The invention relates to a static electrical device assembly comprising a static electrical device, a first heat exchanger adapted to cool the static electrical device, and a second heat exchanger adapted to recover heat from the static electrical device for utilization. Herein a static electrical device comprises a transformer or an inductor.
It is known in the art to adjust cooling of the static electrical device by providing the static electrical device assembly with an adjustable cooling pump adapted to transfer coolant between the static electrical device and the first heat exchanger, and/or an adjustable cooling fan adapted to provide an air flow between outdoor air and the first heat exchanger.
One of the disadvantages associated with the above static electrical device assembly is that the adjustable cooling pump and/or the adjustable cooling fan make the static electrical device assembly a complex and expensive assembly, and the cooling pump and/or the cooling fan increase energy consumption of the static electrical device assembly.
An object of the present invention is to provide a static electrical device assembly so as to alleviate the above disadvantages. The objects of the invention are achieved by a static electrical device assembly which is characterized by what is stated in the independent claim. The preferred embodiments of the invention are disclosed in the dependent claims.
The invention is based on the idea of providing the static electrical device assembly with an adjustable shutter arrangement adapted to regulate an air flow between outdoor air and the first heat exchanger.
An advantage of the static electrical device assembly of the invention is that cooling power of the first heat exchanger has a wide adjustment range, and neither a high air flow state nor a low air flow state of the shutter arrangement requires energy for operation. The static electrical device assembly of the invention is simple and inexpensive. It is possible to convert an existing static electrical device assembly into a static electrical device assembly according to present invention by retrofitting a shutter arrangement and other necessary components.
In an embodiment, a control system of the static electrical device assembly is adapted to keep temperature of the static electrical device within a narrow temperature range by controlling the shutter arrangement.
In the following the invention will be described in greater detail by means of preferred embodiments with reference to the attached drawings, in which
The static electrical device 2 of
The static electrical device 2 comprises a housing 21 and a winding system having a primary winding and a secondary winding. The static electrical device 2 is adapted to transfer electrical energy between the primary winding and the secondary winding. The winding system is located inside a coolant space of the housing 21, the coolant space containing coolant, which is in heat conductive connection with the winding system. The coolant comprises oil. In another embodiment the coolant comprises other electrically non-conductive liquid such as ester.
The heat exchanger system is adapted to remove heat from the coolant, and thereby to cool the winding system. The first heat exchanger 41 is adapted for cooling of the coolant by transferring heat into ambient air. The first heat exchanger 41 is a liquid-to-air heat exchanger. The second heat exchanger 42 is adapted to recover heat from the coolant for utilization. The second heat exchanger 42 is a liquid-to-liquid heat exchanger. In an alternative embodiment, the second heat exchanger is a liquid-to-air heat exchanger. Both the first heat exchanger 41 and the second heat exchanger 42 are in fluid connection with the coolant space of the housing 21.
The flow passage 6 is adapted to provide a route for air flow between outdoor air and the first heat exchanger 41. The shutter arrangement 8 is adapted to adjust a surface area of the flow passage 6 in order to regulate an air flow between outdoor air and the first heat exchanger 41. The control system CTRL is adapted to control the shutter arrangement 8 between an open state shown in
In the enclosed state a surface area of the flow passage 6 is smaller than in the open state. In other words, in the enclosed state the shutter arrangement 8 covers a greater portion of the first heat exchanger 41 than in the open state. The open state provides more cooling power than the enclosed state.
The air flow in the flow passage 6 is adapted to take place exclusively by means of natural convection. Further, a coolant flow between the coolant space of the housing 21 and the first heat exchanger 41 is adapted to take place exclusively by means of natural convection. In an alternative embodiment, the static electrical device assembly comprises a low-power fan adapted to boost air flow in the flow passage, and a low-power pump adapted to boost coolant flow between the coolant space of the housing and the first heat exchanger.
The flow passage 6 comprises a side section 62 and an overhead section 64. The side section 62 is located on one side of the first heat exchanger 41 such that the first heat exchanger 41 is located between the side section 62 and the housing 21 in a horizontal direction. The side section 62 is adapted to provide a route for a horizontal air flow between outdoor air and the first heat exchanger 41. The overhead section 64 is located directly above the first heat exchanger 41, and is adapted to provide a route for a vertical air flow between the first heat exchanger 41 and outdoor air.
