the hose corresponding to one end is equipped with a chamber which is fitted with a chamber. is adapted to be coupled to a fluid source, for example a catheter, through which chamber there is communication between the at least two tubes or channels and the tubing corresponding to the other end is configured to be coupled for a collection device.

The invention will now be described in more detail with reference to the preferred embodiments shown in the drawings, in which:

FIG. 1 shows a device for collecting urine from a patient in which the connecting tube between the urinary catheter and the device for collecting urine is reproduced in 15 sections longitudinally of the tube; FIG. 2 is a section through the tubing connection and the urinary catheter corresponding to their interconnection; FIG. Figure 3 shows an example of uniformly sealing the tube between the urinary catheter and the collecting device; 4 shows two examples in which the tube is mounted with a "tray top" between the urinary catheter and the collecting device; and FIG. 5 shows three examples in which the tubing is mounted with a "tray valley" between the urinary catheter and the collecting device.

All figures are schematic and show only details that are essential to the understanding of the invention, while other details are omitted for the sake of clarity. IN

In all figures, the same reference numerals are used for the same or for similar parts.

5 DK 173857 B1

The FIG. 1, a device for measuring the delivery of 5 urine from a patient comprises a measuring container 10 with an inlet opening 13, to which a continuous continuous supply of urine is effected via a connecting tube 1 and a catheter 20 for a period of time. The measuring container is intended to be mounted on, for example, a hospital bed by means of fittings not shown, the measuring container in the correctly mounted position being oriented horizontally. In addition, the measuring vessel is connected to a urine collection vessel 14, typically in the form of a bag. The measuring container 10 has a small opening 12 15 in the top wall 11 for the outside to allow pressure equalization, whereby the ducts are vented to the outside. The opening 12 need not be designed as a separate or permanent opening, but may, for example, be integrated into a valve device (not shown) capable of opening and closing the flow of liquid 20 to the measuring vessel and / or opening and closing the ventilation. The term ventilation opening as used in claim 1 covers these various options.

The hose 1 is formed with two ducts A and B and is similar to one end mounted to the inlet opening 13 and corresponding to its other end mounted to a coupling element 3 with an inner chamber 6, so that both ducts are connected to both the measuring vessel 10 as the chamber 6, thereby establishing two separate flow connections between the chamber and the measuring vessel.

The coupling member has an opening 2 in conjunction with a coupling means which enables a urinary catheter 20 to be mounted corresponding to the opening 2. Typically, the coupling member 6 DK 173857 B1 is a tapered stud which is pushed into the patient-free free opening on the catheter. To ensure that bacteria cannot migrate into the bladder through the urinary catheter, the coupling element corresponding to the opening 2 is provided with a one-way flap-type valve 5 to 7 which prevents bladder reflux.

In the preferred embodiment, a connecting hose having a circular cross section and an inner plane 10 divides between opposing sides of the hose, thereby establishing two crescent or D-shaped channels. A circular outer circumference of the hose allows for simple attachment to both the coupling element and the measuring vessel by means of a short tubular studs 15 into which the hose can be inserted and secured, but it will also be possible to design both the coupling element and the measuring vessel with the crescent or D-shaped. shaped studs which are inserted and secured in each of the ducts. Furthermore, the end of the tube leading into the measuring container should be designed to ensure a good release function for the liquid, ie. prevent the passage of fluid in the ducts due to the hair tube effect. This can conveniently be ensured by giving the opening on the ducts a larger cross-sectional area, for example by the hose having an inclined end surface.

25

An embodiment with a two-channel multilumen tube is described above, but it will be possible to use more than two channels, as well as separate tubes for each of the channels.

30 The latter, however, will entail a more complicated attachment of the hoses to the coupling element and the measuring vessel, respectively.

7 DK 173857 B1

Figure 2 shows an embodiment in which the connection between the two channels corresponding to the coupling with the catheter is established by inserting the free end of the double lumen tube into the catheter tube 21. The catheter tube is here equipped with a coupling part 22 with a bore in which the multilumen tube is pushed. in. An inner funnel-shaped cavity 23 in the coupling part 22 thus functions as the separate chamber 6 described above.

