FI125386B - A method for manufacturing a manifold for a liquid-cooled cardiac electrical component and a manifold for a liquid-cooled cardiac electrical component - Google Patents

Description

A method for manufacturing a manifold for a liquid-cooled cardiac electrical component and a manifold for a liquid-cooled cardiac electrical component

Field of the Invention

The invention relates to electrical power engineering and to cardiac structural fluid cooling of electrical power components, such as liquid cooling of transformers and chokes, and in particular to a method of manufacturing a manifold for a liquid cooled cardiac electrical power component and liquid cooled electrical power components.

BACKGROUND OF THE INVENTION Components of electrical power engineering are used in a variety of applications in the generation, transmission and distribution of electricity, as well as in various industrial applications. In industry, electrical power technology components are used, for example, in various applications of process and manufacturing technology, in the use of transport equipment, and in applications in the energy industry.

The core components of electrical power technology include transformers and inductors. A transformer is a device used in electrical power technology that converts AC voltage or current to another voltage or current of the same frequency. In its simplest form, the transformer has two separated windings, a primary winding and a secondary winding, wrapped around the same core structure. The alternating current passing through the primary winding of the transformer generates a variable magnetic flux in the heart structure, which in turn induces a voltage corresponding to its rotational speed at the poles of the secondary winding. Similarly, the inductor is a device used in electrical power technology that smooths out changes in the current used in the application and eliminates interference. At its simplest, the inductor has a coil wound around the heart structure. There may be an air gap in the SS structure. The alternating current supplied to the coil generates a variable magnetic flux in the core structure, which in turn generates an electromotive force opposite to the voltage acting on the coil. The resulting electric motor force resists current fluctuations. The inductor thus compensates for changes in winding current and eliminates interference. Indeed, chokes are often used for interference suppression and various filter solutions. The core structures of the electrical power technology components typically include the column structures on which the windings are located, as well as the structures connecting the column structures. The use of cardiac electrical power technology components results in heat loss and, as a result, the heart structures of the components become hot. The most commonly used method for cooling cardiac-based electrical power components is liquid cooling. Liquid cooling of electrical power engineering components in electrical structures is based on fluid cooling elements located in the immediate vicinity of the core structures. Liquid cooling elements are provided with a coolant circulation in which cooled liquid is introduced into the liquid cooling elements. In the fluid cooling elements close to the cardiac structures, the coolant is heated and the heated coolant is further removed from the liquid cooling elements for re-cooling. By recycling the coolant, excess heat can be removed from the core structures of the electrical power engineering components.

When the cooled coolant is introduced into a cardiac electrical power component, it must be capable of being distributed to a plurality of liquid coolant elements. Similarly, the coolant coming from the cardiac electrical power component has to be assembled from a plurality of fluid cooling elements. Thus, manifolds for the distribution and assembly of coolant have typically been used in the recycling of coolant core components for electrical power technology.

Prior art will be described in more detail below with reference to the accompanying drawings, in which:

Fig. 1 is a top plan view of a manifold of a liquid-cooled cardiac electrical power component of the prior art,

Fig. 2 shows a cross-sectional front view of a manifold of a prior art liquid cooled cardiac electrical power component; and

Figure 3 shows a cross-sectional view of a manifold of a component of a prior art liquid cooled cardiac electrical power technology.

Figure 1 is a top plan view of a manifold structure of a prior art liquid-cooled cardiac electrical power component. The manifold 1 of the prior art electrical power component comprises two coolant channel holes 2, 3, from which the coolant can enter the manifold 1, or respectively, from which the coolant can come out of the manifold 1. The coolant channel holes 2, 3 may be provided with threads the connectors for the coolant hoses to be connected can be attached. The holes 2, 3 of the coolant channel can be closed with a screw plug if desired.

Figure 2 is an oblique frontal view of a manifold structure of a prior art liquid-cooled cardiac electrical power component. The prior art electrical power component manifold 1 comprises two coolant channel holes 2, 3. In addition, the prior art manifold 1 comprises manifold holes 4-7 through which the cooled coolant can be supplied from the coolant from the liquid cooling elements of the electric power component may be introduced into the manifold 1. The holes 4 to 7 of the manifolds may also be provided with threads to which the connectors for the liquid coolant hoses to the threaded manifold 1 can be attached. The figure also shows, by numbering, the mounting holes 8, 9 of the prior art manifold, to which the screws to be mounted in the mounting holes 8, 9 fasten the manifold to the binding structures of the cardiac electrical component.

