DE202009005664U1 - Load resistor with metal housing - Google Patents

Abstract

Load resistor with at least one preferably as a resistance coil (1) formed resistive element which is provided with externally accessible supply terminals (3, 4) and enclosed by an electrical insulation (10) in a resistance chamber (12) of a metal heat sink (13), wherein the resistance chamber (12) has a chamber wall (17) enclosing it, with which the insulation is in thermal contact with a large area directly or via a metal jacket (5) enclosing the insulation, characterized in that the cooling body (13) at least partially directly at least partially has around the resistance chamber (12) extending around, continuously open cooling channel (14) acting as a convection channel by a coolant, in particular flows through air.

Description

The The invention relates to a load resistor with at least one preferably designed as a resistance coil resistance element, which with externally accessible supply connections provided and enclosed by an electrical insulation in one Resistance chamber of a metal heat sink is arranged, wherein the resistance chamber enclosing a chamber wall has, with which the insulation directly or via a the insulation enclosing metal coat over a large area is in thermal contact.

A load or braking resistor of the generic type is for example off DE 203 11 068 U1 known, which is used to convert electrical energy that is generated during braking of electric motors into heat and to give them as large as possible to the environment. For this purpose, an aluminum housing is provided as a heat exchanger or heat sink, which has a plurality of outer cooling fins to achieve the largest possible outer surface. In this case, the actual load or braking resistor is accommodated in the form of a wound on a flat coil carrier resistance wire in a form adapted to flat cavity in the middle core part of the aluminum housing.

A similar construction with many cooling fins also shows the case of the EP 1 156 495 A1 known resistance, which is used for the same purpose.

Also the off DE 72 38 703 known electrical resistance is housed to achieve a higher load capacity in an extruded aluminum housing having a plurality of cooling fins.

at this type of cooling housings finds the heat exchange almost exclusively by radiation to the itself warming ambient air instead. The cooling effect is therefore based on the heat exchange surface relatively low.

Furthermore is such a structure with as many cooling fins Afflicted with the disadvantage, a lot of space and a large amount of material to claim.

Of the Invention is based on the object, a load resistance of the above mentioned type with a simple to produce housing structure and a better cooling effect or heat exchange to create with the environment.

Solved This object is achieved according to the invention in that the heat sink at least one at least partially extending immediately around the resistance chamber, having continuously open cooling channel, which serves as a convection channel acting through a coolant, in particular flows through the air becomes.

there consists according to claim 2, the advantageous possibility in a heat sink two or more with resistive elements equipped resistance chambers provide, if necessary, the appropriate purpose can be interconnected.

With the design according to the invention of the load resistance, in particular of preferably consisting of extruded aluminum Cooling housing, the specified task is in duplicate Regard solved advantageous. On the one hand arise through the formation of cooling channels and taking place therein Air flow significantly improved cooling effects and thus higher load capacities or higher power consumption. By this air flow, on the well-known chimney effect is based, can be particularly in a vertical arrangement of the cooling channels achieve maximum cooling effects. On the other hand arise in geometrically much simpler cross-sectional shapes that are can be readily adapted to the particular requirements, both a smaller space requirement as well as a lower cost of materials. This also results in easier handling. The cooling housing can provided with largely smooth textured surfaces which are both the attachment of the load resistor to a flat To simplify surface as its attachment to such and facilitate.

advantageous Embodiments of the invention are the subject of the dependent claims 3 to 12.

Based The drawing figures will be closer to the invention in the following explained. It shows:

1 a complete load resistor with an aluminum housing as a heat sink;

1a in front view a heat sink with two resistance chambers

2 the aluminum load resistance of the 1 on average;

3 an isometric view of a cylindrical load resistor in a one-piece, cuboid cooling housing;

4 an isometric view of a cylindrical load resistor in a one-piece cooling housing having an octagonal cross-sectional shape;

5 in isometric view a load resistance in flat design with one-piece, cuboid cooling housing;

