RU207661U1 - RESISTIVE ASSEMBLY OF HIGH VOLTAGE WATER-COOLED RESISTORS - Google Patents

Abstract

The utility model relates to the field of electrical equipment, namely to power resistors assembled in modules with forced liquid cooling. Increasing the resource of the resistive assembly of highly loaded resistors by increasing the uniformity of their cooling in the common cooling cavity is a technical result of the utility model, which is achieved due to the fact that the resistive assembly contains a housing having inlet and outlet pipes that provide a coolant supply to the internal cavity of the housing and a drain liquid from it, inside which there are high-voltage electrical resistors with a cylindrical outer surface and a guide element to ensure directed movement of the coolant from the inlet of the housing to its outlet, and holes are made in the guide element for resistors to pass through them. The body of the assembly is cylindrical with inlet and outlet end plates on opposite sides. The guide element is made with a helical surface forming with a cylindrical inner surface of the body a spiral channel between the inlet and outlet nozzles, and through-holes are made in the end plates of the body, in which resistors are installed along the longitudinal geometric axis of the inner cavity of the body with the possibility of sealing the inner cavity. 4 c.p. f-ly, 1 dwg

Description

The utility model relates to the field of electrical equipment, namely to power resistors assembled in modules with forced liquid cooling.

Known resistive assembly containing a housing having inlet and outlet pipes, providing a supply of coolant to the internal cavity of the housing and drainage of liquid from it, inside the housing cavity there are (high-voltage) electrical resistors with a cylindrical outer surface and guide elements to ensure the directed movement of the coolant from the housing inlet pipe to its outlet pipe, while holes are made in the guide elements for the resistor resistors to pass through them (US4434417A, publ., 02/28/1984).

The disadvantages of the known device are the unevenness of cooling assembled in a single set (assembly) of resistors, which leads to a decrease in their resource.

The technical problem is the elimination of the noted drawback.

The technical result consists in increasing the resource of the resistive assembly of high-voltage water-cooled resistors by increasing the uniformity of their cooling in the common cooling cavity.

The problem is solved and the technical result is achieved by the fact that the resistive assembly contains a housing with inlet and outlet nozzles, inside the cavity of which there are high-voltage electrical resistors with a cylindrical outer surface and a guide element to ensure the directed movement of the coolant from the inlet nozzle of the case to its outlet nozzle, while holes are made in the guide element for the passage of resistors in them, characterized in that the body is made with a cylindrical surface of the inner cavity and end plates on its opposite sides, the guide element is made with a screw surface forming a spiral channel with the cylindrical inner surface of the body between the inlet and outlet nozzles , and through holes are made in the end plates of the housing, in which resistors are installed along the longitudinal geometric axis of the internal cavity of the housing with the possibility of sealing the internal cavity. The helical surface of the guide element can be made in the form of a helicoid. The inlet and outlet nozzles can be located tangentially to the inner cylindrical cavity of the body, or the inlet and outlet nozzles are fixed coaxially, respectively, on the inlet and outlet end plates along the longitudinal geometric axis of the inner cylindrical cavity of the body, while in the inner cavity of the body coaxially with the inlet nozzle they can to be located an inlet element made in the form of a hyperbolic cone, the top of which is directed towards the flow of liquid flowing through the inlet pipe, and an outlet element installed coaxially with the outlet pipe and made in the form of a hyperbolic cone, the top of which is directed towards the outlet pipe in the direction of the fluid flow flowing from the inner cavity of the body to the outlet. A filler made in the form of a cylinder with a diameter not exceeding the maximum diameter of these elements can be located between the inlet and outlet elements coaxially with them.

The utility model is illustrated with the help of a drawing, which shows a longitudinal section of a resistive array.

The resistive assembly contains a housing 1 with a cylindrical surface of the inner cavity and input 2 and output 3 end plates on its opposite sides. The body 1 has an inlet 4 and an outlet 5 nozzles that provide a supply of coolant to the inner cavity of the body 1 and drainage of liquid from it. Inside the cavity of the housing 1 there are high-voltage electrical resistors 6 with a cylindrical outer surface and a single guide element 7 to provide a directed movement of the coolant from the inlet 4 of the housing 1 to its outlet 5. The guide 7 has a helical surface that forms with the cylindrical inner surface of the housing 1 spiral channel between inlet 4 and outlet 5 nozzles. In the guide element 7, holes 8 are made for the passage of resistors 6, which are located along the longitudinal geometric axis 9 of the internal cavity of the housing 1 with the possibility of sealing the internal cavity of the housing 1. In the end plates 2 and 3, through holes 10 are made in which the resistors 6 are installed. the possibility of sealing the internal cavity of the housing 1, for example, using sealing elements (not shown in the drawing).

The helical surface of the guide element 7 is made in the form of a helicoid. Such a surface is formed by the movement of a straight line rotating around an axis perpendicular to it (in this case, the geometric longitudinal axis 9 of the inner cavity of the housing 1) and simultaneously moving translationally in the direction of this axis, and the speeds of these movements are proportional. Such a surface is easy to manufacture and provides a uniform speed of the coolant along the formed spiral channel, which reduces the uneven cooling of the resistors 6 in the cross section of the assembly.