Figure 3 is a cross-sectional view of a manifold of a prior art liquid-cooled cardiac electrical power component. The manifold 1 of the prior art electric power component comprises holes 2, 3 in the coolant channel, and holes 10, 11 at opposite ends of the coolant channels, respectively. For example, when the holes 2 and 11 of the coolant channels are used, the holes 3, 10 typically located at opposite ends of the coolant channels are closed with plugs. The mounting holes 8, 9 of the prior art manifold are also numbered in the figure.

Figure 3 shows a prior art manifold 1 further comprising manifold holes 4-7, 12-15, through which manifold cooled fluid can be discharged from manifold 1 to the liquid cooling elements of the cardiac electrical power component, or respectively the manifold ice-cooled electroconductor component can also be introduced into manifold 1. The manifold holes 4-7, 12-15 may also be provided with threads to which the coolant hose connectors for the liquid coolant elements to be connected to the threaded manifold 1 can be attached. Further, the holes 4-7.12-15 of the distribution channels which are not used can be closed with plugs.

Prior art solutions for distributing and assembling coolant in cardiac electrical power components as well as prior art manifold solutions and manifold manufac- turing solutions have some significant disadvantages and disadvantages. While the prior art core manifold electrical component manifolds may themselves be made small in size and compact, it is difficult to install compactly in the cardiac electrical component component binder structures themselves. Furthermore, the prior art manufacture of manifolds for cardiac electrical power components is expensive and consumes a lot of material.

In prior art cardiac electrical power component component mountable manifold solutions, the coolant hoses introduced and removed from the manifolds occupy a considerable amount of space in the component. Frequently, the coolant hoses are difficult to install, the mounting directions of the hoses are poor, and the coolant hoses are unreasonably long, increasing the size and manufacturing costs of the electrical power components. Thus, the cardiac electrical component becomes unnecessarily large in relation to the component's power. Still too long coolant hoses not only increase manufacturing costs but also increase the risk of component failure. Further, when manufacturing solutions according to prior art, for example, coolant channels and coolant channel holes 2-3, 10-11 are machined into manifold 1, additional work steps and considerable amount of material are wasted. In addition, the extra screw fittings on the manifold 1 also increase the number of joints and components required in the component. There is, therefore, a clear need and demand for different types of manifold electrical power components for new types of manifold solutions that achieve a more compact design with liquid-cooled core-based electrical components and which can reduce the consumption of liquid-cooled core-based materials.

BRIEF DESCRIPTION OF THE INVENTION It is an object of the present invention to provide a novel solution for manufacturing a manifold for a liquid-cooled cardiac electrical power component and a novel manifold for a liquid-cooled cardiac electrical power component that can be used for liquid cooling of transformers and chokes.

The method of the invention for manufacturing a manifold for a cardiac electrical component from a molded profile rail is characterized in that said profile rail profile comprises clamping projections, a coolant channel, and at least two angles of θ, θ = -30 ° to said machining terminals of said manifold made of manifold rail being provided with holes in the manifold for the fluid cooling method for the fluid coolant.

Preferably, the manifold is made such that it is adapted to engage one of said clamping projections on the binding iron edge of the electrical power component. Preferably, said coolant passage of the manifold is made of circular cross-section. Preferably, at least some of the ends of the manifold coolant channel and / or the holes in the manifold are threaded.

The manifold of a liquid-cooled cardiac electrical power component according to the invention is characterized in that the extruded profile of said profile rail comprises clamps on the fluid channel and at least two angles θ, θ are machined manifold holes extending to the coolant channel for fluid power outlet / return connections for the electrical power component.

Preferably, the manifold is adapted to engage one of said clamping projections on the binding iron edge of the electrical power component. Preferably, said coolant channel of the manifold has a circular cross-section. Preferably, at least a portion of the manifold coolant channel ends and / or manifold holes are provided with threads.

Preferably, at least a portion of the manifold coolant channel ends and / or manifold holes are provided for connection to the coolant hoses. Preferably, at least a portion of the ends of the manifold coolant channel and / or the manifold holes are adapted to be closed by a plug.

An improved solution has now been developed for manufacturing a manifold for a liquid-cooled cardiac electrical power component, and a novel manifold for a liquid-cooled cardiac electrical power component that can be used, for example, in liquid cooling of transformers and chokes. The solution is characterized by what is stated in the independent claims. Certain preferred embodiments of the invention are claimed in the dependent claims. The present invention achieves a number of advantages which will be more fully apparent from the detailed description.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a top plan view of a manifold of a liquid-cooled cardiac electrical power component of the prior art,

Figure 2 is an oblique frontal view of the structure of a manifold of a prior art liquid cooled cardiac electrical power component.

