JP2649083B2 - Switchboard equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a switchboard device suitable for a home switchboard device, and particularly to a single-phase three-wire system, which divides an AC power having an effective value of 100 V or 200 V into a first component. The present invention relates to a main circuit breaker which supplies to a wiring and a second branch wiring, in which an average current value of a current flowing through each of a first breaker and a second breaker of a main circuit breaker is automatically made substantially equal.

(Prior art)

In general, a single-phase three-wire type switchboard that can be distributed to a large number of circuits as the number of distribution circuits indoors increases is adopted as a home switchboard device.

For example, as shown in FIG.
Is provided with a main circuit breaker (safety breaker) 104 having a first breaker 106 and a second breaker 108, and the main circuit breaker 104 has a distribution line 1
AC power is supplied by a single-phase three-wire system 10. First
The distribution line 103 is connected to the first distribution line 110 via the first breaker 106.
AC power with an effective value of 100 V is supplied from the voltage line 124,
The distribution line 132 is connected to the second line of the distribution line 110 via the second breaker 108.
AC power having an effective value of 100 V is supplied from the voltage line 126. The first distribution line 130 distributes power via a plurality of breakers 144, respectively, and the second distribution line 132 also distributes power via a plurality of breakers 146, respectively. Note that reference numeral 128 is a neutral line. Here, when the allowable current value of the first breaker 106 and the second breaker 108 is, for example, 60 A, respectively,
A maximum current of 60 A can flow through the distribution line 130 and a maximum current of 60 A can flow through the second distribution line 132. The first breaker 106 and the second breaker 108 are interlocked, and even if either the first breaker 106 or the second breaker 108 is shut off, both breakers 106 and 108 are shut off at the same time.

Therefore, when each of the breakers 144 and 146 is connected to each of the indoor distribution circuits, the current I ₁ flowing through the first distribution line 130 and the current I ₂ flowing through the second distribution line 132 are substantially equal.
Considering the load current of each distribution circuit, each breaker 144
・ 146 and each distribution circuit are connected. When the load current of each distribution circuit is equal to or larger than the allowable current of each breaker 144, 146, the breaker 144, 146 is cut off.

[Problems to be solved by the invention]

The distribution circuits distributed via the breakers 144 and 146 are used in accordance with the season of electric appliances having a relatively large load current, such as coolers and heaters. At this time, when these coolers and the like are intensively connected to, for example, each circuit of the plurality of breakers 144, the current I ₁ flowing through the first distribution line 130
And the second breaker 108 is shut off at the same time as the first breaker 106 is shut off.
An object of the present invention is to provide a switchboard device capable of preventing the main circuit breaker from being shut off until the total load current reaches the maximum allowable current of the main circuit breaker irrespective of the fluctuation of the load current.

[Means for solving the problem]

The switchboard device according to the present invention includes a first breaker and a second breaker respectively connected to one voltage line and the other voltage line of a single-phase three-wire distribution line to which AC power having an effective value of 100 V or 200 V is supplied. In a switchboard apparatus provided with a main circuit breaker including: a first distribution line connected to a first breaker and distributing power via a plurality of breakers; and a power distribution apparatus connected to a second breaker and receiving power via a plurality of breakers. A second distribution line for distribution, first current detection means for detecting a first current flowing from the first breaker to the first distribution line, and a second current detection for detecting a second current flowing from the second breaker to the second distribution line. Means, first switching means for opening and closing the first distribution wiring, second switching means for opening and closing the second distribution wiring, a first breaker for the first switching means and the second switching means, and Auxiliary switching means provided on the connection line connecting the first branch wiring and the second branch wiring on the side opposite to the second breaker, and the current values detected by the first current detection means and the second current detection means, respectively. Based on the average,
Control means for controlling the first switching means, the second switching means, and the auxiliary switching means so that the average value of the first current and the average value of the second current become substantially equal.

[Action]

In the switchboard device according to the present invention, one voltage line of the single-phase three-wire type distribution line is connected to the first branch wiring via the first breaker of the main circuit breaker, and the first branch wiring is connected to the one voltage wiring. The AC power supplied to the line is respectively distributed through a plurality of breakers. Further, the other voltage line of the distribution line is connected to a second distribution line via a second breaker of the main circuit breaker, and the second distribution line transmits the AC power supplied to the other voltage line to a plurality of breakers. Through each of them.

