DE4241830A1 - Heating device for infusion solution - has heating element incorporated in heat transfer element with reception channel for infusion solution line - Google Patents

Abstract

The heating device uses an electric heating element in thermal contact with a heat transfer element (20), having a reception channel for a section of the infusion soln. line and a heat-insulating outer cladding. The line section is inserted in the reception channel via a slot extending along its entire length parallel to its axis. Pref. the heating element is coupled to the wall of the reception channel in opposition to the insertion slot. USE - For bringing infusion soln. to body temp. independent of flow rate.

Description

The invention relates to a temperature control unit for Infu solutions with a preferably electrical heatable heating element.

Temperature control units of this type are used for the temperature control of infusible liquids to a temperature close to the body temperature of a patient. The administration preheated infusion solutions of this kind have an effect Gentle and should above all the spasms in vessels and thrombophlebitic reactions and increase the bioavailability of the infusion. It Temperature control units of this type are known which are used for on heating of the rivers in the infusion bottle are determined. There is an info on the bottle sionsschlauch connectable through which the infusion solution solution to the lower application point at Pa tients flows. The liquid gives heat to the Environment, causing them to enter the Patient cools down again. This results in Ab dependency on the flow rate Entry temperatures of the infusion solution. The be Known temperature control units are only at relatively high Infusion speeds or with immediate ver administration of the infusion solution with syringes makes sense applicable.

Based on this, the object of the invention reasons to ver the known temperature control device  improve that a warm application of Infu solutions regardless of their flow rate through an infusion tube.

To solve this problem, according to the invention combination of features specified in claim 1 beaten. Further advantageous configurations and Further developments of the invention result from the pending claims.

The solution according to the invention is based on the idea the flowing infusion liquid near the app heat the ligation point to body temperature. There is achieved by that even with very slow flow speeds noticeable cooling occurs. Therefore, according to the invention, one with the heater ment thermally connected, a continuous Ka nal for the positive inclusion of a preferably pa section near the client one of the Infu solution through which the infusion tube flows transmitter, together with the heating element on the outside me insulated heat transfer body proposed the a wall extending the entire length of the channel opening for the lateral parallel insertion of the In fusion tube with its section into the channel right.

To make handling the temperature control unit easier, can the heat transfer body together with the heater element in a pre-attachable to the patient's body  support structure that can be glued on, made of heat-insulating Plastic material is appropriately embedded so that it cannot twist become.

A particularly good heat transfer to the infusion hose can be achieved by the heat Transmission body from a preferably in the cross cut Ω-shaped bent sheet metal.

According to a further advantageous embodiment of the Invention is the support structure as an injection molding or Extruded part made of plastic, preferably polypropy len trained. This makes it more economical position, a modular structure is possible, which means that the Ent care of the plastic from the rest of the structure elements can be easily separated and recycled.

Another preferred embodiment of the invention provides that the heating element from a support plate ceramic material and one with the support plate mechanically connected heating current, preferably made of resistance wire or resistance paste existing heating resistor. This can do that Heating element in the manner of thin-film technology with small be manufactured according to manual manufacturing costs.

To implement a simple passive regulation of the Heating temperature is advantageous according to another Embodiment of the invention with the infusion solution directly or indirectly in thermal contact  temperature-dependent resistance, in particular a PTC resistor, connected in series with the Heizwi the state connected.

Increased security against overheating and one of the flow direction becomes independent control behavior reached when two along the infusion tube part pieces spaced from each other, with one each the ends of the heating resistor in series preferably directly connected by rivets PTC resistors are provided.

In the following the invention is based on one in the Drawing shown in a schematic manner example explained in more detail. Show it

Figure 1 is a perspective view of the temperature control device with infusion tube.

FIG. 2 shows a section along the section line II-II of FIG. 1;

Fig. 3 is a plan view of the broadside surface of the heating element.

The temperature shown in the drawing 10 be is of a substantially tubular, with ei ner via a peripheral opening 11 from outside access recess 13 provided support structure 12 material of art, a heat transfer body 20 and a heat-conductively connected to the heat transfer body 20 heating element 30th The heating element 30 has an elongated rectangular, conveniently made of ceramic material made plate 32 with a film-like heating resistor 34 applied to a broad side surface and two by press rivets 36 ', 36 ''conductively connected to the heating resistor 34 , near the ends of the ceramic plate 32 thermally attached PTC resistors 38 ', 38 ''on. The PTC resistors 38 ', 38 ''are also connected to at one longitudinal end on the ceramic plate 32 with rivets 40 ', 40 '' attached connecting wires of a power supply 42 , the connection of the PTC resistor 38 'to the opposite end by a of the ceramic plate 32 applied conductor track 44 is made. The ceramic plate 32 is glued with its broad side surface opposite the heating resistor 34 to the convex outside of an approximately equally long heat transfer body 20 consisting of a sheet metal Ω-shaped bent in cross section and provided together with the heat transfer body 20 with an electrically insulating plastic coating. The ceramic plate 32 and the heat transfer body 20 unit formed is stirnsei tig inserted into the kom to its outer profile-complementary recess 13 of the support structure 12, wherein the two bent legs 24 of the heat transfer body 20 against rotation are embedded in longitudinal grooves 15 of the supporting structure 12th The support structure 12 is at its end faces with a preferably snap-on plastic cover 14 'or 14 ''splash-proof and easy to clean ver closable. The cover 14 ', 14 ''have an inner contour of the heat transfer body 20 corresponding recess, the located on the power supply side of the heating element 30 cover 14 ' is additionally provided with a bore 16 for carrying out the connecting cable 42 . The opposite cover 14 '' can be molded onto a support structure made in an injection molding process.

