The invention is directed to a hose cartridge for a peristaltic pump including a cartridge housing, a flexible pump hose segment extending through the cartridge housing, wherein both ends of the pump hose segment are fixed in the cartridge housing by means of a first fixing member and of a second fixing member, wherein the first fixing member and the second fixing member are arranged in the area of a first front face of the cartridge housing, and wherein the cartridge housing includes a recess for the engagement of a roller wheel of the pump in the interior of the cartridge housing. The invention is further directed to a peristaltic hose pump system including such a hose cartridge.
Peristaltic hose pumps are, for instance, used as suction and rinse pumps for medical purposes, in particular in minimal-invasive surgery. Specific applications include arthroscopy, laparoscopy, urology, hysteroscopy and cystoscopy. For medical applications, in particular a sterility meeting all requirements is needed, and for this reason, after use, the hose cartridge is usually disposed of, in order to avoid cross contamination between different patients. Therefore, the hose cartridges have to be low-priced, and, in particular, permit simple handling by operators, when the hose cartridge is connected with the pump as well as when it is removed therefrom.
For prior art peristaltic pumps, there are in principle two different basic concepts. The first basic concept is that the hose arranged around the roller wheel is pressed by means of a pressure bracket or the like against the roller wheel. Such peristaltic hose pumps systems are for instance known from the documents U.S. Pat. No. 4,798,580, U.S. Pat. No. 5,044,902, U.S. Pat. No. 5,213,483 and DE 100 62 600.9 A1. By a closure lever mechanism, the hose is fixed and pressed against the roller wheel by means of a pressure bracket.
The second basic concept, which the invention in principle uses, is that the hose is drawn around the roller wheel with a sufficient encircling angle by a traction of a suitable size. Thereby, a pressure bracket or the like is not required. The traction has to be selected, in consideration of the elastic properties of the hose, such that in the area of a roller of a roller wheel, the inner cross section of the hose is practically reduced to zero. With regard thereto, it is for instance known from the document DE 199 60 668 C1 that in a hose cartridges at least one leg of the pump hose segment following the circular segment is arranged displaceably in the longitudinal direction of the hose in the cartridge housing between a mounting position and an operating position. This is in principle very well established, yet requires a relatively complicated construction and is thus expensive to manufacture.
A hose cartridge of the construction mentioned above is known from the document U.S. Pat. No. 4,537,561. Therein, a straight pump hose segment is provided in a hose cartridge. The hose cartridge is inserted at right angles to the extension of the pump hose segment into the peristaltic pump, and the pump hose segment comes into contact with the roller wheel and is tensioned, during the insertion of the hose cartridge, with a low encircling angle around the roller wheel. In the insofar known hose cartridges, it is a disadvantage that, due to the geometry of the components, a sufficient pressure on the pump hose segment by the roller wheel is only achieved with relatively high forces. On the one hand, this requires high forces for the insertion of the hose cartridge, while on the other hand, components of the hose cartridge are subjected to bending moments, thus requiring a relatively stable structure.
It is therefore an object of the invention to provide a hose cartridge and a peristaltic hose pump system, wherein the hose cartridge can be mounted easily and safely, has a simple structure and a high reliability.
For achieving this technical object, the invention teaches that the pump hose segment extends in the hose cartridge along a circular segment spanning an angle of at least 90°, when the hose cartridge is not inserted into the pump. Preferably, the circular segment spans an angle from at least 120° to at least 160°, ideally approx. 180°. In other words, the ends of the pump hose segment are arranged at an angle with respect to each other from 90° to 220°, preferably from 150° to 200°, ideally from 170° to 190°, for instance approx. 180°. An angle of 0° means the angle of the ends with respect to each other, which the ends enclose for a straight extension of the pump hose segment with respect to each other.
