DE19510710A1 - Conditioning device for use with gas insufflator - Google Patents

Abstract

The insufflation gas conditioning device is contained within a body and has a means for adjusting the moisture content and temperature to that required for the human body. The gas is supplied by an insufflation device (92) which at it's outlet side is connected to a gas supply channel (90). The gas supply channel is connected via the conditioning device to an insufflation instrument (100). Within the device at the end of the gas supply channel are arranged a heat exchanger (3), and a moisture controller (4). A device (5) for removing foreign substances from the gas is optional. The heat exchanger is arranged immediately after the end of the gas supply channel. A capillary tube (9) supplies water from a reservoir (6) to the heat exchanger.

Description

The invention relates to an insufflation gas condition renation device in the preamble of claim 1 given type.

With minimally invasive interventions in human or animal body, for example in the area of the abdomen  (in laparoscopy), the uterus (in hysteros copy) or of joints (in arthroscopy), it is necessary, an existing cavity there by means of egg nes gas - for which preferably carbon dioxide is used will - expand. The resulting space creates a sufficiently large field of operations or observation, which allows the surgeon to take the necessary medication African interventions via suitable access points in the body height execution.

Nut developed the development of operative laparoscopy benefits of using minimally invasive technology to increased gas throughputs. These high gas throughputs during an operation, however, result in an unfavorable manner increased stress on the patient from heat and dehumidification from the body tissues in the area of the intervention.

The order of magnitude of the heat removal can thereby be illustrate that the insufflated, relatively cool gas at a gas flow of 30 liters per minute and one Temperature increase of 20 ° C absorbs a quantity of heat, for which he has an electrical power of about 16 watts would be required. This corresponds to about 20 percent of the heat amount which the body of an anesthetized he grown people as a whole.

The drying of the body widened by gas insufflation perhohlraums is due to the fact that for a Gas insufflation gas taken from a compressed gas storage in has essentially no moisture content. in the  Connection with the body heat conditional heating of the gas has an insufflated gas particularly high moisture absorption and removes the insufflated body cavity. Organ or vessel in ver increased moisture, while keeping the sub cooling of the body cavity is enhanced.

The more gas, especially in a relatively short period of time space, insufflated, the stronger the disturbing Effects on the organism.

For sustained damage to the insufflated body empire, for example by a catarral effect to avoid in the case of lung surgery, it is in Many cases require gas insufflation with a To connect gas conditioning. The gas in the sufflation device or an additional device suitable for the patient warmed and if necessary also moistened.

From European patent application EP 0 564 953 A1 a heating device for an insufflation device known with which a greatly reduced pressure gas, which on Device output a temperature in the range of 18 ° C to 24 ° C for the purpose of adaptation to the human body temperature is heated to 30 ° C to 35 ° C. The Erwär mungseinrichtung consists essentially of a Airbag, which is the connection between the Insufflation device and an insufflation instrument for Introducing the gas, preferably carbon dioxide, into the Body. The heating hose has an outer and inner tube layer made of plastic with in between  put on heating wire winding. The hose length is in the Range from 1.8 in to 2.5 m.

However, the solution described above has the after part on that the gas supply line through its inside de heating wire coil has a greatly enlarged diameter and has greater rigidity so that handling availability of the insufflation instrument considerably gets worse. Furthermore, this solution is narrow table unfavorable, since heat losses along the up to 2.5 m long gas supply line cannot be avoided. Become insufflated relatively small amounts of gas, so the Hose walls only a low flow rate speed available so that the required heat input in the gas over the hose wall not or only with considerable difficulties can be achieved. The construct tive change in the gas supply line requires in part way a separate coupling part to the In Connect the sulfation instrument to the gas supply line to be able to.

In addition, according to the European patent application EP 0 569 241 A2 and from the US patent US 5 006 109 Insuf flation systems known in which the gas heating inner half of the actual gas supply system the required pressure control is carried out. A possible gas humidification is separate from gas heating provided outside the gas supply system.

