DE4112677A1 - Fluid-cooled electrical resistor esp. for GTO-thyristor switching - consists of coaxial tubes cooled by contra-flow of liq. over entire surface of resistive elements - Google Patents

Abstract

Three coaxial conductors, comprising thin inner tubes (21) of corrosion-proof resistive material and thick outer tubes (22) of good conductor, are connected (24) electrically in series and cooled by parallel flows of pure water (12), reversed (19) and returned to a collector (18) and outlet (5). The tubes (21, 22) are sepd. by an insulating tube or coating (23) and their electrical connections (3) are taken through the cover (2) of the overall plastic housing. USE/ADVANTAGE - Esp. with gate turn-off thyristors, rapid switching is facilitated by low resistance and inductance with short connections and faster coolant flow for enhanced power capability.

Description

Technical field

The invention is based on an electrical Resistance according to the preamble of patent claim 1.

State of the art

With the preamble, the invention takes on a state of the Technique reference, as known from US-A-27 17 947. There is a low-inductance electrical ribbon resistor for a thyratron described in one Container with a cooling medium is stored. The resistance has at least 3 thin, parallel to each other Resistance flat tapes on one end to each other electrically connected and otherwise thin Mica insulating tapes electrically insulated from each other are. This resistor arrangement is between electrical insulated plates, which cooling openings for have the two outer resistance bands.

From EP-B1-00 66 902 it is known to cool a power resistor for the wiring of thyristors in converter systems from a meandering wire resistor in a closed housing with flowing deionized water. The resistance conductor is arranged with at least two inductances and with alternating current flow direction.

Presentation of the invention

The invention as defined in claim 1 solves the problem of electrical resistance of the type mentioned in such a way that he can be carried out inexpensively in a compact design.

An advantage of the invention is that in particular a low-resistance, for the connection of GTO thyristors low inductive, powerful resistor available stands that fast over short connecting lines electrical operations allowed. The reliable solution enables cost-effective even with small quantities Production. Narrow ladder loops are cooled combined with high fluid flow velocity.

According to an advantageous embodiment of the invention become resistance conductors with high power dissipation Flow velocity and those with lower Power loss with lower flow speed , the cooling fluid is cooled.

To reduce the inductance of the conductor loop the resistive ladder partially by means of thin layers Isolation distant from each other.

Brief description of the drawings

The invention is illustrated below with reference to embodiments play explained. Show it:

Fig. 1 shows a longitudinal section through a fluid cooled power resistance having a resistance conductor 2 bifilar pancake band arrays in series,

Fig. 2 is a perspective view of a resistive conductor of FIG. 1 with a tape holder,

Fig. 3 shows a belt holder according to FIG. 2 with resistance conductors and insulation layer in cross-section,

Fig. 4 is a perspective view of a resistance conductor with pseudo-loops,

Fig. 5 shows a longitudinal section through a fluid cooled power resistance having a coaxial resistor ladder of 3 cooling moderately parallel coaxial tubes and

Fig. 6 is a measurement diagram in which the boiling power of the cooling fluid is plotted as a function of the volume flow for a ribbon and a coaxial resistance conductor.

Ways of Carrying Out the Invention

In Fig. 1, ( 1 ) denotes a low-resistance, low-inductance but high-performance resistance conductor made of 2 bifilar flat ribbon arrangements which are connected in series via an arc section or a bend ( 13 ). This resistance conductor ( 1 ) consists of a chromium-nickel alloy, which is suitable for pure water as a cooling medium or cooling fluid ( 12 ). Typical values for such a resistance conductor ( 1 ) are a resistance of 0.15 R, an inductance of 100 nH and a power consumption of 15 kw.