The first current detection means detects a first current flowing from the first breaker to the first distribution line, and the second current detection means detects a second current flowing from the second breaker to the second distribution line. Further, the first switching means opens and closes the first branch wiring, the second switching means opens and closes the second branch wiring, and the auxiliary switching means switches the first breaker and the second breaker with respect to the first switching means and the second switching means. Since it is provided on the connection line connecting the first branch wiring and the second branch wiring on the side opposite to the breaker, the first switching means is ON, the second switching means is OFF, and the auxiliary switching means is O.
In the case of N, the first current becomes the total power source of the currents flowing through the first branch wiring and the second branch wiring respectively, and the second current becomes “0”. On the other hand, when the first switching means is OFF, the second switching means is ON, and the auxiliary switching means is ON, the first current is "0", and the second current is a current flowing through the first branch wiring and the second branch wiring, respectively. Is the total current.

Therefore, the control means determines the average value of the first current and the average value of the second current based on the average value of the current values from the first current detection means and the average value of the current values from the second current detection means. The ON / OFF control of each of the first switching means, the second switching means, and the auxiliary switching means is performed for each delicate time so that is substantially equal. As a result, an average current of the first current and an average current of the second current equal thereto flow through the first breaker and the second breaker of the main circuit breaker, respectively.

For example, while the second current is 10 A, the first current is 1
When the current suddenly increases from 0A to 50A, the control means turns on the second switching means and controls the opening and closing of the first switching means every minute time to turn on only for 60% of the time.
It turns off only for 40% of the time and turns on the auxiliary switching means during this 40% off time. That is, the first branch wiring has the first
When the switching means is ON, current is supplied from one voltage line, but when the first switching means is OFF, current is supplied from the other voltage line. Therefore, the first switching means and the auxiliary switching means are respectively turned ON. The average value of the first current and the average value of the second current are always approximately equal to 30 A by performing the OFF control. As a result, 30A flows through the first breaker and the second breaker, respectively.

〔The invention's effect〕

According to the switchboard device according to the present invention, as described in the section of [Action], the first branch wiring and the second branch wiring in which electric appliances having a large load current, such as coolers and heaters, are intensively connected. Even when one current value becomes larger than the other current value, the average current value of the first current value and the average current value of the second current value are always equal, and the equal average current is equal to the first breaker of the main circuit breaker. And the second breaker, respectively, so that interruption of the main circuit breaker can be reliably prevented until the total load current reaches an allowable maximum current corresponding to twice the allowable current of the first and second breakers.

〔Example〕

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

First, the home switchboard device 2 including the main circuit breaker 4 will be described. As shown in FIG. 1, a single-phase three-wire distribution line 10 is introduced into a home switchboard device (hereinafter simply referred to as a switchboard) 2, and a first voltage line 24 and a neutral line are provided.
28 and the second voltage line 26 are connected to input terminals 12, 14, 16 of a main circuit breaker (hereinafter simply referred to as breaker 4) 4, respectively. The breaker 4 is the same as a normal breaker. The breaker 4 has an input terminal 12 and an output terminal 18.
A first breaker 6 with a permissible current of 60 A interposed therebetween and a second breaker 8 with a permissible current of 60 A interposed between the input terminal 16 and the output terminal 22 are built in. This first breaker 6
And the second breaker 8 are interlocked with each other.
Even if 8 is cut off, both breakers 6.8 are cut off at the same time. Reference numeral 50 denotes an operation lever for turning on / off the breaker 4. On the other hand, the output terminals 18, 20, and 22 have a first branch line 30, a neutral line 28, and a second branch line extending inward of the switchboard 2.
32 are connected to each other, and a first branch wiring 30 near the output terminal 18 is connected.
The disposed in the first current detector 34 is a non-contact form for detecting a first current I ₁ flowing through the first minute wiring 30 made of a ring-shaped coil, the second minute wiring 32 in the vicinity of the output terminal 22 It is disposed a second current detector 36 is in a non-contact form for detecting a second current I ₂ flowing in the second minute wiring 32 made of a ring-shaped coil. A first switch 38 for opening and closing the first branch line 30 is provided in the first branch line 30, and a second switch 40 for opening and closing the second branch line 32 is provided in the second branch line 32. Have been. Furthermore,
On the side opposite to the first breaker 6 and the second breaker 8 with respect to the first switch 38 and the second switch 40, a first branch wiring is provided.
An auxiliary switch 42 is provided on the connection line 31 connecting the 30 and the second branch wiring 32. These first switch 38 and second switch 38
The switch 40 and the auxiliary switch 42 are similar to each other, and are zero-cross type solid state AC relays having high-speed switching characteristics. This switch 38
Reference numerals 40 and 42 each include a light emitting circuit, a light receiving circuit, a firing control circuit, and a triac. As shown in FIG. 2, the switches are closed at the time of the next zero voltage after the input of the "H" level driving signal. As shown, a load current flows through each of the switches 38, 40, and 42, and the next 0 after the input of the "L" level drive signal.
The switch is opened when the voltage is applied.

