RU2250470C2 - Electronic electricity meter configuration - Google Patents

Abstract

FIELD: electronic electricity meters.

SUBSTANCE: meter has first part of case provided with members of post shoe, second part of case, assembled wiring plate and incomplete shoe post. Wiring plate has toroidal current detectors and voltage isolator. Meter is also provided with contact spring which provides electric connection of assembled wiring plate incomplete shoe post. Meter is additionally provided with binoculars and starter switch.

EFFECT: mechanical simplification of configuration; improved reliability of operation.

35 cl, 27 dwg

Description

The present invention relates to the creation of electronic electricity meters, and more particularly to the creation of the layout (packaging) of electronic electricity meters.

Programmable electronic energy meters quickly replace electromechanical meters due to the wider functionality achieved through the use of programmable logic built into solid state electronic meters. Some of these meters can be used to measure in different electrical ranges without changing hardware. For example, a meter with an effective voltage range from 98 V to 526 V can be used to operate at voltages of 120 V or 480 V. US Pat. 5457621 dated October 10, 1995, “Key power supply with voltage clamp circuit”, examples of such sources are disclosed. In addition, some meters that can be used on any 3-wire or any 4-wire power network are disclosed in US Pat. 5457621.

However, the known counters have a complex layout, which leads to an increase in the complexity of assembly and verification of the counter, as well as to an increase in the manufacturing cost and a decrease in the reliability of the counter. In connection with the above, there is a need to create a reliable layout of the electronic meter, with easy assembly and verification of the assembled closed meter.

The present invention is directed to the creation of an electronic energy meter and its layout. The layout of the meter includes a limited number of parts, and the measuring electronics are installed on the main circuit board, which eliminates microwire leads and hinged installation of wires inside the shell. Due to this, the layout of the counter is mechanically simplified in comparison with the currently known counters, which leads to lower costs and increased reliability of the counter installed inside the shell.

In accordance with various aspects of the present invention, the layout of the meter comprises four main parts and does not have fastening means such as screws or rivets. Interconnections (electrical connections between the circuit board and the metal fittings of the meter) are made through the use of springs between the circuit board and the current rails.

A known electricity meter, the case of which consists of two parts, made with the possibility of pairing with each other, while one of the parts of the case contains many elements of the terminal block, and inside the meter case at least partially placed the circuit board assembly and an incomplete terminal block (RU 2000576 C1).

In addition, the meter further comprises a wiring cover connected to the second part of the housing. This part of the housing can be made of translucent material and have a window.

It is advisable to install toroidal current sensors mainly parallel to each other and at an angle of about 45 degrees relative to the edge of the circuit board.

In contrast to the known, the meter according to this invention further comprises a contact spring, which provides electrical connection of the circuit board assembly with an incomplete terminal block, and the circuit board contains toroidal current sensors.

The counter may further comprise a plurality of current conductors, each of which passes through a corresponding current sensor, wherein each of the current conductors is made of a flat wire, the ends of which are fixed in an incomplete terminal block.

The meter can be equipped with a voltage disconnector. According to the invention, the voltage disconnector comprises a screw and a square nut, into which the screw can be screwed out to form a screw / nut assembly, on the counter circuit board there is a slot in which the screw / nut assembly slides, and on one side a disconnector tide is provided voltage.

Incomplete terminal block of the meter has a socket for the direction of the voltage disconnector. At one end of the slot, the surge of the voltage disconnector forms a short circuit with the screw / nut assembly, and at the other end of the slot, the screw / nut assembly enters the socket inside the power meter, preventing the square nut of the voltage disconnector from rotating.

The electricity meter according to the invention may further comprise binoculars mounted between the second part of the housing and the circuit board assembly.

The binoculars for the electricity meter include: a first rail and a second rail parallel to the first rail, the first and second rails being hollow, and also a rib located between the first and second rails, which prevents mutual influence between the first and second rails.

The first and second guides and rib are made of an opaque elastic material, which can be used as a thermoplastic elastomer.

The electricity meter also further comprises a starter switch. The starter switch comprises an internal starter and an external casing, the internal starter being connected to the external casing through the second part of the meter housing and having ribs separated by at least one gap, while the external casing has a fixing device which can be inserted at least into one clearance for interlocking.