This form of gas conditioning is therefore disadvantageous because if the gas supply system heats up  to protect heat-sensitive measuring and control devices special thermal insulation is required. Wei then the insufflation gas must have a larger amount of heat be supplied so that a heat loss along the trans portweges to the point of gas introduction into the body is compensable. A smaller amount of heat supplied and thus an energetically more favorable form of gas conditioning In this case, increased heat insulation tion of the gas supply line possible. This leads to night liger way in turn to an increase in diameter Line, which increases the overall cost of manufacturing increase the gas supply line. By one in diameter stronger gas supply line also deteriorates at the same time the manageability of the insufflation instruct to a considerable extent.

The invention is therefore based on the object Insufflation gas conditioning device of the beginning to create the type mentioned, which is both constructive is simple and also energetically favorable and at the same time easy handling of the insufflationsin struments guaranteed.

This task is carried out with the characteristic features of the Claim 1 solved.

The invention includes the knowledge that by a Conditioning device in which an insufflie gas with regard to the requirements of the respective is conditioned according to the intervention or patient specification, constructive and energetic advantages for the Insuffla  tion system can be reached if at least the means the conditioning device with which the temperature of the gas to be insufflated is adjusted as densely as possible to be positioned at the location where the insufflating gas should be made effective.

Conditioning is heating and / or Humidification and / or filtering and in particular a com combination of at least two of these treatments of Understand insufflation gas.

In the conditioning device are accordingly preferred embodiment of the invention optionally the Structurally summarized, with which an adjustment the temperature and the humidity of the gas or the proportion of foreign substances in the gas quantity at the respective uses purpose of the gas can be made. It is favorable, the means for adjusting the gas in the requ moisture on the outflow side of a in the con ditionierung provided heat exchanger for order the temperature adjustment of the gas, since that already heated gas on the one hand absorbing moisture favored and on the other hand also an opportunity there is the evaporative cooling when moisture is released balance.

The conditioning device points up and down each side a connection means for a connection with the gas supply line and with the insufflation instrument on. For the connection of the conditioning device there is always a hose with the gas supply line  priced cheap. For the connection of the conditioning device with the insufflation instrument is additional also a connection means in the form of a, preferably conical insert or a screw binder advantageous because it is particularly short Transition paths between conditioning device and Insufflation instrument result or the conditioning device and the insufflation instrument on simple Can be summarized as a structural unit.

As the heat transfer to the insufflated and already regulated gas only in the immediate vicinity of the Effective range of the gas is made in green tiger way no constructively complex measures Avoidance of heat loss or later influences Pressure changes to the gas temperature required.

A possible heat loss in the area of the insufflation instruments can be neglected as the instrument largely in the patient's body or in the hand of the patient Surgeon is located and the temperature spread between the gas to be insufflated and the temperature of the Insufflationsinstrument has almost the value zero.

The shape of the gas supply line is essential for that Manageability of the entire insufflation system. These can - because with gas heating by directly with the Insufflation instrument related conditioning device for possible heat loss irrelevant - be trained very easily and flexibly, which makes the The insufflation instrument is extremely easy to use is.  

According to another embodiment of the invention are the connection means, preferably by screwing, with each other to form a closed annulus connectable. This annulus forms part of a heat metauschers, for example as a heating foil or as Heating winding from the heating element formed the annulus grips like a sleeve. The heat input into the con ditioning gas, which is built into one of the Connection means slowed down and to flow through the Annular space is forced, takes place in an advantageous manner through heat conduction.

After a favorable development of the invention to increase the temperature of the gas to be insufflated exposed heat exchangers essentially cylindrical educated. It consists of a good heat-conducting ceramic body with the gas flowing in the direction of flow cylindrical breakthroughs. For heating the ceramic Body is an electrical heating cable and at least a temperature sensor is provided to control the To be able to make gas temperature.

According to another advantageous embodiment of the heat exchanger are for the heat transfer from the heatable surface flow around the insufflating gas elements provided, which are star-shaped or arc-shaped formed or forming essentially transverse to the flow direction, flowable schika NEN are arranged within the heat exchanger.

That the heat exchanger in the direction of flow of the gas subordinate means for changing the gas moisture is  hydrophilic, preferably sponge-like and as Coating on the surface of the cylindrical heat exchange body pers attached. The amount of water required is one Liquid reservoir can be removed via a capillary. The Liquid reservoir is located on the outer wall the conditioning device.

