CN103255459B - Electrooxidation built-in water-cooling energy-saving electrode seat - Google Patents

Abstract

The invention provides an electrooxidation built-in water-cooling energy-saving electrode seat comprising a bridging electrode plug (1), a circulated cooling water pipe (2), a conductive contact region (3), an electrode seat (4), a high-strength corrosion-resisting spring (5), an insulating plate (6), a copper-aluminum alloy electrode plate (7) and a fixed bolt (8), wherein a 45-degree V-shaped inclined plane is arranged between the conductive contact region (3) and the bridging electrode plug (1); the circulated cooling water pipe (2) is arranged in the electrode seat (4); the electrode seat (4), the high-strength corrosion-resisting spring (5) and the fixed bolt (8) are arranged on the insulating plate (6); the high-strength corrosion-resisting spring (5) and the fixed bolt (8) are mutually separated; and the copper-aluminum alloy electrode plate (7) is fixed below the electrode seat (4). The electrooxidation built-in water-cooling energy-saving electrode seat disclosed by the invention has the technical effects that 1) the positioning and the contacting are reliable; 2) the energy conservation and the consumption reduction are obvious; 3) the service life is long; 4) the safety is high; and 5) the installation and the maintenance are convenient.

Description

Electrooxidation built-in water-cooling electricity-saving electrode seat

Technical field

the present invention relates to a kind of electrooxidation built-in water-cooling electricity-saving electrode seat, belong to electrooxidation technical field.

Background technology

When electrooxidation built-in water-cooling electricity-saving electrode seat is mainly used in aluminium shape surface electrooxidation, the conductive attachment between energising crane span structure and copper-aluminum alloy electrode plate.The use of the conducting heavy current of electrooxidation more than aluminium industry 20KA can be met.

Summary of the invention

The object of the invention is to overcome the deficiencies in the prior art part, a kind of electrooxidation built-in water-cooling electricity-saving electrode seat is provided.

Electrooxidation built-in water-cooling electricity-saving electrode seat of the present invention, comprise crane span structure electrode plug (1), circulating cooling water pipe (2), conductive contact district (3), electrode holder (4), high-strength corrosion-resisting spring (5), insulcrete (6), copper-aluminum alloy electrode plate (7) and standing bolt (8), between described conductive contact district (3) and crane span structure electrode plug (1), be provided with the V-type inclined-plane of 45 degree; Described circulating cooling water pipe (2) is located in electrode holder (4); Described electrode holder (4), high-strength corrosion-resisting spring (5) and standing bolt (8) are all placed on insulcrete (6); Described corrosion-resistant spring (5) and standing bolt (8) are spaced from each other; Described copper-aluminum alloy electrode plate (7) fixed electorde seat (4) below;

Described high-strength corrosion-resisting spring (5) has four, is located at electrode holder (4) four side;

Described electrooxidation built-in water-cooling electricity-saving electrode seat, also comprises spring chucking lug seat (9), and described corrosion-resistant spring (5) is connected with spring chucking lug seat (9);

In described conductive contact district (3), the surfaceness of two contact surfaces all reaches Ra0.8.

Electrooxidation built-in water-cooling electricity-saving electrode seat of the present invention, has following technique effect,

1) aligned contact is reliable

Between conductive contact district (3) and crane span structure electrode plug (1), adopt the V-type inclined-plane of 45 degree as contact surface, four high-strength corrosion-resisting springs (5) are equipped with as supporting in electrode holder (4) four side, and rise and automatically adjust contact gap, location is reliable, and order of contact is high.

2) significantly energy-saving and cost-reducing

Conduction region contact surface is large, and resistive impedance is little, big current by time the heat that produces little.Electrode holder (4) inside is provided with special circulating cooling water pipe (2) simultaneously, the heat energy that conductive contact district (3) surface produces because of impedance can be taken away rapidly, which overcome conventional apparatus causes contact surface due to heating ablation in conductive contact district, impedance increases, the drawback that energy consumption raises is energy-saving and cost-reducing very remarkable.

3) long service life

In conductive contact district (3), two contact surfaces all adopt ground finish to form, and the surfaceness of two contact surfaces all reaches Ra0.8, and surface planarity is high, and conduction region closes wide, are conducive to the adjustment of electrode movement and the stable of electric arc.When with high load currents, surface action is low, and burn out rate is little, and electric heating conductivity is high, and after life-time service, is also added with work two contact surface by secondary returning, makes 2.5 times that reach the original design life-span its work-ing life.