The internal starter may be rotatable relative to the outer casing and comprise an upper surface with a flange having two lateral sides that are flexible, which allows the fixing fixation to be introduced into the clearance, the fixing fixation may have a bevel. The outer casing may further comprise a hexagonal portion as well as a plurality of cantilevered springs.

The foregoing and other characteristics and advantages of the invention will be more apparent from the following detailed description, given by way of example, not of a limiting nature and given with reference to the accompanying drawings.

Figure 1 schematically shows an exploded view of the layout of the counter in accordance with the present invention.

Figure 2 shows a front view of an exemplary meter (with the cover of the wiring removed (wire connection section)) in accordance with the present invention.

Figure 3 shows a top view of an exemplary circuit board assembly with current sensors and current conductors in accordance with the present invention.

Figure 4 shows a perspective side view of an exemplary circuit board assembly with current sensors and current conductors in accordance with the present invention.

5A, 5B, 5C, and 5D schematically show various views of a current conductor in accordance with the present invention.

6 is a perspective side view of an example assembly of a current sensor in accordance with the present invention.

7 shows a top view of an exemplary assembly of a current sensor with a circuit board and part of a terminal block in accordance with the present invention.

FIG. 8 is a perspective side view of an example assembly of a current sensor with a circuit board, an incomplete terminal block, and a contact spring in accordance with the present invention.

FIG. 9 shows a mirror image of FIG. 8 with a tear-out section of a circuit board.

10 is a perspective view of an example assembly of a current sensor with a contact spring in accordance with the present invention.

11 is a perspective view of an exemplary contact spring in accordance with the present invention.

12 is a perspective view of an example voltage disconnector in accordance with the present invention.

On Fig shows a side view with a breakout of Fig. 12.

On Fig schematically shows an exemplary data label, built into the packaging of the meter in accordance with the present invention.

On Fig shows a cross section of an exemplary data label, built into the packaging of the meter in accordance with the present invention.

On Fig shows a perspective view in front of an exemplary binoculars in accordance with the present invention.

17 is a rear perspective view of an exemplary binocular in accordance with the present invention.

On Fig schematically shows the binoculars and the associated circuit board Assembly in accordance with the present invention.

On Fig shows a perspective view of an exemplary switch starter (disassembled) in accordance with the present invention.

On Fig shows a perspective view of an exemplary internal starter switch starter in accordance with the present invention.

On Fig shows a perspective view from below of an exemplary internal starter in accordance with the present invention.

On Fig shows a perspective view of an exemplary outer casing of the switch starter in accordance with the present invention.

On Fig shows a perspective view of an exemplary switch starter (complete) in accordance with the present invention.

On Fig shows a rear view of one of the sections of the second part of the exemplary housing in accordance with the present invention.

Figure 1 shows a perspective view of an exemplary counter (disassembled) in accordance with the present invention. The meter has a first part of the housing 10 and a second part of the housing 20, which together form a housing for accommodating electrical components (for example, a circuit board assembly 30). The counter further comprises a wiring cover 40, which is attached to the second part of the housing 20. FIG. 2 shows a front view of an exemplary counter (with the wiring cover 40 removed).

The first part of the housing 10, which acts as the back or base of the meter, contains terminal block 12 elements that eliminate the need for a separate, fully equipped terminal block. The elements of the terminal block 12 form insulating voltage barriers between various metal assembly parts in the housing having different potentials. This function is provided in conjunction with the provided incomplete terminal block 50. The incomplete terminal block 50 has characteristics similar to terminal block 12, and when it engages with terminal block 12, voltage isolation between the serviced components is provided, with free access to internal metal components, which facilitates assembly. Thus, instead of using a separate component, known as a terminal block, in accordance with the present invention, it is proposed to use elements 12 molded in the lower portion of the first part of the housing 10 together with a multifunctional incomplete or upper terminal block 50, which allows for the desired insulation between the metal components . Such a construction simplifies assembly operations and allows simultaneously grab assembly of almost all components, while ensuring large voltage leakage distances between the components. In this case, the total number of components is reduced, since some of the metal parts can be combined.

