DE102019211863A1 - Setting device for setting a flow rate of a medical elastomer pump - Google Patents

Abstract

Such an actuating device comprising a housing body with a fluid conduction path extending between an inlet opening and an outlet opening, which has a section with several fluid conduction channels connected in parallel, each with an orifice, and comprising an actuating element which is movably mounted on the housing body and is manual relative to the housing body is displaceable between at least a first setting position and a second setting position, wherein a sealing element connected to the setting element interacts with the mouth openings and in the first setting position seals a first number of the fluid line channels in a fluid-tight manner and in the second setting position seals a second number of the fluid line channels in a fluid-tight manner, whereby a The flow resistance of the fluid line path is variable, and thus the flow rate along the fluid line path is adjustable. According to the invention, the sealing element w At least one raised sealing section which protrudes at least in the first setting position in the axial direction into one of the mouth openings, the mouth opening and the at least one sealing section forming a latching connection which can be overridden by manual displacement of the adjusting element into the second setting position. Use in infusion therapy .

Description

The invention relates to an adjusting device for adjusting a flow rate of a medical elastomer pump, having a housing body with a fluid conduction path extending fluidly between an inlet opening and an outlet opening, which has a section with several fluid conduction channels connected in parallel, each with an orifice, and having an adjusting element that is movable mounted on the housing body and manually displaceable relative to the housing body between at least a first setting position and a second setting position, a sealing element connected to the setting element interacting with the mouth openings and sealing a first number of the fluid line channels in a fluid-tight manner in the first setting position and in the second setting position a second number of the fluid line channels seals fluid-tightly, whereby a flow resistance of the fluid line path is variable and thus the flow rate along the fluidle itation path is adjustable.

Such an adjusting device is generally known in the field of medical technology and is provided for setting a flow rate of a medical elastomer pump. Such elastomer pumps are generally known in particular in outpatient pain therapy for administering a medical fluid. The well-known adjusting device is offered on the market by the applicant under the name “Flow Selector” and has a housing body with an inlet opening and an outlet opening. In a ready-to-use state connected to the elastomer pump, the inlet opening is connected in a fluid-conducting manner to an outlet opening of the elastomer pump by means of a hose line. The outlet opening of the adjusting device is connected to a further hose line, which can also be referred to as a patient line. A fluid conduction path extends between the inlet and outlet openings of the actuating device and is formed in sections from a plurality of fluid conduction channels connected in parallel and having a comparatively small diameter. At one end, the fluid line channels each have an orifice. Furthermore, the known adjusting device provides an adjusting element which is designed as an adjusting wheel and is mounted on the housing body so as to be rotatable about an axis of rotation. The adjusting element can be manually displaced between different adjusting positions relative to the housing body. A sealing element connected to the adjusting element is provided for the optional fluid-tight sealing of the fluid line channels. In the different setting positions, the sealing element interacts with the mouth openings and in this way - depending on the setting position - seals a different number of fluid conduit channels. As a result, the flow resistance of the fluid line channel and thus the flow rate that can be conveyed by means of the elastomer pump along the fluid line path can be set. In the known adjusting device, the adjusting element and the sealing element are non-positively connected to one another and the sealing element covers the orifice openings for sealing the fluid channels in each case flat.

The object of the invention is to provide an actuating device of the type mentioned at the beginning which avoids incorrect metering and enables improved application safety.

