KR100297479B1 - Power Resistor Cooled by Natural Convection - Google Patents

Abstract

The invention relates to a power resistor cooled by natural convection including at least one resistive strip (43) arranged in a casing providing for its support and supporting the electrical connections to the strip, the support of the resistive strip being achieved by means of support combs holding the resistive strip by its longitudinal edges, characterised in that the casing consists only of two flanges (31, 32) spaced apart by at least a part of the support combs (33, 34). <IMAGE>

Description

Power Resistor Cooled By Natural Convection

The present invention relates to a power resistor that is cooled by natural convection.

These power resistors are used in rail traction as brake resistors. To reduce overheating and wear of mechanical brakes, much of the train's kinetic energy is converted into electrical energy dissipated in the form of heat in the power resistors. These resistors must withstand the harsh operating conditions encountered in rail vehicles.

These resistors are in the form of box parts combined to provide the total resistance required. Each box portion contains a resistance wire usually made of an alloy of chromium and nickel.

In each individual application, the resistor must be optimized to optimize the following two main components: resistance (ohms) and thermal power dissipation. The air in contact with the resistor is heated and lean compared to the outside.

In some prior art coil resistors cooled by natural convection, the resistive component is formed from an appropriately sized strip wound in the edge direction and supported by a ceramic dielectric guide. The coiled shape allows the resistor to cool effectively. The assembly is designed such that the elements are freely expandable as the temperature increases. For application to railroad cars, the resistors are mounted in a form that is exposed below the vehicle or on the vehicle roof.

The disadvantage of this kind of resistor is that the coil has a high inductance. Each coil may have an inductance of 100 μH and the entire resistor may include about ten coils. For this reason, these resistors cannot be used with modern electronic power circuits. The entire resistor must have an inductance less than 20μH.

Another disadvantage of this resistor is its inherently high coil price. The high price is due to the shape of the coil itself, the large number of parts required to maintain the placement and formation to maintain the shape.

In the prior art resistors cooled by forced convection, the resistance wires are made of wires zigzag-contacted and welded at each end. The assembly of the line in the box portion must have maximum heat exchange between the line and the cooling air flow, maintain the line mechanically, accommodate the thermal expansion effect and prevent short-circuit between the facing portions of the line. The box portion has a flat rectangular block shape, an insulating member and an electrical connection terminal, sealed on four vertical sides by a plate supporting a member for holding the line mechanically. Ventilation is performed by air forced between the open top and bottom surfaces.

In order to remedy the disadvantages of the coiled resistor described above, the present invention proposes a power resistor in which the resistor wire is used in a resistor in which forced resistance is cooled by forced draft but its structure can be well ventilated by natural convection. This means that at the same overall size, the coiled resistor can be replaced with a resistor according to the invention which dissipates the same amount of heat.

The power resistors according to the invention are also inexpensive, easy to assemble, and manual adjustment between the wrinkles of the resistance wires will be unnecessary.

Therefore, the present invention is characterized in that the box portion consists of only two flanges spaced apart by at least several comb-like retaining member assemblies, the comb-holding member assembly retaining the resistance wire and retaining the resistance wire by the longitudinal edge. And a power resistor adapted to be cooled by natural convection comprising at least one resistance wire disposed in the box portion supporting the connection to the line held by the wire.

Some of the comb retaining member assemblies space the flanges and other comb retaining member assemblies float between the flanges. This prevents the deformation of the flange due to thermal expansion transmitted by the comb-shaped retaining member assembly.

The resistor may include two overlapping resistance wires separated by a common comb retaining member assembly.

The common comb retaining member assembly may have an insulating cylindrical comb member having an axial hole inserted with a rod held at both ends by a flange of the box portion.

Each resistance wire should be zigzag.

In this case, the resistance wire may be made of a metal member having one or more wrinkles and the ends welded to each other to form a resistance wire.

Each resistance wire should be relatively thick. This strengthens the resistance wire and eliminates the need to use a waffle type structure. There is also no need for an insulating pillar to prevent shorts between facing parts.

The flange may be provided with an insulating bush on the inner side of the box portion. This prevents a short between the flange and the resistance wire.

It is advisable to provide lugs for securing the box parts to the flanges.

The electrical connection can be fixed to the flange by an insulating material.

The flange is preferably integrated with the vent. These holes also reduce weight.

1 is a plan view of a power resistor according to the invention.

2 is an elevational view of the power resistor seen in the direction of arrow II of FIG.

3 is an elevational view of the power resistor seen in the direction of arrow III of FIG.

4-6 show a comb-type retaining member assembly for a resistor in accordance with the present invention.

