RU108634U1 - CONNECTIVE SENSOR - Google Patents

Abstract

 1. A detachable current sensor comprising a housing, a magnetic circuit and a sensing element, wherein the housing is made of non-magnetic material, consists of two parts — a base and a casing — and has a through hole at the junction to accommodate the test conductor, and a closed magnetic circuit located in the housing sensor made of soft magnetic material, characterized in that it contains an electronic device inside the housing, implemented on a printed circuit board, which is mounted vertically in the grooves of the casing, in a plane parallel to the frame the magnetic circuit, and the connector mounted on the same printed circuit board in the opening of the window made in the wall of the casing, while the closed magnetic circuit is made of two U-shaped parts, with one part in the base and the other in the casing. ! 2. The detachable current sensor according to claim 1, characterized in that the sensing element is made in the form of two serially connected inductors placed on opposite shoulders of the U-shaped element of the magnetic circuit, and the electronic device is a voltage converter. ! 3. The detachable current sensor according to claim 1, characterized in that it contains compensating inductors, and the sensing element is made in the form of Hall sensors located in the gaps between the two U-shaped parts of the magnetic circuit, while the electronic device includes a direct current generator, power amplifier and load resistance.

Description

Appointment

The utility model relates to measuring equipment, in particular, to sensors for non-contact measurement of current parameters in a current-carrying conductor and can be used for measurements among a wide class of electrical devices and power distribution networks.

State of the art

Known current and voltage sensors of the company ABB ("Power Electronics", No. 9, 2006, pp. 124-125), designed for non-contact measurement of direct, alternating and pulsed currents flowing in the conductor. The sensors have a wide range of parameters, have high sensitivity and accuracy. However, when mounting or removing the sensor, the conductor either needs to be torn or dragged through the hole in the sensor.

Known sensors with a measuring coil and a closed core (US patent No. 4529931 from 04/07/1983). The disadvantage of the sensor is that, in order to pass the conductor through the core, the latter makes a slot with the possibility of closing it after installation, while the surfaces of the contacting parts must have a precise fit.

The current sensor according to the patent of the Russian Federation No. 2100811 of 06/18/96 contains a body of non-magnetic material with a base and two opposite walls, in which a U-shaped concentrator of magnetic flux is partially placed. The sensor includes a capsule containing a sensitive element in the form of a core inductance coil. The capsule is mounted on the studied conductor and is rigidly connected to the walls of the magnetic flux concentrator. Thus, to measure the current in the studied conductor, the latter does not need to be cut, but must be laid in the sensor housing and covered with a capsule. The sensor has significant drawbacks. The open and protruding ends of the concentrator are susceptible to the ingress of small metal objects or chips on them, as well as exposure to external electromagnetic fields that reduce the sensitivity of the sensor. The hub is cut at its base and does not represent a closed loop, which also contributes to the impact of external fields on it. All this reduces the operational capabilities of the sensor, its sensitivity and measurement accuracy.

The closest in technical essence to the claimed object is a current sensor (utility model of the Russian Federation No. 21457 from 09/20/2001), which contains a body of non-magnetic material with a cavity for placement of the conductor under study, a magnetic flux concentrator located in the sensor housing, as well as a sensitive element, moreover, the sensor is detachable and consists of two parts. At least one of the parts is provided with a sensing element. When assembled, the magnetic flux concentrator forms a closed loop.

Each component of the sensor is equipped with a magnetic flux concentrator, which is made of soft magnetic material and consists of three components, while the two component parts of the concentrator are flush with their ends flush with the plane of the connector of the sensor components. The sensitive element of each component of the sensor is made in the form of an inductance coil with a core and is placed inside the housing of the component. As the core of the inductor, the third component of the magnetic flux concentrator is used. The core of the inductor is oriented in such a way that in the working position the projection of the magnetic flux generated by the flow of alternating (pulsed) current through the conductor under study onto the core axis is non-zero.

The disadvantage of the sensor is the implementation of the magnetic flux concentrator of three components, which leads to a significant effect of external magnetic fields. Electronic circuits for power supply and preliminary processing of the signal generated by the sensor are not structurally included in the current sensor and can be located only at some distance from the current sensor, which leads to an increase in noise and loss of the amplitude of the useful signal.