This object is achieved in that the sealing element has at least one raised sealing section which, at least in the first setting position, protrudes in the axial direction into one of the mouth openings, the mouth opening and the at least one sealing section forming a latching connection which, by means of manual displacement of the adjusting element into the second position can be overridden. The solution according to the invention improves the positioning of the sealing element relative to the mouth openings. For this purpose, the solution according to the invention provides the at least one raised sealing section which protrudes into one of the mouth openings at least in the first setting position while forming the latching connection. This ensures that the sealing element is clearly positioned in the first setting position. In this way, a sealing that does not meet the requirements, which results from inaccurate positioning of the sealing element and in which too many or too few of the fluid line channels are sealed, can be avoided. As a result, incorrect settings of the flow rate and thus incorrect dosages of the medical fluid can be avoided by the solution according to the invention. This increases the reliability of the actuating device and the elastomer pump. The fluid conduction channels connected in parallel to conduct fluid can also be referred to as capillary channels. Connected in parallel fluid-conducting means that the fluid line path branches into the multiple fluid line channels in the area of the mouth openings and thus has multiple parallel sub-paths along which the medical fluid can be conveyed. The mouth openings are each arranged at one end of the fluid line channels and can each form an inlet or an outlet of the relevant fluid line channel. The mouth openings preferably each form an inlet of the relevant fluid line channel. In comparison to the fluid conduit path, the fluid conduit channels preferably each have a small diameter. The adjusting element can be connected to the sealing element in a non-positive, positive and / or cohesive manner. The adjusting element and the sealing element are preferably joined together in a materially bonded manner. The adjusting element, together with the sealing element, can be mounted on the housing body so as to be linear, rotatable and / or pivotable relative to the housing body. A rotatable displacement is preferably provided. The sealing element is preferably made of an elastic material. The sealing section has a raised design and can in this respect be designed, for example, in the form of a bulge, a projection, a projection or the like. At least in the first setting position, the sealing section protrudes into the respective mouth opening in the axial direction. In this way, the sealing section interacts positively with the mouth opening and forms the latching connection. The first setting position can therefore also be referred to as the first latching position. The locking connection can be over-locked and thus released by means of a displacement of the adjusting element into the second adjusting position. The sealing section preferably engages in a further of the mouth openings, so that the second setting position can also be referred to as the second locking position. The locking connection is preferably designed to be fluid-tight. Alternatively, the locking connection can be designed to be fluid-permeable and the fluid-tight sealing of the mouth opening assigned to the sealing section can also be effected by means of the sealing element.

In an embodiment of the invention, a spring element that is operatively connected to the sealing element and / or the actuating element is provided, by means of which a prestressing of the locking connection acting in the axial direction is brought about. The preload causes a force fit between the sealing element and the housing body and in this way supports the fluid-tight sealing of the fluid line channels in the set positions. In addition, the preload supports the function of the latching connection, since in particular an unintentional reaching out of the sealing section from the mouth opening is avoided. In this way, an incorrect setting of the flow rate can also be counteracted. The spring element can in particular be designed as a spiral spring or leg spring and made of metal or plastic, in particular an elastomer.

In a further embodiment of the invention, the at least one sealing section has a conical cross-sectional shape in relation to a central longitudinal plane. The conical cross-sectional shape of the sealing section enables the sealing section to grip better into and out of the respective mouth opening. This enables, in particular, a sufficiently smooth and yet defined locking of the locking connection. At the same time, the conical cross-sectional shape supports self-centering of the sealing section in the respective mouth opening. A further improved positioning of the sealing element can hereby be achieved. In addition, this design supports the fluid-tight sealing of the relevant fluid channel. The central longitudinal plane is preferably oriented perpendicular to a plane of displacement of the actuating element during a displacement between the different actuating positions.

In a further embodiment of the invention, the mouth openings - in relation to a respective central longitudinal plane - each have a conical cross-sectional shape. The conical cross-sectional shape of the mouth openings supports self-centering of the sealing section. In this way, a further improved positioning of the sealing element in the set positions can be achieved. At the same time, this design can support the fluid-tight sealing of the fluid line channels in the actuating positions. The respective central longitudinal plane is preferably oriented perpendicular to a plane of displacement of the actuating element when it is displaced between the different actuating positions. This embodiment of the invention is particularly advantageous if the sealing section also has a conical cross-sectional shape. Here, the conical cross-sectional shapes are preferably designed to be complementary and geometrically matched to one another. With such a complementary design, the sealing section and the respective mouth opening work together, as it were, in the manner of a valve and a valve seat. This is a particularly advantageous embodiment of the invention.

In a further embodiment of the invention, the sealing element has a plurality of sealing sections, a different number of sealing sections being effective in the different setting positions. With this configuration, in the first setting position, a first one of the sealing sections can engage in a first one of the mouth openings. If the actuating element is then moved into the second setting position, the first sealing section disengages from the first opening - the locking connection is therefore overlocked - and then engages in a second of the opening, with a second of the sealing sections simultaneously engaging the first opening. In this state, two locking connections are therefore effective. With an increasing number of effective sealing sections and thus the fluid-tight sealed fluid conduit channels, there is thus an increased expenditure of force for a further manual displacement of the actuating element to reduce the flow rate. As a result, a user of the actuating device receives improved manual feedback during operation.