The resistance conductor ( 1 ) is in a housing ( 2 ) made of plastic with a cooling medium inlet ( 4 ), a cooling medium outlet ( 5 ) and 2 power connections ( 3 ) for voltages of z. B. 0 V and 400 V. A spacer film or an electrically insulating insulation layer ( 6 ) of 1 mm thickness is arranged between the bifilar flat strips of the resistance conductor ( 1 ). A plastic corrosion protection hood ( 7 ) in the area of the curvature ( 13 ) of the resistance conductor ( 1 ) and adapted to the curvature ( 13 ) extends between the two power connections ( 3 ) to the cover of the housing ( 2 ) that in the area of the bend ( 13 ) an electrolytic corrosion of the resistance conductor ( 1 ) is reduced. The greatest potential difference and thus the greatest risk of corrosion exist in the area of the bend ( 13 ).

The cooling fluid ( 12 ) flowing in from the cooling medium inlet ( 4 ) flows in the right part of the housing ( 2 ) from below along the two non-insulated band sides of the bifilar resistance conductor ( 1 ) upwards and in the left part of the housing ( 2 ) downwards again to the cooling medium outlet ( 5 ).

One or more band holders or resistance holders ( 8 ) with closures, preferably snap closures ( 8 a), can be arranged along the bifilar part of the resistance conductor ( 1 ), cf. Fig. 2. For the sake of clarity, only one resistance holder ( 8 ) is shown.

Such a resistance holder ( 8 ), shown in cross section in FIG. 3, with 2 by 3 ribs ( 9 ) on the front and rear, ensures good contact of the bifilar part of the resistance conductor ( 1 ) with the insulation layer ( 6 ). The ribs ( 9 ) press against the bifilar part of the resistance conductor ( 1 ) from both sides and leave channels ( 10 ) between them through which the cooling fluid ( 12 ) can flow. Essentially the entire non-insulated areal part of the resistance conductor ( 1 ) can be flowed through and cooled well.

It goes without saying that instead of 3 ribs ( 9 ), a different number of ribs can also be provided. The resistance holder ( 8 ) can also be composed of halves.

The low-inductance resistance conductor ( 1 ) shown in FIG. 4 has a relatively high resistance of, for example, alternating from left and right by inserting pseudo loops or cutouts ( 15 ). B. 10Ω n. With ( 14 ) low-inductive pseudo loops are designated and with ( 11 ) attached terminals. An edge-side mounting zone ( 16 ) with low power dissipation is suitable for mechanical mounting of the resistance conductor ( 1 ).

In the resistor shown in FIG. 5, the resistance conductor consists of 3 (or more) electrically coaxial conductors connected in series and in parallel in terms of cooling. Each coaxial conductor has a thin-walled inner tube ( 21 ) made of a stainless resistance material, a somewhat thicker, well-conducting, cylindrical outer tube ( 22 ) and an insulation layer or an insulation tube ( 23 ) between the two coaxial tubes. The side by side in the housing (2) arranged coaxial tubes are held in their mutual position by 3 diaphragms or resistance holder (20), wherein the middle and upper diaphragm (20) have openings for the passage of the cooling fluid (12). The lower closed diaphragm ( 20 ) ensures that the cooling fluid ( 12 ) from a flow or cooling medium inlet ( 4 ) via a lower distribution chamber ( 17 ) through the interior of the inner tube ( 21 ) into an upper deflection chamber ( 19 ) and from there flows through the openings in the upper panel ( 20 ) along the outer surfaces of the outer tubes ( 22 ) and then through the openings in the central panel ( 20 ) via a collecting chamber ( 18 ) to a return or to the cooling medium outlet ( 5 ). The electrical series connection of the 3 coaxial resistors is effected by electrical connections ( 24 ).

A relatively high power loss is achieved in the thin-walled inner tube ( 21 ), which is dissipated by relatively cool water or cooling fluid ( 12 ) at a high flow rate. A lower power loss is achieved in the thick-walled outer tube ( 22 ), which is dissipated with cooling water ( 12 ) which has already been warmed up at a lower flow rate. The screens ( 20 ) made of an insulating material provide high resistance to electrolytic corrosion by keeping the electrolysis current density low.

Instead of pure water cooling, hybrid cooling can also be provided, in which the inner tubes ( 21 ) are cooled with water and the outer tubes ( 22 ) with air. Other cooling fluids can also be provided as the cooling fluid ( 12 ) instead of water and air. The coaxial tubes can also z. B. be wound. Single and multiple parallel connection of coaxial tubes is possible.

