KR101284645B1 - The distribution system with smart power searching and inverse time switching function - Google Patents

Abstract

PURPOSE: A distribution system with smart power metering and inverse time power switching functions is provided to facilitate the management of electric charges by sensing power consumption in real time. CONSTITUTION: A branch adaptor (200) is composed of a connector and a load data processing unit. An alarm unit (300) receives current power consumption and load data. A terminal (400) receives the power consumption and current. A bolt passes through a hole of a contact. A flat spring delivers the power of the bolt to the contact. [Reference numerals] (300) Alarm unit; (300c) Time delay determination unit; (300d) Acceleration sensor; (AA) Power side; (BB) VC detector; (CC) Voltage; (DD) Current; (EE) Time; (FF) Acceleration; (GG) Power supply unit; (HH) Load side

Description

Distribution system with smart power metering and inverse time switching function {The distribution system with smart power searching and inverse time switching function}

The present invention sets the current peak power using a smart phone by wireless communication, and smart power meter reading function to control the load power by operating the circuit breaker of the distribution panel based on the set peak power, and the case of earthquake or building shaking severely A distribution system having an inverse time switching function for controlling a load power by operating a circuit breaker of a distribution panel based on time operation characteristics.

The present invention relates to a smart grid type distribution system, and more specifically, a power user using a power such as a home or a factory office sets a peak power, and sets the peak power by checking the current power through a real-time notification service. It is related to a smart grid type distribution board that is configured to cut off the load power when approaching, so that energy use can be efficiently managed.

If you look at the electricity bill currently charged by KEPCO, the electricity charge consists of a basic charge and a power charge. There are currently 170,000 high-voltage customers nationwide, and the base charge for high-voltage customers is charged based on peak power. In more detail, the base rate is calculated by multiplying the rate applied power and the unit price of the base rate. The method of calculating the rate applied power is calculated by calculating a peak power value with the highest power consumption of the year.

In other words, KEPCO's electricity rate system sets the base rate based on the peak value of the highest power consumption of the year, and sets the usage rate based on the electricity used monthly. These base rates must be paid monthly, even if no electricity is used.

In particular, when looking at the current state of electricity rates, the proportion of the basic rate is 20-44%, and the electricity rate is charged as the base rate based on the peak power value of the power used by the user. The base rate can be reduced, and even a 30% reduction in base rate can save 300,000 ~ 500,000 won per month.

However, in general, the user's electric charges can be notified of monthly usage amount, peak power value, and monthly electricity charges by being notified of the monthly bill, and in fact, how much power the user uses in real time. In addition, there is a problem in that the user's use of peak power, which is a standard for calculating the base rate, is barely unknown, and the electric charge is unprotected.

In addition, even if the current user's current power consumption is recognized, if the power usage state has already exceeded the peak power, even if the user's use state is recognized, the increase in the base rate due to the peak power increase It cannot be avoided.

Also, in various building electrical distribution systems, power is separated and cut off through various breakers such as a main breaker, a branch breaker, and an earth leakage breaker. The main breaker and the sub-breaker branch the power through an energization bus.

To this end, a branch adapter is used between the circuit breaker or the earth leakage breaker and the energizing mos so that power of each phase is supplied to the load through the breaker.

1 is a block diagram illustrating a method of mounting a branch adapter to a conventional circuit breaker. Referring to FIG. 5, the branch adapter 20 is connected to the circuit breaker 10 and the connector 21, and the connector 21 is in contact with the conducting moss R, S, T, N, and 22 to supply power to the power supply side. It plays a role of delivering to the load side.

In addition, there is an upper terminal 24, and when the bolt 25 is tightened, the upper terminal 24 comes down to tighten the energizing bus 22 and the connector 21.

However, since the upper terminal 24 of the branch adapter 20 is tightened only with the bolt 25, shaking occurs when the energizing bus 22 is inserted in such a structure, and the usage period of the branch adapter 20 becomes long. It is pointed out that the more the phenomenon that the conduction bus 22 shakes is worse.