In a further embodiment of the invention, the sealing element and the adjusting element are joined together to form a one-piece functional component. This can cause an unwanted Relative movement between the adjusting element and the sealing element can be avoided during a displacement between the adjusting positions. Accordingly, this embodiment of the invention supports the improved positioning of the sealing element, whereby incorrect settings of the flow rate can additionally be counteracted. The sealing element and the adjusting element are preferably joined together in a materially bonded manner.

In a further embodiment of the invention, the adjusting element is formed from a first plastic material, the sealing element is formed from a second plastic material and the functional component is manufactured in the form of a multi-component injection-molded part. This is a particularly advantageous embodiment of the invention. Manufacturing processes for the production of multi-component injection-molded parts are in any case known as such in the field of plastics technology. The first plastic material is preferably dimensionally stable. The second plastic material is preferably elastic. It has been shown that this embodiment of the invention can counteract unwanted settling of the sealing element in particular. Such settling phenomena can lead to leaks.

In a further embodiment of the invention, the adjusting element is designed in the form of an adjusting wheel rotatably mounted on the housing body about an axis of rotation, and the sealing element is designed in the form of a sealing ring arranged coaxially with the adjusting wheel. This embodiment of the invention enables particularly ergonomic operation of the actuating device. In addition, a particularly space-saving arrangement of the components, in particular the fluid line channels, can be achieved. In this embodiment of the invention, the mouth openings of the fluid line channels are preferably arranged along a circular path and at a constant radial distance from the axis of rotation on the housing body.

The invention also relates to a medical elastomer pump for conveying a medical fluid, having an elastomer membrane which forms a pump volume for receiving and conveying the medical fluid, the elastomer membrane being elastically stretched when the pump volume is at least partially filled with the medical fluid, and wherein by means of the elastically stretched membrane, a delivery pressure is brought about on the pump volume for delivering the medical fluid through an outlet of the pump volume, and having an adjusting device according to the above description, the inlet opening of the adjusting device being connected to the outlet of the pump volume in a fluid-conducting manner.

• 1 zeigt in schematisch stark vereinfachter Darstellung eine Ausführungsform einer erfindungsgemäßen medizinischen Elastomerpumpe, die zur Verwendung bei einer Infusionstherapie vorgesehen ist und eine Ausführungsform einer erfindungsgemäßen Stelleinrichtung aufweist,
• 2 in schematisch stark vereinfachter Darstellung die Stelleinrichtung nach 1 mit einem Gehäusekörper, durch den ein abschnittsweise verzweigter Fluidleitungspfad erstreckt ist, sowie mit einem Stellelement und einem Dichtelement,
• 3 in perspektivischer Explosionsdarstellung die Stelleinrichtung nach den 1 und 2 unter zeichnerischer Ausblendung einzelner Bauteile und/oder Abschnitte,
• 4 in vergrößerter Schnittdarstellung das Stellelement und das Dichtelement gemeinsam mit einem Federelement und
• 5 in teilweise abgeschnittener vergrößerter Schnittdarstellung einen Dichtabschnitt des Dichtelements bei einer fluiddichten Abdichtung eines der Fluidleitungskanäle des Fluidleitungspfads.

Further advantages and features of the invention emerge from the claims and from the following description of a preferred exemplary embodiment of the invention, which is illustrated with reference to the drawings.

• 1 shows in a greatly simplified schematic representation an embodiment of a medical elastomer pump according to the invention, which is intended for use in an infusion therapy and has an embodiment of an actuating device according to the invention,
• 2 the adjusting device according to FIG 1 with a housing body through which a partially branched fluid conduit path extends, and with an actuating element and a sealing element,
• 3 in a perspective exploded view the adjusting device according to the 1 and 2 by drawing out individual components and / or sections,
• 4th in an enlarged sectional view the actuating element and the sealing element together with a spring element and
• 5 in a partially cut-off enlarged sectional view a sealing section of the sealing element in the case of a fluid-tight seal of one of the fluid conduit channels of the fluid conduit path.

A medical elastomer pump 1 after 1 is to convey a medical fluid 2 provided as part of an outpatient and / or inpatient infusion therapy. The medical elastomer pump 1 can also be referred to as an elastomeric infusion pump.