When used as intended, a section 50 of an infusion tube close to the application site is first pressed in axially parallel through the edge opening 11 of the support structure 12 into the concave, advantageously a slight undersize compared to the infusion tube 50 having an inner channel 22 of the heat transfer body 20 . The support structure 12 is then fastened to the patient using a suitable fastening means, for example a plaster. Here, the edge opening 11 of the recess 13 for additional thermal insulation of the channel inner and to secure the fusion tube 50 against accidental extraction hen advantageously in the direction of the patient. The Heizele element 30 is powered by a power supply or a battery. The current-carrying heating resistor stood 34 heated over the heat coupling between ceramic plate 32 , heat transfer body 20 and infusion tube section 50, the infusion solution flowing through approximately to the patient's body temperature. At a flow rate of 130 ml / h, a heating output of approx. 2 watts is required. To regulate the heating power as a function of the Durchflußge speed two variable resistors 38 ', 38 ''with a positive temperature coefficient (PTC resistors or PTC thermistor) are provided with the infusion solution in thermal contact. The PTC resistors are connected in series with the heating resistor 34 . At higher flow rates, the infusion solution cools the PTC resistors more, thus reducing their resistance and increasing the heating current. The faster flowing liquid is consequently supplied with more heat. Conversely, when the liquid flows slowly, the heat dissipation decreases. The temperature and resistance of the PTC thermistor then increase and the heating current drops. This results in a passive control behavior of the heating element 30 with an approximately constant outlet temperature of the infusion solution. Due to the short flow distance from the temperature control unit 10 to the application point, the infusion solution is cooled only slightly.

Due to the temperature difference between the entry and exit of the infusion solution, a temperature gradient occurs along the temperature control device 10 . In order to achieve a control behavior independent of the direction of flow, a PTC resistor 38 ', 38 ''is arranged sym metrically to both ends of the heating resistor 34 appropriately. The arranged in the flow direction on the output side PTC resistor is then at a higher temperature and consequently has a higher resistance to the heating current. At the same time, the use of two PTC resistors increases operational safety against the short circuit of a PTC resistor.

In summary, the following can be stated: The invention relates to a temperature control device for infusion solutions with a heat transfer body 20 that can be heated by a thermally connected heating element 30 for heating an infusion solution flowing through an infusion tube, the inventive design of the temperature control device providing a body-warm temperature of the infusion solution close to the application site on a patient. The heat transfer body 20 has a continuous channel 22 with a wall opening extending over the entire channel length 25 for axially parallel insertion of a portion 50 of the infusion tube. The heating element 30 and the heat transfer body 20 are embedded in a heat-insulating support structure 12 which can be fastened to a patient's body.

Claims (12)

1.Tempering device for infusion solutions with a preferably electrically heatable heating element ( 30 ) characterized by a thermally conductively connected to the heating element ( 30 ), a continuous channel ( 22 ) for the positive reception of a section ( 50 ) of an infusion tube through which the infusion solution is flowing, common with the heating element ( 30 ) on the outside heat-insulated heat transfer body ( 20 ), which has a ge over the entire channel length extending wall opening ( 25 ) for lateral axially parallel insertion of the infusion tube with its portion ( 50 ) in the channel interior. 2. Temperature control device according to claim 1, characterized in that the heating element ( 30 ) on the wall opening ( 25 ) opposite the channel wall side to the heat transfer body ( 20 ) is thermally coupled. 3. Temperature control device according to claim 1 or 2, characterized in that the heat transfer body ( 20 ) together with the heating element ( 30 ) in a fastened to a patient's body, preferably stickable, liquid-tight sealable support structure ( 12 ) made of heat-insulating plastic material appropriately non-rotatably embedded is. 4. Temperature control device according to claim 3, characterized in that the support structure ( 12 ) a continuous, the heat transfer body ( 20 ) and the heating element ( 30 ) containing an edge opening ( 11 ) for the lateral insertion of the infusion tube with its section ( 50 ) has in the channel interior de recess ( 13 ). 5. Temperature control device according to claim 3 or 4, characterized in that the supporting structure ( 12 ) is formed as a molded part made of plastic. 6. Temperature control device according to one of claims 1 to 5, characterized in that the heat transfer body ( 20 ) consists of a good heat-conducting material, in particular of a metal such as aluminum or copper. 7. temperature control device according to claim 6, characterized in that the heat transfer body ( 20 ) consists of a preferably in cross-section Ω-shaped bent NEN sheet metal. 8. Temperature control device according to one of claims 1 to 7, characterized in that the heating element ( 30 ) has a support plate ( 32 ) made of ceramic material and one with the support plate ( 32 ) mechanically connected NEN, acted upon with heating current, preferably made of resistance wire or resistance paste heating resistor ( 34 ). 9. Temperature control unit according to claim 8, characterized in that the support plate ( 32 ) with its Heizwi resistance ( 34 ) opposite broad side surface is thermally coupled to the heat transfer body ( 20 ). 10. Temperature control device according to one of claims 1 to 9, characterized in that at least one with the infusion solution directly or indirectly in ther thermal contact temperature-dependent Wi resistance, in particular a PTC resistor, is connected in series with the heating resistor ( 34 ). 11. Temperature control device according to claim 10, characterized in that two along the infusion tube section ( 50 ) arranged at a distance from each other, with one of the ends of the heating resistor in series circuit, preferably directly connected by rivets ( 36 ', 36 '') PTC resistors ( 38 ', 38 '') are provided. 12. Temperature control unit according to one of claims 8 to 11, characterized in that the support plate ( 32 ) arranged on one side connection contacts ( 40 ', 40 '') and one of a connection contact ( 40 ') to the opposite end of the support plate led Lei terbahn ( 44 ) for the expediently battery-supplied power supply to the heating resistor ( 34 ).