Cooling Unit for a Heat Exchanger

Abstract

The invention is a cooling unit for a heat exchanger, which preferably is a heat exchanger integrated in an oxygenator for the purpose of controlling the temperature of blood conveyed in an extracorporeal blood circuit. The cooling unit has a reservoir in which a liquid is stored, a reaction vessel comprises a reactant and which, in conjunction with the liquid, is able to initiate an endothermal reaction. A fluidic access is generated between the reservoir and the reaction vessel. A fluid line extends at least in part inside the reaction vessel which has an inlet line and outlet line, which are each connectable or connected in a fluid-tight manner to a hose system of the heat exchanger, which together with the hose system of the heat exchanger, provides least part of a fluid circuit.

Claims

1-17. (canceled)

18. A cooling unit for a heat exchanger, integrated into an oxygenator comprising: a reservoir in which a liquid is stored; a reaction vessel comprising a reactant which in conjunction with the liquid, can initiate an endothermal reaction; a means which provides a fluidic access between the reservoir and the reaction vessel; and a fluid line extending at least in part inside the reaction vessel and which has an inlet line and outlet line, which are each connectable to a hose system of the heat exchanger, and which, together with a hose system of the heat exchanger, form at least part of a fluid circuit; and wherein an expansion tank having an overflow into which the liquid from the reservoir flows after fluidic access is generated between the reservoir and the reaction vessel, so that overflow provides a fluid connection to the reaction vessel through which a proportion of stored liquid in the reservoir passes into the reaction vessel to initiate an endothermal reaction with the reactant, so that the fluid line is fluidically connected to the expansion tank, into which a remaining proportion of the stored liquid from the reservoir passes; and a fluid pump is located along the fluid line, so that liquid from the expansion tank passes into the fluid line which extends at least in part inside the reaction vessel.

19. The cooling unit according to claim 18, comprising: a non-return valve located along the fluid connection of the overflow, which prevents a return flow of liquid from the reaction vessel into the expansion tank.

20. The cooling unit according to claim 18, wherein: the fluid pump is configured as a suction unit which is located along the fluid line outside the expansion tank and reaction vessel.

21. The cooling unit according to claim 18, wherein: the fluid pump comprising a peristaltic pump.

22. The cooling unit according to claim 18, wherein: the fluid line downstream of a region extending inside the reaction vessel provides the outlet line along which a filter is positioned extending outside the reaction vessel.

23. The cooling unit according to claim 22, wherein: the filter unit is a Legionella filter.

24. The cooling unit according to claim 18, wherein: the inlet line of the fluid line feeds into the expansion tank, and the fluid circuit includes the expansion tank, the fluid line and the hose system of the heat exchanger, through which a remaining proportion of the liquid circulates as heat transfer liquid of the heat exchanger.

25. The cooling unit according to claim 18, comprising: the reservoir being disposed vertically above the expansion tank; and means providing fluidic access which is a sharp-edged object which is positioned vertically below the reservoir; and a spacer is disposed between the reservoir and the expansion tank, which vertically spaces apart the reservoir above the means providing fluidic access; and upon removal of the spacer, the reservoir is driven by gravitational force comes into contact with the means for providing fluidic access, which mechanically penetrates the reservoir, so that the liquid stored in the reservoir pours into the expansion tank.

26. The cooling unit according to claim 18, wherein: the means for providing fluidic access is fixedly positioned on the expansion tank.

27. The cooling unit according to claim 18, comprising: an agitator inside the reaction vessel which is driven by a mechanical interface by a drive motor outside the reaction vessel.

28. The cooling unit according to claim 18, wherein: at least the reservoir, the means for providing fluidic access and the reaction vessel are disposable articles.

29. The cooling unit according to claim 28, wherein: the filter unit and the agitator are parts of the disposable article and the drive motor and the fluid pump are connected to an electrical energy source and an electrical controller which is a modular for a mechanical attachment to the disposable article.

30. The cooling unit according to claim 18, wherein: the heat exchanger is integrated into a cooling system.

31. The cooling unit according to claim 18, wherein a binding agent is stored inside the reaction vessel, which upon coming into contact with the liquid entering into the reaction vessel a gel is formed with the liquid.

32. The cooling unit according to claim 18, wherein: at least the reservoir and the reaction vessel comprise a plastic packaging material.

33. The cooling unit according to claim 32, wherein: at least an inner wall of the reaction vessel which contacts the liquid is coated with a liquid-tight coating.