The second part of the housing 20, which operates as the front or top of the meter, is predominantly made of a translucent material, which eliminates the need for a separate front cover. A window area 24 is provided for the digital indicator 31 of the circuit board assembly and the nameplate of the meter. The rest of the surface of the second part of the housing 20 can be textured (matted) so that the internal components of the counter are not visible from the outside. This eliminates the need to use a separate transparent material for the window connected to the shell 20, or a separate front cover, which reduces the number of components.

The circuit board assembly 30 contains electrical components and circuits necessary for the implementation of typical meter functions. Although the circuit board assembly 30 may include any electrical components and meter circuits that provide the desired functions, the elements described below are used in an example circuit board in accordance with the present invention.

The circuit board assembly 30 advantageously comprises toroidal current sensors 33. As shown in FIG. 3, the current sensors 33 are mounted at an angle of about 45 degrees relative to the circuit board 30. The toroidal current sensors 33 are mounted on the circuit board parallel to each other, but at an angle of about 45 degrees from the edge of the circuit board. Toroidal current sensors 33 can be pre-installed on the circuit board 30 by using any suitable technology, such as wave soldering. Despite the fact that any current sensors can be used, current sensors with current transformers having cores with low magnetic permeability (for example, with permeability of approximately less than 10000 and preferably in the range of approximately 1000 to 10000), which are nanocrystalline or amorphous, are mainly used. . As an example of preferred cores, amorphous cores manufactured by Vacuumschmeize (Germany) can be cited. An advantage of this configuration is that it allows current conductors 35 to pass through the center of each individual current sensor 33 after the current sensors 33 are mounted on the circuit board 30. This configuration is very compact and eliminates the need for wall mounting and microwire leads.

Current conductors 35 are passed through the center of each current sensor 33, as shown in FIGS. 3 and 4. Each current conductor 35 advantageously comprises a flat rather than a regular round wire, which increases the contact area. Flat conductors are received from the coil of a flat wire, and do not stamp and cut them, which reduces the waste of the wire to zero. FIGS. 5A, 5B, 5C, and 5D respectively show top, side, front, and perspective views of an exemplary current conductor. The angular bends of the wires allow you to create a very compact assembly while maintaining the desired gap between the conductors, which contributes to their flat configuration.

The ends of the current conductor 35 are inserted into the clamp 14 and clamped with the clamp screw 15, as shown in FIG. 6. The wire clips are connected by means of known fixing means to an incomplete terminal block 50, as shown in FIG. 7.

Toroidal current sensors 33 are mounted so that current conductors 35 can be passed through them during mechanical assembly. Thus, when connecting a current source, individual tests can be carried out until the parts of the housing 10 and 20 are finally connected to each other, since the current sensors 33 installed in close proximity to each other are compactly mounted on the circuit board and are electrically connected to it, as a result, a complete efficient counter is created. This allows you to calibrate and test the "counter" in the form of a circuit board assembly or a component of the finished product, instead of calibrating and testing the finished product after the final assembly of the housing. In this case, it is easier to detect defective circuits, and the final assembly can be done at the production site, where there is no equipment for testing and calibrating the meter.

On Fig shows a front perspective view of the circuit board 30 Assembly, connected to an incomplete terminal block 50 in accordance with the present invention, and Fig.9 shows a mirror image of Fig.8 with a section of the tear. The flexible contact spring 37 acts as a spring connection when compressed and provides a wireless and solder-free voltage connection between the current conductors 35 and the mounting plate 30, resulting in the connection of an incomplete terminal block 50 with the mounting plate 30. Figure 10 shows a side view of the interconnect circuit board 30 and current conductors.

11 is a perspective view of an exemplary contact spring in accordance with the present invention. The spring can be made of any material with appropriate mechanical properties and suitable electrical conductivity, such as stainless steel, phosphor bronze or Be-Cu. Each contact area of the spring 38 is bifurcated (39), which creates a backup contact point and further increases the reliability of the connection.

A spring 37, which is a leaf spring with an axial load, is used to provide a voltage connection between the input current phase and the circuit board assembly 30. In this mechanical connection, the corresponding contact pressure is maintained, which allows to maintain an inextricable electrical connection in all specified operating conditions of the product . The design of the spring eliminates the use of microwire leads and hinged mounting in the meter. This design greatly simplifies the physical assembly of the product. As shown in FIG. 9, the spring 37 is held onto the circuit board assembly 30 by means of elements 52 molded in the upper half of the terminal block 50. The assembly of these parts does not require the use of a special tool.

