KR200330177Y1 - terminal mechanism for electricity meter - Google Patents

Abstract

The present invention relates to a terminal structure for a wattmeter to prevent conduction, and includes a test terminal for testing a wattmeter in a terminal block without exposure to the outside and a fixing means for fixing an electric wire. In order to solve the inconvenience of installing terminal cover on the terminal block and sealing it, it is composed of the coupling structure so that the fixing of voltage terminal, current terminal and wire can be detached. It relates to a terminal structure.

Description

Terminal structure for electricity meter {terminal mechanism for electricity meter}

The present invention relates to a terminal structure for a wattmeter, and more particularly, a test voltage terminal necessary for a test of a wattmeter in order to prevent a conduction and a safety accident is built in a terminal block without exposing the outside to the inside of the terminal block. In order to solve the inconvenience of having to install the terminal cover on the terminal block and make sure to seal the terminal block, the power meter is composed of a coupling structure to detach the voltage terminal, the current terminal, and the fixing of the wire. It relates to a terminal structure.

In general, the electricity industry has developed such a huge amount of electricity for decades so that the electricity meter can handle electricity transactions of 16.5 trillion won (as of 2002) in Korea alone.

However, despite these vast developments, some technologies in the electricity meter have not escaped the framework of the past, and one of them is anti-challenge technology.

In recent years, there has been a great deal of news about the use of meter reading by the media, and according to the arrested experts, there is actually a class that specializes in challenge.

However, the realistic aspect that makes it difficult to manage a large number of structurally challenging electricity meters has been on the standpoint of the challenge, and despite the above-mentioned problems, the current electricity meters, which have had structural contradictions for decades, The use was due to the inability to eliminate the voltage test link used for instrument testing and recalibration.

In addition, the commonly used wattmeter used screws to separate and couple the test voltage terminals for precision test, and screws were used to fix the wires. Had.

For this reason, KEPCO encourages efforts to develop equipment such as lead seals and PVC seals, rotary seals, and thorough sealing management to prevent enormous power loss due to challenges. Have not been harvested.

In addition, the terminal cover has been installed and sealed as a way of supplementing these points, but it requires a lot of improvement in order to keep up with the trend of the era of pursuing low cost because it requires a lot of manpower and cost in accordance with the establishment and follow-up of the instrument. It has been a problem to do.

On the other hand, a conventional power meter terminal block having the above-described problem will be described with reference to the accompanying drawings.

1 is a view showing a conventional conventional three-phase four-wire meter block terminal block, Figure 2 is a view showing the electrical connection state of the wattmeter according to Figure 1, as shown in the accompanying drawings The conventional electricity meter (2) is installed in each user's home, and can connect the input power R phase, S phase, T phase, and neutral wire (N) to the terminal block 100 at the bottom to measure the electricity usage. The current terminals 1S, 2S, 3S and 0S on the input side are constituted.

That is, each phase is coupled correspondingly to the current terminal 110. The R-phase current signal is connected to the R line of the external input side wire 4 by the two terminal screws 112 provided at the current terminal 110. By press-fitting into the current terminal 110, the current signal supplied from the external wire 4 is energized to the current terminal 110.

In addition, the test voltage terminal 120 coupled to the current terminal 110 is fixedly coupled by a pair of fixing screws 122 provided on one side of the current terminal 110 to be supplied from an external wire. The voltage signal is energized by the test voltage terminal 120.

On the other hand, the current signal and the voltage signal of the S and T phases are also coupled corresponding to the respective current terminals to maintain the same energized state as the current and voltage signals of the R phase.

In addition, in the case of the neutral wire (N) for grounding is coupled to the N line of the external input side and the current terminal (OS) provided in the terminal block using a screw.

On the other hand, the output terminals 1L, 2L, 3L and 0L can be connected to the customer's load. Similar to the above input side, these wires are also provided with two terminal screws 112 for each terminal, and are connected to the load side wires 6 using these screws.

Thus, after the connection and installation of the electricity meter 2 is completed, the terminal cover 114 may be covered, and then the sealing screw 115 may be fastened to prevent an electric shock accident caused by a person other than the person in contact with the terminal being a charging part.

