RU2647995C2 - Device for diagnostics of contacts of power electrical equipment - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to fire alarm signalling means and can be used, in particular, in shipbuilding to prevent the fire danger of ship electrical equipment potentially exposed to intentional power electromagnetic influences. The device for diagnostics of contacts of power electrical equipment contains groups of diodes connected to pairwise interacting groups of contact parts of this equipment, a voltage indicator, connected to these diodes with an output, connected to the alarm signal shaper of the diagnostics system. In this case, the diodes are connected to the contact parts of one of the pairwise interacting groups by one pole, and to the contact parts of the other by the other pole, the opposite poles of the diodes of each group are connected to each other and connected to the polarity corresponding voltage inputs of the voltage indicator. To the contact parts of one of the pairwise interacting groups, the diodes are connected through pairs of metal lobes cantilevered on the electrical heat insulator. At least one of the lobes is made of thermos-bimetal with active and passive layers. The lobes are made with the same length of the console part and installed at a distance equal to the value of the first lobe end offset during its heat deformation, corresponding to the value of recorded temperature. Armature of heat-resistant material can be installed at the interacting ends of the lobes.

EFFECT: invention makes it possible to reduce the consequences of destructive influence of potential means of intended electromagnetic power influence on ships by increasing the accuracy of contact diagnostics.

3 cl, 2 dwg

Description

The invention relates to devices for diagnosing contacts in high-current equipment, as well as to means for signaling a fire hazard and can be used, in particular, in shipbuilding.

Thermal imagers (Russian Joint-Stock Company of Energy and Electrification "UES of Russia". Department of Development Strategy and Scientific and Technical Policy. Basic Provisions. Methods of infrared diagnostics of electrical equipment and overhead lines. RD 153-34.0- are used to diagnose contacts of power electrical equipment for fire prevention in high-current equipment. 20.363-99).

The main disadvantage of thermal imaging diagnostics of the contacts of power electrical equipment on ships is the need to use all the main consumers of electricity directly during the examination to ensure nominal current loads on the examined contact joints.

The closest in technical essence is a device for diagnosing contacts of power electrical equipment, containing groups of diodes connected to pairwise interacting groups of contact parts of this equipment, and a voltage indicator connected to these diodes, connected to an alarm driver of the diagnostic system (AS USSR No. 870926, IPC G01D 5/56).

However, this device has inherent disadvantages in that it is not possible to prevent the fire hazard of ship power electrical equipment that is potentially exposed to deliberate power electromagnetic influences.

These disadvantages are due to the lack of resistance of the electronic components of the device to deliberate electromagnetic forces.

Persistence in this case means the ability to withstand impacts that cause irreversible disruption. This concept is characterized by the boundary values of the influencing factor (voltage, field strength, energy), at which the stable functioning of this device is still preserved. Moreover, for relays, the resistance is several orders of magnitude greater than the resistance of electronic circuits (Habiger. Electromagnetic compatibility. Fundamentals of its provision in technology. M: Energoatomizdat, 1995, Fig. 3.1).

For unshielded microelectronics directly interacting with the contacts of electrical equipment, the probability of failure as a result of exposure to an electromagnetic pulse is high, and shielding it complete with power electrical equipment in the frequency range of potential intentional power electromagnetic effects unnecessarily complicates and increases the cost of the construction of ship upper deck products.

Deliberate power electromagnetic effects with sufficient power and repetition rate have a destructive effect on the contacts of the power electrical equipment of the upper deck devices on the ship, causing an increase in their transition resistance. This leads to further accelerated degradation of the contact transition under the influence of an aggressive marine environment. The degradation of the contact transition is accompanied by overheating of both detachable and collapsible contact joints, and switching contacts of electrical equipment, which could potentially lead to the ignition of this electrical equipment and a fire on the ship.

The invention solves the problem of preventing fire hazard of ship electrical equipment, potentially exposed to deliberate power electromagnetic effects, in terms of diagnostics of large transient resistance of contact joints by identifying the latter overheating during operation.