A surface area of the overhead section 64 is equal to a surface area of the first heat exchanger 41 defined on a horizontal plane such that in the open state of the shutter arrangement 8 projections of the shutter arrangement 8 and the first heat exchanger 41 on a horizontal plane do not overlap. In other words, the shutter arrangement 8 allows, in the open state thereof, a completely unobstructed air flow upwards from the first heat exchanger 41 to outdoor air. In an alternative embodiment, a surface area of the overhead section defined on a horizontal plane is at least 75% of a surface area of the first heat exchanger defined on a horizontal plane.
In the enclosed state of the shutter arrangement 8 the first heat exchanger 41 is substantially isolated from outdoor air such that there is substantially no route for an air flow between outdoor air and the first heat exchanger 41. This means that in the enclosed state of the shutter arrangement 8 there is no intentional route for air flow between outdoor air and the first heat exchanger 41 but all such routes, if any, result from manufacturing tolerances and roughness of materials.
In an alternative embodiment, a surface area of the flow passage corresponding to the enclosed state is at least 90% smaller than a surface area of the flow passage corresponding to the open state. In another alternative embodiment, a surface area of the flow passage corresponding to the enclosed state is at least 75% smaller than a surface area of the flow passage corresponding to the open state. In a further alternative embodiment, a surface area of the flow passage corresponding to the enclosed state is at least 50% smaller than a surface area of the flow passage corresponding to the open state. Basically it is easier to achieve high percentage in new assemblies than in retrofitted assemblies.
The static electrical device assembly further comprises a restricting wall arrangement 10 adapted to restrict air flow between outdoor air and the first heat exchanger 41. The restricting wall arrangement 10 comprises a first side wall, a second side wall and a bottom wall. The first side wall and the second side wall are vertical and parallel walls spaced apart from each other. The first heat exchanger 41 is located between the first side wall and the second side wall. The bottom wall is a horizontal wall connecting the first side wall and the second side wall. The bottom wall is located below the first heat exchanger 41.
The first side wall, the second side wall and the bottom wall are located close to the first heat exchanger 41. Distance between the first heat exchanger 41 and each of the first side wall, the second side wall and the bottom wall is less than 0.5 m. In an alternative embodiment distance between the first heat exchanger and each of the first side wall and the second side wall is less than 1.0 m.
Each of the first side wall, the second side wall and the bottom wall is made of material capable of blocking both air flow and thermal radiation. In an alternative embodiment, the restricting wall arrangement 10 comprises thermal insulation material.
The shutter arrangement 8 has a plurality of intermediate states between the open state and the enclosed state thereof. In
A shaft around which the roller shutter 82 is wound in the open state of the shutter arrangement 8 is a horizontal shaft located above the first heat exchanger 41, and spaced apart from the first heat exchanger 41 in horizontal direction. When transferring from the enclosed state towards the open state of the shutter arrangement 8, the side section 62 is uncovered first and the overhead section 64 of the flow passage 6 is uncovered subsequently.
In alternative embodiments, the shutter arrangement comprises at least one shutter element comprising at least one roller shutter and/or at least one jalousie. In an embodiment, the first side wall and the second side wall of the static electrical device assembly of
In the enclosed state of the shutter arrangement 8, distance between the first heat exchanger 41 and the roller shutter 82 is less than 0.5 m. In an alternative embodiment distance between the first heat exchanger and the shutter arrangement is less than 1.0 m when the shutter arrangement is in the enclosed state of thereof.
The shutter arrangement 8 is adapted to cooperate with the first side wall, the second side wall, the bottom wall and an end wall 219 of the housing 21 in order to provide the enclosed state of the shutter arrangement 8 in which the first heat exchanger 41 is substantially isolated from outdoor air. The first side wall, the second side wall, the bottom wall and the end wall 219 of the housing 21 are fixed walls, and only the shutter arrangement 8 is adapted to adjust cooling power of the first heat exchanger 41.
In alternative embodiments, there are fewer fixed walls than in the embodiment shown in
The flow passage 6 is defined by the shutter arrangement 8, the restricting wall arrangement 10 and the end wall 219 of the housing 21. In an alternative embodiment the flow passage is defined by the shutter arrangement and the restricting wall arrangement, wherein the restricting wall arrangement comprises a back wall which is a fixed vertical wall connecting the first side wall and the second side wall, and located between the first heat exchanger and the static electrical device.
In a general case, cooling power of the first heat exchanger corresponding to the enclosed state is at least 50% lower than cooling power of the first heat exchanger corresponding to the open state. Depending on embodiment, such a decrease in cooling power can be achieved by relatively small change in the surface area of the flow passage.