The first distribution line 30 and the neutral line 28 have five breakers 44.
Are connected in parallel to each other through a breaker 44 and are distributed to a plurality of circuits. Further, five breakers 46 are connected in parallel to the second branch wiring 32 and the neutral line 28, respectively, and are connected to a plurality of circuits through the breaker 46. Has been distributed. The breakers 44 and 46 are the same as the existing breakers, and are cut off when a load current of 15 A or more flows through each distribution circuit.

The first current detection circuit 34, the second current detector 36, the first switch 38, the second switch 40, and the auxiliary switch 42 are connected to a control box 48, respectively.

Since the home switchboard device 2 is configured as described above, the 100 V AC power supplied to the first voltage line 24
The 100V AC power distributed to the plurality of distribution circuits via the breaker 6, the first switch 38, the first distribution line 30, and the breaker 44, and supplied to the second voltage line 26 is supplied to the second breaker 8, the second switch The signal is distributed to a plurality of distribution circuits via the second distribution wiring 40 and the breaker 46.

Next, the control device C in the control box 48 will be described with reference to the block diagram of FIG.

The first current detector 34 is connected to an input / output interface 65 via an A / D converter 60, and the second current detector 36 is connected to an input / output interface 65 via an A / D converter 61. detection current value signal (digital signal) and the detection current value signal corresponding to the detected current i ₂ detected by the second current detector 36 (digital signal) output interface corresponding to the detected current i ₁ which is
Output to 65 respectively. The first switch 38 is connected via a drive circuit 62, the second switch 40 is connected via a drive circuit 63, and the auxiliary switch 42 is connected via a drive circuit 64 via an input / output interface.
Connected to 65. An input / output interface 65 is connected to a CPU (central processing unit) 67 via a bus 66 such as a data bus.
And the ROM 68 and the RAM 69 are connected to each other. Although not shown, each A / D converter 6 is provided in the control box 48.
0 ・ 61, each drive circuit 62-64, input / output interface 6
5. A power supply circuit for supplying a drive current to the CPU 67, the ROM 68, and the RAM 69 is provided.

The ROM 68, the current equalization control control program for substantially equal the average value of the first current I ₁ and the average value of the second current I ₂ is stored in advance. The current equalization control program includes a detected current value signal input from the first current detector 34 via the A / D converter 60 and an input from the second current detector 36 via the A / D converter 61. conversion subroutine for converting the detected current value signal the actual to the first current I ₁ and the second current I ₂ that is, when I _1> I _2, sets the control time ratio of turning oN the first switch 38 Arithmetic expression (I ₁ + I ₂ ) / 2I ₁ and an arithmetic expression (I ₁ −I ₂ ) / 2I ₁ , I ₁ <I ₂ for setting a control time ratio for turning off the first switch 38 and turning on the auxiliary switch 42. In the above equation, an arithmetic expression (I ₁ + I ₂ ) / 2I ₂ for setting a control time ratio for turning on the second switch 40 and an arithmetic operation for setting a control time ratio for turning on the auxiliary switch 42 while turning off the second switch 40 The equation (I ₂ −I ₁ ) / 2I ₂ is stored in advance. The control time obtained by these arithmetic expressions is a ratio of the ON time and the OFF time. When the switches 38, 40 and 42 are actually driven, it takes about one cycle in the case of 60 Hz alternating current.
The control time is determined with a basic time of 16 ms, or about 20 ms required for one cycle in the case of AC of 50 MZ. RAM69
Are provided with a work memory and various memories for temporarily storing results of arithmetic processing by the CPU 67.

