CS259452B1 - A process for preparing a thin non-metallic protective coating on copper and zinc alloys - Google Patents

Abstract

The solution relates to a method for preparing a thin non-metallic protective coating on copper and copper-zinc alloys. The method enables the creation of a corrosion-resistant coating that protects brass from corrosion in aqueous solutions of neutral chlorides and ensures long-term protection against the adverse effects of dilute aqueous solutions, especially cooling waters. The protective coating is formed by immersing the metal surface in a solution of 0.5 to 4 g of sulfuric acid with 0.4 to 4 g of chromium trioxide or with a solution of 0.9 to 8 g of sulfuric acid with 0.50 to 5.6 g of sodium chromate in 100 g of aqueous solution at a temperature of 20 to 80 degrees Celsius for 0.5 to 10 hours and after rinsing with water, the metal surface is immediately passivated with an aqueous solution containing 0.9 to 4 g of sodium chromate in 100 g of solution at a temperature of 20 to 80 °C for 4 to 100 hours.

Description

The invention relates to a circuit of a counter parity prediction circuit.

Binary counters connected in parity-secured systems are usually provided by a parity predictor.

These circuits are usually realized as complex combination circuits, composed of individual gates and designed so that the connection of such a circuit is directly dependent on the counting range of the secured counter. The disadvantage of such wiring is the difficulty of using higher integration circuits and the purpose of each such wiring for a given counter range.

The above drawbacks eliminate the simple wiring of the counter parity prediction circuit, which is based on the fact that the preceding parity 3 signal input is connected to the non-equivalence circuit, whose predicted parity signal output is the output of the entire wiring, with the counter content group connected to the priority encoder. to which the non-equivalence circuit input is connected.

The main advantage of the circuitry according to the invention is that the parity predictor uses standard circuits of the priority encoder, allowing in addition a simple cascade connection of such a predictor, thus allowing a modular solution of circuits providing binary counter parity with any number of orders.

The attached figure shows schematically the circuit of the counter for parity prediction. The previous parity signal input 01 is coupled to the non-equivalence circuit 2, whose predicted parity signal output 22 is the output of the entire wiring, and the counter content group 02 is connected to the priority encoder 1 to which the non-equivalence circuit input 21 is connected. ,

The wiring function for counter parity prediction is as follows:

The signal at the output of the priority encoder J determines if the lowest order with a zero value of the counter content applied to the inputs of the priority encoder J by the group of feeds of the counter content 2 is even or odd. If this order is even, the number of orders of magnitude changes by one and the parity of the counter changes accordingly. If this order is odd, an even number of its orders will change as the counter content increases by one, and therefore its parity will remain unchanged.

The output of the priority encoder JL indicates if the parity of the counter changes by one increment. The parity change signal is fed from the priority encoder JL to the non-equivalence circuit input 21, where the original counter parity applied to the non-equivalence circuit 2 is changed by input 01 of the previous parity signal so that a corresponding signal is output at the non-equivalence circuit 23. the parity of the counter content after magnification by one.

The counter parity prediction circuit is used in the EG 1027 computer control electronics block.

Claims (1)

OBJECT OF THE INVENTION A prediction wiring, counter parity characterized in that the preceding parity signal input (01) is connected to a non-equivalence circuit (2), whose predicted parity signal output (22) is the output of the entire wiring, wherein the counter content group (02) is connected to a priority encoder (1) to which the non-equivalence circuit input (21) is connected (21).