Figure 3 is a cross-sectional view of a manifold of a prior art liquid cooled cardiac electrical power component;

Fig. 4 is a side elevational view of a structure of a manifold of a liquid-cooled cardiac electrical power component according to an embodiment of the invention,

Figure 5 is an oblique frontal view of the structure of a manifold for a liquid-cooled cardiac electrical power component according to an alternative embodiment of the invention,

Fig. 6 is an oblique frontal view of the structure of a manifold of a liquid-cooled cardiac electrical power component according to another alternative embodiment of the invention,

Figure 7 shows a manifold according to an alternative embodiment of the invention mounted in a liquid-cooled cardiac electrical power component, obliquely viewed from the front

Fig. 8 shows a manifold according to another alternative embodiment of the invention mounted obliquely in front of a liquid-cooled cardiac electrical power component.

Figures 1-3 are shown above. Some embodiments of the invention will now be described in more detail with reference to some preferred embodiments, with reference to Figures 4-8.

DETAILED DESCRIPTION OF EMBODIMENT OF THE INVENTION

Fig. 4 is a side elevational view of a manifold structure of a liquid cooled cardiac electrical power component according to an embodiment of the invention. The manifold 16 of the liquid-cooled cardiac electrical component of the invention is made of a molded profile rail. The shape-extruded profile of the manifold 16 according to the invention comprises fastening projections 17-18 by means of which the manifold can be easily attached to the binding iron edge of the electrical power component. The manifold 16 according to the invention also comprises a coolant passage 19 passing through the manifold 16, from whose ends the cooled coolant can enter the manifold 16 or respectively from which the coolant to be cooled can come out of the manifold 16. The coolant passage 19 of the manifold 16 can be made e.g. The manifold 16 according to the invention also comprises connector projections 20-21 arranged at a suitable angle for liquid cooling. Connector projections 20-21 of manifold 16 are suitably machined with manifold holes for fluid cooled flow / return connections of the cardiac electrical component. The manifold 16 has only one coolant channel 19 so that it functions as either a liquid coolant manifold or a liquid coolant manifold. There are at least two terminal projections 20-21 of the manifold 16 and the direction of the terminal projections 20-21 16 is selected at a suitable angle Θ, 0 = -30 ° to 300 ° with respect to the mounting direction. In Fig. 4, the mounting direction of the manifold 16 is to the left, with the direction Θ of the first connector projection 20 of the manifold 16 being about 0 ° relative to the mounting direction (0 = 0 °) and the second connector projection 21 correspondingly about 250 ° relative to the mounting direction.

Figure 5 is an oblique frontal view of the structure of a manifold for a liquid-cooled cardiac electrical power component according to an alternative embodiment of the invention. The manifold 22 of the liquid-cooled cardiac electrical power component according to the invention is made of a molded profile rail and comprises anchoring projections 23-24, a coolant passageway 25 passing through the manifold 22, a fluid-cooling component of a cardiac electrical component for fluid cooling / return connections. The manifold 22 has only one coolant channel 25 so that it functions as either a liquid coolant manifold or a liquid coolant manifold.

At the ends of the coolant channel 25 passing through the manifold 22 according to an alternative embodiment of the invention, the cooled coolant can enter the manifold 22 or respectively from which the coolant to be cooled can come out of the manifold 22. The securing projections 23-24 of the manifold 22 are suitably shaped can be easily attached to the binding iron edge of an electrical power component, for example by tapping manifold 22 with a suitable tool.

The direction of the terminal projections 26-27 of the manifold 22 according to an alternative embodiment of the invention is selected at an angle Θ suitable for liquid cooling. Coolant cooled through manifold holes 28-30 machined into manifold terminals 26-27 may be discharged from manifold 22 to fluid coolant elements of a cardiac electrical component. Similarly, the coolant from the liquid cooling elements of the cardiac electrical component of the manifold 22 via the manifolds 28-30 may be introduced into the manifold 22. The manifold holes 28-30 may be machined to the desired number of terminals 26-27. The holes in the ends of the coolant channel 25 may be provided with threads to which the coolant hose connectors to be connected to the threaded manifold 22 can be attached. One of the 25 holes in the coolant channel is typically closed, for example, by a screw plug. Also, the holes 28-30 in the manifold can be provided with threads to which the connectors for the coolant hoses for the fluid cooling elements to be connected to the threaded manifold 22 can be attached. Further, the holes 28-30 of the distribution channels which are not used can be closed with plugs.