Utility Model Disclosure

The detachable current sensor comprises a housing of non-magnetic material. The case is detachable, consisting of two parts: the base and the casing. In the lower part of the casing, a through groove is made, which, when assembling the case, when connecting the lower and upper parts, turns into a through hole for placement of the studied conductor in it. A closed magnetic circuit (magnetic flux concentrator), made of two U-shaped elements obtained, for example, from a single rectangular magnetic circuit by cutting, is placed inside the housing. One U-shaped element is located in the base, the other in the casing. In the casing there is a sensitive element that registers the magnetic field generated by the studied conductor placed in the hole, and also - an electronic device implemented on a printed circuit board with radio elements and a socket part of the connector. The board is fixed in the grooves of the casing vertically and parallel to the plane of the frame of the magnetic circuit. Through the connector, power is supplied to the electronic device, which converts the voltage supplied to the sensitive element, for which purpose a window is located in the casing wall located opposite the socket part of the board connector, through which the plug of the external cable is connected. In the base and the casing there are corresponding holes for tightening the housing parts together with each other by bolts. At the base there are grooves for mounting the sensor to the structural elements of the measurement object.

The introduction of the essential features:

- implementation of a closed magnetic circuit in the form of two U-shaped elements, ensuring the presence of only two gaps (in contrast to the six gaps of the prototype), in which the magnetic flux is scattered, and

- placement inside the casing of an electronic device (designed to supply power to the sensitive element and process the measuring signal) in close proximity to the sensitive element,

provides high sensitivity and noise immunity of a measuring signal

There are two options for performing the sensitive element.

According to the first embodiment, the sensitive element is made in the form of two inductors located on opposite shoulders of the U-shaped element of the magnetic circuit located in the casing. Such a sensing element can be used to detect alternating current.

According to the second variant, two Hall sensors located in the gaps between the two parts of the magnetic circuit are used as a sensitive element. The Hall sensor measures both alternating and direct current. The inductors here are also located, as in the first embodiment, on opposite sides of the U-shaped part of the casing magnetic circuit. However, in this case, they perform compensatory functions. Moreover, the constant compensation of the primary magnetic flux created by the conductor with current, carried out with their help, allows the sensor to work even at overload values of the primary current, measuring its instantaneous changes.

The essence of the utility model is illustrated by drawings, which depict:

Figure 1. General view of the current sensor in the context (option 1).

Figure 2. General view of the current sensor in the context (option 2).

Figure 3. Schematic diagram of the current sensor (two options)

Consider the specific design of the current sensor.

The case of the current sensor consists of two parts: the base 1 and the casing 2, made of non-magnetic dielectric material. A through groove 3 is made in the lower part of the casing, which, when assembling the housing, turns into a through hole in the housing for placement of the conductor under study. A closed magnetic circuit 4 (magnetic flux concentrator), made of two U-shaped elements obtained from a single rectangular magnetic circuit by cutting, is placed inside the housing. One element of the magnetic circuit is fixed in the base 1, the other is located inside the casing 2. The magnetic circuit is made of an alloy of amorphous iron. In the casing is a sensitive element that registers the magnetic field created by the investigated conductor. In the first embodiment, the sensitive element is made in the form of two inductors 5 located on opposite shoulders of the U-shaped element of the magnetic circuit located in the housing 2. In the housing there is a printed circuit board 6 with an electronic circuit of the converter and a socket 7 of a two-pin connector, through which power is supplied to electrical circuit and eat a useful signal. As a converter, the BURRBRAUN XTR114 chip can be used. The inductors 5 are tightly seated on the cores of the magnetic circuit, the printed circuit board 6 is attached to the frame of the inductors 5 using plastic sleeves 5. The socket 7 of the connector is rigidly fixed to the printed circuit board 6. In the casing there is a window 8 located opposite the socket 7 of the connector through which to this socket an external cable is connected. In the base 1 and the casing 2 there are holes 9 for tightening bolts 10 of these parts of the housing with each other, and in the base there are grooves 11 for attaching the sensor to the structural elements of the device on which measurements are made. For ease of assembly, the upper part of the casing is made in the form of a removable clamping cover 12, fixing the magnetic circuit in the sensor housing through the seal 13 with screws 14, screwed into the tides 15 in the wall of the casing 2. For ease of assembly and additional fixation, there are grooves inside the casing (not shown) for fixing the circuit board 6. According to the electrical circuit, the contacts “a” (plus) and “b” (minus) of the two-pin socket 7 are connected to the converter 16, which is connected to the inductance coils 5 connected in series.