The problem is solved in that in the contact diagnostics device of power electrical equipment, containing groups of diodes connected to pairwise interacting groups of contact parts of this equipment, and a voltage indicator connected to these diodes with an output connected to the diagnostic driver of the alarm system, to the contact parts of one of pairwise interacting groups of diodes are connected by one pole, and to the contact details of the other by another pole. The opposite poles of the diodes of each group are interconnected and the voltage indicator inputs are connected to their respective polarities. The diodes are connected to the contact parts of one of the pairwise interacting groups through pairs of metal petals, at least one of which is made of thermobimetal with active and passive layers and is cantilevered, adhering to provide thermal and electrical contact to the corresponding contact part with the active layer, and the second lobe is parallel to the first and cantilevered end to electrothermal insulator.

The petals are made with the same length of the cantilever part and are installed with the active layer facing the corresponding contact part. The petal is located at a distance from the loose end of the cantilever part of the first petal, equal to the displacement of this end of the first petal at its temperature deformation corresponding to the value of the recorded temperature. The second lobe is made of thermo-bimetal with the length of the cantilever part corresponding to the length of the cantilever part of the first lobe, and is installed with an active layer directed towards the first lobe. On the ends of the petals interacting by contacting, lining made of refractory material is installed.

As a result, after deliberate power electromagnetic effects, the device appears to be in working condition and allows you to quickly identify the contacts of electrical equipment, which had a destructive effect. Timely restoration of these contacts eliminates their overheating and fire during equipment operation after deliberate power electromagnetic exposure.

All of these signs are essential and sufficient to increase the reliability and survivability of fire alarm systems, and therefore, to achieve a technical result - to prevent the fire hazard of ship electrical equipment, potentially exposed to deliberate electromagnetic forces.

The invention is illustrated in the drawing, where in FIG. 1 shows a device for diagnosing contacts of power electrical equipment, and in FIG. 2 - the node of the device with the petals in an enlarged view.

A diagnostic device for contacts of power electrical equipment with an interacting group of contact parts 1.1-1.3 of live busbars connected with a group of contact parts 2.1-2.3 in the form of cable lugs for a power supply network contains:

a group of diodes 3.1-3.3 connected by one pole to the contact parts 1.1-1.3;

a group of diodes 4.1-4.3 connected by another pole to the contact parts 2.1-2.3;

the poles of the diodes 3.1-3.3, opposite to those connected to the contact parts 1.1-1.3, are interconnected and connected to the voltage polarity indicator 5 input connected to the diagnostic driver 6 of the alarm signal generator 6.

The voltage indicator 5 preferably provides galvanic isolation of the device of the emergency driver of the diagnostic system 6,

in the variant without using microelectronics, it can be implemented by an electromechanical relay, the contacts of which are connected to the diagnostic system 6, or in the form of a gas-discharge emitter interacting with the photodetector of the diagnostic system directly or through a fiber.

In an embodiment using microelectronics, the indicator can be made in the form of an emitter of an electromagnetic or acoustic signal interacting with the corresponding receiver of the diagnostic system. When using an electromagnetic or acoustic signal generator as a voltage indicator, a large displayed voltage value corresponding to the operating voltage of the ship electrical power supply network and low voltage values of microelectronic electromagnetic or acoustic signal generation circuits allow the use of voltage dividers with wide-range voltage limiters (varistors, gas dischargers, capacitive filters and other similar media you, in which the level of exposure is reduced to acceptable values).

The poles of the diodes 4.1-4.3, opposite to those connected to the contact parts 2.1-2.3, are also interconnected and connected to the voltage indicator 5 input corresponding to their polarity.

To the contact parts 1.1-1.3, diodes 3.1-3.3 are connected through metal tabs 6.1-6.3.

To the contact parts 2.1-2.3, diodes 4.1-4.3 are connected through metal lobes 7.1-7.3.

Petals 6.1-6.3 and 7.1-7.3 are made of thermal bimetal with active and passive layers.

Petals 6.1-6.3 are cantilevered fixed adjacent to one end, providing thermal and electrical contact, to the corresponding contact parts 1.1-1.3.

Petals 7.1-7.3 are cantilevered in parallel with the corresponding petals 6.1-6.3 at one end on 8.1-8.3 electrical insulators.

