SU1048518A1 - Shift register - Google Patents

Abstract

The offset register contains memory cells, each of which consists of a double-winding relay, a first single-winding relay, and divides L1. a diode, a write key, the input of which is connected to the first power bus, the write key gate is connected to the start of a double-winding winding; rvlv guervoy memory cell key shift control. information, the input of which is connected to the first power bus, the ends of the windings of the memory cell stubs are connected to the second power bus, and the clock busbars 1, so to speak, so that, in order to simplify the shift register , it contains a formative contact pulses, consisting of a second and third single ecth relays, a diode and a delay element included parallel to the winding of the second / one winding relay, the ends of the windings of the second and third single output relays of the clock pulse generator connected with second power rail, start of winding torogo odnoobmotochnogo turnips clock shaper is connected via a diode to the first output control shift key information and a first clock bus, the second output sdvigsm control key. information is connected via successively connected contacts of the second and third section of the winding relay of the clock pulse generator with the anodes of the separation diodes of the memory cells and with the second clock bus, the beginning of the third single winding relay of the clock chip generator is connected via the closing contact of the second single relay of the clock chip generator of pulses with an output of a key. controlling information shift, the beginning of the first winding of a two-part relay of each memory cell (L dynen o through the first closing contact of the first single-winding relay of the previous memory cell with the first clock bus,; the beginning of the second winding of the double-winding reI of each memory cell is connected through i in series with the first closing contact of this relay, the breaking contact of the first single-winding relay 1 of the previous memory cell and the first one. For the 4th contact is a two-winding relay 00 of the next memory cell - with the third clock bus, the beginning of the first single-winding relay of each memory cell 00 is connected via the last Two secondary winding contacts of the previous cell and the first black contacts of the first, single winding turnip of this memory cell to the first power bus, the start of the first single winding relay of each memory cell are connected via serially connected third short contact. V of this relay and the second closure number. cycle of two-winding relay follow

Description

1048518

the third clock bus memory cell, the contact of the double-winding turnip turnip of the pre- diode diode diode of each whose- second cell from the start of the first one memory is connected via the second short-circuit relay of the given memory cell.

The invention relates to computing technology and automation and can be used in the construction of automatic automatic control devices for production technological machines, in particular, the implementation of technical means in controlling multi-position aggregate machines and automatic lines when it is necessary to track the flow of installed products by position. their transportation. A shift register is known, consisting of on-off storage elements (flip-flops), connected by delay lines; Each bit of the multi-bit dvd register contains a trigger and a delay in which the delay is due to the capacitor and the resistance ij. A disadvantage of the known register is the presence of capacitors in each bit, which complicates its structure. The closest to the invention of the technical essence. is a shift register, each memory cell of which consists of a double-winding relay with magnetic latching recording and information storage and a double-winding neutral relay, a capacitor, two resistors and a diode providing information shift in adjacent bits. The register also contains the switching contact of the information shift command and the power bus. The disadvantages of this register are the presence in each memory cell of a capacitor and resistors, the diversity of the element base (various types of relays, a ladder, resistors, a diode) and the elemental structures of the circuit (disconnecting the relay by shunting its coil, turning on the relay with discharge current the capacitor, the connection of the contacts, the control elements of the delay line to the second coil power bus), which complicates the structure of the register and reduces its reliability. The circuit of the invention is the simplification of the shift register. The goal is achieved by the fact that the shift register containing memory cells, each of which consists of a two-winding relay, a first single-winding relay and a separation diode, a write key, whose input is connected to the first power bus, the output of the write key is connected to the start of the first winding the first cell's dual-winding relay; the shift control key. the information, the input of which is connected to the first power bus, the ends of the windings of the turnips of the memory cells are connected to the second power bus, and the clock buses, contains a clock pulse generator consisting of the second and third single-winding relays, a diode and a delay element connected in parallel to the winding, of the second one-winding relay, the ends of the windings of the second and third single-watt relays of the clock pulse generator are connected to the second power bus, the start of the winding of the second single-winding turnip clock generator Through the diode with the first output of the information shift control key and with the first clock bus, the second output of the information shift control key is connected via successively connected disconnecting contacts of the second and third single-winding relay of the clock generator with the anodes of the separation diodes of the memory cells and with the second clock bus, the start of the winding the third one-winding relay of the clock clock pulse generator is connected via the closing contact of the second single-winding turnip clock switch clock pulse with a second m output key. information shift control, the beginning of the first winding of a two-winding turnip of each memory cell is connected via the first closing contact of the first single-winding relay of the Previous memory cell to the first clock bus, the start of the second winding of a double-winding turnip of each cell pa, the minute is connected through a gradually connected first closing contact of this turnip, the opening contact of the first single turnip turnip of the previous memory cell and the first contact to the double-turn turnip of the next memory cell - from the third clock, apo first odnoobmotochnogo turnips each memory cell is connected through a series connection of a second normally open contact two winding previous cell relay and the first normally open contact of the first rap odnoobmotochnogo this memory cell to a first power bus, the beginning of the first relay odnoobmotochiogo each memory cell is connected. through the third closed contact of this turnip and the second closing contact of the next winding memory cell with the third clock bus, the cathode of the separation diode of each memory cell is connected via the second winding relay of the previous cell with the start of the first single winding turnip of this memory cell. The drawing shows a functional diagram of the proposed shift register (only three bits are shown). The register contains the key 1 of the record, the key 2 of the information shift control, the shaper of 3 clock pulses consisting of turnips 4 and 5, the delay element 6 of the diode 7 and contacts 8-10, turnips 11 with contacts 12 and 13, turnips 14 with contacts 15-17 entering in (i -1) -th bit, turnip 18 with contacts 19 and 2O, relay 21 with contacts 22-24, entering into i -and bit, turnip 25 with contacts 26-28, Turnip 29 with DZ and 31 contacts included in (r + 1) -th discharge, contacts 32 and 33 (windings are not shown) and split diodes 34-36, which are included in the subsequent bits (ve shown), busbars 37 and 38 power, clock tires 39-41. The register works as follows: The control command records a unit of information in the (i -1) th digit, i.e. The relay 11 is turned on, which includes the relay 14, as the 4O bus is under voltage. When the 5184 key 2 is turned on, the voltage is removed from the buses 40 and 41 and fed to the bus 39, as a result of which the turnips 4 of the driver 3 are turned on. The contact 15 of the relay 14 signal of the unit is transmitted in the i-th bit, and the relay 18 is turned on. Turnip 14 remains in the on state for overwriting information despite the de-energization of the bus 40, which occurs due to its pin 17 connected to the power bus 37 . After opening the key 2, the relay 5 is turned on and the closing contact 9 energizes the bus 41. I switch off the coil relay 11 via the bus 41 circuit and the closing contact 12 receives power and the relay 11 turns off. At the same time, due to the smith of the pin 13, turnips 14 are turned off. After the time delay expires, relays 4 and 5 turn off, the 4O bus is powered and through the diode 35 and the closing contact 2O of the relay 18 turns on the relay 21 of the f-th digit. Similarly, the device works by moving a unit of information {and other bits. When writing two units in i -1) -th. and the 1 st bit of information moves when shifted to the (+1) th bit and remains in the 1 st bit. In this case, during the reset stroke, when power is supplied to the bus 41, when turnip 11 is turned off, the relay 14 remains switched on by means of contact 27, which is turned on at the first write cycle of relay 25, and its own closing contact 16. This way to the turn-off coil of turnip 18 of the f record Once a voltage is not applied, the voltage is not applied, and it remains in the on state. After de-energizing bus 41, relay 14 (-1) of the th bit is turned off. In this way, movement along the bit of the recorded information is provided. The advantages of the proposed register. the shift in comparison with the known are the absence of a delay with an RC chain in each discharge, which reduces the dimensions and simplifies the installation of the device; The simplification of the structure of smiles, which do not require the connection of turnips to the second common power bus, increases the reliability of the circuit. The absence of heterogeneity in the structure of communications and the element base increases the reliability of operation, simplifies installation and operation.