4) security is high

Electrode holder (4) and high-strength corrosion-resisting spring (5) are all placed on insulcrete (6), make electrical conductor and installation foundation mutually isolated; Simultaneously the location of corrosion-resistant spring (5) is spacing by spring chucking lug seat (9), is spaced from each other with the upper standing bolt (8) of insulcrete (6), thus high load currents and electrical insulator completely isolated, security is high.

5) installation, maintenance is convenient

Complete assembly is directly placed on mounting base, with standing bolt (8) fixed insulation plate (6), the upper installation four high-strength corrosion-resisting springs (5) of fixed insulation plate (6), more spacing with spring chucking lug seat (9), fixed electorde seat (4).Inlet tube and outlet tube all adopts soft strength, can change along with the change of telescopic spring amount.Copper-aluminum alloy electrode plate (7) adopts special technique to be directly welded on electrode holder (4), and reduce secondary clamping, compact construction, installs and keep in repair very convenient.

Accompanying drawing explanation

Fig. 1 is the front view of electrooxidation built-in water-cooling electricity-saving electrode seat of the present invention.

Fig. 2 is the vertical view of electrooxidation built-in water-cooling electricity-saving electrode seat of the present invention.

Embodiment

As shown in Figure 1 and Figure 2, electrooxidation built-in water-cooling electricity-saving electrode seat of the present invention, comprise crane span structure electrode plug (1), circulating cooling water pipe (2), conductive contact district (3), electrode holder (4), high-strength corrosion-resisting spring (5), insulcrete (6), copper-aluminum alloy electrode plate (7) and standing bolt (8), between described conductive contact district (3) and crane span structure electrode plug (1), be provided with the V-type inclined-plane of 45 degree; Described circulating cooling water pipe (2) is located in electrode holder (4); Described electrode holder (4), high-strength corrosion-resisting spring (5) and standing bolt (8) are all placed on insulcrete (6); Described corrosion-resistant spring (5) and standing bolt (8) are spaced from each other; Described copper-aluminum alloy electrode plate (7) fixed electorde seat (4) below; Described high-strength corrosion-resisting spring (5) has four, is located at electrode holder (4) four side; Described electrooxidation built-in water-cooling electricity-saving electrode seat, also comprises spring chucking lug seat (9), and described corrosion-resistant spring (5) is connected with spring chucking lug seat (9); In described conductive contact district (3), the surfaceness of two contact surfaces all reaches Ra0.8.

What finally illustrate is, above embodiment is only in order to illustrate technical scheme of the present invention and unrestricted, other amendments that those of ordinary skill in the art make technical scheme of the present invention or equivalently to replace, only otherwise depart from the spirit and scope of technical solution of the present invention, all should be encompassed in the middle of right of the present invention.

Claims (4)

1. electrooxidation built-in water-cooling electricity-saving electrode seat, it is characterized in that, comprise crane span structure electrode plug (1), circulating cooling water pipe (2), conductive contact district (3), electrode holder (4), high-strength corrosion-resisting spring (5), insulcrete (6), copper-aluminum alloy electrode plate (7) and standing bolt (8), between described conductive contact district (3) and crane span structure electrode plug (1), be provided with the V-type inclined-plane of 45 degree; Described circulating cooling water pipe (2) is located in electrode holder (4); Described electrode holder (4), high-strength corrosion-resisting spring (5) and standing bolt (8) are all placed on insulcrete (6); Described corrosion-resistant spring (5) and standing bolt (8) are spaced from each other; Described copper-aluminum alloy electrode plate (7) fixed electorde seat (4) below.

2. electrooxidation built-in water-cooling electricity-saving electrode seat as claimed in claim 1, it is characterized in that, described high-strength corrosion-resisting spring (5) has four, is located at electrode holder (4) four side.

3. electrooxidation built-in water-cooling electricity-saving electrode seat as claimed in claim 1, it is characterized in that, described electrooxidation built-in water-cooling electricity-saving electrode seat, also comprises spring chucking lug seat (9), and described corrosion-resistant spring (5) is connected with spring chucking lug seat (9).

4. electrooxidation built-in water-cooling electricity-saving electrode seat as claimed in claim 1, it is characterized in that, in described conductive contact district (3), the surfaceness of two contact surfaces is Ra0.8.