According to an exemplary embodiment of the present invention, the use of a voltage disconnector is provided, wherein the disconnector in accordance with the present invention replaces the remote wire means that are commonly used in known voltage disconnectors. Voltage disconnectors are used to isolate current and voltage sources during testing and calibration of certain types of test equipment. The voltage disconnector comprises a screw 61, a square nut 63 and a slot 64 in the mounting plate 30, as shown in FIGS. 10, 12 and 13. The mounting plate assembly 30 contains at least one tide of the voltage disconnector 66 to the side of the slot 64, and may contain several tides 66 on the sides of the slot 64. The screw 61 and the square nut 63 of the voltage disconnector are connected so that they can slip in the slot 64. At one end of the movement, the contacts of the tide 66 are closed with assembly 61/63, as a result of which the voltage circuit closes. In the other extreme position of movement of the assembly 61/63 in the slot 64, this assembly falls into the socket (pocket) 55 (which is mainly rectangular in shape) molded on the upper half of the terminal block 50. The socket 55 on the upper half of the terminal block 50 prevents the nut 63 from rotating and allows the assembly to lock in a closed or open position. Moreover, due to the specified disconnector, the voltage source can be isolated from the current source. To control the disconnector, a screwdriver is used, with which the thread is loosened by half a turn, while assembly 61/63 can slide freely in slot 64. FIG. 12 and 13 also show an auxiliary voltage connector 8.

Referring again to FIG. 1, it is shown that the wiring cover 40 has an inlet 42 that provides access to an internal power outlet 32 (located, for example, on a circuit board) that allows power to be supplied to the meter to read stored data, for example during power outages to the meter. A cover for the inlet 44 is provided, which may comprise, for example, a seal with an adhesive backing that adheres to the inlet 42 from above and does not allow dust and moisture to pass, and also allows obtaining information about unauthorized access. To provide access to the internal power outlet 32, pierce, tear or remove the cover 44, and then insert the external power plug, which is part of the external power unit (not shown), through the inlet 42, into the internal power socket 32. This allows you to feed power supply to the counter to ensure data exchange. After completion of this operation, the old inlet cover 44 (or a new cover 44) may be used to re-install on the electrical wiring cover to close the inlet 42.

The components of the counter during assembly are predominantly connected to each other by snapping in, for example, using protrusions and grooves formed on parts of the housing 10 and 20, thereby eliminating the need for screws. However, in accordance with the applicable requirements, a seal screw 22 may be provided to judge unauthorized access.

The use of the components in accordance with the present invention simplifies the assembly operations and allows you to simultaneously grab the assembly of almost all components, while providing more significant voltage leakage distances between the components. In this case, the total number of components is reduced, since some of the metal parts can be combined.

A limited number of parts were used in the layout of the meter, and the measuring electronics are installed on the main circuit board, which eliminates the use of microwire leads and mounted mounting in the meter. Due to this, the layout of the counter is mechanically simplified in comparison with the currently known counters, which leads to lower costs and increased reliability of the counter installed in the housing.

In accordance with one embodiment of the present invention, the second part of the housing 20 has a nameplate 26 with a serial number, as shown in FIG. The nameplate 26 is mainly made of plastic and contains data (for example, the serial number of the counter, technical specifications, etc.) that are directly applied to it, for example, by means of thermal printing. The nameplate can be of any desired size, for example, it can be rectangular and located behind the window 24. Advantageously, the nameplate 26 can be snapped into the retention element 25 formed on the second part of the housing 20 opposite the window 24, so that the data from the nameplate can be seen through window 24. The molded holding member 25 may comprise, for example, protrusions or grooves, and the second part of the housing 20 preferably has a curved surface, as shown in FIG. 15, which helps to hold the snap-in inserted m of the nameplate, and also increases the rigidity of the second part of the housing 20. Latching eliminates the need to use glue, which was used to attach the nameplates and nameplates in previously known counters. Thus, through the use of snapping, the laborious operation of installing the nameplate on the glue is eliminated.