Fig. 6 is an oblique frontal view of a manifold structure of a liquid-cooled core-power electrical component according to another alternative embodiment of the invention. The manifold 31 of the liquid-cooled cardiac electrical power component according to the invention is made of a molded profile rail and comprises clamping projections 32-33, a coolant passage 34 through the manifold 31, and clamps 35-36, and a structural electrical power component for fluid cooling man / no connections. Also, the longer design manifold 31 has only one coolant channel 34 so that it functions as either a liquid coolant manifold or a liquid coolant return manifold.

At the ends of the coolant conduit 34 passing through the manifold 31 according to another alternative embodiment of the invention, the cooled coolant may enter the manifold 31 or respectively from which the coolant to be cooled may come out of the manifold 31. The securing projections 32-33 of the manifold 31 are suitably shaped easily attaching the electrical power component to the edge of the binding iron, for example, by tapping the manifold 31 with a suitable tool.

The direction of the terminal projections 35-36 of the manifold 31 according to another alternative embodiment of the invention is selected at an angle Θ suitable for liquid cooling. Coolant cooled through the manifold holes 31-39 in the manifold terminals 35-36 may be discharged from the manifold 31 to the fluid cooling elements of the cardiac electrical component. Similarly, the coolant from the liquid cooling elements of the cardiac electrical component of the manifold 31 can be introduced into the manifold 31 via the manifolds 37-39, and the required number of holes 37-39 in the manifolds can be machined to the desired locations. The holes in the ends of the coolant channel 34 may be provided with threads to which the coolant hose connectors to be connected to the threaded manifold 31 can be attached. One of the holes in the coolant channel 34 is typically closed, for example, by a screw plug. Also, the holes 37-39 of the manifolds may be provided with threads to which the connectors for the coolant hoses for the fluid cooling elements to be connected to the threaded manifold 31 can be attached. Further, the distribution channel holes 37-39 which are not used can be closed with plugs.

Figure 7 shows an manifold according to an alternative embodiment of the invention, mounted obliquely in front of a liquid-cooled cardiac electrical power component. The liquid-cooled core-power component of electrical power engineering comprises a core-structure 40, bandages 41-42, and fluid-cooling elements 43-48. The manifold 22 of the liquid-cooled cardiac electrical power component according to the invention comprises, at its first end, a coolant passage 49 for introducing coolant into or out of the manifold 22 of coolant. In this figure, the coolant is illustrated for clarity. The other opposite end of the manifold 22 coolant channel is closed, for example, by a screw plug.

The manifold 22 according to an alternate embodiment of the invention is fastened to the edge of the binding iron 41 of the electrical power component by means of suitably shaped mounting projections. The coolant can be brought out of the manifold 22 to the fluid coolant elements 43-48 of the core electrical power component via the coolant via the manifold terminals 50-51 and the coolant hoses 52-53 and the coolant cooled here. in the figure, the coolant is supplied via the manifold 50 and the coolant hose 52 from the manifold 22 to the liquid coolant 44 or back. Similarly, through the manifold connector 51 and the coolant hose 53, coolant is supplied from the manifold 22 to the liquid coolant member 47 or back. For the sake of clarity, the coolant hoses of other manifolds are not shown in this figure. Non-used distribution channel holes can be closed with plugs.

Figure 8 shows a manifold according to another alternative embodiment of the invention, mounted obliquely in front of a liquid-cooled cardiac electrical power component. The liquid-cooled core-power component of electrical power engineering comprises a core-structure 40, bandages 41-42, and fluid-cooling elements 43-48. The manifold 31 of the liquid-cooled cardiac electrical power component of the invention comprises, at its first end, a coolant passage 54 for introducing coolant into or out of the manifold 31 of the manifold 31. In this figure, the coolant is illustrated for clarity. The other opposite end of the manifold 31 coolant channel is closed, for example, by a screw plug.

The manifold 31 according to an alternative embodiment of the invention is fastened to the edge of the binding iron 41 of the electrical power component by means of suitably shaped attachment projections. The coolant cooled via the manifold terminals connected to the manifold holes on the manifold 31 terminals and the coolant lugs 55-60 can be brought out of the manifold 31 to the fluid cooling elements 43-48 of the cardiac electrical power component or the liquid cooled coolant 43 respectively. for the sake of clarity, only one manifold 31 is described, and thus only the coolant hoses 55-60 which go either to the liquid cooling elements 43-48 or from the liquid cooling elements 43-8. Non-used distribution channel holes can be closed with plugs. Due to the appropriate design of the manifold 31 and the manifold holes, shorter and also standard coolant lanes 55-60 can be used.

