Arrangement and method for de-icing a heat exchanger

What is claimed is: 1. An arrangement for de-icing a heat exchanger in a motor vehicle, the arrangement comprising: an air guiding housing that includes an inlet opening and an outlet opening, the air guiding housing being configured to take in an air from an outside of the motor vehicle through the inlet opening and to discharge the air from the outlet opening; and at least one fan that is positioned between the inlet opening and the outlet opening inside the air guiding housing and that is configured to circulate the air in the air guiding housing, wherein the heat exchanger is positioned between the inlet opening and the outlet opening inside the air guiding housing and allows the air to pass therethrough, thereby being configured to cool the air, the inlet opening and the outlet opening each are configured to be closed, and the air guiding housing is configured to cause a circulation flow therein when the at least one fan is operated while the inlet opening and the outlet opening are closed, wherein the arrangement further comprises: a partition wall that is positioned in the air guiding housing and that is configured to cause the circulation flow, wherein the partition wall is positioned in an end portion of the heat exchanger, the partition wall, together with the air guiding housing, defines a side channel that allows the air to flow therethrough and to pass through the end portion and a main channel that allows the air to flow therethrough and not to pass through the end portion, and the at least one fan faces the main channel along a flow direction along which the air flows from the inlet opening to the outlet opening. 2. The arrangement for de-icing a heat exchanger according to claim 1 , the arrangement further comprising a second heat exchanger that is housed in the air guiding housing and that is positioned between the inlet opening and the outlet opening, wherein the second heat exchanger is configured to allow the air to pass therethrough and is configured to transfer heat to the air. 3. The arrangement for de-icing a heat exchanger according to claim 2 , further comprising a partition wall that is positioned in the air guiding housing and that is configured to cause the circulation flow, wherein the at least one fan includes a first fan and a second fan, the partition wall defines a first passage that allows the air to flow therethrough and to pass through the first heat exchanger and a second passage that allows the air to flow therethrough and to pass through the second heat exchanger, and the partition wall is positioned asymmetrically relative to one of the first fan and the second fan. 4. The arrangement for de-icing a heat exchanger according to claim 2 , further comprising a partition wall that is positioned in the air guiding housing and that is configured to cause the circulation flow, wherein the at least one fan includes a first fan and a second fan, the partition wall is centrally arranged and divides a surface of the first heat exchanger into a first surface and a second surface and divides a surface of the second heat exchanger into a third surface and a fourth surface, the partition wall defines a third passage that allows the air to flow therethrough and to pass through the first surface area and the third surface area and a fourth passage that allows the air to flow therethrough and to pass through the second surface area and the fourth surface area the partition wall is positioned asymmetrically relative to one of the first fan and the second fan. 5. The arrangement for de-icing a heat exchanger according to claim 1 , the arrangement further comprising a plate door that is rotatable, wherein the at least one fan is located downstream of the heat exchanger in a flow direction along which the air flows from the inlet opening to the outlet opening, and the plate door is configured to be switched between a first position where the plate door guides the air flowing through the side channel to flow into the at least one fan and a second position where the plate door connects to the partition wall to extend the side channel to a radial end of the at least one fan. 6. The arrangement for de-icing a heat exchanger according to claim 1 , wherein the partition wall divides a surface of the heat exchanger into a first side surface and a first main surface, the side channel allows the air to flow therethrough and to pass through the first side surface, the main channel allows the air to flow therethrough and to pass through the first main surface, and the partition wall is positioned asymmetrically relative to the at least one fan. 7. The arrangement for de-icing a heat exchanger according to claim 2 , the arrangement further comprising a partition wall that is positioned in the air guiding housing and that is configured to cause the circulation flow; and a switching device that is configured to open and close a bypass channel, wherein the partition wall is positioned between the air guiding housing and at least one of the first heat exchanger and the second heat exchanger in a direction perpendicular to a flow direction along which the air flows from the inlet opening to the outlet opening, the bypass channel is defined between the partition wall and the air guiding housing and allows the air to flow therethrough while bypassing the at least one of the first heat exchanger and the second heat exchanger, and the switching device closes the bypass channel when the inlet opening and the outlet opening are open. 8. The arrangement for de-icing a heat exchanger according to claim 7 , wherein the switching device includes a flap that is configured to receive a tension pulling the flap along the flow direction. 9. The arrangement for de-icing a heat exchanger according to claim 7 , wherein the first heat exchanger and the second heat exchanger are arranged along the flow direction such that the first heat exchanger is located downstream of the second heat exchanger, the partition wall includes a first partition wall that is positioned between the first heat exchanger and the air guiding housing, extends along the flow direction, and defines a first bypass channel together with the air guiding housing, the first bypass channel allowing the air to flow therethrough while bypassing the first heat exchanger and a second partition wall that is positioned between the second heat exchanger and the air guiding housing, extends along the flow direction, and defines a second bypass channel together with the air guiding housing, the second bypass channel allowing the air to flow therethrough while bypassing the second heat exchanger, when the inlet opening and the outlet opening are open, the switching device is configured to be positioned selectively at a first open position where the switching device closes the first bypass channel to allow the air to flow through the second bypass channel and to flow into the first heat exchanger without flowing into the first bypass channel, a second open position where the switching device closes the first bypass channel and the second bypass channel to allow the air to flow through the first heat exchanger and the second heat exchanger. 10. A method for de-icing a heat exchanger in an arrangement according to claim 7 , the method comprising: closing the inlet opening and the outlet opening; and forming the circulation flow in the air guiding housing, wherein the bypass channel is optionally open and/or the fan is operated to cause a pressure difference between one side and an other side of the partition wall. 11. The method for de-icing a heat exchanger accor