In the 1 and 2 is shown a load resistor consisting of a resistance wire coil 1 exists on a winding core consisting of insulating raw material 2 wound up and with connection leads 3 and 4 is provided. The winding core 2 with the resistance spiral 1 is in a coaxial position in a cylindrical metal casing pipe 5 made of metal, preferably copper or stainless steel, which is closed at both ends. The on the winding core 2 wound resistance coil 1 is embedded in a highly compressed insulating material 10 which may consist of quartz sand, magnesium oxide, silicon oxide or the like. Task of this insulating material 10 it is, on the one hand, the resistance coil opposite the metal casing pipe 5 electrically isolate and on the other hand that of the resistance wire coil 1 generated heat with the least possible delay to the metal casing pipe 5 forward.

The load resistor thus constructed 11 is in a resistance chamber 12 used by a the diameter of the metal casing pipe 5 adapted cylindrical cavity of a metal, preferably made of aluminum or an aluminum alloy heat sink 13 is formed. Here is the load resistance 11 with his metal casing pipe 5 coat surface in thermal contact with the wall 17 the resistance chamber 12 ,

As in particular from 1 can be seen, the heat sink has 13 several cooling channels acting as convection channels 14 on, around the resistance chamber 12 arranged around only through the chamber wall 17 from the resistance chamber 12 are separated. These cooling channels 14 consist of continuous open cavities that can have any cross-sectional shapes, but over their entire length should have the same cross-section. The cooling channels 14 are substantially radially to the axis (not shown) of the resistance chamber 12 running partitions 16 separated from each other and from a common outer jacket wall 15 enclosed. In the embodiment of the 1 is this outer jacket wall 15 formed by two parallel side walls 18 and 19 as well as from a cover wall 20 and a floor 21 ,

Through these cooling channels 14 On the one hand, an enlarged cooling surface is formed. On the other hand, the chimney effect results in an increased flow of air along the cooling surfaces and thus an increased cooling effect. This has an increased heat transfer to the environment result and thus a higher load capacity of the load resistance 11 , The aforementioned chimney effect is strongest when the cooling housing is vertically aligned.

In 1a is a heat sink in front view 13 ' shown with two cylindrical resistance chambers 12 equipped, like the 1 each of several cooling channels 14 are surrounded. There is also the possibility of heat sinks with more resistance chambers 12 to provide according to the same design principle. The in the individual resistance chambers 12 housed resistive elements can be appropriately interconnected or individually controlled.

The profiles of the heat sink 13 and 13 ' with the cooling channels 14 are preferably made by extrusion, so that they each of a long contiguous strand in each appropriate length as a heat sink 13 . 13 ' can be cut off. That in the embodiment of the 1 and 2 the ends of the heat sink 13 are each cut obliquely, is justified by a particular application of the embodiment. Of course, the heat sink 13 Also be provided with plane front ends, as is the case with the other embodiments.

Although even with such heat sinks 13 . 13 ' the possibility exists, the outer surfaces of the outer jacket wall 15 To provide for enlarging the surface with grooves and / or ribs, according to the invention a smooth outer surface of the outer shell wall 15 prefers. Smooth outer surfaces are easier to keep clean and they can heat transfer over the entire surface z. B. attached to metal walls of machines or cabinets.

To the load resistance 11 with his metal casing pipe 5 in the heat sink 13 to attach so that the metal casing pipe 5 temperature-dependent axially in the resistance chamber 12 can move without changing its predetermined axial position, fixing elements are provided in the embodiments with the cylindrical load resistors, which radially into or through the resistance chamber 12 and the cross-sectional profile of the metal sheath tube 5 stand out but can be designed differently.

In the embodiment of 3 is the cylindrical load resistance 11 in the central resistance chamber 12 an integrally manufactured, elongated cuboid heat sink 1.13 housed in aluminum. This heat sink 1.13 is with only four cooling channels 14 provided, all directly with the chamber wall 17 the resistance chamber communicate.

Only to show the many possible variations is in 4 a cross-section achtecki ger heatsink 2.13 shown, in which a central resistance chamber 12 around eight cooling channels 14 are arranged. Again, the cooling channels 14 in direct contact with the chamber wall 17 and they are by radially extending partitions 16 separated from each other. The existing here outer jacket wall 15 has the cross-sectional shape of a regular octagon.