In addition, after the sealing screw 115 is fastened, the sealing line 116 is inserted into a hole in the head of the sealing screw 115, and the lead 117 is sealed to use, and the power meter 2 is used. Will be achieved.

Hereinafter, the operation of the electricity meter 2 made as described above will be described.

FIG. 2 is an electrical connection diagram of FIG. 1, and the supply side R, S and T lines are connected to the current terminals 1S, 2S and 3S terminals of the electricity meter 2, respectively.

The neutral wire N on the supply side is connected to the 0S terminal of the electricity meter 2.

In addition, 1L, 2L, 3L and 0L terminals of the electricity meter 2 connects the corresponding wire 6 on the load side, respectively, and since it is a three-phase electricity meter, the power calculation is the sum of the power amounts of each of three phases as shown in the following formula.

3 phase total power = R phase + S phase + T phase

= Pr + Ps + Pt [kwh]

First, in case of the R phase, the current signal input from the R side of the power supply is supplied in series to the load. The current terminal 110 is connected to the load side terminal via the current line 110a and the current circuit 110b inside the electricity meter 2 via the current terminal 110. Flows through the load. The voltage signal is supplied to the voltage circuit 120b through the R-phase test voltage terminal 120 through the current terminal 110 and through the voltage signal line 120a.

Based on the values sensed by the current circuit 110b and the voltage circuit 120b of R phase, the value of the power of R phase is calculated as follows.

Power of R phase = Vr * Ir * cos Φ

Secondly, in the case of the S phase, the current signal input from the S phase of the power supply side is supplied in series to the load, and is loaded through the load side terminal via the current line 110a and the current circuit 110b inside the wattmeter through the current terminal 110. Flows into. The voltage signal is supplied to the voltage circuit 120b via the S-phase test voltage terminal through the current terminal 110 and through the S-phase voltage terminal 120 and the voltage signal line 120a.

Based on the values detected by the current circuit 110b and the voltage circuit 120b of the S-phase, the value of the power of the S-phase is calculated as in the following formula.

Power of S phase = Vs * Is * cos Φ

Finally, in the case of the T phase, the current signal input from the T side of the power supply is supplied in series to the load, and is loaded through the load side terminal via the current line 110a and the current circuit 110b inside the wattmeter via the current terminal 110. Flows into. The voltage signal is supplied to the voltage circuit 120b through the T-phase test voltage terminal 120 through the current terminal 110 and through the S-phase voltage terminal and the voltage signal line 120a.

Based on the values detected by the current circuit 110b and the voltage circuit 120b of the T-phase, the value of the power of the T-phase is calculated as in the following formula.

The amount of power in T = Vt * It * cosΦ where cosΦ is the phase difference between the two voltages and the current signal to calculate the effective power amount.

In other words, the supplied power is supplied to the user after passing through the sealed power meter (2) as described above, but in spite of the above-mentioned seal, the terminal block is disconnected and the wiring of the test terminal block connected is disconnected or tightened. The use of non-conductors such as enamel or menigure on the part frequently occurred.

This is because the current signal is normally supplied to the electricity meter 2, but the voltage signal is in a state in which the test voltage terminal is open so that the electricity meter cannot be metered.

In other words, the electricity meter only measures 1/3 to 2/3 of the actual amount of power used, so the user always pays less than the electricity used.

In addition, it is impossible to tighten the two terminal screws 112 to have the same pressing force in the wire that is bound as described above.

This, in the process of tightening the two terminal screws 112 will cause a phenomenon that the terminal screw is tightened much or less. In other words, if the tightening degree of the two screws are different depending on the strength and skill of the wrist of the technician handled in the actual site, one side is loosened and the contact surface is reduced, resulting in a difference in contact resistance.

At this time, when a large current that cannot be handled flows through the reduced contact surface, resistance heat is generated in the loose part, which melts the terminal block made of polycarbonate, which is the main cause of burned power meter, and in some cases, may cause a fire. .

Therefore, the present invention has been devised to solve the above problems, and the test voltage terminal required for the test of the wattmeter is built in the inside of the terminal block without exposing to the outside, thereby preventing the conductivity. Its purpose is to provide a terminal structure for a meter.