In addition, in order to tighten the bolt 25, the hassle of forming a separate thread on the connector 21 and the spring 23 providing elasticity to the bolt are in direct contact with the bolt, so that the thread of the bolt 25 If the spring 23 is sandwiched in the gap occurs, the coupling is not easy and there is a problem that causes the wear of the spring.

In addition, as shown, the upper terminal 24 in contact with the energizing bus 22 has a structure parallel to the energizing bus, in which the current flows in the same direction when instantaneous current or large current flows. 22) and the upper terminal 24 has a problem that the repulsive force acts to fall apart and eventually the function of the circuit breaker 10 does not work properly.

In addition, when an overcurrent occurs in an earthquake or a severe shaking of the building, the power supply is cut off as the circuit breaker trips in the distribution panel.

However, if an overcurrent occurs due to an earthquake or the like, if the overcurrent exceeds the set value due to the characteristics of the circuit breaker, the circuit breaker will trip regardless of the magnitude of the overcurrent, so the power supply of the lighting facility such as an elevator or emergency power supply that is actually needed for evacuation. It also has a problem that can be blocked together with more confusion in evacuation.

In order to solve the above problems, the present invention provides a power distribution system having a smart power meter reading function configured to allow the user to detect and manage the current power currently being used in a building or home based on the peak power at all times. The purpose.

In addition, an object of the present invention is to provide a power distribution system equipped with a branch adapter configured to maintain the function of the circuit breaker is mounted without a stable shaking, the energizing bus connected to the branch adapter constituting the distribution system, even when a large current occurs. do.

In addition, an object of the present invention is to provide a power distribution system in which a delay time required for evacuation time is taken into consideration when an overcurrent occurs while an earthquake occurs in a building or the like.

In order to achieve the above object, the present invention is a distribution system for distributing power on the power supply side to the load side through a circuit breaker, connected to the power supply side and a plurality of power supply buses, and the power supply bus to supply power to the load side A branch adapter having a connector for connecting the circuit breaker and configured to receive load data through the connector to calculate a current power and perform digital processing; The load data processing unit of the branch adapter receives the digitally processed current power and load data, and is used for wiring when the current current is greater than or equal to the set CPU set value or when the current power is greater than or equal to 95% of the CPU's set peak power. A reminder unit configured to transmit a trip signal to the trip relay of the breaker to cut off power; And a terminal configured to set an overcurrent and peak power in the alert unit and receive current and current power through the alert unit, wherein the distribution system has an inverse time characteristic, a smart power meter reading, and a power switching function. To present.

The reminder unit includes an acceleration sensor for detecting a shake of a building and a delay delay determination unit for detecting an earthquake by judging the strength of a signal of the acceleration sensor based on a set value. When the above signal is detected, the CPU is configured to transmit a control signal to the CPU such that an overcurrent is detected and a delay time is included in the trip signal transmitted to the trip relay of the circuit breaker.

The control signal transmitted from the delay delay determination unit to the CPU is set to an inverse time characteristic such that a delay time is shorter in the trip signal transmitted from the CPU to the trip relay as the strength of the signal determined by the delay delay determination unit increases. .

The present invention has a hole formed in each conducting bus to maintain a gap between the plurality of conducting buses to prevent a short, and a groove is formed in the projection and the bottom which is inserted into the hole formed in the conducting bus and protrudes the projection and By forming a ceramic fixing seat including a binding support, between the ceramic fixing seat and the projection of the ceramic fixing seat inserted into the conductive busbar is coupled to the groove of the support of the other ceramic fixing seat to form a laminated structure, Between the bus bar is configured to form a gap as wide as the width of the support.