Fig. 6 shows a measurement diagram for a flat ribbon resistance conductor (B) and a coaxial resistance conductor (K), in which on the ordinate the boiling power (P) in kW as a limit for cooling and on the abscissa the volume flow (Q) in 1 / h are applied. The water inlet temperature was 50 ° C.

The flat ribbon resistance conductor (B) with a width of 30 mm, a thickness of 0.2 mm and a length of 804 mm consisted of a material with 80% Ni and 20% Cr. The Resistance was 0.152 ß, the inductance <0.1 µH.

The resistance coaxial conductor (K) made of a stainless steel In quadruple parallel connection, material had one Resistance of 0.172 Ω and an inductance of 0.155 µH.

Claims (10)

1. electrical resistance with fluid cooling, in particular for connecting thyristors,

• a) with a resistance conductor ( 1 ) which is at least sectionally flat,
• b) the planar part of the resistance conductor ( 1 ) being arranged parallel to one another at least in sections with an alternating current flow direction and a small mutual surface spacing, characterized in that
• c) that essentially the entire area of the resistance conductor ( 1 ) is exposed at least on one side, that is to say a cooling fluid ( 12 ) can flow through it.

2. Electrical resistance according to claim 1, characterized in that at least the flat part of the resistance conductor ( 1 ) is stabilized in its position by at least one resistance holder ( 8 , 20 ). 3. Electrical resistance according to claim 2, characterized in

• a) that the flat part of the resistance conductor ( 1 ) is band-shaped and
• b) that the resistance holder ( 8 ) has at least 2 ribs ( 9 ) for resting on the flat part of the resistance conductor ( 1 ), which ribs ( 9 ) each leave a channel ( 10 ) for a cooling fluid ( 12 ) between them.

4. Electrical resistance according to claim 3, characterized in

• a) that the resistance holder ( 8 ) 2 engages in a small surface spacing parallel planar parts of the resistance conductor ( 1 ) and
• b) has at least one closure (a).

5. Electrical resistance according to one of claims 1 to 4, characterized in that the resistance conductor ( 1 ) is formed in a band shape in a meandering shape, ie with lateral cutouts ( 15 ) to increase the resistance, the cutouts ( 15 ) alternating from one and from the other side of the band substantially transverse to the longitudinal direction of the band ( Fig. 4). 6. Electrical resistance according to one of claims 1 to 5, characterized in

• a) that at least 2 bifilar ribbon arrangements of a resistance conductor ( 1 ) are connected in series via an arc section ( 13 ) and
• b) that the bend section ( 13 ) has a corrosion protection hood ( 7 ) made of an electrically insulating material on the outside, ie in the area between 2 potentially different power connections ( 3 ).

7. Electrical resistance according to claim 1 or 2, characterized in

• a) that the resistance conductor ( 1 ) is designed in the form of at least one coaxial tube or double tube with an inner tube ( 21 ) and an outer tube ( 22 ) which surrounds the inner tube ( 21 ),
• b) that the outer tube (22) opposite the inner tube (21) electrically insulated and
• c) is electrically connected in series with the inner tube.

8. Electrical resistance according to claim 7, characterized in

• a) that the inner tube ( 21 ) inside with a cooling medium inlet ( 4 ) and
• b) that the outer tube ( 22 ) is connected on the outside to a cooling medium outlet ( 5 ) in such a way that a cooling fluid ( 12 ) first cools the inner tube ( 21 ) and then the outer tube ( 22 ) of the resistance conductor ( 1 ).

9. Electrical resistance according to claim 8, characterized in

• a) that several double tubes ( 21 , 22 ) of the resistance conductor ( 1 ) are connected in parallel in terms of cooling and are electrically connected in series,
• b) in particular that several double tubes ( 21 , 22 ) are arranged side by side.

10. Electrical resistance according to one of claims 7 to 9, characterized in that the inner tube ( 21 ) is thinner than the outer tube ( 22 ).