To provide optical communication using binoculars 16, which is shown in figures 1, 16 and 17. The binoculars 16 provides an inextricable connection between the counter and the external device. The binoculars contains two guides 17 for light emitting diodes (LEDs) 18 mounted on the circuit board 30, as shown in Fig. 18, which are separated by a rib 18. Preferably, the binoculars 16 are formed from an opaque elastic material such as a thermoplastic elastomer, but this is not mandatory and other suitable material may be used. The binoculars 16 provide full contact between the second part of the housing 20 and the circuit board assembly 30, while ensuring complete shielding of the surrounding light. The rib 19 eliminates the mutual influence of the LED 18. Since the binoculars 16 are molded from an elastic material, due to its flexibility it can compensate for the tolerances of parts and provide a good press fit. The elastic material also acts as a shock absorber. It should be borne in mind that the use of binoculars 16 is more preferable than the use of two separate optical fibers, which were previously used to transmit light signals, since the attenuation of the signal in the air guides 17 of the binoculars is much less than in the solid material of ordinary optical fibers.

In accordance with one embodiment of the present invention, the counter comprises a starter switch. FIG. 19 is a perspective view of an exemplary starter switch 100 (disassembled), and FIG. 20 shows the starter switch 100 as an assembly. The switch starter 100 can be used to actuate a variety of hidden switches of any kind. The switch 100 includes an internal starter 110 and an external casing 120, which is installed on the second part of the housing 20.

FIGS. 20 and 21 are a top and bottom view, respectively, of an exemplary internal starter 110. The upper clearance 114 between the ribs 115 of the internal starter 110 corresponds to a fixing mustache 126 inside the outer case 120 (FIG. 22). When the internal starter 110 is inserted from the rear into the second part of the housing 20 and when the external casing 120 is inserted from the front into the second part of the housing 20, the mustache 126 is fixed in the gap 114. In this case, the internal starter 110 and the external casing 120 form a single unit and can together move up downward, however, the inner starter 110 can rotate freely in the outer casing 120. Both sides of the flange 117, which forms the upper surface of the inner starter 110, can bend down and pass the locking mechanism 126. FIG. 22 shows that the chamfer 128 on the base ii mustache fixation 126 contributes to its commissioning and prevents hair loss. The hexagonal portion 129 does not allow the outer casing 120 to rotate inside the second part of the housing 20. This also limits the downward movement of the starter switch inside the second part of the housing 20.

At the bottom of the outer casing 120, a spring 130 is cantilevered, which returns the switch to its upper position. The switch of the starter 100 is introduced into the second part of the housing 20 through the hole 26. On Fig shows a rear view of one of the sections of the second part of the housing 20. The boss 28, which is inserted into the hole 26 behind the second part of the housing 20, limits the rotation of the internal starter 110 within an angle 90 degrees to either side. Apertures 122 are provided in the outer casing 120, and an aperture 113 in the inner starter 110, which allows the starter switch to be sealed in a position in which it will not rotate. This allows you to isolate one of the functions when it is possible to perform another function. At the bottom of the internal starter 110, two substantially flat flanges 116 are provided which predominantly (but not necessarily) extend at an angle of 90 degrees to each other. These flanges 116 cooperate with tactile switches that are mounted on a circuit board. Using compression technology can reduce material consumption and simplify the formation of these parts. The plugs 105 obtained by molding are used to prevent the buttons from turning without obstacles to actuate one of the switches. Slit 118 on the extension of the upper part of the internal starter 110 allows you to rotate using a coin or screwdriver.

Thus, the specified switch starter can carry out two functions with one button, that is, to operate two switches. First, one switch is actuated, after which the starter switch is rotated 90 degrees and the second switch is actuated. As already described, the starter switch is built into the casing and drives the switches or tides on the assembly circuit board 30 lying below it.

Despite the fact that the preferred embodiment of the invention has been described, it is quite clear that it will be modified and supplemented by those skilled in the art, which do not, however, fall outside the scope of the claims.