In addition, another object of the present invention is to provide a terminal structure for a watt-hour meter that can prevent burnout of the watt-hour meter without the need for terminal screws generated when the wires are combined.

1 is a view showing a terminal block for a conventional general power meter.

2 is a view showing the electrical connection state of the electricity meter according to FIG.

3 is a view showing a terminal structure for a power meter according to an embodiment of the present invention

Figure 4 is an exploded perspective view showing an enlarged terminal structure for a power meter according to an embodiment of the present invention.

5 is a cross-sectional view showing a state in which the coupling terminal is coupled to the terminal structure for a wattmeter according to an embodiment of the present invention.

6 is a view showing a coupling terminal and a test screw of the power meter terminal structure according to an embodiment of the present invention, Figure 6a is a view showing the contact state of the voltage terminal by the test screw, Figure 6b is A diagram showing an off state of a voltage terminal contact point.

<Description of the symbols for the main parts of the drawings>

2: wattmeter 4: wire

4a: voltage signal line 4b: current signal line

6: load side wire 10,100: terminal block

12: coupling groove 14: incision

16: Hole 20,120: Voltage terminal

22: spiral hole 30, 110: current terminal

32: home 34: home

40: fixing means 42: body

44: give portion 46: fixed piece

48: round part 50: stepped part

52: Handle 60: Test Screw

62: spiral 110a: internal current line

110b: current circuit 112: terminal screw

114: terminal cover 115: sealing screw

116: sealing line 117: lead

120a: voltage signal line 120b: voltage circuit

A: Coupling terminal

The wattmeter terminal structure of the present invention for achieving the above object is in the terminal block of the wattmeter connected to the input side wire and the load side wire,

The terminal block has a plurality of coupling grooves on the front surface, the upper surface of the terminal block is made of an integral type having a hole in communication with each coupling groove perpendicularly, coupled to the coupling groove of the coupling terminal corresponding to the terminal block, It is characterized in that the contact is coupled on / off (on / off) by the inserted test screw.

Hereinafter, the present invention will be described in more detail with reference to an embodiment of the present invention.

Prior to describing the present invention, since a plurality of current terminals, voltage terminals, and fixing means are installed in the input terminal of the terminal block in the same structure, the same parts are given the same reference numerals, and the repeated description thereof will be omitted. Only the differences are explained.

3 is a diagram illustrating a terminal structure for a wattmeter according to an embodiment of the present invention, the terminal structure of the wattmeter of the present invention is made of a wattmeter and a terminal block, and the wattmeter 2 is supplied. The amount of power is calculated by measuring the voltage and current, and the terminal block 10 protruding from the lower part of the wattmeter has a plurality of voltage terminals 20 and current terminals for sending voltage and current signals supplied to the wattmeter 2. 30) is combined and supplied to the user via the electricity meter (2).

On the other hand, the electricity meter (2) as described above is installed in each user's home, and the terminal block 10 of the lower left of the electricity meter to the R-phase, S-phase, T-phase and The input side current terminals 30 to which the neutral wire N can be connected are composed of 1S, 2S, 3S, and 0S, respectively.

At this time, the current terminal 30 is coupled to each phase (phase), in the case of the R phase, the current signal is connected to the current terminal 30 and the terminal screw inside the R line and 1S of the external input side wire (4) The voltage signal is also connected without exposing the test voltage terminal to the outside.

On the other hand, in the case of the S phase, the current signal is connected to the S line of the external input side wire 4 and the current terminal and terminal screw inside the portion labeled 2S, and the voltage signal is also exposed without the test voltage terminal 20 exposed to the outside. Connected.

In the case of the T phase, the current signal is connected to the T line of the external input side wire 4 and the current terminal 30 and the terminal screw inside the portion labeled 3S, and the voltage signal is also connected to the test voltage terminal 20 to the outside. Connected without being exposed.

In the case of the neutral wire, the N line of the external input side wire 4 and the terminal and the terminal screw inside the portion marked 0S are connected without using.

The current terminal 30 described above is connected to the wire connecting method by crimping the copper wire portion from which the rubber coating in the groove 32 of the current terminal 30 is removed without using a screw.

In addition, at the lower right end, the output side current terminals 30 1L, 2L, 3L, and 0L, which can be connected to the load side wires 6 of the customer, are configured. These wires are also connected to each terminal without using terminal screws in the same manner as the above-described input side.

