Liquid cooling arrangement

The invention claimed is: 1. An arrangement for cooling, with liquid, one or more electrical devices or structural units of an electrical device that is/are in at least one installation enclosure, which arrangement comprises a suction channel ( 32 ) and a return channel ( 33 ) for distributing the liquid to the one or more electrical devices ( 22 ) to be cooled or to the structural units of the one or more electrical devices, a liquid container ( 30 ), which is connected to the return channel ( 33 ) directly and to the suction channel ( 32 ) via a second suction channel ( 28 ), a pump and a heat exchanger ( 24 ), and a shut-off valve ( 34 ) being operatively connected to the return channel ( 33 ) and being positioned at an uppermost point of the return channel ( 33 ), wherein the liquid container ( 30 ) is disposed below the one or more electrical devices ( 22 ) to be cooled or structural units of the one or more electrical devices ( 22 ) to be cooled, and an amount of liquid to be contained in the arrangement is configured to be such that ends of both the second suction channel ( 28 ) and the return channel ( 33 ) that are inside the liquid container ( 30 ) are situated below a liquid surface ( 29 ) of the liquid container ( 30 ), wherein the pump includes a drive motor ( 26 ), and a speed of rotation of the drive motor ( 26 ) of the pump is configured to be controlled according to a cooling requirement by monitoring a temperature of the one or more electrical devices ( 22 ) to be cooled or of the structural units of the one or more electrical devices, wherein when the shut-off valve ( 34 ) is closed, liquid is retained within the return channel ( 33 ) due to hydrostatic pressure and a positioning of the ends of the second suction channel ( 28 ) and the return channel ( 33 ) below the liquid surface ( 29 ). 2. The arrangement according to claim 1 , wherein shaping and cross-sectional area of the suction and return channels ( 32 , 33 ) are arranged in such a way that allows for an internal flow to the one or more electrical devices ( 22 ) to be cooled or the structural units of the one or more electrical devices ( 22 ) to be cooled by dynamic pressure losses of the suction and return channels ( 32 , 33 ) that are configured to be smaller relative to the dynamic pressure losses of an internal cooling channels of the one or more electrical devices ( 22 ) to be cooled or of their structural units regardless of the position in which the one or more electrical devices to be cooled or the structural units of the one or more electrical devices to be cooled is situated in a system. 3. The arrangement according to claim 1 , wherein the speed of rotation of the drive motor ( 26 ) of the pump is configured to be controlled by means of a frequency converter ( 27 ). 4. The arrangement according to claim 1 , wherein the signal controlling the speed of rotation of the drive motor ( 26 ) of the pump is configured to be formed in a separate control unit (CU) that is common to all the one or more electrical devices to be cooled or to the structural units of the one or more electrical devices to be cooled, which control unit is configured to monitor the temperatures (θ) of the one or more electrical devices ( 22 ) or of the structural units of the one or more electrical devices. 5. The arrangement according to claim 1 , wherein any of the one or more electrical devices ( 22 ) to be cooled is configured to form a signal controlling the speed of rotation of the drive motor ( 26 ) of the pump on a basis of the internal measurement (θ) of temperature of any of the one or more electrical devices or the structural units of the one or more electrical devices. 6. The arrangement according to claim 1 , wherein when the shut-off valve ( 34 ) is open and when the pump is inactive a whole cooling liquid content of the one or more electrical devices ( 22 ) to be cooled is able to flow to outside them. 7. The arrangement according to claim 1 , wherein a cooling piping is airtight when the shut-off valve ( 34 ) is closed. 8. The arrangement according to claim 1 , wherein the heat exchanger ( 24 ) is a liquid-air exchanger or a liquid-liquid exchanger. 9. The arrangement according to claim 1 , wherein the arrangement is configured to cool only the one or more electrical devices ( 22 ), or structural units of them, that are disposed in one installation enclosure. 10. The arrangement according to claim 2 , wherein the speed of rotation of the drive motor ( 26 ) of the pump is configured to be controlled by means of a frequency converter ( 27 ). 11. The arrangement according to claim 2 , wherein the signal controlling the speed of rotation of the drive motor ( 26 ) of the pump is configured to be formed in a separate control unit (CU) that is common to all the one or more electrical devices to be cooled or to the structural units of them, which control unit is configured to monitor the temperatures (θ) of the one or more electrical devices ( 22 ) or of the structural units of the one or more electrical devices. 12. The arrangement according to claim 3 , wherein the signal controlling the speed of rotation of the drive motor ( 26 ) of the pump is configured to be formed in a separate control unit (CU) that is common to all the one or more electrical devices to be cooled or to the structural units of them, which control unit is configured to monitor the temperatures (θ) of the one or more electrical devices ( 22 ) or of the structural units of the one or more electrical devices. 13. The arrangement according to claim 2 , wherein any of the one or more electrical devices ( 22 ) to be cooled is configured to form a signal controlling the speed of rotation of the drive motor ( 26 ) of the pump on a basis of the internal measurement (θ) of temperature of any of the one or more electrical devices or the structural units of the one or more electrical devices. 14. The arrangement according to claim 3 , wherein any of the one or more electrical devices ( 22 ) to be cooled is configured to form a signal controlling the speed of rotation of the drive motor ( 26 ) of the pump on a basis of the internal measurement (θ) of temperature of any of the one or more electrical devices or the structural units of the one or more electrical devices.