Thereby it is achieved that the ends of the pump hose segment are practically exclusively subjected to tension. Further, by the high encircling angle, a safe sealing of the hose by the roller wheel is secured, and consequently a high achievable peristaltic pressure is obtained. In any case, it is not required to provide pressure means for pressing the pump hose segment against the roller wheel, when the hose cartridge is inserted into the pump. Equally, displaceable ends of the pump hose segment for the purpose of tensioning the pump hose segment around the roller wheel are not needed. Rather, the ends of the pump hose segment are stationary relative to the cartridge housing.
For the purpose of invention, in principle two different variants are possible.
On the one hand, it may be provided that the recess for the roller wheel extends in the area of the first front face between the first fixing member and the second fixing member. Then the insertion of the hose cartridge is achieved by a substantially linear movement from a mounting position into an operating position in a direction radially with regard to the roller wheel.
On the other hand, the recess may extend in an area of a side surface of the cartridge housing being orthogonal to the first front face and parallel to the circular segment. Then the cartridge can be inserted in a mounting position by placing the cartridge on the roller wheel in an axial direction. Thereafter follows either a linear displacement of the cartridge in a radial direction of the roller wheel or a rotational movement of the cartridge with a movement component radially to the roller wheel. Both movements terminate in the operating position. In each of the above variants, the pump hose segment is tensioned around the roller wheel by the movement of the hose cartridge into the operating position.
A preferred embodiment of the invention is characterized by that the fixing members comprise two hose lines each hydrostatically communicating with one end of the pump hose segment, the hose lines preferably being arranged substantially antiparallely to the ends of the pump hose segment. Then the hose lines can exit in particular through a second front face of the cartridge housing being opposed to the first front face. The term antiparallel relates to the flow direction of a fluid in the ends of the pump hose segment or in the hose lines. This embodiment is in particular suitable for a variant of the invention, in which the hose cartridge is displaced by a linear movement in the direction radially to the roller wheel into the operating position. In this embodiment it is further easily achievable that the roller wheel is arranged in the interior of a pump housing, thus any risk of injury or access possibility in the area of the roller wheel being excluded. Guiding of the linear movement of the hose cartridge is then performed by a cartridge pit being complementary to the shape of the hose cartridge.
In a cartridge housing according to the invention, there may also be provided two (or more) substantially parallel, stacked pump hose segments. In a corresponding manner, the hose lines connected to the ends of the pump hose segments have also to be doubled. In this embodiment, typically two roller wheels are provided in the pump, one pump hose segment each being assigned to one roller wheel. In this embodiment, it may also provided that both roller wheels can be controlled separately. In this way, for instance an independent control of a sucking function may take place by means of one pump hose segment, and a rinsing function by means of the other pump hose segment. It is however also possible to use one roller wheel only, and the roller wheel has then the necessary width in order to tension both pump hose segments simultaneously around the roller wheel.
Furthermore, it may be provided that at least one fixing member comprises a flexible membrane arranged in the area of the first front face and hydrostatically communicating with the pump hose segment. In the operating position of the hose cartridge, this flexible membrane is then in connection with a force and/or travel transducer, thereby in the operating position of the hose cartridge at last a pressure measurement being possible. Usually it will be recommended to arrange this flexible membrane at each fixing member, which represents the pressure side of the pump hose segment.
The invention further relates to a peristaltic hose pump system comprising at least one hose cartridge according to the invention, comprising a pump, which has at least one pump housing and a driven roller wheel, the hose cartridge and the pump housing having connecting members being complementary to each other, which are arranged relative to each other such that the pump hose segment is tensioned around the roller wheel, when the hose cartridge is connected with the pump housing and moved into an operating position.