Claims (33)

1. An electric meter including a first housing part comprising a plurality of terminal block elements, a mounting plate assembly for performing measurement functions, an incomplete terminal block, and a second housing part, the first and second housing parts being configured to pair each other with the other for forming the meter body, wherein the circuit board assembly and the incomplete terminal block are at least partially located inside the meter body, characterized in that the circuit board contains a toroidal current sensors, and the counter additionally contains a contact spring that provides electrical connection of the circuit board assembly with an incomplete terminal block. 2. The electricity meter according to claim 1, characterized in that it further comprises a wiring cover connected to the second part of the housing. 3. The electricity meter according to claim 1, characterized in that the second part of the housing is made of translucent material. 4. The electricity meter according to claim 1, characterized in that the second part of the housing has a window. 5. The electricity meter according to claim 1, characterized in that the toroidal current sensors are installed mainly parallel to each other and at an angle of about 45 degrees relative to the edge of the circuit board. 6. The electricity meter according to claim 1, characterized in that it further comprises a plurality of current conductors, each of which passes through a corresponding current sensor. 7. The electricity meter according to claim 6, characterized in that each of the current conductors is made of a flat wire, the ends of which are fixed in an incomplete terminal block. 8. The electricity meter according to claim 1, characterized in that the contact spring has forked ends. 9. The electricity meter according to claim 1, characterized in that the circuit board assembly further comprises a voltage disconnector. 10. The electricity meter according to claim 9, characterized in that the voltage disconnector comprises a screw and a square nut, wherein the circuit board assembly further has a slot for the voltage disconnector and at least one tide of the voltage disconnector on one side of said slot. 11. The electricity meter according to claim 10, characterized in that the incomplete terminal block has a socket for guiding the voltage disconnector. 12. The electricity meter according to claim 1, characterized in that it further comprises a data plate attached to the second part of the shell. 13. The electricity meter according to claim 1, characterized in that it further comprises binoculars mounted between the second part of the shell and the circuit board assembly. 14. The electricity meter according to item 13, wherein the binoculars has two guides separated by an edge. 15. The electricity meter according to claim 1, characterized in that it further comprises a switch starter. 16. The electricity meter according to clause 15, wherein the starter switch contains an internal starter and an outer casing, and the inner starter is connected to the outer casing through the second part of the housing. 17. The electricity meter according to clause 16, characterized in that the internal starter has ribs separated by at least one gap, and the outer casing has a fixing device, which is made with the possibility of its introduction into at least one gap for interlocking. 18. A voltage disconnector for isolating current and voltage sources from each other in an electric meter having a circuit board assembly, characterized in that it includes a screw, a square nut, made with the possibility of screwing in and out of the specified screw, and the screw and nut form a screw / nut assembly, a slot on the circuit board assembly in which the screw / nut assembly slides, as well as a surge disconnector provided on at least one side of said slot. 19. The voltage disconnector according to claim 18, characterized in that at one of the ends of said slot, the surge of the voltage disconnector forms a short circuit with the screw / nut assembly. 20. The voltage disconnector according to claim 18, characterized in that at the other end of the slot, the screw / nut assembly enters the socket inside the electricity meter. 21. The voltage disconnector according to claim 20, characterized in that said socket prevents rotation of the square nut of the voltage disconnector. 22. Binoculars for an electricity meter, including a first guide and a second guide parallel to the first guide, the first and second guides being hollow, characterized in that there is a rib between the first and second guides that prevents mutual influence between the first and second guides. 23. The binoculars of claim 22, wherein the first and second guides and the rib are made of an opaque elastic material. 24. The binoculars according to item 23, wherein the thermoplastic elastomer is used as an opaque elastic material. 25. A starter switch, including an internal starter, which contains ribs separated by at least one gap, characterized in that it has an external casing, which contains a locking device configured to mate with at least one of the specified gap to ensure deadlock. 26. The starter switch of claim 25, wherein the internal starter is rotatable relative to the outer casing. 27. The starter switch according to claim 25, wherein the inner starter comprises an upper surface with a flange having two sides. 28. The starter switch according to item 27, wherein the two sides of the flange are flexible, which allows you to enter into the clearance of the fixation. 29. The starter switch of claim 25, wherein the fixation mustache has a bevel. 30. The starter switch of claim 25, wherein the outer casing further comprises a hexagonal portion. 31. The starter switch according to claim 25, wherein the outer casing further comprises fixed springs by the console. 32. The starter switch of claim 25, wherein the internal starter further comprises mainly flat flanges. 33. The starter switch according to claim 32, wherein said flat flanges are offset from each other by an angle of about 90 degrees.

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