The branch adapter may include: a contactor having both ends in contact with the connector and having a hole formed at an upper center portion thereof; A bolt penetrating the hole of the contactor; A leaf spring formed between the contact and the bolt so that the bolt penetrates and transfers the force of the bolt to the contact; A pop nut mounted on a hole formed in the connector, the upper nut having a wider width than a lower thread formed with a screw thread coupled to the bolt; A spring supported on the upper layer of the pop nut to provide an elastic force to the bolt; And a bush positioned between the spring and the bolt to be supported by the upper layer of the pop nut to prevent the screw thread of the bolt from being inserted into the gap of the spring.

A support groove is formed at one end of the contactor, and a hole is formed in the connector portion below the support groove of the contactor, and a stopper configured to be pressed into the hole while contacting the support groove is configured. The stopper is configured to prevent the contact from being pushed back when inserted into the other end.

The other end of the contact point into which the energizing busbar is inserted is configured to be in contact with the energizing busbar in a bent shape.

The present invention can achieve the following effects by the smart power meter reading and the distribution system having the power switching function of the inverse time characteristic.

First, the user can always detect the current power currently being used in a building or home through the reminder unit of the present invention in real time, and if the detected power value is more than the peak power value set in the CPU, the circuit breaker It is possible to manage the rise of the electricity bill through the power management by cutting off.

Second, through the configuration of the stopper and the contact grooves of the contactor configured in the branch adapter of the present invention, the contactor is stably fixed to the connector, so that an energizing bus connected to the contactor of the branch adapter is stably mounted without shaking.

Third, through the bushing configured in the branch adapter of the present invention can solve the problem that the thread of the bolt is fitted to the spring, there is an effect that can be screwed with the bolt without forming a separate thread in the connector through the pop-nut.

Fourthly, the branch adapter of the present invention has a curved shape of the contactor in contact with the energizing bus, so that even when a large current occurs, the contactor and the energizing bus are attracted to each other so that the function of the circuit breaker is maintained. It is effective.

Fifthly, a plurality of ceramic busbars of the present invention are connected to the ceramic fixing seats in a stacked manner to maintain the gap between the busbars, thereby preventing shorts due to contact between the busbars.

Sixth, when the overcurrent occurs according to the earthquake of the present invention, through the anti-time characteristic of the delay delay determination unit, the greater the intensity of the earthquake, the shorter the delay time is set in the trip signal transmitted from the circuit breaker, the shorter the time-limit characteristic is cut off. The distribution system with the switching function has the effect of securing the power required for the evacuation time while considering the power off time according to the earthquake degree.

1 is a configuration diagram showing a method of mounting a branch adapter in a conventional circuit breaker.
2 and 3 is a configuration diagram of a power distribution system having a smart power meter reading and a power switching function of the inverse time characteristic as an embodiment of the present invention.
4 is a configuration diagram of a branch adapter and a circuit breaker according to an embodiment of the present invention.
5 is an exploded view showing the fastening state inside the branch adapter according to an embodiment of the present invention.
6 and 7 is a configuration diagram showing a short-circuit state between the energizing bus bus is mounted on the branch adapter according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings for a power distribution system having a smart power meter reading and the power switching function of the inverse time characteristic.

2 and 3 is a configuration diagram of a power distribution system having a smart power meter reading and a power switching function of the inverse time characteristic as an embodiment of the present invention.

Referring to the bar, the distribution system of the present invention for distributing the power of the power supply side to the load side through the circuit breaker is connected to the circuit breaker 100 and the power supply side and a plurality of power supply buses, and to supply power to the load side A branch adapter 200 having a connector for connecting a circuit breaker is configured.

The branch adapter 200 receives load data such as current, voltage, and phase angle from a power source flowing through the connector through a sensor such as CT (Purrent Transformer) or PT (Potential Transformer) to calculate current power and digitally. The load data processing unit 200n for processing is configured.

