CS214511B1 - Connection for combined release of the signal passage - Google Patents

Description

BACKGROUND OF THE INVENTION The present invention relates to circuitry for coupled release of signals, particularly in the field of dedicated discrete automata.

It is a wiring consisting of two signal lines, which consist of a first and a second input and a first and a second output, connected via Logic Circuits.

This is a very special circuit for a narrow range of tasks, especially for the control of two-position drives, for example power pneumatic cylinders controlled by two-way gate valves, which are completely missing in the field of known circuits.

These disadvantages are overcome by a circuit-breaker circuit consisting of a first signal line and a second signal line according to the invention, which consists in that the first signal line consists of a first input of a first signal line connected to a first input of a first terminal logic circuit whose output represents a first output of a first signal line, from a second input of a first signal line coupled to a first input of a first combinational logic circuit of a first signal line, wherein the output of the circuit is. connected by β to the first input of the second terminal logic circuit, the output of which is the second output of the first signal line, the second signal line consisting of a first input of the second signal line coupled to the first input of the first combinational logic circuit of the second signal line

234 511 the output of this circuit is connected to a first input of a first terminal logic whose output represents a first output of the second signal line, from a second input of a second signal conduit connected to a first input of the second terminal logic whose output represents a second output of a second signal line said signal lines being such that the first input of the first signaling line is further coupled to the second input of the first combining logic circuit of the second signaling line with ae 'input of the timing circuit of the second signaling line; , the second input of this circuit is coupled to the second auxiliary input, the second input of the second signal line is further coupled to the second input of the first combinational logic circuit of the first signal line, and to the time input the first signal line circuit, the output of said circuit being coupled to the first input of the second combinational logic circuit of the first signal line, the second input of said circuit being coupled to the first auxiliary input, wherein the outputs of the second combinational logic circuit of the first signal line and the second signal line are coupled to the second input a second terminal logic circuit, optionally with a second input of the first terminal logic circuit of the first signal line and the second signal line.

The advantage of the circuitry for coupled release of the signal passage is the mutual conditionality of the signal passage from one or the other input of the single signal line to one or the other output of the same or opposite signal line, determined by the time interval of the time circuits used and the auxiliary inputs.

In the exemplary embodiment, the circuit for coupled release of signals of the invention is shown in the accompanying drawing, in which FIG. 1 shows the preferred embodiments, and FIGS. 2, 3 shows the advantageous connection of time circuits composed of two time elements in series.

Fig. 1 shows the first signal line composed of the first input A1 and the second input. As of this first signaling science, the second signal line consisting of the first input Bj and the second input Bg of the second signal line is shown, these inputs being connected via logic circuits with outputs X ^, Xg, Yp Yg of these signal lines. .

of this circuit represents the first output X1 of the first signal line.

The second input Ag of the first signal line is connected to the first input kj of the first combinational logic circuit K of the first signal line, the output of this circuit is connected to the first input Pg of the second logical circuit Pg. .

The first input of the second signal line is connected to the first input 1j of the first combinational logic circuit L of the second signal line, the output H of this circuit 6 being

Connected to the first input r ^ of the first terminal logic circuit Rp, the second input r · of this circuit R- is not connected, and the output of this circuit R ^ represents the first output of the second signal line. _with

The second input Bg of the second signal line is connected to the first input _{12 of the} second terminal logic circuit Rg, the output of this circuit Rg representing the second output Yg of the second signal line.

The first terminal logic P ^ and the second terminal logic Pg represent the final stage T-1 of the first signal line, the first terminal logic circuit R ^ and the second terminal logic circuit Rg represent the final stage Tg of the second signal line.

The interconnection of these signal lines is such that the first input of the first signal line is further coupled to the second input 1g of the first combinational logic circuit L of the second signal line and to the input 6 of the second signal line timing circuit. n- ^ of the second combinational logic circuit N of the second signal line, the second input ng of this circuit H is connected to · 2 auxiliary input Cg, and the outputs of this circuit N are connected to the second input ^with rg of the second terminal logic circuit Rg · Bg of the second signal line is longer connected to the second input kg of the first combinational logic circuit X of the first signal line and to the input e of the timing circuit E of the first signal line, the output Q of this circuit E is connected to the first input m ^ , the second input mg of this circuit M is the connections n with the first auxiliary input Cj and the output U of this circuit M is connected to the second input Pg of the second terminal logic circuit Pg.

