Method, sample carrier, and device for the qualitative and/or quantitative detection of particles in a fluid

What is claimed is: 1. A device for detection of particles in a fluid, the device comprising: a receiver having a conduit for feeding the fluid, and a conduit for the discharge of the fluid; a light source; an optical sensor; a sample carrier, arranged between the light source and the optical sensor, for receiving fluid to be examined, wherein the sample carrier is movable relative at least to the sensor and is connectable via a fluid inlet to the conduit for feeding the fluid, and via a fluid outlet to the conduit for the discharge of the fluid, and wherein the sample carrier is exchangeably arranged in the receiver, the sample carrier comprising a closed channel formed between the fluid inlet and the fluid outlet conduit connections, the closed channel, at least in sections, comprising a transparent wall on two opposite sides; a pivotable bar arrangement for moving into a closed position fixing the sample carrier with a positive fit in a designated position in the receiver, the pivotable bar arrangement moving to an open position for withdrawal and replacement of the sample carrier with another sample carrier. 2. A device according to claim 1 , further comprising a blocking devices for blocking at least one of the conduit for feeding the fluid and the conduit for the discharge of fluid. 3. A device according to claim 1 , wherein the receiver comprises the conduit for feeding the fluid and the conduit for the discharge of fluid and each of the conduit for feeding the fluid and the conduit for the discharge of fluid extend from below the receiver into the sample carrier. 4. A device according to claim 1 , wherein the light source and the optical sensor are arranged in a manner movable relative to the sample carrier in steps. 5. A device according to claim 1 , wherein an optical axis formed between the light source and optical sensor is at an angle between 4° to 8° to a perpendicular through-beaming direction through the sample carrier. 6. A device according to claim 1 , further comprising a position means provided between the receiver and the sample carrier only permitting a fluid conductive connection to at least one of the fluid inlet and the fluid outlet when the sample carrier is arranged in the designated position in the receiver. 7. A device according to claim 6 , wherein the position means comprise a first switch which switches when the designated position of the sample carrier in the receiver is reached. 8. A device according to claim 1 , wherein a positive-fit means is provided between the receiver and sample carrier for ensuring a designated arrangement of the sample carrier in the receiver. 9. A device according to claim 6 , wherein the position means comprises: a first switch which switches when reaching the designated position of the sample carrier in the receiver; and a second switch which switches when the bar is in the position locking the sample carrier in the receiver. 10. A sample carrier for a device for detection of particles in a fluid, the device comprising a receiver, a light source, an optical sensor and the sample carrier, arranged between the light source and the optical sensor, for receiving fluid to be examined, wherein the sample carrier is movable relative at least to the sensor and is connectable via a fluid inlet to a conduit for feeding the fluid, and via a fluid outlet to a conduit for the discharge of fluid, the fluid inlet and the fluid outlet being arranged next to one another in an insertion direction, and wherein the sample carrier is exchangeably arranged in the receiver, wherein the sample carrier comprises a carrier frame which is closed off by transparent plates, with one of the transparent plates being at each of two sides, at least one of the transparent plates being arranged in a set-back manner with respect to a peripheral frame part, at least one channel-forming rib, which forms part of the carrier frame is provided between the fluid inlet and the fluid outlet, a projection at an insertion side, the projection being arranged out-of-center and forming a positive-fit means for positioning. 11. A sample carrier according to claim 10 , wherein the carrier frame comprises a plastic injection molded part which is fixedly and sealingly connected to the transparent plates with a material fit by way of welding. 12. A sample carrier according to claim 10 , wherein in the region of the inlets and outlets each comprise a recess in a portion of the frame part, each recess being filled with an elastic and seal-forming plastic. 13. A sample carrier according to claim 10 , wherein the frame comprises a grip piece, which forms part of the frame, on one side. 14. A sample carrier according to claim 10 , wherein the sample carrier has an essentially longitudinally extended and flat cuboid shape with flat sides with the transparent plates and with longitudinally extended sides arranged in an insertion direction. 15. A sample carrier according to claim 10 , further comprising a closed channel formed between the fluid inlet and the fluid outlet conduit connections, the closed channel being on an inner side of the transparent walls and being provided with at least one of a coating and a surface structuring which prevents the formation of deposits. 16. A sample carrier according to claim 15 , further comprising at least one marking provided between the transparent walls, on an inner side of the wall, in a region for an optical detection of the fluid. 17. A sample carrier according to claim 16 , wherein the closed channel, in the region for the optical detection of the fluid, has a channel cross section with a width that is greater than a height, in a perpendicular through-beaming direction, and is 1.5 to 3 times as large. 18. A method for detecting particles in a fluid with a device comprising a receiver, a light source, an optical sensor and a sample carrier arranged between the light source and the optical sensor, for receiving fluid to be examined, wherein the sample carrier is movable relative at least to the sensor and is connectable via a fluid inlet to a conduit for feeding the fluid, and via a fluid outlet to a conduit for the discharge of fluid, and wherein the sample carrier is exchangeably arranged in the receiver, wherein the sample carrier comprises a carrier frame which is closed off by transparent plates, with one of the transparent plates being at each of two sides, the method comprising the steps of: bringing the sample carrier into a designated position in the device; introducing the fluid to be examined into the sample carrier via the feed conduit; shutting off the discharge conduit; closing the feed conduit after the build-up of pressure within the sample carrier; allowing a dwell time to pass and effecting the optical detection of the sample; and after the optical detection, the feed and discharge conduits are opened, whereupon the fluid located in the sample carrier is replaced and the cycle is repeated beginning with the step of shutting off the discharge conduit.