In other words, the load data processing unit 200n detects the voltage (V) / current (I) and the phase angle (φ) supplied to the load, calculates the effective power (VI cosφ) and the power factor value (cosφ), and converts it to AD. It is configured to calculate the peak power by converting, and the basic data necessary for the calculation is configured to be programmed and stored in advance.

In addition, the branch system of the present invention is configured with the alert unit 300, the alert unit is configured with a CPU (300a) to receive the current power and load data digitally processed by the load data processing unit 200n of the branch adapter. do.

The CPU 300a operates the relay driver 300b when the current current flowing to the load side from the load data received through the load data processing unit 200n is greater than or equal to the set CPU set value so that the trip relay 100a of the circuit breaker is operated. It is configured to cut off the power by transmitting a trip signal.

In addition, the CPU 300a operates the relay driver 300b when the current power is greater than or equal to 95% of the peak power set by the CPU in the load data received through the load data processor 200n to trip the relay of the circuit breaker. It is configured to cut off the power by transmitting a trip signal to 100a).

That is, when the current power on the load side approaches the peak power, the load power is cut off in advance. In the present invention, the load power is set to 95% of the peak power, but this value may be modified to some extent by those skilled in the art. However, it will be important to shut off when approaching peak power.

In addition, the branch system of the present invention comprises a terminal 400 for setting the over-current and peak power as a reference value that is a reference value to the reminder unit 300, the terminal at the same time the current and current through the reminder unit 230 Power is received. The terminal is a device using a wireless communication, means a smart phone or other wireless communication device, the alert unit 230 or the terminal 400 includes a wireless communication device that can use a wireless network, such as data network or wifi do.

Through the reminder unit 300 and the terminal 400 of the present invention, the user can always sense the current power currently being used in a building or at home in real time, and the detected power value is set at the CPU 300a. In the case of more than the power value, while preventing the rise of the base rate through power management to block the circuit breaker 100, there is an effect that can block the rise of the electricity rate.

The alert unit 300 is configured with an acceleration sensor 300d for detecting the shaking of the building, and further, the delay delay determination unit for detecting an earthquake by determining the strength of the signal of the acceleration sensor based on a set value thereof. 300c) is configured.

When an overcurrent is detected in the CPU 300a while an earthquake or shaking occurs in the building, the CPU 300a transmits a trip signal to the trip relay 100a of the circuit breaker 100.

However, when a trip signal is transmitted to the trip relay 100a of the circuit breaker 100 and all the power in the building is cut off immediately, the power of lighting facilities such as an elevator or emergency power required for evacuation in the building is also cut off together. The evacuation could be even more disruptive.

Therefore, when a signal equal to or greater than a set value is detected in the signal transmitted from the acceleration sensor 300d in the delay delay determining unit 300c of the present invention, the trip relay 100a of the circuit breaker 100 in the CPU 300a is detected. The control signal is transmitted to the CPU 300a so that the delay time is included in the trip signal transmitted to the CPU 300a.

In addition, the control signal transmitted from the delay determination unit 300c to the CPU 300a is transmitted from the CPU 300a to the trip relay 100a as the intensity of the signal determined by the delay determination unit 300c increases. It is configured to set the inverse time characteristic so that the delay time is short for the trip signal.

In other words, when the overcurrent occurs due to an earthquake, the time delay characteristic of the delay delay determining unit 300c increases the strength of the earthquake, so that the delay time is shortened in the trip signal transmitted from the circuit breaker 100 to cut off the power. Through the distribution system of the present invention having a switching function of the earthquake, as the degree of earthquake increases, it is possible to secure the power required for evacuation time in the building while setting the power cut-off time short.

4 is a configuration diagram of a branch adapter and a circuit breaker according to an exemplary embodiment of the present invention, and FIG. 5 is an exploded view illustrating a fastening state inside the branch adapter according to the exemplary embodiment of the present invention.

Referring to FIG. 5, a contact adapter 200c having both ends of the branch adapter 200 contacting the connector 200j and having a hole 200c-a formed at the upper center portion thereof is formed.