34. The cooling unit according to claim 18, wherein: the reaction vessel includes a vent.

Description

BRIEF DESCRIPTION OF THE INVENTION

[0030] The invention is described by way of example hereinafter without limation, using an exemplary embodiment with reference to the drawing, in which:

[0031] FIG. 1 shows a schematic view of a cooling unit according to the invention for controlling the temperature of a heat exchanger integrated in an oxygenator in the state before activating the cooling function;

[0032] FIG. 2 shows a schematic view of the cooling unit after activating the cooling function; and

[0033] FIG. 3 shows an alternative embodiment of the cooling unit according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

[0034] FIG. 1 illustrates in schematic view of a cooling unit K according to the invention for providing a cooled heat transfer liquid for operating a heat exchanger W which is preferably part of an oxygenator O.

[0035] The cooling unit K has four modules M1 to M4. At least the modules M1-M3 thereof are able to be assembled vertically to be one above the other according to the modular principle. The module M1 has a reservoir 1 for a liquid which preferably is water. Preferably the reservoir 1 has a plastic bag or plastic canister filled with water and which is at least partially surrounded by a first housing 2 for protection and for being mechanically joined to the module M2 located therebelow.

[0036] The second module M2 is arranged vertically below the first module M1 and comprises an expansion tank 3 in which a functional means 4 which is an object, for example a needle, pin etc., tapering vertically upwardly to a sharp edge, which is fixed. The expansion tank 3 is surrounded by a second housing 5. An overflow 6 having a fluid connection 7 feeds vertically from above into the reaction vessel 8 of the third module M3, which is surrounded by a third housing 9, which protrudes vertically from below into the interior of the expansion tank 3. The fluid connection 7 is a pipeline which is open on both sides and has a non-return valve 10 which prevents an entry of liquid from the reaction vessel 8 into the expansion tank 3. A reactant 11 in granular form, which preferably is granular urea, is stored in the reaction vessel 8.

[0037] Moreover, a fluid line 12 discharges in the bottom region of the expansion tank 3 with the fluid line extending further inside the reaction vessel 11, to preferably form coiled lines 13, in order to produce a fluid line surface which is as large as possible inside the reaction vessel 8. The fluid line 12 is fluid light and leads outwardly through the third housing 9 and also functions as an outlet line 14 of the cooling unit K. The fluid line 12 extending in the interior of the reaction vessel 9, and in particular the coiled lines 13 located therein, are produced from a material which is very effective at conducting heat, preferably from metal, whereas the fluid line along the outlet line 14 consists of a material which is a poor heat conductor and resilient, for example plastics.

[0038] A filter unit 15, preferably a bacterial filter, is inserted along the outlet line 14. A fluid pump 16, which preferably is a peristaltic pump, is downstream from the filter unit 15 along the outlet line 14. Downstream from the fluid pump 16 is a releasable fluid-tight coupling 17 to provide a fluid-tight connection to a hose system 18 of the heat exchanger W.

[0039] Similarly, the hose system 18 is connected by a releasable fluid-tight coupling 17′ to the inlet fluid line to inlet line 19 into the expansion tank 3 of the cooling unit K.

[0040] The third module M3 also has an agitator 20 which is coupled via a releasable gear unit 21 to a drive motor 22. The drive motor 22, the fluid pump 16, and an electronic control unit 23 in combination with an electrical energy source 24 operates the drive motor 22 and the fluid pump 15, as the fourth module M4 which is surrounded by a fourth housing, not shown further.

[0041] The first and second module M1, M2 are vertically spaced apart by a spacer 25 so that the functional means 4, in the form of an object tapering vertically upwardly, does not come into contact with the reservoir 1 contained inside the first module M1. The spacer 25 is slidably mounted between the first and second module M1, M2 and preferably is secured by a latching mechanism (not shown) against slipping out to the side in an uncontrolled manner.

[0042] For activating the cooling unit K it is imperative that the spacer 25 is able to be removed to the side from the vertical module assembly M1, M2, for example by manually pulling out to the side as illustrated arrow P.

[0043] FIG. 2 illustrates the state after the spacer 25 has been removed to the side from the modular stack assembly. As a result of the missing spacer 25, the reservoir 1 drops down vertically together with the first housing 2, whereby the upwardly tapering functional means 4 locally perforates the reservoir 1. In order to ensure that the dropping and joining process of the first module M1 onto and into the second module M2 takes place in a specific manner, the first and second housings 2, 5 on their respective vertically facing sides have peripheral joining contours F at the side.