The medical elastomer pump 1 has an elastomeric membrane 3 on that a pump volume 4th for receiving and conveying the medical fluid 2 trains. The medical fluid 2 is in the present case an unspecified drug liquid. Based 1 is the medical elastomer pump 1 shown in a filled state. The elastomeric membrane is in this state 3 as a result of mechanical action of the medical fluid 2 stretched like a balloon, soft and elastic. Here is the elastomeric membrane 3 based 1 for graphic reasons shown with an excessive wall thickness. In contrast, the membrane is 3 in one - not shown in the drawing - not with the medical fluid 2 filled state limp or at least less elastic stretched. For filling the pump volume 4th or the membrane 3 with the medical fluid 2 is a resealable filler neck 5 provided, which is fluid-tight to the membrane in a basically known manner 3 connected.

The elastically stretched membrane 3 causes a delivery pressure p on the pump volume 4th . The medical fluid is produced by means of the delivery pressure p ist effected in this way 2 through an outlet 6th the pump volume 4th into a fluid-conducting with the medical elastomer pump 1 connected medical fluid line system 7th fundable. The fluid line system 7th is for this purpose in a basically known manner fluid-conducting to an outlet nozzle 8th connected. The outlet port 8th is on the membrane 3 set. The fluid line system 7th has a first hose line 9 and a second hose line 10 on. Furthermore, the fluid line system 7th an adjusting device 11 assigned by which a based 1 fluid conduit path only indicated by dashed lines 12 is extended. The second hose line 10 has a fluid connector at one end 13 on, the fluid-tight connection with a dashed line indicated patient line 14th is provided. The other end is the second hose line 10 fluid-conducting with an outlet opening 15th the control device 11 connected. The first hose line 9 is fluid-conducting at one end with the outlet opening 6th the pump volume 4th and on the other end fluidly with an inlet opening 16 the control device 11 connected. The fluid conduit path 12 is fluid-conducting between the inlet opening 16 and the outlet opening 15th extends and has an adjustable flow resistance W in a manner to be described in more detail. By means of an adjustment of the flow resistance W there is thus one by means of the medical elastomer pump 1 along the fluid conduit path 12 and thus through the fluid line system 7th adjustable flow rate.

The further objective structure as well as the functionality of the actuating device 11 are particularly based on the 2 to 5 evident.

The control device 11 has a housing body 17th on which both the inlet port 16 as well as the outlet opening 15th is arranged. The fluid conduit path 12 is fluid-conducting between the inlet opening 16 and the outlet opening 15th extends and has a section A with a plurality of fluid conduction channels connected in parallel in a fluid-conducting manner 18a to 18e on. The fluid conduits 18a to 18e each have a mouth opening at one end 19a to 19e on. The mouth openings 19a to 19e are present at the inlet opening 16 facing ends of the fluid line channels 18a arranged. It goes without saying that the based 2 visible extension of the fluid line channels 18a to 18e is purely exemplary. The same applies to the present number of fluid conduit channels 18a to 18e .

Next, the control device 11 an actuator 20th on. The adjusting element has a sealing element 21st connected. Both the actuator 20th as well as the sealing element 21st are based 2 only shown greatly simplified and dashed. The actuator 20th is common with the sealing element 21st movable on the housing body in a manner to be described in more detail 17th stored and relative to the housing body 17th manually displaceable between at least a first setting position and a second setting position. In the embodiment shown, there are more than two set positions, namely a total of five and thus one of the number of fluid line channels 18a to 18e corresponding number of positions, provided.

The sealing element 21st acts in the different setting positions in a manner to be described in more detail with the mouth openings 19a to 19e together and in this way seals the individual fluid conduits 18a to 18e fluid-tight. The flow resistance W of the fluid conduction path 12 is dependent on the number of fluid-tight sealed fluid conduits 18a to 18e changeable. Are for example all fluid line channels 18a to 18e released, the flow resistance W is comparatively low. In such a state there is accordingly a comparatively high flow rate by means of the medical elastomer pump 1 along the fluid conduit path 12 fundable. With an increasing number of fluid-tight sealed fluid conduits 18a to 18e the flow resistance W increases to comparatively higher values. The flow rate decreases accordingly. Through this design of the actuating device 11 the flow rate can be adjusted in steps and in a simple manner according to the respective medical requirements.