The wiring function for coupled release of the signals of FIG. 1 depends in detail on the particular type of signals at the inputs and the particular kind of logic circuits used.

It is assumed that level-type signals are received at inputs A ^, Ag, B ^, Bg, C ^, Cg, and logic 1 signals lasting for finite time slots. The first combinational logic circuit K, L, e, the second combinational logic circuit Μ, N represents the logic product circuit, the first terminal logic circuit P ^, R ^ and the second terminal logic circuit Pg, Rg represent the logical total circuit. the time circuit E, F represents the time memory excited by the on-time logic signal for a period of time of a predetermined finite length.

Under these assumptions, starting from the initial state of the logic zero signals at inputs Α _χ , Ag, Bp Bg and the auxiliary inputs Cp Cg, the wiring function of Fig. 1 is such that by applying a logic one signal to the first input A ^ of the first signal line input of the first terminal logic circuit of the first signal line and causes the logic 1 signal to be excited at the output of this circuit Ρ _η , - = thus also at the first output of the first signal line. The bass duration of the logic 1 signal at this output is the same as the duration of the logic 1 signal at the first input A1 of this first signal line.

The logic 1 signal from the first input A 1 of the first signal line passes simultaneously to the second input 1g of the first combinational logic circuit L of the second signal line and to the input f of the timing circuit F of the second signal line. If, during the duration of this signal, the logic 1 signal arrives at the first input B1 of the second signal line, the logic 1 signal passes to the first input 1 of the first combinational logic circuit Lana of output H of this circuit. and the first output Y of the second signal line.

The logic 1 signal at the first input A 1 of the first signal line causes the logic 1 signal to be excited at the output S of the second signal line timing circuit F for a time interval of a predetermined second length. If, during this time interval, the logic 1 signal arrives at the second auxiliary input Cg, this signal passes to the second input n _{2 of the} second combinational logic circuit N of the second signal line and the output V of this circuit N generates a logic one signal r _{2 of the} second terminal logic circuit Rg of the second signal line and causes the logic 1 signal to be excited at the output of this circuit Rg, i.e. 1 at the second output Yg of the second signal line.

By applying a logic 1 signal to the second input Ag of the first signal line, the signal passes to the first input of the first combinational logic circuit K of the first signal line, either prior to or simultaneously applying the logic 1 signal to the second input Bg of the second signal line. of this circuit K causes an excitation of the logic 1h signal and output 0 of this circuit.

* 1

The logic 1 signal from this output 6 simultaneously passes to the first input Pg of the second terminal Pg of the first signal line and causes the logic 1 signal to be excited at the output of this Pg circuit, i.e. the second output Xg of the first signal line.

Due to the symmetrical circuit structure of FIG. 1, the signal flow applied to the inputs Bp Bg is quite similar and the resulting wiring function is such that the signal applied to the first input of the first signal line passes to the first input Xj of the first signal line. B ^ first input a second signal line to the first output of the second signal lines Y, signal applied to a second input B of the second signal line ₂ is transferred to the second output of the second signal line Yg and also determines the release of the signal transmission from the second input a ₂ of the first signal on vede.ní a second output Xg of the first signal line.

Thus, the signal at the first input A1 of the first signal line is subordinated to the flow. first input signal from the second B-signal line to the first output Yi of the second signal line, the signal at the second input the second signal line Bg is subordinated 3ignálu flow from the second inlet and the first signal line ₂ to the second output Xg of the first signal line.

The signal on the first auxiliary input allows the signal to pass from the second input Bg of the second signal line to the second output Xg of the first signal line for a period of time of the first length without having applied the signal to the second input Ag of the first signal line. passing the signal from the first input A vstupu of the first signal line to the first output Y ^ of the second signaling line for a period of time of the second length, without signaling the second input Bg of the second signaling line. The result is a mutual subordination of both signal lines.

