RU203512U1 - DETERMINATOR OF DEVICE SYMPTOM CODE - Google Patents

Abstract

The utility model relates to the field of electroautomatics and is designed to recognize variants of means of destruction. The sign of a variant of the weapon is determined by connecting to one contact of the connector one of a number of built-in circuits of the weapon: a circuit with an open circuit, a circuit connected to the body of the device, and a circuit with a diode. The determinant of the code of the sign of the means of destruction generates signals of the connected circuits for the subsequent determination of the type of means of destruction. The technical result is achieved by introducing a determinant unit into the determinant of the code of the sign of the means of destruction. The determinant unit is made in electronic design, which allows using the element base without selective selection, and also increases the reliability of the device and ensures a stable operating mode.

Description

Determinant of the code of the sign of the means of destruction

The utility model relates to the field of electroautomatics for recognizing devices that require separation according to their functional purpose with certain parameters and functions (code of the indication of the execution of weapons), when the appearance of the devices is hardly distinguishable.

From the prior art, a determinant of the code of the sign of the means of destruction is known using one or more contacts from a number of unused contacts (leads) of the adapter connector (Product SUO-806P. Technical operation manual IGAP. 794125.008. - Kursk: OJSC "Pribor", 2007. - 61 s.). The number of unused contacts in such a device is not limited. In the case of a limited number of free contacts in the connector, a different recognition method is proposed.

This device is shown in FIG. 1. The functional diagram of the device is implemented for one free contact on the connector, where one of the three functional devices of the means of destruction is connected to the connector of the feature determining device. The determinant of the code of the sign of the means of destruction performs the identification of each of the three different types of means of destruction with different functional purposes. These three types of means of destruction differ by the presence on the unused contact of the connector of various electrical circuits - signs of means of destruction in the form of: a circuit with high impedance (open circuit) - SP1, a circuit connected to the body of the device - SP2, and a circuit in which diode D1 is connected, connected by a cathode to the body of the device, and the anode to the unused contact of the connector - SDR. The power supply for the determinant of the weapon sign code is provided by a source of the on-board network with a voltage of +27 V and a separate power supply of -27 V. and the resistance of the relay coil K1.2 connected through the open transistor T1 of the 5/27 converter. The upper terminal of the resistor R1 is connected to the voltage of the on-board network +27 V, the lower terminal of the winding of the relay K1.2 is connected to the stabilized voltage of the power supply -27 V. The connector of the measuring divider is connected to the input of the converter 27/5. Normally open contact 1 of the controlled circuit of relay K1.1 is connected to the housing terminal, and the switching contact 2 of the controlled circuit of relay K1.1 is connected to input P of the control device, and also through a limiting resistor R2 is connected to the onboard power supply +27 V.

The specified determinant of the code of the sign of the means of destruction works as follows. If there is a sign of a means of destruction SP1: at the input P of the control device (contact 2 of the relay circuit K1.1) there is a signal level of the positive voltage of the on-board network. The voltage of the on-board network level +27 V is fed to the input of the converter 27/5 and forms a logic signal of the upper level to the control device. As a result, the transistor T1 in the 5/27 converter is closed, and the relay coil K 1.2 is de-energized. At the input of the control device there are two signals that form the codes of the connected weapon: 1 and 1.

In the presence of the sign of the means of destruction SP2: at the input of the identifier of the code of the sign of the means of destruction on the connector (and, accordingly, on the divider and at the input of the 27/5 converter) there is a signal level "case". In this case, a logical zero level is formed at the output of the converter 27/5, which is also a consequence of the formation of the signal to turn on the converter 5/27 and the opening of the transistor T1, and hence the voltage supply of the signal level "case" to the relay coil K1.2. As a result of the actuation of the controlled circuit of the relay K1.1, its contacts are switched and the signal level "case" is fed to the input P of the control device. At the inputs of the control device there are two signals that form the codes of the connected weapon: 0 and 0.

If there is a sign of a means of destruction SP3: there is a voltage on the connector and the measuring divider below the level of the signal "case". In this case, the voltage at the input of the converter 27/5 is a logical zero, at the output of the converter 27/5 a logical zero is formed, as a result the transistor T1 is open, the voltage on the winding of the relay K1.2 is below the level of the trigger signal, the relay contacts are open. There are two signals on the control device that form the codes of the connected weapon: 0 and 1.

The disadvantage of this technical solution is the selective selection of the relay according to the level of response sensitivity, a large current consumption and a long-term on-state mode of the relay winding, leading to its overheating and a subsequent decrease in the resource.

In this device, the current on the coil of the K1.2 relay is in the range from 30 to 50 mA, and the voltage is 27 V, as a result of which the heating temperature of the relay is about 100 ° C. This heating temperature violates the insulation of the relay coil K1.2. During the manufacturing process of this device, it takes 5 hours to check its operability in a thermal chamber, as well as 1.5 hours to set up the device.