In addition, fixing holes for fixing the electricity meter 2 to the wall are formed at both lower sides of the electricity meter 2, and when the connection and installation of the electricity meter are completed, there is no metal at the charging part exposed to the terminal block 10. Manipulation can be prevented and electric shock can be prevented.

Therefore, it is possible to configure the terminal block 10 which can omit the terminal cover and the seal.

Figure 4 is an exploded perspective view showing an enlarged power meter terminal structure according to an embodiment of the present invention, Figure 5 is a cross-sectional view of the coupling terminal coupled to the power meter terminal structure according to an embodiment of the present invention As shown in the figure, the terminal block 10 as described above is made of an integrated body that does not require a cover, a plurality of coupling grooves 12 are formed on the front thereof, the cutout portion 14 is formed on both sides thereof, On one side of the upper surface is formed a hole 16 which communicates perpendicularly to each coupling groove 12.

At this time, the test screw 60 to be described later is coupled to the hole.

On the other hand, the voltage terminal 20 is fixed to the inner side of the coupling groove 12 is fixed in a state of being made of a predetermined thickness as a plate having an elastic force, the spiral hole 22 formed through the one surface is formed .

In addition, the voltage terminal 20 is spaced apart from the hole 16 formed in the terminal block 10, the spiral hole 22 is coupled to be in communication, one end is supplied to the inside of the electricity meter (2) The voltage signal line 4a is coupled.

In addition, the current terminal 30 press-fitted to the lower portion of the coupling groove 12 to be in contact with the voltage terminal 20 has a groove 32 in which the wire 4 to be supplied to the electricity meter 2 is seated on one side thereof. And a current signal line 4b supplied to the inside of the electricity meter 2 on the other side thereof.

In addition, the coupling surface of the current terminal 30 coupled in contact with the voltage terminal 20 corresponds to the spiral hole 22 of the voltage terminal 20, and has a groove larger than the diameter of the spiral hole 22. 34). It is inserted into the hole 16 of the terminal block 10, the test screw 60 is coupled to the spiral hole 22 to separate the voltage terminal 20 in contact with the current terminal 30, the current terminal 30 ) To prevent contact.

Meanwhile, the wire 4 is press-fitted into the coupling groove 12 so as to be positioned above the current terminal 30 and pressurizes the wire 4 seated in the groove 32 to seat the wire 4 seated on the current terminal 30. Fixing means 40 is coupled to enhance the contact force of the.

At this time, the fixing means 40 is made of a body 42 corresponding to the upper portion of the coupling groove 12 to a predetermined length, the guides protruding on both sides of the body 42 is pressed into the incision 14 Part 44 is formed, the guide part 44 and the body 42 is made to be inclined downward (5 ~ 7 °) in the direction in which one end is inserted into the coupling groove 12, the pressing force to the wire located below Is increased.

In addition, at the lower end of the downwardly inclined body 42, the fixing piece 46 increases the pressing force on the wire 4 seated on the current terminal 30 to strengthen the coupling force between the current terminal 30 and the wire 4. Is combined.

At this time, the fixing piece 46 has a strong elastic force, and the steel of the copper alloy as an alloy material which is not sensitive to secular changes in order to compensate for the problem that elasticity of the steel with elasticity is reduced by physical force or secular change. It is preferable to consist of.

In addition, the fixing piece 46 is fixed to one end of the body 42, is fixed to be located on the lower surface in the longitudinal direction of the body 42, the fixing piece 46 corresponds to the diameter to the wire (4) One curved round portion 48 is formed, and a plurality of protrusions are formed on the surface thereof, so that a stronger pressing force can be applied to the wire 4 seated on the current terminal.

On the other hand, at the other end of the body 42 press-fitted to the upper portion of the coupling groove 12 of the terminal block 10 is formed with a stepped portion 50 for preventing excessive entry into the coupling groove 12, the back surface By holding the body 42, the handle 52 is protruded to facilitate the coupling and separation into the coupling groove 12, thereby forming the fixing means (40).