Referring to Figures 3 to 5, the function of the inventive hose connection will be described. As initially described, in practice, there will always be more urine in one channel than in the other when the flow of urine ceases, which is why there will be two columns of urine in the respective channels A and B. Due to the combined effect of gravitational forces and capillary tube action on each of the columns, the longest will "take over" and move toward the measuring container 10. Since the two columns are connected via the chamber 6 (see Figure 1) in the coupling element 3, like the 20 short column in channel B through the opening 12 in the measuring container. 10 is ventilated to the surroundings, the two columns will act as a single column, causing the short column in channel B to be pulled backwards in the direction a the coupling element and then through channel A to the measuring container. If the hose connection is arranged with a steady drop as shown in Figure 3 it will be self-emptying, ie. all liquid will run into the container without any further action.

30 Figure 4 shows a situation where the hose connection is provided with "tray top". If the free end of the longest of the liquid columns is at a level below the coupling element 3 as shown in the upper situation, the hose due to the siphon effect will be self-emptying.

8 DK 173857 B1

If the free end of the longest of the liquid columns is at a level below the coupling element 3 as shown in the lower situation, the hose will not be self-emptying. This is not a problem, however, as it merely requires that the tubing and catheter corresponding to the coupling element 3 be raised so that a situation as shown in Figure 3 or Figure 4, upper situation, arises. The hose will then be completely emptied.

10 Figure 5 shows a situation in which the hose connection is arranged with "ground valley". If the free end of the longest of the liquid columns is at a level below the coupling element 3 as shown in the upper situation, the hose due to the siphoning action will also be self-emptying here. If the free end of the longest of the liquid columns is at a level where it must run "uphill" as shown in the two lower situations, the hose will not be self-emptying. This is not a problem, however, as it simply requires the hose and cautery corresponding to the coupling element 3 to be raised so that a situation as shown in figure 3 or figure 5, upper situation, exists. The hose will then be completely emptied.

In experiments, it has been found that a cross-sectional area for each of the channels corresponding to an internal diameter of 4 to 6 mm for a circular hose works well. A suitable material for the hose is soft PVC.

In the foregoing, the invention is described for use in connection with a measuring vessel and a urinary catheter, but the invention will be applicable wherever a liquid is transported in a hose connection to a ventilated vessel and where complete discharge of the hose connection has hitherto been a problem.

35

Claims (7)

An apparatus for transporting fluid, comprising: 5. a hose connection (1) comprising at least two separate flow channels (A, B) each having a first and a second end, the first ends of which being arranged to be connected to an inlet opening (13) ) on a container (10); A coupling element (3), wherein the coupling element comprises a chamber (6) to which the at least two channels are connected, so that through the chamber there is communication between the two channels and the chamber has an opening (2) to which a source of liquid can be connected; 15, characterized in that the opening in the chamber comprises a one-way valve (7) which only allows liquid to flow from the source of liquid into the chamber. Apparatus according to claim 1, characterized in that the hose connection is a single multilumen tube with at least two channels. Apparatus according to claim 1 or 2, characterized in that the hose connection has precisely two channels, preferably formed as two D-shaped channels in a hose with a circular outer circumference. Apparatus according to any one of the preceding claims, characterized in that the fluid source is a urinary catheter DK 173857 B1 An apparatus for collecting liquid in combination with an apparatus for transporting liquid according to any one of the preceding claims, comprising: - a container (10) having an inlet opening (13) and a ventilation opening (12); wherein the first end of the flow channels is connected to the inlet opening (13) so that liquid can be fed from the liquid source to the container through any of the at least two channels. Apparatus according to claim 5, characterized in that the container (10) is an apparatus for measuring the delivery from a patient of a liquid, in particular urine. Apparatus according to any one of the preceding claims in combination with a urinary catheter.