The bolt 200a penetrates through the hole 200c-a of the contactor 200c, and a hole is formed between the contactor 200c and the bolt 200a so that the bolt 200a penetrates and the force of the bolt. The plate spring (200b) for crimping the connector 200j is transmitted to the contact is configured.

In addition, the fastening portion of the branch adapter has a pop nut (200g) is mounted while being mounted in the hole (200j-a) formed in the connector to be fastened to the thread of the bolt.

The pop nut 200g has a groove formed therein, and is configured such that an upper layer portion 200g-a of the formed groove has a wider width than a lower layer portion 200g-b in which a screw threaded to the bolt is formed.

The illustrated spring 200f is supported by the upper layer portion 200g-a of the popnut 200g to provide elastic force to the bolt.

In addition, it is located between the spring (200f) and the bolt (200a) to be supported by the upper layer portion (200g-a) of the pop nut (200g) to prevent the thread of the bolt is fitted into the gap of the spring (200f). The bush 200d is configured.

The present invention can solve the problem that the thread of the bolt (200a) is fitted to the spring (200f) through the bushing (200d) configured in the branch adapter, unlike the conventional branch adapter, to the connector 200j through the pop nut (200g) There is an effect to be screwed with the bolt (200a) even without forming a separate thread.

In addition, a support groove 200c-b is formed at one end of the contactor 200c of the present invention, and a hole 200j is formed at a portion of the connector 200j contacting the support groove below the support groove 200c-b of the contactor. -b) is formed, and a stopper 200i supporting the contactor 200c is formed while being in contact with the support groove 200c-b while being pressed into the hole 200j-b.

In this case, the stopper 200i prevents the contactor 200c from being pushed back when the conduction bus 200h is inserted into the other end of the contactor 200c.

The contactor 200c is stably fixed to the connector 200j through the stopper 200i configured in the branch adapter of the present invention, so that the conduction bus 200h connected to the contact of the branch adapter 200h is stably mounted without shaking. have.

In addition, the other end of the contact member 200c into which the conduction bus 200h of the branch adapter of the present invention is inserted is configured to be in contact with the conduction bus 200h in a bent shape as shown.

As shown in FIG. 4, the shape of the contactor 200c at the site of contact with the conduction bus 200h is bent to form a bent shape, so that even when a large current occurs due to a short circuit, the current of the contactor 200c and the conduction bus 200h is maintained. In the opposite direction, the attraction force is applied to each other and maintained to be attached to each other. In the conventional case, the repulsive force is applied to solve the problem that the function of the circuit breaker was not properly maintained.

6 and 7 are configuration diagrams showing a short prevention state between energizing bus bars mounted to the branch adapter according to the embodiment of the present invention.

Referring to FIG. 5, in order to prevent a short due to contact between the energizing buses 200h mounted on the branch adapters, the gaps between the plurality of energizing buses 200h must be maintained.

To this end, in the present invention, a hole is formed in each energizing bus 200h, and the ceramic fixing seat 200l is mounted in the hole in a stacked manner to maintain a gap between the energizing buses 200h.

The ceramic fixing seat 200l includes a protrusion 200l-a that is inserted into and protrudes into a hole formed in the energizing bus line 200h and a support portion 200l-b that is connected to the protrusion while a groove is formed at the bottom thereof.

As shown in the figure, between the ceramic fixing seat 200l and the protrusion 200l-a of the ceramic fixing seat inserted into the conduction bus 200h are coupled to the groove of the support 200l-b of the other ceramic fixing seat. The laminated structure is formed.

As a result, the gap between the energizing busbars is formed so as to form a gap corresponding to the width of the supporting portions 200l-b of the ceramic fixing seat 200l.

In addition, in order to reinforce the bonding force between the ceramic fixing seat (200l), the bolt (200k) is formed in the center of the ceramic fixing seat (200l) so that the bolt (200k) penetrates all the ceramic fixing seat mounted on the energizing busbars It can be configured to penetrate.

