SE451801B - DEVICE FOR BREATHING A FLUID THROUGH A PIPE - Google Patents

Description

15 20 25 30 35 451 801 in the expansion chamber, time is gained for the formation of bubbles of suitable size, which can be passed through the pump to the deaeration chamber without being too much broken down in the pump, at the same time as bubbles formed in the chamber are automatically controlled directly. towards the outlet. Furthermore, a complete emptying of the expansion chamber is made possible by means of a pump arranged later in the system.

Preferably, the inlet to the expansion chamber is arranged at its bottom, which further facilitates said control. Preferably, a non-return valve is arranged directly after the outlet of the expansion chamber.

Suitably a valve is arranged in the shunt line, which is arranged to be kept closed at normal working pressure, but which opens when the normally negative pressure rises to nominally lower values, e.g. in connection with air entering the expansion chamber, when the system is emptied by means of the above-mentioned pump arranged later in the system. The valve arranged in the shunt line can simply consist of a compressible hose, which is automatically sucked together at a nominally higher negative pressure, ie pressure corresponding to the normal working pressure.

In order to ensure a safe closing of the hose, a squeezing device can be arranged thereon, which is arranged to compress the points which are to form the end points of the compressed hose already in the open position of the hose. Without this clamping device, there is a risk of a certain leakage precisely at these end points.

The inlet to the vent chamber is suitably arranged tangentially at a higher level than the outlet to the same.

This facilitates bubble separation both through the level difference and through generated centrifugal forces.

In a manner known per se, an outlet for air collected therein is arranged in the venting chamber at its highest point and in the same chamber a float valve, which is arranged to prevent liquid from being sucked out through the air outlet.

The throttle arranged upstream of the expansion chamber is suitably made adjustable. In this way, e.g. the degree of deaeration is regulated, at the same time as the dialysis flow can be regulated at the same time as the dialysis flow can be changed. m8 10 15 20 25 30 35 40 ß 451 801 In order for the system as a whole to be emptied efficiently, the same is suitably provided with a suction pump arranged downstream of the deaeration chamber. This pump can, for example, consist of the pump which normally sucks the dialysis liquid through the dialyzer.

As mentioned above, the invention is primarily intended to be part of a system for preparing dialysis fluid by mixing one or more concentrates with water.

It will therefore be described in the following with reference to just such a system.

Bubble separation is further facilitated if the outlet is arranged tangentially, but countercurrent to the vortex formation produced by the inlet.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 schematically shows a flow chart for a substantially complete system for the preparation of dialysis fluid.

Fig. 2 shows in more detail and as an example a possible design for an air separation chamber included in said system.

Fig. 3 schematically shows a section III-III through the same air separation chamber and is intended to illustrate the location of the inlet of the chamber resp. outlet.

Fig. 4 shows how a hose included in the system could possibly be sucked up incompletely, if it was not provided with a squeezing device in accordance with Fig. 5, which causes the suction to instead be that shown in Fig. 6.

PREFERRED EMBODIMENT OF THE INVENTION In the exemplary system for preparing dialysis solution, water is introduced at an inlet 1 into a conduit 2 with a temperature gauge 3 and an inlet valve 4.

From the inlet valve 4, the water flows through a line 5 to a heating vessel 6 with a level control float 7, a heating coil 8 and a stirrer 9. Alternatively, the water can flow to the heating vessel through a line 10 with a valve 11, which allows larger flows to provide an efficient rinsing the vessel 6, e.g. in connection with sterilization. From the vessel 6 the water flows via a line 12, a flow valve 13 and a suitably adjustable second flow valve or throttle 14 to an inlet 15 arranged at the bottom of an expansion chamber 16. At the upper point of this chamber is an outlet 17 arranged to a line 18 with a non-return valve 19. In parallel with the chamber, a shunt line 20 is also arranged with a valve 21. In a preferred embodiment this shunt line 20 and valve 21 are simply constituted by the one in Figs. 4-6. shown the hose 20a with a pre-squeezing device 2la. Thanks to this pre-squeezing device 21a, the hose receives the shape obtained in Fig. 6 with sufficient negative pressure instead of the otherwise possible and shown in Fig. 4. Before the liquid reaches the expansion chamber 16, it is supplied by means of a pump 22 through a line 23 concentrate and before that the temperature is further measured once more by means of a temperature meter 24.

The line 18 continues via a pressure gauge 25 and a pump 26 to a vent chamber 27. An example of such a chamber is shown in more detail in Fig. 2 and schematically in Fig. 3. The chamber 27 is thus provided with inlet 28 and a lower level one. arranged outlet 29 for the liquid and an outlet 30 for air collected in the chamber. A float 31 is further arranged in the chamber, which closes the outlet 30, when the liquid level has risen so high that there is a risk that liquid is sucked out through the outlet 30.