[0044] As a result of the mechanically initiated perforation of the reservoir 1, the entire liquid contents of the reservoir 1 flows into the expansion tank 3. Approximately 80% of the quantity of liquid stored in the reservoir 1 flows via the overflow 6 and the fluid connection 7 into the reaction vessel 8 and initiates an endothermal chemical reaction with the reactant 11, so that cooling takes place inside the reaction vessel 8. A remaining proportion 26 of the liquid remains inside the expansion tank 3 and serves as heat transfer liquid for operating the heat exchanger W. At the same time as the removal of the spacer 25 and, as a result, the gravity-driven perforation of the reservoir 1, both the fluid pump 16 and also the drive motor 22, which drives the agitator 20 via the gear unit 21, are activated by the electronic control unit 23. The fluid pump 16 which operates as a suction pump that suctions the liquid located inside the expansion tank 3, and a remaining proportion 26, through the fluid line 12 which is cooled due to the cooling inside the reaction region 8. In order to optimize the heat transfer from the liquid conveyed inside the fluid line 12 to the liquid/reactant mixture cooling in the path of the endothermal reaction, it is imperative to ensure a heat transfer contact surface is as large as possible between the fluid line 12 and the liquid-reactant mixture present in the interior of the reaction vessel 8. To this end, the line path of the fluid line 12 in the interior of the reaction vessel 8 is configured at least in some sections to be helical or in a helical manner.

[0045] The cooled liquid is pumped via the outlet line 14 through the filter unit 15 into the heat exchanger W. After exiting the heat exchanger W, the outflowing heat transfer liquid passes via the inlet line 19 back into the expansion tank 3 from which liquid is suctioned for the purpose of the cooling thereof via the fluid line 12 back into the region of the reaction vessel 8.

[0046] Advantageously the first, second and third modules M1, M2, M3 are disposable articles, and the fourth module M4 comprising the electrical components may be reused as often as desired. The filter unit 15 is preferably an integral component of the third module M3 and thus also part of a disposable article. For reasons of weight and cost, the modules M1, M2 and M3 are produced from a plastics lightweight packaging material, which may also be sent for material recycling. Additionally the expansion tank 3 and the reaction vessel 8, formed by the modules 2 and 3, are provided with a liquid-tight coating on the inner wall.

[0047] A further preferred embodiment of the configuration of the cooling unit in the state of the directly vertically positioned modules M1, M2 and M3 is illustrated in FIG. 3, comparable with the view in FIG. 2. All of those components which are identical to the already described components are provided with the already introduced reference numerals.

[0048] In contrast to the view in FIG. 2, the fluid line 12 leads directly downstream to its fluid connection with the expansion tank 3 to outside the reaction vessel 8, where the fluid pump 16 is incorporated along the fluid line 12 and suctions liquid from the expansion tank 3 into the fluid line 12. Downstream of the fluid pump 16, which is outside the reaction vessel 8, the fluid line 12 leads back again into the reaction vessel 8 The fluid line 12 is helically shaped to provide a heat transfer contact surface which is as large as possible ensuring an effective cooling of the liquid conveyed inside the fluid line 12.

[0049] The filter unit 15 is arranged along the outlet line 14 from the reaction vessel 8. The filter unit is a bacterial filter, for example a Legionella filter, ensuring that the cooled liquid is germ-free, so that the heat exchanger W inside the oxygenator is not contaminated.

[0050] Additionally, the reaction vessel 8 has a vent 27 in the upper region, with a hydrophobic filter ensuring a complete and rapid filling of the reaction vessel 8 which prevents an uncontrolled escape of liquid to the outside.

[0051] After the cooling process is complete, a binding agent 28, preferably xanthan, which is stored in the reaction vessel 8, causes gelling of the liquid-reactant mixture so that a simple disposal of the modules 1, 2 and 3 is possible, such as for example household waste. To this end, the binding agent 28 is encapsulated with a liquid-soluble material which completely dissolves after a certain residence time inside the liquid and releases the binding agent inside the reaction vessel.

List of reference numerals

[0052] 1 Reservoir [0053] 2 First housing [0054] 3 Expansion tank [0055] 4 Functional means [0056] 5 Second housing [0057] 6 Overflow [0058] 7 Fluid connection [0059] 8 Reaction vessel [0060] 9 Third housing [0061] 10 Non-return valve [0062] 11 Reactant [0063] 12 Fluid line [0064] 13 Coiled line [0065] 14 Outlet line [0066] 15 Filter unit [0067] 16 Fluid pump [0068] 17, 17′ Releasable fluid-tight coupling [0069] 18 Hose system [0070] 19 Inlet line [0071] 20 Agitator [0072] 21 Gear unit [0073] 22 Drive motor [0074] 23 Electrical control unit [0075] 24 Electrical energy source, battery [0076] 25 Spacer [0077] 26 Remaining proportion of liquid [0078] 27 Venting unit [0079] 28 Binding agent [0080] W Heat exchanger [0081] O Oxygenator [0082] M1, M2, M3, M4 Modules [0083] P Direction of arrow [0084] K Cooling unit