In a practical application, the output stage T ^ of the first signal line is connected β by the first drive / so that the signal at the first output X ^ determines the start, and the signal at the second output Xg determines the stop of this first drive. The output stage Tg of the second signal line is coupled to the second drive so that the signal at the first output Y ₃ determines the start, and the signal at the second output Yg determines the stop of the second actuator.

The conditions for starting and stopping these drives are contained in the signal flow description above.

A special case of these drives is, for example, pneumatic or other power cylinders actuated by electromagnetic gate valves. In this application, for example, the signal at the first output X?, Y? Switches the slider to the first position for moving forward the power cylinder, the signal at the second output X ?, Yg switches the slider to the second position for moving back the power cylinder.

The signal sources on inputs A ^, Ag, B ^, Bg on auxiliary inputs C ^, Cg can be buttons, position sensors, outputs of the connected logic network etc.

By omitting a further connection, for example a second connection of the second signal line input Bg to the second input kg of the first combinational logic circuit K and ee of the first signal line time circuit e and the associated logic circuits, one-sided subordination, e.g. first signal line.

Another application of the circuit for coupled release of signals is that the first combinational logic circuit K, L is a logic sum circuit. In this connection, the signal from the first input A1 of the first signal line passes to the first output Xj of the first signal line and at the same time to the first output Yj of the second signal line, leaving the signal to pass independently of the second signal line, the signal from the second input Bg of the second signal line passes to the second output Yg of the second signal line and at the same time to the second output Xg of the first signal line, leaving the signal _{g of} this first signal line.

A further modified circuit for coupled release of signals is that the first signal line timing circuit E. consists of a first timing element -E ^ and a second timing element Eg of the first signaling line in series, see FIG. the member E1 is connected to the input e1 of the second time member E1, the input e1 of the first time member represents the input e of the time circuit E, and the output of the second time member E1 represents the output 2 of the time circuit E of the first signal line. obvod'F time the second signal line comprises a first timing element F ^ and the second timing element Fg second signal line in series, see Fig. 3, where the output of the first timing element F ^ is connected to the input f ₂ of the second timer FG, the input f. of the first timing element represents the input čas of the timing circuit E and the output of the second "jk I" of the timing element Fg represents the output S of the timing circuit F of the second signal line.

It is assumed such properties of timers that the output of the first timeline

Ep Ep F ^ arises when the logic 1 signal is input on the input of the logic 1 signal lasting for the first time interval, at the output of the second time element Eg, Fg .

This modified circuit has the property * that the passage of signals - from inputs A.,

2

Ag of Cp Cg auxiliary inputs to the second input P _2> r _g, the second terminal of the logic circuit Pg, R₂ and the second output signal line pryního Xg, Yg second output of second signal lines - is time limited in the range of the second time interval.

Another advantageous modified circuit for coupled release of signals is that the output 6 of the second combinational logic circuit J1 of the first signal line is connected to the second input rg of the second terminal logic circuit Rg, the output V of the second combinational logic circuit N of the second signal line is connected to the second p

input p _{2 of the} second terminal logic circuit Pg of the first signaling lead.

This advantageous modified circuit has the property that by applying a logic 1 signal to the second auxiliary input Cg, the second terminal logic circuit Pg of the first line signal is energized within the second time interval, and by applying a logic 1 signal to the first auxiliary input Cg of the second logic line terminal Rg in the second time interval.

Another advantageous modified circuit for coupled release of signals is that the output U of the second combinational logic circuit M of the first signal line is connected to the second input Ρχ of the first terminal logic circuit Ρχ of the first signal line 2 or to the second input Γχ of the first terminal logic. the second signal line combining logic N of the second signal line is coupled to the second input r ^ of the second signal line R ^ '' 2 ', or to the second input Ρχ of the first terminal logic circuit Ρχ of the first signal line knowledge.

The first modification involves energizing the first terminal logic circuit P1 of the first signal line after the first signal has been applied to the second input Bg of the second signal line within the second time interval ⁷ by applying the signal to the first auxiliary input Οχ. R- ^ of the second signal line after the first signal is applied to the first input Αχ of the first signal line within the second time interval, by applying the signal to the second auxiliary input; above feeding, the second input signal B of the second signal line ₂ in the range of the second time interval, and applying a signal to the first auxiliary input Οχ and znovuvybuzení first terminal of the logic circuit Ρχ first signal line after the previous p status signal to a first input Αχ first signal line within the range of the second time interval, and applying a signal to the second auxiliary input Cg.