In an embodiment, the first heat exchanger comprises a heat exchanger stack having a plurality of substantially planar heat exchanger elements stacked adjacent each other such that planes defined by the heat exchanger elements are vertical. In said embodiment, it is possible to greatly reduce the cooling power of the first heat exchanger simply by reducing air flow between the heat exchanger elements. Said reducing can be achieved with jalousies provided between the heat exchanger elements. It should also be noted that in order to reduce a vertical air flow between the heat exchanger elements, it is basically sufficient to provide one jalousie above or below the heat exchanger stack. Similarly, in order to reduce a horizontal air flow between the heat exchanger elements, it is basically sufficient to provide one jalousie at one side of the heat exchanger stack.
The sensor system comprises temperature sensors adapted to provide information relating to temperature of the static electrical device 2, and a heat requirement sensor 542 adapted to provide information relating to heat requirement of the second heat exchanger 42. The temperature sensors comprise a winding temperature sensor 523 adapted to provide information relating to temperature of the winding system, and a coolant temperature sensor 525 adapted to provide information relating to temperature of the coolant.
The heat recovering pump 3 is adapted to transfer coolant between the coolant space and the second heat exchanger 42. The control system CTRL is adapted to control the heat recovering pump 3 and the shutter arrangement 8 based on information provided by the sensor system. The control system CTRL is adapted to increase cooling of the static electrical device 2 by controlling the shutter arrangement 8 towards the open state, and by increasing rotation speed of the heat recovering pump 3. The control system CTRL is adapted to decrease cooling of the static electrical device 2 by controlling the shutter arrangement 8 towards the enclosed state, and by reducing rotation speed of the heat recovering pump 3.
In an embodiment the heat recovering pump is omitted. In said embodiment, the control system is adapted to increase cooling of the static electrical device by controlling the shutter arrangement towards the open state. The control system is adapted to decrease cooling of the static electrical device by controlling the shutter arrangement towards the enclosed state.
The hotter the coolant, the more heat the second heat exchanger 42 can recover. In situations where the second heat exchanger 42 requires heat, and the heat recovering pump 3 is running, the control system CTRL is adapted to keep the shutter arrangement 8 in the enclosed state, unless temperature of the static electrical device 2 rises higher than allowed by prevailing operating state.
In an embodiment, the second heat exchanger is located inside a building, and heat recovered by the second heat exchanger is utilized for heating of the building. In an alternative embodiment, heat recovered by the second heat exchanger is utilized for producing hot water.
The control system CTRL has an isothermic operating state in which the control system CTRL is adapted to keep temperature of the static electrical device 2 within a favourable temperature range, wherein information relating to the temperature of the static electrical device 2 is provided by at least one of the temperature sensors. The favourable temperature range is a narrow temperature range which is remote from the maximum allowable temperature of the static electrical device 2. In an embodiment, width of the favourable temperature range is 10° C. In another embodiment width of the favourable temperature range is less than or equal to 20° C.
The isothermic operating state of the control system CTRL reduces need for maintenance. Temperature variation of the static electrical device 2 sucks moisture from ambient air, and therefore reducing the temperature variation reduces need to replace desiccation material of the static electrical device 2.
The control system CTRL further has a heat recovery operating state in which the control system CTRL is adapted to optimize heat recovery by the second heat exchanger 42. In the heat recovery operating state the control system CTRL is adapted to keep temperature of the static electrical device 2 within a heat recovery temperature range which is wider than the favourable temperature range.
Operating state of the control system CTRL is adapted to be selected by operating personnel of the static electrical device assembly. In an alternative embodiment, the control system is adapted to select operating state thereof automatically based on at least one predetermined condition.
In an embodiment the heat recovery temperature range only has an upper limit, which is less than or equal to the maximum allowable temperature of the static electrical device. In an alternative embodiment, the heat recovery temperature range also has a lower limit which is selected to ensure that the coolant remains in liquid state.
In an embodiment, the static electrical device assembly comprises a heat pump, which is adapted to use the second heat exchanger as a source of heat. In this embodiment, the control system has a heat recovery operating state in which the control system is adapted to maximise operating efficiency of the heat pump.
It will be obvious to a person skilled in the art that the inventive concept can be implemented in various ways. The invention and its embodiments are not limited to the examples described above but may vary within the scope of the claims.
Number | Date | Country | Kind |
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18248066.5 | Dec 2018 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/082212 | 11/22/2019 | WO | 00 |