From the vent chamber 27, via a further outlet 32, a line 33 runs via a valve 34 back to the heating vessel 6. This line is intended to be used in connection with sterilization in a manner which is described in more detail in the above-mentioned U.S. patent 4,158,034.

From the deaeration chamber 27 the liquid flows via a line 35 to a conductivity meter 36 and in the case that a second concentrate is also to be supplied with an additional conductivity meter 37. The second concentrate is then supplied by means of a pump 38 through a line 39 Thanks to these two conductivity meters 36 and 37, the conductivity can be measured before and after the addition of the second concentrate. the liquid is then passed through a line 40 via a flow meter 41, a temperature meter 42 (If) 10 15 20 25 30 5 451 801 and a valve 43 to the schematically shown dialyzer 44. Should, for example, temperature or conductivity not take the desired values, the liquid is passed instead by means of a valve 45 in a line 46 past the dialyzer to a second channel 41 'in the above-mentioned flow meter.

If, on the other hand, the desired conditions are met, the liquid is passed from the dialyzer 44 through a line 47 via a pressure gauge 48 and a valve 49 to the channel 41 'in the flow meter. From there, the liquid is fed via a line 50 with a blood leak detector 51 and a valve 52 to a suction pump 53.

With the aid of this suction pump 53, the dialysis solution is thus sucked through the dialyzer 44. The same pump was also used for emptying the system as a whole. From the pump 53, the liquid is normally passed via an outlet valve 54, a throttle 55 and a safety control meter 56 for pH measurement to the drain 57. Alternatively, for example in sequence dialysis, extracted ultrafiltrate can be passed from the valve 54 via a line 58 to a special collection point 59 for such filtrate.

Finally, 60 denotes a safety bypass, which is used only in connection with sterilization of the device.

This may be of the type described in more detail in U.S. Patent 4,122,010.

The invention is of course not limited only to the exemplary embodiment described above, but can be varied within the scope of the appended claims. For example, of course, the details included in the system can be varied in both form and function. Furthermore, the invention can also be applied for, for example, deaeration of replacement liquid for haemofiltration or plasmapheresis or for deaeration of liquids in general. Incidentally, compare the construction according to the co-pending Swedish patent application 83.06574-8, which describes an alternative venting device which contains details which can be combined with the construction according to the present invention.

Claims (12)

10 15 20 25 30 35 4511801 6 PATENT REQUIREMENTS A device for venting a liquid flowing through a line (2, 5, 12, 18, 35), comprising a choke (14), a suction pump (26) arranged downstream thereof and a venting chamber (27) arranged downstream of the pump and an expansion chamber (16) arranged between the choke (14) and the pump (26), the outlet (17) of which is arranged at the top thereof, characterized by a shunt line (20) arranged parallel to the expansion chamber (16), which is connected to a second outlet arranged at the bottom of the expansion chamber. Device according to claim 1, characterized in that the inlet (15) to the expansion chamber (16) is arranged at its bottom. Device according to claim 2, characterized by a non-return valve (19) arranged directly after the outlet (17) of the expansion chamber (16). Device according to claim 1, characterized by a valve (21) arranged in the shunt line (20), which is arranged to be kept closed at normal working pressure, but which is opened when the normally negative pressure rises to nominally lower values. Device according to claim 4, characterized in that the valve (21) arranged in the shunt line (20) consists of a compressible hose (20a): which is automatically sucked together at nominally higher negative pressure. Device according to claim 5, characterized by a pre-squeezing device (2la) arranged on the hose (20a), which is arranged to compress the points which are to form the end points of the compressed hose already in the open position of the hose. Device according to one of Claims 1 to 6, characterized in that the inlet (28) to the venting chamber (27) is arranged tangentially at a higher level than the outlet (29) thereof. 'à 10 15 20 7 451 801 Device according to claim 7, characterized in that it is arranged tangentially, but (28) produces a vortex image in that also the outlet (29) is countercurrent to that of the inlet. Device according to one of Claims 1 to 7, characterized by an outlet (30) for air collected therein arranged at the highest point of the vent chamber (27), and by a float valve (31) arranged in the same chamber (27). which is arranged to prevent liquid from being sucked out through the air outlet (30). _ Device according to one of the preceding claims, characterized in that the choke (14) arranged upstream of the expansion chamber (16) is adjustable. 11. ll. Device according to one of the preceding claims, characterized by a suction pump (53) arranged downstream of the venting chamber (27). Device according to any one of the preceding claims, characterized in that it is part of a system for preparing dialysis fluid by mixing one or more concentrates with water. I »'§í¿ ___. 1 ~ - v? __- 1 «f ~ - .r a J