In the present embodiment, the actuator is 20th in the form of a rotatable about an axis of rotation D on the housing body 17th mounted adjusting wheel designed ( 3 ). That based on 3 sealing element not visible 21st is on the underside of the setting wheel in relation to the drawing plane there 20th arranged and designed in the form of a coaxially oriented to the axis of rotation D sealing ring. The sealing ring 21st engages in one on the housing body 17th formed channel groove 22nd one representing a portion of the fluid conduit path 12 forms. The channel groove 22nd is oriented coaxially to the axis of rotation D and extends in a circular ring. The mouth openings 19a to 19e are in the channel groove 22nd arranged and spaced from one another in the circumferential direction, based on 3 only three of the mouth openings 19a to 19e can be seen. The sealing element seals in the assembled state 21st the channel groove 22nd outwards and acts with the mouth openings 19a to 19e together. Depending on which of the setting positions the setting wheel is in 20th is rotated around the axis of rotation D, will have a different number of orifices 19a to 19e of the sealing element 21st sealed.

Deviating from the specific configuration described above, an embodiment of the actuating device (not shown) provides that the actuating element is mounted on the housing body, together with the sealing element, so that it can move linearly between the different actuating positions.

Next is based 4th shown that the sealing element 21st a raised sealing portion 23 having. The sealing section 23 is with respect to an underside U of the sealing element 21st designed raised and in this way forms a kind of projection, bulge, projection or the like. The underside U is otherwise smooth. The sealing section 23 protrudes into one of the mouth openings at least in one of the set positions 19a to 19e into ( 5 ). This is based on 5 exemplary in interaction with the mouth opening 19a of the fluid conduit 18a shown. For sealing the fluid line channel 18th the sealing section protrudes 23 in the axial direction Z of the mouth opening 19a into the same. In this way form the sealing section 23 and the mouth opening 19a a locking connection. This locking connection is by means of a manual displacement of the adjusting element 20th can be locked in another of the positions.

In the event of such an overlocking, the sealing section engages 23 against the axial direction Z from the mouth opening 19a and is due to the displacement movement of the adjusting element 20th along the basis 5 apparent direction X - which in this case is a circumferential direction - from the mouth opening 19a moved away.

In the based 5 shown central longitudinal plane of the sealing section 23 this has a conical cross-sectional shape Q1 on. The cross-sectional shape Q1 tapers along the axial direction Z. The mouth opening 19a one to the cross-sectional shape Q1 Complementary and in this respect also conical cross-sectional shape Q2 on. This configuration supports the fluid-tight seal and at the same time ensures that the snap-in connection is easily manually locked. In addition, the sealing section is self-centering 23 in the mouth 19a achieved that a particularly precise positioning of the sealing element 21st relative to the mouth openings 19a to 19e supported. In the based 5 In the apparent state, a conical outer surface area acts accordingly F1 of the sealing section 23 and a conical inner lateral surface F2 the mouth opening 19a fluid-tight together.

In the embodiment shown, there is also a spring element 24 provided, by means of which a bias acting in the axial direction Z between the sealing section 23 and the mouth opening 19a trained locking connection is effected. The spring element 24 is designed in the form of a spiral spring and made of metal. Here is the spring element 24 on a shaft section 25th of the actuator 20th set and one end in the axial direction Z on radially from the shaft portion 25th protruding foot sections 26th supported. The shaft section is in the assembled state 25th along the axis of rotation D into a circular-cylindrical receiving recess 27 of the housing body 27 plugged in ( 3 ). The foot sections 26th reach behind the mounting recess 27 in the radial direction, so that the adjusting element 20th is set axially along the axis of rotation D. The spring element 24 is here at one end on the housing body in a manner not shown in detail 17th and the other end on the foot sections 26th and thus the actuator 20th supported. This is the actuator 20th together with the sealing element 20th Preloaded along the axial direction Z, which results in the above-described non-positive support of the latching connection.

In the embodiment shown, the adjusting element 20th and the sealing element 21st formed with the formation of a one-piece functional component in the form of a multi-component injection-molded component E. Here is the actuator 20th from a first plastic material K1 and the sealing element 21st is made from a second plastic material K2 educated. The first plastic material K1 is a dimensionally stable and mechanically sufficiently stressable plastic. The second plastic material K2 is in the present case an elastomer. The multi-component injection-molded part is formed in a basically known manner, with the first plastic material K1 and the second plastic material K2 be joined together in one piece in the course of a common injection molding process.

In the embodiment shown, the sealing element 21st only the one sealing section 23 on. However, this is not mandatory. In an embodiment not shown, several sealing sections 23 be provided, with a different number of the sealing sections interacting with the mouth openings in the different setting positions.