In the second embodiment, two Hall sensors 17 are used as the sensing element, located in the gaps between the two parts of the magnetic circuit. Inductors 5 are also located on opposite sides of the U-shaped part of the casing magnetic circuit, however, they are compensatory in function. According to the electrical diagram, the contacts “a” (plus) and “g” (ground) of the 4-pin socket of connector 7 are connected to a DC generator 18, contact “b” (minus) and “g” (ground) with a power amplifier 19, the last connected to two Hall sensors connected in series by power. The DC generator can be made according to the standard mirror circuit on two transistors DC847 and two transistors BC857. The power amplifier can be performed on a BURRBRAUN XTR114 chip on two transistors DC847 and two DC857 according to the circuit shown in the form for this chip. The power amplifier is connected at the input to the Hall sensors, and at the output to a circuit from two compensating induction coils 5 in series and a load resistance 20. The signal taken from the load resistance 20 is applied to terminal “b” (output) of the socket of socket 7.

The sensor operates as follows. The base 1 of the current sensor is installed in the area where the studied conductor will pass, using the grooves 11 available on the base and the fasteners. The test conductor is laid across the base so that the conductor is in the projection of the groove 3 of the casing, close with a casing (without a cover), fasten the casing with the base with bolts 10. Then, with the help of screws 14, the casing is closed with a clamping cover 13. To the socket of the connector 7 of the sensor connect the cable of the measuring device (not shown in the figure) and take its readings when passing current through the studied conductor.

According to the first embodiment, the current flowing through the conductor forms a magnetic flux, which, through the magnetic circuit 4, induces an EMF in the inductors 5 proportional to the values of the current flowing through the studied conductor. The supply voltage is supplied through the socket of the connector 7 to the converter 16, and then supplied to the inductors 5 connected in series.

It should be noted that power is supplied and the signal is taken through the same connector pins on the printed circuit board. This is because in order to power the sensor, a constant voltage is applied to the connector contacts, which is supplied to the converter 16, which generates a constant current in the wires connected to the connector contacts. This direct current changes when placed in the cavity of the sensor of the investigated conductor with the measured current. This change judges the magnitude of the measured current.

According to the second option, the supply voltage is supplied from connector 7 to the DC generator 18 and the power amplifier 19. The DC generator 18 supplies power to the Hall sensors 17. The signal from them is supplied to the power amplifier 19, and from the amplifier to compensation inductive coils 5 and resistance loads 20. The magnetic flux generated by the compensation coils compensates the magnetic flux from the current flowing in the studied conductor. A useful signal from the load resistance 20 is supplied to the output contacts of the connector 7.

The sensor has successfully passed tests at the stage of the laboratory layout and prototype.

Claims (3)

1. A detachable current sensor comprising a housing, a magnetic circuit and a sensing element, wherein the housing is made of non-magnetic material, consists of two parts — a base and a casing — and has a through hole at the junction to accommodate the test conductor, and a closed magnetic circuit located in the housing sensor made of soft magnetic material, characterized in that it contains an electronic device inside the housing, implemented on a printed circuit board, which is mounted vertically in the grooves of the casing, in a plane parallel to the frame the magnetic circuit, and the connector mounted on the same printed circuit board in the opening of the window made in the wall of the casing, while the closed magnetic circuit is made of two U-shaped parts, with one part in the base and the other in the casing. 2. The detachable current sensor according to claim 1, characterized in that the sensing element is made in the form of two serially connected inductors placed on opposite shoulders of the U-shaped element of the magnetic circuit, and the electronic device is a voltage converter. 3. The detachable current sensor according to claim 1, characterized in that it contains compensation inductors, and the sensing element is made in the form of Hall sensors located in the gaps between two U-shaped parts of the magnetic circuit, while the electronic device includes a direct current generator, power amplifier and load resistance.