Claims (1)

SHIFT REGISTER containing memory cells, each of which consists of a double winding turnip, the first single winding turnip and divide the diode *, the write key, the input of which is connected to the first power bus, the output of the write key is connected to the beginning of the first winding · double winding; turnip of the first memory cell, shift control key. information input coupled to a 'first power bus, the ends of the windings turnips memory cells connected to the second power bus and clock bus of m and n and w u h and I th with the fact that, with the chain ¹ simplification Nia shift register , it contains the form of a clock cycle consisting of the second and third single-winding turnips, a diode and a delay element, including. · One parallel to the winding of the second single-winding turnip, the ends of the windings of the second and third single-winding turnip of the pulse shaper are connected to the second power bus, the start of the winding of the second single-winding turnip of the clock shaper is connected through a diode to the first output of the information shift control key and to the first clock bus, the second output of the shift control key. information is connected through serially connected disconnecting contacts of the second and third single-winding turnip clock pulse shaper with the anodes of the dividing diodes of the memory cells and to the second clock bus, the beginning of the winding of the third single-winding turnip turnip clock generator is connected through the make contact of the second single-winding turnip _ pulse shaper to the second key output -shift information management, the beginning of the first winding of a double-wrap $ winding turnip of each memory cell is connected via rvy make contact first odnoobmotochnogo turnips previous memory location to the first clock bus; start of second winding of double winding re | each memory cell is connected via the first closing contact of the turnip connected in series, the opening contact of the first single-winding turnip of the previous memory cell and the first double-winding contact of the subsequent memory cell is connected to the third clock bus, the beginning of the first single-winding turnip of each memory cell is connected through the second the make contact of the double winding turnip of the previous cell and the first make contact of the first single winding turnip of this memory cell with th power bus / beginning of the first odnoobmotochnogo turnips each memory cell is connected through a series connection of a third normally open contact of turnips and second closing con- tact * two winding turnips subsequent ' SU ... 1048518 memory cells with a third clock bus, the cathode of the diode diode of each memory cell is connected through the second make contact of the double-winding turnip of the previous cell with the beginning of the first one-winding turnip of this memory cell.