Explanation of symbols on the main parts of the drawings

31, 32: Flange 33, 34, 35, 37, 38, 45: Comb retaining member assembly

43,44: Resistance wire 48,49,52: Insulation material

53, 54, 55: Lug 56: Bush

58: ventilation hole 61, 62: comb member element

The present invention will be described in more detail with reference to the accompanying drawings, and features and advantages of the present invention will be described below by way of non-limiting practice.

1 to 3 show a power resistor that can be used as a power resistor of a railway vehicle.

The resistor has two parallel square flanges 31 and 32. The flanges are spaced by four comb retaining member assemblies each connected to one flange on the other and the other on the flange. 1 shows two upper comb retainer member assemblies 33 and 34 screwed to flanges 31 and 32. 2 shows one 35 of two lower comb retainer member assemblies acting as spacers. 3 shows the position of the hole 36 on the flange 31 for securing the comb retainer member assembly acting as a spacer.

The box portion includes two other intermediate comb retaining member assemblies 37 and 38 between the comb retaining member assemblies 33 and 34 and on the top surface. Two other intermediate comb retaining member assemblies are not shown in the figure in a corresponding relationship with the comb retaining member assemblies 37 and 38 on the lower face of the box portion. The intermediate comb retainer member assemblies on the top and bottom faces are screwed into the flange 32. The hole 39 is used to screw the comb retaining member assemblies 37 and 38. This comb holding member assembly is not fixed to the flange 31. Instead, they are simply connected to the flange by pins in the holes 40 of the flange 31. At room temperature there is a gap between the flange 31 and the end plates 41 and 42 of the intermediate comb retaining member assemblies 37 and 38. This gap prevents deformation of the flanges 31 and 32 when the comb retaining member assemblies 37 and 38 expand.

The resistors shown in FIGS. 1 through 3 comprise two overlapping resistance wires 43 and 44. Each resistance wire is zigzag folded to extend from one flange to the other flange, and the folded resistance wire is parallel to the flange. The comb retaining member assemblies 33, 34, 35, 37 and 38 therefore cross each tangled resistance line.

The box portion also includes a comb-shaped retaining member assembly on an intermediate surface between the upper and lower surfaces of the box portion to hold the resistance lines 43 and 44 at the intermediate level. 1 and 2 show one 45 of this intermediate comb retaining member assembly. This intermediate comb retaining member assembly is floating mounted relative to the flanges 31 and 32.

The resistor includes two electrical connections for connection into the electrical circuit. FIG. 1 shows these connections 46 and 47 secured to flanges 31 and 32 via insulation. Each connecting portion 46 and 47 is fixed to each flange through two insulating materials. The connecting portion connects each resistance wire in parallel. The connecting portion 46 has one branch 50 welded to one end of the upper resistance wire 43 and is fixed to the flange 31 through the insulating material 48. The connecting portion 46 has another branch 51 welded to one end of the lower resistance wire 44 and is fixed to the flange 31 through the insulating material 52. The same applies to the first FIG. Connection 47 which is shown only the insulating material 49 which secures the upper branch to the flange 32.

The box section is fitted with three fixing lugs that are used to install resistors in the equipment. Two lugs 53 and 54 are welded to the flange 31 and one lug 55 is welded to the flange 32. Fixing lugs define a rectangle that holds the box portion.

Holes through the flanges 31 and 32 receive an insulating bush that prevents a short between the flange and the resistance wire.

The resistance wire is made of, for example, a chrome nickel alloy. If the resistance wires are thick enough (eg 1.2 mm thick), they are strong enough to not overdeform as a result of thermal expansion. Each line can be formed by welding each line element end to end, and each element is W-shaped (ie, includes two corrugations). 1 shows an area 57 in which two elements are welded to each other end to end.

Holes 58 in the flange (see FIG. 3) improve the ventilation of the resistor and also reduce the weight of the box portion.

The upper and lower comb retaining member assemblies may be in the form shown in FIGS. 4 through 6.

4 shows an insulating ceramic (for example steatite or cordierrite) comb-type retaining element 1. At the bottom of each side the element has two grooves 2 and 3 extending over its entire length. The upper part includes a tooth 4 on which each line is arranged. One end 5 of the comb member constitutes only the lower part while the other end 6 constitutes only the upper part.

5 shows a complete comb retainer member assembly. The comb-shaped retaining member assembly comprises a metal support 10 in the form of a stainless steel channel cross section with inward lips 11 and 12. The metal support 10 has stainless steel transverse end plates 13, 14. This plate is welded to the support 10. The plate 13 seals the opening in the support at the end. However, the plate 14 has a cutout so that the opening in the support at the end is opened (see also FIG. 6).