The task of the utility model is to reduce the current consumption, increase the manufacturability and reliability of the device, reduce the labor intensity of manufacturing and avoid selectivity, and ensure a stable thermal mode of operation of the device.

The problem is solved by the fact that the identifier block is introduced into the determinant of the code of the sign of the means of destruction, which identifies the type of loaded external means of destruction. The work of the determinant block is carried out according to the feature of the download option, implemented on one of the unused contacts of the connector.

The proposed version of the device is made in electronic design and is devoid of the above disadvantages.

The block diagram of the proposed device is shown in Fig. 2.

The determinant unit consists of a resistor R5, the upper terminal of which is connected to the emitter of the transistor T1 in the 5/27 converter, as well as to the cathode of the Zener diode D3. The lower terminal of the resistor R5 is connected to a stabilized voltage source of the on-board network of -27 V, and to the left terminal of the resistor R3. The output of the anode of the Zener diode D3 is connected to the input 3 of the anode of the optocoupler OT1 and to the upper output of the resistor R4, which shunts the input of the optocoupler OT1. The lower terminal of the resistor R4 is connected to the right output of the resistor R3 and the lower terminal 4 of the optocoupler OT1. Output 2 of the output of the optocoupler OT1 is connected to the input of the control device, to which the voltage of the on-board network +27 V is supplied through the resistor R2.

The signal of the sign of the means of destruction enters through the connector to the measuring divider formed by the resistor R1 and the resistor R5 of the determiner unit. The upper terminal of the resistor R1 is connected to the voltage of the on-board network +27 V, and the lower terminal of the resistor R1 is connected to the collector of the Peak transistor cathode of the Zener diode D3.

The proposed determinant of the code of the sign of the means of destruction works as follows.

If there is a sign of a means of destruction SP1: on the connector and the measuring divider there is a voltage of the on-board network of +27 V. At the same time, a logical unit level is present at the output of the 27/5 converter, the transistor T1 of the 5/27 converter is closed, and at the output of the optocoupler OT1 there is an "open" ... Thus, codes 1 and 1 are generated at the output of the control device, corresponding to the sign of the means of destruction SP1.

If there is a sign of a means of destruction SP2: there is a voltage of the signal level "housing" on the connector and the measuring divider. Here, the current from the +27 V on-board network source flows through the resistor R1 to the "case". Converter 27/5 at the voltage at the input of the signal level "housing" forms a logical zero at the output and turns on the converter 5/27. The open transistor T1 passes the current from the -27 V source through the resistor R5 and, accordingly, the current through the Zener diode D2 and the optocoupler OT1. As a result, the output of the optocoupler OT1 forms at the output a voltage level "case", and at the output of the control device codes 0 and 0 are generated, corresponding to the sign of the means of destruction of SP2.

If there is a sign of a means of destruction SP3: there is a voltage on the connector at a level below the "case" value and below the stabilization voltage of the Zener diode D3. In this case, diode D2 and zener diode D3 are closed. The input voltage of the 27/5 converter corresponds to the "case" level, and a logical zero is present at the output of the 27/5 converter and the input of the 5/27 converter. As a result, the 5/27 converter opens the transistor T1, but the voltage across the resistor R5 is lower than the voltage level of the zener diode D3, therefore the current does not flow through the optocoupler OT1 and the outputs of the optocoupler OT1 are open, and codes 0 and 1 are generated at the output of the control device, corresponding to the sign of the means of destruction SP3 ...

The presented device was developed by the specialists of JSC "Aviaavtomatika" them. V.V. Tarasova ", and is used in weapons control systems.

The utility model was implemented for a weapon control system using various available standard elements. When using the utility model, there is no need to select a specific element base with strictly regulated technical characteristics (for example, in the original version of the identifier of the weapon attribute code (Fig. 1), it was necessary to use a relay with certain characteristics for a current of 50 mA from the voltage of the on-board network).

As a result, current consumption is reduced. Selective selection of elements is not required and the labor intensity of manufacturing is also reduced. The reliability of the device is increased, its stable thermal mode of operation is ensured.

The foregoing allows us to conclude about the industrial applicability of the utility model.

Claims (1)

Determinant of the weapon sign code, consisting of a connector, a measuring divider, a 5/27 converter, a 27/5 converter and a control device, characterized in that the determinant of the weapon sign code includes a unit for determining the type of loaded weapons, consisting of resistors, an optocoupler and a zener diode, where the cathode of the zener diode is connected to the emitter of the transistor of the 5/27 converter, the anode of the zener diode is connected to the anode of the optocoupler, the output of the optocoupler is connected to the input of the control device, which makes it possible to identify the signal of the type of loaded means of destruction implemented on one of the unused contacts of the connector.

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