According to a favorable development of the invention, this Liquid reservoir a line connection to the inflow side of the heat exchanger to the (otherwise essentially water caused solely by capillary action) transport into the sponge body by an additional Support pressure. In the conditioning device is a moisture on the downstream side of the heat exchanger speed sensor provided in combination with the Erfas a combined regulation of the gas temperature To be able to carry out gas conditioning.

According to another development of the invention, where the means for adjusting the temperature and the humidity of the gas to be insufflated not at the is in the same position, is the means of moistening trained as an ultrasonic nebulizer.

The means to reduce the foreign matter content is after an additional development of the invention with the Means to adjust the moisture to a structural Unit summarized. It is the moisturizer upstream and contains paper or having electrostatically charged plastic fibers Filter elements.  

Advantageous developments of the invention are in the Un claims are identified below along with the description of the preferred embodiment the invention with reference to the figures. It demonstrate:

Fig. 1 shows a longitudinal section through a preferred imple mentation of the invention,

Fig. 2 is a view of the device on the upstream side Wär metauschers shown in Fig. 1 conditioning,

FIGS. 3a to 3c advantageous developments of the Wär metauschers shown in Fig. 1 embodiment of the invention,

Fig. 3d shows another embodiment of the conditioning device according to the Invention

Fig. 4 shows a longitudinal section through another part before embodiment of the invention,

FIGS. 5a to 5c is a longitudinal section of details of the conditioning apparatus shown in FIG. 4
such as

Fig. 6 shows an additional development of the invention.

The conditioning device 1 shown in Fig. 1 as a longitudinal section in schematic form is designed as a through-flow cylindrical hollow body and has inflow and outflow sides respectively a connection means 11 and 12 which are connected to the gas supply line 90 and the insufflation instrument 100 of an insufflation assembly . The conditioning device 1 for the gas to be insufflated 16 thus forms a direct coupling member between the gas supply line 90 and insuffla tion instrument 100 and makes the use of additional components unnecessary. The connection means 11 is preferably designed as a hose connector, whereas the connection means, depending on the design of the insufflation instrument 100, is designed in the form of a screw connector or a preferably conical connector. The existing on the insufflation instrument 100 connection means 101 is selected to match the connection means 12 of the conditioning device 1 , so that it can be at least partially structurally integrated into the insufflation instrument. As a result, the conditioned insufflation gas 17 can advantageously reach its place of use by the shortest route.

The heat exchanger 3 for heating the gas to be insufflated, preferably up to the body temperature of the patient, is designed as a cylindrical disk and is shown in a top view in FIG. 2 from the inflow side. It has a plurality of similarly formed, preferably circular cylindrical, openings 10 , the longitudinal axis of which extends parallel to the direction of flow of the gas 16 , 17 and consists of a good heat-conducting material, preferably of a ceramic material. A sponge-like means 4 is provided on the outflow side of the heat exchanger 3 in order to be able to increase the moisture content of the gas 16 . The sponge layer 4 attached to the outflow side of the heat exchanger 3 is supplied with water 7 from a liquid reservoir 6 via a capillary tube 9 . In order to be able to use the pressure on the upstream side of the heat exchanger 3 to support the water discharge, a connecting line 8 is provided between the liquid reservoir 6 arranged on the outside of the conditioning device and the upstream side of the heat exchanger 3 .

The heat input into the heat exchanger 3 takes place via electrical heating wires 13 , which are attached to the heat exchanger 3 on the upstream side. The thermocouples 14 , 15 provide the measured values required for temperature control. The corresponding connecting lines are marked with 18.

A filter element 5 is provided downstream of the capillary tube 9 in order to free the tempered and humidified gas 17 from foreign matter particles at the outlet of the heat exchanger 3 .

In FIGS. 3a, 3b and 3c are other forms for the insertable into the conditioning device Wär exchanger 50, shown in simplified form, 60 and 70. In order to obtain a heat exchanger with the smallest possible dimensions and at the same time to have a large heat exchange surface, several heatable surface elements 51 , 61 , 71 are provided, which are arranged in an arrow-shaped or star-shaped manner on a flat surface or are seen with curved surfaces and limit the flow path of the gas to be conditioned in the radial direction.