The liquid-cooled core-power electric component of the invention with manifolds can be resin coated, if desired, for example by means of a vacuum resin process.

By means of the manifold of the liquid cooled cardiac electrical power component of the invention, it is possible to reduce the number of long coolant hoses and thereby simplify the structure of the liquid cooled cardiac electrical power component. Electrical power engineering components having a simplified structure according to the invention have less risk of component failure than prior art solutions.

The manifold of the liquid-cooled cardiac electrical power component according to the invention can also reduce work stages and the consumption of manufacturing materials.

The electrical power technology component of the invention may be, for example, a three-phase choke or a three-phase transformer, whereby the liquid cooling solution of the electrical power technology component typically comprises at least three liquid cooling elements. The component of the electric power technology according to the invention may also be, for example, a single-phase choke or a single-phase transformer. Single-phase reactors or transformers typically have two column structures, whereby the liquid cooling solution of the electric power component of the invention comprises at least two liquid cooling elements.

The electrical power technology component of the invention can be used in power generation, power transmission and distribution, as well as in various industrial applications, such as various applications in process and manufacturing technology, transport equipment applications and energy industry applications.

It will be obvious to a person skilled in the art that as technology advances, the basic idea of the invention can be implemented in many different ways. The invention and its embodiments are thus not limited to the examples described above, but may vary within the scope of the claims. Thus, various features may be omitted, modified, or replaced by equivalents, and the features disclosed in this application may be combined to form various combinations.

Claims (7)

A method for manufacturing a manifold for a liquid-cooled cardiac electrical power component from a molded profile rail, characterized in that the profile of said profile rail comprises clamps (17-18), (23-24), (32-33), a coolant channel (19), (25). ), (34) and at least two connector projections (20-21), (26-27), (35-36) adapted to be provided at an angle θ, θ = -30 ° to 300 ° with respect to the liquid cooling, the manifold (16), (22), (31) being adapted to engage at said edge of a binding iron disposed on said brace portion of said electrical power component of said fastening projections (17-18), (23-24), (32-33), (16), ( 22), (31) machining holes (28-30), (37-) in the coolant passage (19), (25), (34) to the coolant passage (19), (25), (34), (39) the power unit component for liquid cooling inlet / return connections; and that at least a portion of the ends of the manifold (16), (22), (31) coolant channel (19), (25), (34) and / or the holes (28-30) of the manifold (37-39), ) is adapted to be connected to coolant hoses (52), (53), (55-60). Method according to claim 1, characterized in that said coolant channel (19), (25), (34) of the manifold (16), (22), (31) is made of circular cross-section. Method according to Claim 1 or 2, characterized in that at least a portion of the ends and / or holes (28-) of the coolant channel (19), (25), (34) and / or the manifold holes (16), (22), (31) 30), (37-39) are threaded. A manifold made of a molded profile rail of a component of a liquid-cooled cardiac electrical power technology, characterized in that the molded profile of said profile rail comprises clamps (17-18), (23-24), (32-33), a coolant channel (19), (25), (25). 34) and at least two connector projections (20-21), (26-27), (35-36) arranged at an angle θ 0 = -30 ° to -300 ° with respect to the liquid cooling, such that the manifold (16), ( 22), (31) is adapted to engage said bonding projections of said fastening projections (17-18), (23-24), (32-33) on the brace portion of an electrical power component, and that said manifold (16), (22), (31) the terminal projections (20-21), (26-27), (35-36) are machined into coolant channel passages (19), (25), (34), and the distribution channel holes (28-30), (37-39) of the electric power component for liquid cooling inlet / return connections and for at least a portion of the manifold (16), (22), (3 1) the ends of the coolant channel (19), (25), (34) and / or the holes (28-30), (37-39) in the distribution channels are adapted to be connected to the coolant hoses (52), (53), (55-60) . Manifold according to Claim 4, characterized in that said coolant channel (19), (25), (34) of the manifold (16), (22), (31) has a circular cross-section. Manifold according to Claim 4 or 5, characterized in that at least a portion of the ends and / or holes (28-) of the manifold (16), (22), (31) coolant channel (19), (25), (34) 30), (37-39) are provided with threads. Manifold according to one of the preceding claims 4 to 6, characterized in that at least a part of the ends and / or the holes (19), (25), (34) of the manifold (16), (22), (31) 28-30), (37-39) is adapted to be closed by a stopper.