In addition, the ceramic fixing seat 200m positioned on the R may be formed of only the supporting portions 200l-b of the ceramic fixing seat 200l.

As a result, the ceramic fixing seat 200l is connected to each other between the plurality of energizing buses 200h of the present invention so as to maintain a gap between the energizing buses 200h to prevent shorts due to contact between the energizing buses 200h. There is.

Preferred embodiments of the present invention described above are disclosed for purposes of illustration, and those skilled in the art will be able to make various modifications, changes and additions within the spirit and scope of the present invention. Additions should be considered to be within the scope of the following claims.

100: circuit breaker 100a; Trip relay
200: branch adapter 200a: bolt
200b: leaf spring 200c: contactor
200d: bush 200f: spring
200g: Popnut 200j: Connector
200k: 200l bolt, 200m: ceramic seat
200n: load data processing unit 300: alert unit
300a: CPU 300b: relay driver
300c: delay delay determination part 300d: acceleration sensor
400: terminal

Claims (7)

In a distribution system for distributing power on the power supply side to the load side through a circuit breaker,
The connector is connected to the power supply side and a plurality of power supply buses, and a connector is connected to the power supply bus and the circuit breaker to supply power to the load side. The load data is input through the connector to calculate the current power and perform digital processing. A branch adapter configured with a load data processor;
A notifier unit for receiving the currently used power and load data digitally processed by the load data processor of the branch adapter; And
And a terminal receiving current and current power through the alert unit.
The branch adapter,
A contactor in contact with both ends of the connector and having a hole formed at an upper center portion thereof;
A bolt penetrating the hole of the contactor;
A leaf spring formed between the contact and the bolt so that the bolt penetrates and transfers the force of the bolt to the contact;
A pop nut mounted on a hole formed in the connector, the upper nut having a wider width than a lower thread formed with a screw thread coupled to the bolt;
A spring supported on the upper layer of the pop nut to provide an elastic force to the bolt; And
Inverse time characteristic and smart power meter reading, characterized in that it comprises a; bush between the spring and the bolt is supported on the upper layer of the pop nut and prevent the screw thread of the bolt from being inserted into the gap of the spring; Distribution system with power switching function. The method of claim 1,
A support groove is formed at one end of the contactor, and a hole is formed at the connector portion below the support groove of the contactor.
The stopper is configured to be pressed into the hole while contacting the support groove,
And the stopper is configured to prevent the contactor from being pushed back when the energizing bus is inserted into the other end of the contactor. The method of claim 2,
The other end portion of the contact is inserted into the power bus is bent shape distribution system having an inverse time characteristic and smart power meter reading and power switching function, characterized in that configured to be in contact with the power bus. In a distribution system for distributing power on the power supply side to the load side through a circuit breaker,
The connector is connected to the power supply side and a plurality of power supply buses, and a connector is connected to the power supply bus and the circuit breaker to supply power to the load side. The load data is input through the connector to calculate the current power and perform digital processing. A branch adapter configured with a load data processor;
A notifier unit for receiving the currently used power and load data digitally processed by the load data processor of the branch adapter; And
And a terminal receiving current and current power through the alert unit.
Holes are formed in each energizing busbar to prevent a short circuit by maintaining gaps between the plurality of busbars,
By forming a ceramic fixing seat including a support portion coupled to the protrusion while a groove is formed at the bottom and is inserted into and protrudes into the hole formed in the energizing busbar,
Between the ceramic fixing seat to form a laminated structure while the protrusion of the ceramic fixing seat inserted into the energizing busbar is coupled to the groove of the support of the other ceramic fixing seat,
The power distribution system having an inverse time characteristic, a smart power meter reading, and a power switching function, the gap between the energizing buses is configured to form a gap equal to the width of the support part. delete delete delete

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