In the conditioning device 80 shown in FIG. 3d as a longitudinal section, only a heating of the gas 82 to be insufflated is provided. The heat exchanger is formed from a plurality of heatable baffles 81 which extend substantially transversely to the direction of flow and which are contacted by the gas 82 when it flows through the device 80 .

Fig. 4 shows a further embodiment of a conditioning device 20 in longitudinal section. The individual parts 21 , 22 , 23 , from which the conditioning device 20 is composed, are also shown in FIGS. 5a, 5b and 5c as a longitudinal section.

The items 21 and 22 each have a hose connector 30 , 40 as a connecting means. The ends of the connection means facing away from the respective hose connector can be screwed together by means of the threaded parts 21.2 and 22.2 provided there and thereby enclose a cylindrical annular space 27 . A wall 21.5 blocking the flow channel 21.1 of the hose connector 30 on the outflow side forces the gas to be conditioned to flow into the annular space 27 through the holes 21.4 and to flow out of the annular space 27 into the flow channel 22.1 of the hose connector 40 through the holes 21.3 . As a result, a slowdown and swirling of the gas to be conditioned is achieved without a substantial increase in the flow resistance inside the conditioning device 20 .

Via the threaded section 22.3 of the hose connector 40 , the interconnected hose connector 30 , 40 can be connected by screwing to a sleeve-shaped radiator 23 (threaded section 23.1 ) made of a poorly heat-conducting material, which - due to a conical guide - closely to the outer wall of the annular space 27 is present, so that an essentially radially inward heat input into the gas to be insufflie-generating can take place by conduction. The heater 23 has for this purpose on its inner wall an electric heating element 23.2 , which is designed as a winding or foil-like term.

The heat exchanger thus formed is enclosed by a housing which can be assembled from two parts 24 , 25 and has axial openings from which the hose connections 30 , 40 protrude. By using a variable diaphragm 26 , one of the axial housing openings can be changed in diameter.

The arrangement of the bores 21.3 and 21.4 of the individual part 21 described above allows the flow direction of the gas to be insufflated in the conditioning device 20 to be freely selected in a favorable manner.

The insufflation arrangement shown in FIG. 6 has a pressure adapted to supply the gas to be insufflated, the insufflation device 92 , a gas supply line 90 , a conditioning device 1 'and an insufflation instrument 100 , which is connected to the conditioning device 1 ' on the downstream side by means of an adapter 102 . The conditioning device 1 'is used to heat the gas to be insufflated. The electrical heating power is supplied from the insufflation device 92 via a line 91 . The connection means 11 , 12 of the conditioning device 1 'are formed as a hose connector. The use of the adapter 102 enables the connection of different insufflation instruments 100 to the conditioning device in an advantageous manner.

The invention is not restricted in its implementation to the preferred embodiment given above game. Rather, a number of variants are conceivable which of the solution shown also in principle makes use of different types.

In particular, the described or similar built conditioning devices over a suitable, each with the output of the insufflation instrument or the measurement associated with the insufflated body cavity lers connected control unit operated such that the parameters of the insufflation gas are controlled. There at enables the extensive structural integration of Heating and humidifying devices also in simple Combined temperature / humidity control or -Regulation. The required temperature and / or Humidity sensors and control components are as such  knows.

Claims (22)