On the other hand, Figure 6 is a view showing a coupling terminal and a test screw of the power meter terminal structure according to an embodiment of the present invention, Figure 6a is a view showing a contact state of the voltage terminal by the test screw on. 6b is a diagram illustrating a contact state of a voltage terminal in an off state. As illustrated, the coupling terminal A is used for a test when the current terminal 30 and the voltage terminal 20 are opened for a test. The screw 60 is inserted into the hole 16 formed in the terminal block 10, and the spiral 62 formed at one end of the test screw 60 is perpendicular to the hole and positioned at the lower surface of the hole. It is coupled to the spiral hole 22.

Subsequently, when the test screw 60 coupled to the spiral hole 22 of the voltage terminal 20 is rotated clockwise, the voltage terminal 20 rises along the spiral 62 of the test screw 60. In the off state, the contact of the voltage terminal is separated from the current terminal 30.

At this time, if the test screw 60 is rotated counterclockwise after the power meter (2) is tested, the test screw (60) is lowered along the spiral (62) of the test screw (60), and the test screw (60). Is separated from the voltage terminal 20, the voltage terminal 20 is crimped to the current terminal 30 by the elastic force, the contact of the voltage terminal is turned on.

That is, the wattmeter 2 made as described above can test the wattmeter 2 using the test screw 60 from the outside, unlike the conventional wattmeter test method that has been carried out by opening the cover of the terminal block. The cover and terminal screws of the terminal block are not required, and safety accidents due to conduction and wiring can be prevented in advance.

As described above, the power meter terminal structure of the present invention can prevent safety accidents due to wiring by not using a terminal screw, open a test voltage terminal from the outside, or tighten a voltage terminal and a current terminal. It can not be operated arbitrarily, such as coating of non-conductor, and there is no live part exposed to the terminal block part, so that the conductivity can be prevented in advance.

Also, for the error test of the electricity meter, it is a voltage terminal that does not short the voltage between the current terminal and the current terminal even if it is separated by using a screw when it is opened between the current terminal and the voltage terminal. Since the terminal of is coupled by using the elastic force of the voltage terminal, it is useful to prevent safety accidents due to wiring.

Claims (4)

In the terminal block 10 of the wattmeter 2 to which the input wire 4 and the load wire 6 are connected, The terminal block 10 has a plurality of coupling grooves 12 on the front surface, the upper surface is made of an integral type having a hole 16 which is in communication with each of the coupling grooves 12 perpendicularly, Coupling terminal A corresponding to the terminal block 10 is coupled to the coupling groove 12, coupled by the test screw 60 inserted into the hole 16 to be turned on / off (on / off) Power meter terminal structure, characterized in that. The method of claim 1, wherein the coupling terminal (A), It is fixed while being elastically supported in one side of the coupling groove 12, the spiral hole 22 formed in one surface is coupled to be spaced apart from the hole 16, the voltage signal line supplied to the inside of the electricity meter (2) A voltage terminal 20 to which 4a) is coupled; The groove 32 is press-fitted and fixed to the lower portion of the coupling groove 12 to be in contact with the voltage terminal 20, and a recess 32 is formed on one side to which the wire 4 supplied to the electricity meter 2 is seated, and on the other side of the power meter ( A current terminal 30 to which a current signal line 4b supplied into 2) is coupled; And The body 42 press-fitted into the coupling groove 12 is formed to have a predetermined length so as to be positioned above the current terminal 30, and at one end thereof, the step portion 50 for preventing excessive entry into the coupling groove 12. ) Is formed to protrude, and is composed of a fixing piece 46 is fixed to the body 42 so as to be located below the body 42, the groove 32 of the current terminal 30 by the fixing piece 46 Consists of the fixing means 40 to press the wire (4) provided in), Power meter terminal, characterized in that coupled to the on / off (on / off) contact of the voltage terminal 20 in contact with the current terminal 30 by rotating the test screw 60 inserted into the hole 16 rescue. The method of claim 2, On both sides of the body 42, the guide portion 44 press-fitted into the incision 14 is protruded, characterized in that the body 42 and the guide portion 44 is inserted inclined downward in the coupling groove 12. Terminal structure for power meters. The method of claim 2, The fixing piece 46 is configured to form a curved round portion 48 corresponding to the diameter of the electric wire (4) terminal structure for a power meter.