Petals 6.1-6.3 and 7.1-7.3 are made with the same length of the cantilever part and are installed with an active layer facing the contact part, respectively 1.1-1.3.

The loose ends of the cantilever part of the petals 7.1-7.3 are located at a distance from the loose ends of the cantilever part of the petals, 6.1-6.3, respectively, equal to the amount of their displacement during thermal deformation corresponding to the recorded temperature.

On interacting by contacting the ends of the petals 6.1-6.3 and 7.1-7.3 installed lining of refractory material, such as tungsten.

The device operates before and after intentional power electromagnetic exposure as follows.

During a deliberate electromagnetic force, the voltages induced on the contact parts through capacitive connections of the pairs of petals and spark gaps between their ends, short-term pulses are not perceived by the diagnostic system. Tungsten pads at the ends of the petals prevent them from burning and with appropriate protection of the voltage indicator from surge surges after this exposure, the device is in its original operational state.

With this deliberate electromagnetic force effect due to powerful pulse overheating, contact pressure between the interacting pairs of contact parts 1.1 and 2.1, and / or 1.2 and 2.2, and / or 1.3 and 2.3 can be weakened. In the process of operating electrical equipment, under the influence of an aggressive marine environment, this will cause overheating of these pairs of contact parts by currents of power supply of electrical equipment and accelerate their corrosion, which, in turn, will accelerate the process of raising the temperature until it reaches the ignition level of insulating materials and, accordingly, electrical equipment. With a limited number of ship personnel and its workload with functional responsibilities, it is not possible to monitor thousands of power contact joints and timely identify defective ones during ship operation. Therefore, during the operation of the ship, an increase in the contact resistance of the contact joints of the pairs of contact parts

When overheating, at least one pair of contact parts, for example 1.1-2.1, the lobe 6.1 is deformed and its end is in contact with the lobe 7.1. Through the diode 3.1, a voltage with a polarity opposite to that supplied through the diodes 4.1-4.3 is supplied to the input of the voltage indicator 5, and the indicator 5 starts the alarm driver of the diagnostic system 6.

When one pair or two pairs of contact parts are connected, a pulse voltage is generated, which, if necessary, can be smoothed by additional filters, and when all three pairs of petals are connected, an almost constant pulsating voltage is formed (three-phase one-half-wave rectification).

The voltage indicator 5 generates an alarm for the diagnostic system 6, after which the ship personnel eliminates the defect in the corresponding contact by pulling it up or stripping it, which prevents the occurrence of a fire hazard on the ship.

The proposal allows to reduce damage from the destructive influence of potential means of deliberate power electromagnetic impact on ships.

Claims (3)

1. A device for diagnosing contacts of power electrical equipment, containing groups of diodes connected to pairwise interacting groups of contact parts of this equipment, a voltage indicator connected to these diodes with an output connected to the emergency driver of the diagnostic system, characterized in that the contact parts of one of the pairwise interacting groups of diodes are connected by one pole, and to the contact parts of the other by another pole, the opposite poles of the diodes of each group are interconnected and the voltage indicator inputs are connected to their respective polarities, moreover, the diodes are connected to the contact parts of one of the pairwise interacting groups through pairs of metal petals, at least one of which is made of thermobimetal with active and passive layers and is cantilevered, adjoining to ensure thermal and an electrical contact to the corresponding contact part with the active layer, and the second lobe parallel to the first is cantileverly fixed with an end on an electrothermal insulator, the petals are made s of equal length arm portion and are mounted with an active layer facing toward the corresponding contact piece, the second lobe is spaced apart from the unattached end of the cantilevered portion of the first tab by a distance equal to the offset value of the end of the first lobe when the temperature of deformation corresponding to the value recorded temperature. 2. The device of claim 1, characterized in that the second lobe is made of thermal bimetal with a length of the cantilever part corresponding to the length of the cantilever part of the first lobe, and is installed with an active layer directed toward the first lobe. 3. The device of claim 2, characterized in that lining made of refractory material is installed on the ends of the petals interacting by contact.

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