1. Insufflationsgas conditioning device with means for adapting the gas humidity and / or Gastem temperature to the conditions in a human body, for use for an insufflation arrangement having a compressed gas storage ( 92 ), the output side with the beginning of a - preferably tubular and gas supply line ( 90 ) connected to an insufflation instrument ( 100 ), characterized by the arrangement of the means ( 3 , 4 , 20 , 50 , 60 , 70 , 80 ) and / or adapting the moisture and / or the temperature of the gas to be insufflated a means ( 5 ) for reducing the foreign substance content of the gas at one of the ends of the gas supply line ( 90 ) provided for the connection between the insufflation arrangement ( 92 ) and the insufflation instrument ( 100 ), the means ( 3 , 20 , 50 , 60 , 70 , 80 ) at the end of the gas supply line ( 90 ) that was last passed by the gas during the supply t is. 2. Conditioning device according to claim 1, characterized in that at least partially a structural integration of the means ( 3 , 4 ) with the insufflation instrument ( 100 ) is provided. 3. Conditioning device according to one of the preceding claims, characterized in that the means ( 3 , 4 ) for influencing the gas temperature and / or the gas humidity is assigned at least one means ( 5 ) with which the foreign substance content of the insufflation gas ( 16 , 17 ) is reduced. 4. Conditioning device according to claim i, characterized in that the means for influencing the gas temperature or the gas on the inflow and outflow sides each have a connection means ( 11 , 12 , 30 , 40 , 83 , 84 ), at least one of the connection means as Hose connector ( 30 , 40 ) is formed. 5. Conditioning device according to claim 4, characterized in that the downstream connection means ( 12 ) is designed as a screw connector. 6. Conditioning device according to claim 4, characterized in that the outflow-side connection means ( 12 ) is designed as a connector element. 7. Conditioning device according to one of the preceding claims, characterized in that an adapter ( 102 ) is provided between the downstream connection means ( 12 ) and the insufflation instrument ( 100 ). 8. Conditioning device according to claim 3, characterized in that the tem perature of the flow medium influencing means is designed as a heat exchanger ( 3 , 20 , 50 , 60 , 70 ), which consists of a flowable, substantially circularly cylindrical body, the The axis extends essentially parallel to the direction of flow of the gas ( 16 , 17 ) to be insufflated. 9. Conditioning device according to claim 8, characterized in that as a heat exchanger a breakthrough ( 10 ) having, with inserted electrical heating elements ( 13 ) provided ceramic disc ( 3 ) is provided. 10. Conditioning device according to claim 8, characterized in that within the heat exchanger ( 20 ) deflecting means ( 21.3 , 21.4 , 21.5 ) are provided for slowing down or swirling the gas. 11. Conditioning device according to one of claims 10 and 11, characterized in that the cylinder consists of two, each a connection means ( 30 , 40 ) for connection to the gas supply line or with the insufflation instrument having individual parts ( 21 , 22 ) which are screwed together form a cylin drical annular space ( 27 ) which is encompassed by a heating element ( 23 ) having a heating foil or heating coil ( 23.2 ). 12. Conditioning device according to claim 8, characterized in that the heat exchanger ( 50 , 60 , 70 , 80 ) has heatable surface elements which are star-shaped ( 51 ) or arc-shaped ( 61 ) or form substantially transverse to Baffles ( 81 ) which extend around the flow and are arranged inside the heat exchanger. 13. Conditioning device according to one of claims 8 to 12, characterized in that the means ( 4 ) for influencing the moisture of the gas to be insufflated ( 16 , 17 ) on the outflow side of the heat exchanger ( 3 , 50 , 60 , 70 , 80 ) are arranged is. 14. Conditioning device according to one of claims 8 to 13, characterized in that the agent is designed as a hydrophilic, preferably schwammar term element ( 4 ) and attached to the surface of the heat exchanger ( 3 ). 15. Conditioning device according to claim 14, characterized in that schwammar term element ( 4 ) via a capillary ( 9 ) with a liquid reservoir ( 6 ) is connected. 16. Conditioning device according to claim 15, characterized in that the liquid reservoir ( 6 ) is located on the outer wall of the conditioning device ( 1 ). 17. Conditioning device according to claim 15, characterized in that the liquid keitsreservoir ( 6 ) has a line connection ( 8 ) to the upstream side of the conditioning device. 18. Conditioning device according to claim 1, there characterized in that the agent to influence the humidity of the gas to be insufflated is designed as an ultrasonic nebulizer. 19. Conditioning device according to one of claims 8 to 15, characterized in that a filter element ( 5 ) is provided for reducing the solids content of the insufflation gas, which is located on the outflow side of the heat exchanger ( 3 ). 20. Conditioning device according to claim 3, there characterized in that the insuf flation instrument or the insufflated body area at least one sensor to record the gas temperature and / or the gas humidity is assigned, the / whose Output signal (s) to control gas conditioning ge will be used. 21. Conditioning device according to claim 20, characterized in that the heat exchanger ( 3 ) has at least one thermal sensor ( 14 , 15 ) whose output signal is used to control the temperature of the Insuffla tion gas. 22. Conditioning device according to claim 3, characterized in that the means ( 5 ) for reducing the foreign matter content is associated with the means ( 4 ) for adjusting the moisture and has filter elements consisting of paper or electrostatically charged plastic fibers.