In 5 is a load resistor shown in flat construction, in which the electrical part 11 of the load resistance in a flat, rectangular in cross section resistance chamber 2.12 a flat heat sink 13.3 is housed. Around the four-sided chamber wall 2.17 the flat rectangular resistance chamber 2.12 There are a total of eight cooling channels around 14 whose inner boundary is the chamber wall 2.17 forms and that by partitions 16 separated from each other and by an outer jacket wall 2.15 are enclosed. Similar to the embodiment of the 1 there is the outer jacket wall 2.15 from two parallel side walls 18 . 19 as well as from a cover wall 20 and a floor 21 whose outer surfaces are smooth. That with this cross-sectional shape, the partitions 16 not radially but partly at right angles to the top wall 20 or to the ground 21 run and partially corner connectors between the chamber wall 2.17 and the outer jacket wall 2.15 represent, constructively results from the cross-sectional shape.

In such load resistors in flat construction, it is also possible, wound on a flat winding support resistance wire winding in a Isolierstoffpackung 10 to bed and compress them by flat pressing, where it can be recommended, the flat-side cooling channels 14 during the pressing process with a pressing force on the chamber wall 2.17 to temporarily complete the transferring mass.

It is thus shown that in principle load resistance and heat sink with different cross-sectional shapes can be provided with cooling channels, for a higher cooling effect and load capacity too enable.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 20311068 U1 [0002]
• EP 1156495 A1 [0003]
• - DE 7238703 [0004]

Claims (12)

Load resistance with at least one preferably as resistance coil ( 1 ) formed resistive element, which with externally accessible supply terminals ( 3 . 4 ) and an electrical insulation ( 10 ) enclosed in a resistance chamber ( 12 ) of a metal heat sink ( 13 ), wherein the resistance chamber ( 12 ) a chamber wall enclosing it ( 17 ), with which the insulation is directly or via a metal sheath enclosing the insulation ( 5 ) is in thermal contact over a large area, characterized in that the heat sink ( 13 ) at least one at least partially immediately around the resistance chamber ( 12 ) extending therethrough, continuously open cooling channel ( 14 ), which is flowed through as a convection channel by a coolant, in particular of air. Load resistor according to claim 1, characterized in that the heat sink ( 13 ' ) a plurality of resistance chambers ( 12 ), each of at least one cooling channel ( 14 ) are at least partially enclosed. Load resistor according to claim 1 or 2, characterized in that the cooling channel ( 14 ) only by a chamber wall ( 17 ) from the resistance chamber ( 12 ) is disconnected. Load resistor according to one of claims 1, 2 or 3, characterized in that around a resistance chamber ( 12 ) around each a plurality of cooling channels ( 14 ) are arranged. Load resistor according to claim 1 or 4, characterized in that the cooling channels of a common outer jacket wall ( 15 ) and by several partitions ( 16 ) are separated from each other. Load resistor according to claim 1 or 4, characterized in that the partitions ( 16 ) substantially radially to a central axis of the resistance chamber ( 12 ). Load resistor according to claim 5, characterized in that the outer jacket wall ( 15 ) has an at least largely smooth outer surface. Load resistor according to one of claims 1 to 7, characterized in that the insulation in the resistance chamber ( 2.12 ) is compressed. Load resistor according to claim 8, characterized in that the at least one resistance element ( 1 ) in one of a metal casing pipe ( 5 ) enclosed insulation ( 10 ) is embedded. Load resistor according to claim 8 or 9, characterized in that the insulation of a preferably compressed insulating material ( 10 ) (made of MgO, SiO ₂ or quartz sand). Load resistor according to claim 9, characterized in that the resistance chamber ( 12 ), both in terms of their cross-section and in terms of their length to the dimensions of the metal casing tube ( 5 ) is tuned. Load resistor according to one of claims 1 to 10, characterized in that the heat sink ( 13 ) consists of an aluminum alloy or stainless steel or other good heat conducting metal.