As connecting members may in particular be used detachable latch connections. In detail, the connecting members may comprise the following components: a) at least one guide element arranged at or in the pump housing for a translational movement of the hose cartridge in directions orthogonally to the first front face (and radially to the roller wheel), b) at least one latch connection with a first latch element arranged at the cartridge housing and a second latch element arranged at the pump housing and being complementary to the first latch element, the latch connection latching thereinto, when the hose cartridge is displaced in the direction of the operating position, and c) a detachment member for releasing the latch connection. Alternatively, the connecting members may comprise the following components: a) at least one pivot axis arranged at or in the pump housing and substantially extending parallely to the axis of rotation of the roller wheel, about said pivot axis the hose cartridge being swiveling, the pivot axis being laterally displaced compared to the center of the pump hose segment, referred to the first front face, b) a latch connection with a first latch element arranged at the cartridge housing and a second latch element arranged at the pump housing and being complementary to the first latch element, the latch connection latching thereinto, when the hose cartridge is rotated about the pivot axis into the operating position, and c) a detachment member for releasing the latch connection. In either case, the hose cartridge is displaced or swiveled in a simple way and by using one hand only in the direction of the operating position, until the latch connection is activated. By actuation of the detachment member, then not only the latch connection is detached, but by the tension of the pump hose segment provided in the operating position, there is also an automatic ejection of the hose cartridge, in particular in the case of the variant with translational movements between the mounting and operating positions.
For a hose cartridge having a flexible membrane, it may be provided that the pump housing comprises a force and/or travel transducer being connected in the operating position of the hose cartridge with the flexible membrane of the hose cartridge. Thereby the pressure force of the fluid provided by the flexible membrane is converted in the fixing member into an electrical signal, which can then be used for pressure display and/or control or regulation purposes.
A peristaltic pump according to the invention typically comprises an electric motor drive means for the roller wheel. This may be a direct-current motor, an alternating-current motor or a stepper motor. Between a drive shaft of the motor and the drive shaft of the roller wheel, a mechanical reduction gear may be provided. However, a direct drive is also possible, for instance in the case of the stepper motor. Typically, the rotational speed of the motor is controllable and adjustable. For this purpose, typically a control circuitry is provided, and an operator can adjust the desired flow rates or pressures by control elements, such as buttons or switches, and the control circuitry controls and adjusts the correlated speeds according to an operating program. Further, the control circuitry will compare if applicable pressure values measured in the pump hose segment to desired pressure values or maximum pressure values and control the speed of the roller wheel in a corresponding manner. In an extreme case, the roller wheel may also be controlled in a reverse direction of rotation. A peristaltic pump according to the invention may alternatively or optionally be operated with mains voltage or with a battery or an accumulator. The technologies for drive and control or adjustment of a roller wheel of a peristaltic hose pump are known in the art and therefore need not to be explained here in more detail.
The hose cartridge or the cartridge housing may comprise a coding, which is specific for an application, such as arthroscopy, laparoscopy, urology or hysteroscopy. In the operating position of the hose cartridge, then by suitable means of the pump this code can be read. These means are in connection with the electronic controller and control for the respective application suitable operating parameters according to the operating program. Coding may take place mechanically, by means of a transponder or smart labels or the like.
In the following, the invention will be explained in more detail with reference to figures representing examples of execution only.
In
In
In
The cartridge housing 3 comprises a recess 10 for the engagement of the roller wheel 11 of the pump 2 in the interior of the cartridge housing 3. The recess 10 is arranged substantially in the area of the first front face 9 between the first fixing member 7 and the second fixing member 8. It also extends, however, in part into the side surface 12 of the cartridge housing 3 arranged at right angles to the first front face 9, such that the cartridge housing 3 can completely be slid over the roller wheel 11. The pump hose segment 4 is arranged in the hose cartridge 1 along a circular segment K spanning an angle of approx. 180°, when the hose cartridge 1 is not inserted into the pump 2. It is understood that that the term circular segment K needs not necessarily extend precisely along a circular arc, but represents the course, which results at a given angle of the two ends 5, 6 with respect to each other (here 180°).
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Number | Date | Country |
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236 143 | May 1986 | DE |
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Number | Date | Country | |
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20070217933 A1 | Sep 2007 | US |