Multi-objective core-flood test system for oil recovery evaluation

The invention claimed is: 1. A system for performing a core-flood test, the system comprising: a core holder configured to be coupled to a computed tomography (CT) scanner system to monitor fluid saturations of a core comprising a rock sample; and a core sleeve to be received in the core holder, the core holder and the core sleeve separated by a confining space, the core sleeve to receive the core, wherein the core sleeve is configured to contact the core in response to a confining pressure applied to the core sleeve in the confining space and to be separate from the core in response to the confining pressure being removed, creating a fracture space between the core and the core sleeve, and wherein the core is configured to receive injected hydrocarbon; an injection plate attached to a first end of the core holder for transferring injected fluids to the core, the injection plate comprising an injection end cap tapered to substantially matching an inner diameter of the core sleeve for sealing the injection plate and the core sleeve; and a production plate attached to a second end of the core holder for collecting at least a portion of the hydrocarbon produced from the core. 2. The system of claim 1 , further comprising a plurality of rods for connecting the injection plate, the production plate, and the core holder. 3. The system of claim 2 , further comprising sealants applied around an edge of the core sleeve in contact with the injection plate and an edge of the core sleeve in contact with the production plate. 4. The system of claim 1 , wherein each of the injection plate and the production plate comprises a distribution channel for uniformly distributing injected fluids into the core. 5. The system of claim 4 , wherein the distribution channel further comprises an outer channel configured to transfer injected fluids to the fracture space between the core and the core sleeve. 6. The system of claim 1 , wherein the injection plate comprises: a first injection port for transferring an injection fluid into the core; and a second injection port for transferring a confining fluid into the confining space. 7. The system of claim 1 , wherein the production plate comprises a production port for transferring produced hydrocarbon. 8. The system of claim 1 , wherein the core holder is made of polyvinyl chloride (PVC). 9. A system for performing a core-flood test, the system comprising: a core holder configured to be coupled to a computed tomography (CT) scanner system to monitor fluid saturations of a core comprising a rock sample; and a core sleeve to be received in the core holder, the core holder and the core sleeve separated by a confining space, the core sleeve to receive the core, wherein the core sleeve is configured to contact the core in response to a confining pressure applied to the core sleeve in the confining space and to be separate from the core in response to the confining pressure being removed, creating a fracture space between the core and the core sleeve; and an injection plate attached to a first end of the core holder for transferring injected fluids to the core, the injection plate comprising an injection end cap substantially matching an inner diameter of the core sleeve for sealing the injection plate and the core sleeve. 10. The system of claim 9 , wherein the core is configured to receive injected hydrocarbon, and wherein the system further comprises a production plate attached to a second end of the core holder for collecting at least a portion of the hydrocarbon produced from the core. 11. A core-flood test method comprising: performing a first core-flood test of a core inside a core holder, wherein the core holder is mounted in a horizontal orientation; performing a second core-flood test of the core inside the core holder, wherein the core holder is mounted in a vertical orientation; and evaluating a gravity effect on hydrocarbon production based on a comparison of results of the first core-flood test and the second core-flood test. 12. The core-flood test method of claim 11 , wherein each of the first core-flood test and the second core-flood test comprises a saturation test and an imbibition test. 13. The core-flood test method of claim 11 , wherein performing the first core-flood test on the core inside the core holder comprises: collecting a first plurality of computed tomography (CT) images of the core while performing a third core-flood test; after performing the third core-flood test, performing a fourth core-flood test on the core using the core holder; collecting a second plurality of CT images of the core while performing the fourth core-flood test; and analyzing fluid saturations of the core based on the first plurality of CT images and the second plurality of CT images. 14. The core-flood test method of claim 13 , wherein the third core-flood test comprises a saturation test and the fourth core-flood test comprises an imbibition test. 15. The core-flood test method of claim 13 , further comprising, prior to performing the third core-flood test, collecting a CT image of the core to calculate porosity of the core. 16. The core-flood test method of claim 13 , wherein performing the third core-flood test on the core comprises: applying a confining pressure; injecting brine into the core; and injecting a hydrocarbon fluid into the core. 17. The core-flood test method of claim 16 , further comprising injecting CO 2 into the core before injecting the brine into the core. 18. The core-flood test method of claim 13 , wherein performing the fourth core-flood test on the core comprises: releasing a confining pressure; injecting a hydrocarbon fluid into a fracture space between the core and a core sleeve; injecting brine into the core to mimic a water flood; and injecting a surfactant flood into the core.