The inlet 4 and outlet 5 nozzles can be located tangentially to the inner cylindrical cavity of the body 1 and are connected to the body 1 about, respectively, the inlet 2 and outlet 3 end plates, together with the cross section of the spiral channel corresponding to the size of the nozzles 4 and 5.

The drawing shows the coaxial arrangement of the inlet 4 and outlet 5 nozzles. On the inlet end plate 2 along the longitudinal geometric axis 9, an inlet nozzle 4 is fixed, and in the inner cavity of the housing 1, coaxially with the inlet nozzle 4, there is an inlet element 11 made in the form of a hyperbolic cone, the top of which is directed towards the fluid flow flowing through the inlet nozzle 4. An outlet 5 is fixed on the outlet end plate 3, and an outlet element 12 is installed in the inner cavity of the housing 1, installed coaxially with the outlet 5 and made in the form of a hyperbolic cone, the top of which is directed towards the outlet 5 in the direction of the fluid flow flowing from the inner the cavity of the body 1 into the outlet pipe 5. With such a design of the pipes between the inlet 11 and outlet 12 elements, filler 13 can be located coaxially with them, made in the form of a cylinder with a diameter not exceeding the maximum diameter of these elements 11 and 12. At the same time, to optimize the parameters fluid flow filler diameter 13 is 30-40% of the diameter of the inner cavity of the body 1.

To ensure the integrity of the body 1 when its temperature changes, it is equipped with a bellows insert 14.

The described utility model is used as follows. High voltage electrical resistors 6 require intensive cooling. To simplify the cooling system, a set of resistors 6 are assembled in a single cooled housing 1, through which coolant is pumped. In this case, an uneven supply of liquid across the body 1 leads to uneven cooling of various resistors 6, which leads to their premature failure, and due to the subsequent overload, the entire electrical system fails.

The coolant is supplied through the axial inlet pipe 4, and its flow enters the inlet element 11, the top of which is directed towards the inlet fluid flow. The shape of the hyperbolic cone of the inlet element 11 provides a smooth change in the direction of flow from axial to spiral between the surfaces of the guide element 7. Prevention of fluid vortices at the entrance to the internal cavity of the housing 1 ensures the organization of a laminar flow of fluid both along each cylindrical resistor 6 and in the cross-section of the spiral channel , regardless of the distance from the resistor 6 to the geometrical axis 9. Such organization of the liquid outlet from the inner cavity of the housing 1 also helps to ensure a uniform flow of the coolant.

The "through" arrangement of the resistors 6 in the housing 1 with the exit of their ends from the holes 10 in the end plates 2 and 3 allows, in addition to ensuring the convenience of servicing the assembly, to ensure the implementation of correct geometric internal surfaces without the use of internal switches or fasteners, which improves the flow of fluid in the internal cavity , increasing the uniformity of cooling resistors 6.

Thus, the claimed useful model makes it possible to increase the resource and reliability of the resistive assembly of high-voltage resistors by increasing the uniformity of their cooling in the common cooling cavity, achieved by organizing a uniform flow of liquid around the resistors in the assembly.

Claims (5)

1. A resistor assembly containing a housing with inlet and outlet nozzles, inside the cavity of which there are high-voltage electrical resistors with a cylindrical outer surface and a guide element to ensure directed movement of the coolant from the inlet nozzle of the case to its outlet nozzle, while holes are made in the guide element for passage of resistors in them, characterized in that the body is made with a cylindrical surface of the inner cavity and end plates on its opposite sides, the guide element is made with a screw surface forming with the cylindrical inner surface of the body a spiral channel between the inlet and outlet nozzles, and in the end plates of the body through holes are made, in which resistors are installed along the longitudinal geometric axis of the internal cavity of the housing with the possibility of sealing the internal cavity. 2. An assembly according to claim 1, characterized in that the helical surface of the guide element is made in the form of a helicoid. 3. The assembly according to claim 1, characterized in that the inlet and outlet pipes are located tangentially to the inner cylindrical cavity of the body. 4. An assembly according to claim 1, characterized in that the inlet and outlet nozzles are fixed coaxially, respectively, on the inlet and outlet end plates along the longitudinal geometric axis of the inner cylindrical cavity of the body, while the inlet element is located in the inner cavity of the body coaxially with the inlet nozzle, made in the form of a hyperbolic cone, the top of which is directed towards the flow of liquid flowing through the inlet pipe, and an outlet element installed coaxially with the outlet pipe and made in the form of a hyperbolic cone, the top of which is directed towards the outlet pipe in the direction of the fluid flow flowing from the inner cavity housing into the outlet. 5. The assembly according to claim. 4, characterized in that between the inlet and outlet elements coaxially with them is a filler made in the form of a cylinder with a diameter not exceeding the maximum diameter of the said elements.

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