Plates 13 and 14 are used to secure the support 10 to the flange. The plate 13 comprises two screw holes 16 for screwing in the flange 32. The plate 14 also includes screw holes for screwing to the flange 31 when the comb retaining member assembly is at the edge of the flange. In the case of the intermediate comb retaining member assembly, the plate 14 comprises two holes 17 which enable a pinned coupling to the flange 31 with a slight clearance. This gap allows the support 10 to expand in response to thermal stress without deformation of the resistor structure and without deformation of the resistor itself.

The comb member element is quickly and easily mounted to the support by sliding inward from the open end of the support, and the ribs 11, 12 of the support enter the grooves 2 and 3 on the comb member. The end plate 13 provides a stop for the comb member element.

The comb retaining member assembly comprises a comb member 1 and end comb members 21 and 22 which are identical to each other. The comb-shaped member 1 is arrange | positioned end by side so that the edge part 6 of one comb-shaped member may overlap with the edge part 5 of the adjacent comb-shaped member. The end comb members 21 and 22 are different from the comb member 1. The end of the comb member 22 adjacent to the plate 13 and the end of the comb member 21 adjacent to the plate 14 need not be in contact with the end of the adjacent comb member. The opposite ends, however, are shaped to overlap with the adjacent comb member 1.

The length of the comb retaining element is such that two adjacent comb members always overlap, regardless of the operating temperature of the resistor. Thus, the dielectric barrier for the leakage current path between the resistance wire and the comb-shaped retaining member assembly is always maintained.

The comb member elements, including the comb member elements, at the support ends can be of different lengths to cover all possible combinations.

The intermediate comb retainer assembly is floating mounted relative to the flanges 31 and 32. 2 shows the intermediate comb retaining member assembly in detail. The intermediate comb retaining member assembly consists of a series of tubular insulating ceramic comb member elements such as comb member elements 61 and 62. The axial through hole receives a metal rod 63 long enough to penetrate both flanges. The omega shaped part 64 has a center portion accommodated in a square hole in the flanges 31 and 32, which prevents their rotation. The rod 63 terminates inside a hole provided in the center portion of the component 64 and is prevented from moving by the set of keys and washers.

The comb-shaped members 61, 62 and the like have a flat inner open end of the axial hole. At the end connecting the flange 32 the component 64 extends partially into the axial hole in the comb member and is seated in the joined planar shape. Between two consecutive comb member elements (eg comb member elements 61 and 62) an insulating ceramic intermediate part is received in the cavity defined by the opposing planes of the comb member elements 61 and 62 and the comb member elements are mutually Rotation with respect to the rod 63 is prevented. This prevents the intermediate comb retaining member assembly from rotating itself.

According to the present invention, a kind used in a resistor in which a resistance wire is cooled by forced ventilation, which improves the disadvantages of the coiled resistor described above, or the structure thereof, is provided with a power resistor that allows the resistor to be well ventilated by natural convection. do. Thus, coiled resistors at the same overall size can be replaced with resistors according to the invention which dissipate the same amount of heat.

Claims (11)

In natural convection comprising at least one resistance wire 43, 44 arranged in a box portion consisting of two flanges 31, 32 holding the resistance wire by the comb-shaped retaining member assembly and supporting the electrical connection to the resistance wire. A power resistor adapted to be cooled by The box portion is spaced only by some of the comb retaining member assemblies 33, 34, 35, and the other comb retaining member assemblies 37, 38, 45 are floating mounted between the flanges, And the comb-shaped retaining member assembly (33, 34, 35, 37, 38, 45) all retain the resistance wire by its longitudinal edge. 2. The power resistor of claim 1, wherein some of the comb retaining member assemblies 33, 34, 35 are spaced apart from the flange and the other comb retaining member assemblies 37, 38, 39 are floating mounted between the flanges. . The method according to claim 1 or 2, Power resistor, characterized in that it comprises two overlapping resistance wires (43,44) separated by a common comb retaining member assembly (45). The method of claim 3, The common comb retaining member assembly 45 includes an insulating cylindrical comb member element 61, 62 with an axial hole into which the rod 63 supported at both ends by the flanges 31, 32 of the box portion is inserted. A power resistor, characterized in that. The method according to claim 1 or 2, A power resistor, wherein each resistance wire is in a zigzag shape. The method of claim 5, And the line is made of metal elements having one or more corrugations and welded to each other to form a line. The method according to claim 1 or 2, Wherein each of the resistance wires is relatively thick. The method according to claim 1 or 2, And the flange is provided with an insulating bush (56) on the inner side of the box portion. The method according to claim 1 or 2, The flange is provided with lugs (53, 54, 55) for fixing the box part. Power resistor according to claim 1 or 2, characterized in that the electrical connection (46,47) is secured to the flange via an insulating material (48,49,52). The method according to claim 1 or 2, Power resistor, characterized in that the flange (31,32) has a vent hole (58).