For further description it is assumed that in the based on 5 apparent configuration only the fluid conduit 18a is sealed fluid-tight. The adjusting element is used to further reduce the flow rate 20th - in relation to the plane of the drawing 3 - rotated clockwise around the axis of rotation D. As a result, the sealing section engages 23 against the axial direction Z from the mouth opening 19a out ( 5 ). Reaching out of the sealing section 23 and thus the release of the locking connection is made possible by the respective conical design of the cross-sectional shapes Q1 , Q2 or by the conical design of the outer jacket surface F1 and the inner lateral surface F2 supported. Further as a result of the displacement of the actuator 20th the sealing section moves 23 in the circumferential direction X of the channel groove 22nd and reaches the mouth 19b ( 3 ). The sealing section engages here 23 in the axial direction Z into the mouth opening 19b on. This is achieved by means of the spring element 24 caused preload supported. The second mouth opening is in the second set position that has now been reached 19b sealed fluid-tight. At the same time is the mouth opening 19a under the action of the sealing element 21st sealed fluid-tight. Here is the bottom U of the sealing element 21st flat at the mouth opening 19a at.

Claims (9)

Adjusting device (11) for adjusting a flow rate of a medical elastomer pump (1), comprising a housing body (17) with a fluid conduction path (12) which extends between an inlet opening (16) and an outlet opening (15) and has a section (A) with several having fluid conduction channels (18a to 18e) connected in parallel, each with an orifice opening (19a to 19e), and having an adjusting element (20) which is movably mounted on the housing body (17) and manually between at least a first one relative to the housing body (17) Adjustment position and a second adjustment position can be displaced, a sealing element (21) connected to the adjustment element (20) interacting with the mouth openings (19a to 19e) and in the first adjustment position a first number of the fluid conduit channels (18a to 18e) seals fluid-tight and in the second set position a second number of the fluid line channels (18a to 18e) seals fluid-tight, whereby a The flow resistance (W) of the fluid line path (12) is variable and thus the flow rate along the fluid line path (12) is adjustable, characterized in that the sealing element (21) has at least one raised sealing section (23) which at least in the first setting position in the axial direction ( Z) protrudes into one of the mouth openings (19a to 19e), the mouth opening (19a) and the at least one sealing section (23) forming a latching connection which can be locked into the second adjusting position by manually moving the adjusting element (20). Adjusting device (11) after Claim 1 , characterized in that a spring element (24) operatively connected to the sealing element (21) and / or the actuating element (20) is provided, by means of which a prestressing of the latching connection acting in the axial direction (Z) is effected. Adjusting device (11) after Claim 1 or 2 , characterized in that the at least one sealing section (23) - with respect to a central longitudinal plane - has a conical cross-sectional shape (Q1). Adjusting device (11) according to one of the preceding claims, characterized in that the mouth openings (19a to 19e) each have a conical cross-sectional shape (Q2) in relation to a respective central longitudinal plane. Adjusting device (11) according to one of the preceding claims, characterized in that the sealing element (21) has several sealing sections (23), a different number of sealing sections (23) being effective in the different setting positions. Adjusting device (11) according to one of the preceding claims, characterized in that the sealing element (21) and the adjusting element (20) are joined together to form a one-piece functional component (E). Adjusting device (11) after Claim 6 , characterized in that the adjusting element (20) is formed from a first plastic material (K1), that the sealing element (21) is formed from a second plastic material (K2) and that the functional component is in the form of a multi-component injection-molded part ( E) is made. Adjusting device (11) according to one of the preceding claims, characterized in that the adjusting element is designed in the form of an adjusting wheel (20) rotatably mounted on the housing body (17) about an axis of rotation (D), and that the sealing element in the form of a coaxial to the Adjusting wheel (20) arranged sealing ring (21) is designed. Medical elastomer pump (1) for conveying a medical fluid (2), comprising an elastomer membrane (3) which forms a pump volume (4) for receiving and conveying the medical fluid (2), the elastomer membrane (3) in at least one partially with the medical fluid (2) filled filling state of the pump volume (4) is elastically stretched, and by means of the elastically stretched membrane (3) a delivery pressure (p) on the pump volume (4) for conveying the medical fluid (2) through a Outlet (6) of the pump volume (4) is effected, and having an adjusting device (11) according to one of the preceding claims, wherein the inlet opening (16) of the Adjusting device (11) is connected to the outlet (6) of the pump volume (4) in a fluid-conducting manner.

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