The circuit for coupled release / passage of signals according to the invention is used in the construction of automatic machines for controlling two-position elements, especially power cylinders by means of electromagnetic gate valves.

Claims (5)

SUBJECT OF THE INVENTION 1. A pre-coupled signal release circuit comprising a first signal line and a second signal line, characterized in that the first signal line comprises a first input (A ^) of the first signal line associated with a first input (Ipp of the first terminal logic circuit (P ^). ), whose output constitutes the first output (Xjj first signal line, a second input (A _2), a first signal line connected to a first input (k ^) of the first combination logic circuit (K) of the first signal line, wherein the output (G) of this circuit ( K) is connected to the first input (^ g) of the second terminal logic circuit (Pg), the output of which is the second output (Xg) of the first signal line, the second signal line consisting of the first input (B ^) of a second signal line coupled to the first input (1 · ^) of the first combinational logic circuit (L) of the second signal line, the output (H) of this circuit (L) being connected to the first input ( ^L r ₁ ) of the first terminal logic circuit ( ^L ) R ^), whose output represents the first output (Y ^) of the second signal line, from the second input (Bg) of the second signal line associated with the first input (· * Τ ₂ ) of the second terminal logic circuit (Rg) Yg) of the second signal line, the interconnection of these signal lines is such that the first input (A ^) of the first signal line is further coupled to the second input (1g) of the first combinational logic circuit (L) of the second signal line and the time input (f) circuit (F) of the second signal line, the output (S) of this circuit (F) being connected to the first input (n ^) of the second combinational logic circuit (N) of the second signal line, the kind ý the input (n ₂ ) of this circuit (N) is connected to the second auxiliary input (Cg), the second input (Bg) _{Λ of the} second signal line is further connected to the second input (kg) of the first combination logic circuit (K) of the first signal line; with the input (e) of the first signal line timing circuit (E), the output (Q) of this circuit (E) being connected to the first input (mj) of the second combining logic circuit (M) of the first signal line, the second input (mg) of this circuit ( M) is coupled to a first auxiliary input (C ^), wherein the outputs (U, V) of the second combinational logic circuit (Μ, N) of the first signal line and the second signal line are connected to the second input (Pg, r _g ) of the second terminal logic circuit (P _2! . Rg), optionally with a second input (Pp r ^) of the first terminal logic circuit (Pp R ^) of the first signal line and the second signal line. Wiring according to claim 1, characterized in that the output (U) of the second combination logic circuit (M) of the first signal line is connected to the second input (p ₂ ) of the second terminal logic circuit (Pg) of the first signal line, the output (V) of the second signal line. the combination logic circuit (N) of the second signal line is coupled to the second input (r ₂ ) of the second terminal logic circuit (Rg) of the second signal line. 3. The circuit according to claim 1, wherein the output (U) of the second combination logic circuit (M) of the first signal line is connected to the second input (p1) of the first terminal logic circuit (P1) of the first signal line, and the output (U). V) of the second combinational logic circuit (N) of the second signal line is coupled to the second input (^ rj) of the first terminal logic circuit (R ₁ ) of the second signal line. 4. Connection according to claim 1, characterized in that the output (U) of the second combinational logic o circuit (M) of the first signal line is connected to a second input (r ^) of the first terminal logic circuit (Rj) of the second signal line, output (V) of the second The second logic circuit (N) of the second signal line is coupled to the second input (first terminal logic circuit (Pj) of the first signal line). 5. The circuit according to claim 1, characterized in that the time circuit (Ε, F) consists of a first time element (Ep F ^) and a second time element (Eg, ^F 2 ^ ⁱⁿ series), where the output of the first time element (E ^ , F ^) is connected to the input (e ₂ , fg) of the second time element (E ₂ , F ₂ ), wherein the input (e ^, f ^) of the first time element (E ^, F ^) represents the input (e, f) ) of the time circuit (E, F), and the output of the second time element (Eg, Fg) represents the output (Q, S) of the time circuit (E, F).