Next, a routine of the current equalization control performed by the control device C in the control box 48 will be described with reference to the flowchart of FIG. In the figure, Si (i = 1, 2, 3,.
・ ・) Is each step.

The breaker 4 is turned on by operating the operation lever 50 of the breaker 4.
As a result, this control is started and the initial setting is first executed (S1), and the first switch 38 and the second switch 40 are turned on and the auxiliary switch 42 is turned off (S2). At this time, since various electric products in distribution circuit connected to each breaker 44, 46 are used, the first minute wiring 30 first current I ₁ flows, the second minute wiring 32 second current I ₂ flows. Then, the detection current value signal from the first current detector 34 is read in, first current I ₁ real is stored in the work memory of the RAM69 are obtained by computation by the conversion subroutine (S3), to the work memory Stored past multiple times (for example, 10
Its average current value ▲ ▼ is calculated by using the first current I ₁ times) (S4). Next, the second current detector 36 detects current value signal is read in from the actual second current I ₂ is stored in the work memory RAM69 is obtained by computation by the conversion subroutine (S5), in the work memory the average current value using the past stored plurality of second current I ₂ ▲ ▼ is calculated (S6). Next, it is determined whether or not the average current value ▲ ▼ is equal to the average current value ▲ ▼ (S7). If the average current value ▲ ▼ is equal, the process returns to S2.
The current from the first voltage line 24 is continuously supplied to 30, and the current from the second voltage line 26 is continuously supplied to the second distribution line 32. On the other hand, when the average current value ▲ ▼ is not equal to the average current value ▲ ▼, No is determined in S7, and it is determined whether the average current value ▲ ▼ is larger than the average current value ▲ ▼ (S8). The first current I ₁ is the second current I ₂
If it is larger, the average current value ▼ is larger than the average current value ▼, so it is determined to be Yes, and the second switch 40 is turned on by the drive signal from the drive circuit 63 (S
9). Next, the first switch 38 and the auxiliary switch 42
_1> Control of ON time and OFF time on the basis of the equation at the time of I ₂ is respectively calculating (S10), Wataru the first switch 38 a predetermined time on the basis of the controlled variable (e.g., 200~300ms) The ON / OFF control is continuously performed, and the auxiliary switch 42 is also continuously ON / OFF controlled for a predetermined time (however, the auxiliary switch 42 is turned OFF when the first switch 38 is ON, and the first switch 38 is O
It is turned ON at the time of FF) (S11), and returns to S3. For example, the first current I ₁ 10A whereas a second current I ₂ 10A
When the current suddenly increases from 50 A to 50 A, the second switch 40 is turned ON, the first switch 38 is turned ON for 60% of the predetermined time, the remaining 40% is turned OFF, and the auxiliary switch 42 is turned ON for this 40% OFF time.
Let it. As a result, the first switch 38 is
During the ON time, current is supplied from the first voltage line 24, and during the OFF time of the first switch 38, the current from the first voltage line 24 continues from the second voltage line 26 via the auxiliary switch 42. Since the current is supplied, the average current value ▼ and the average current value ▼ are substantially equal to 30 A, and the 30 A flows through the first breaker 6 and the second breaker 8, respectively. Therefore, even when the load current flowing through the first branch wiring 30 and the second branch wiring 32 fluctuates, the necessary current can be supplied to the first branch wiring 30 and the second branch wiring 32, and the total load current is reduced by the first breaker. 6 and the first breaker 6 until the maximum allowable current corresponding to twice the allowable current (60 A) of the second breaker 8 is reached.
In addition, the interruption of the second breaker 8 can be reliably prevented.

Further, when the second current I ₂ is larger than the first current I ₁ is
Since the average current value ▲ ▼ is larger than the average current value ▲ ▼, it is determined as No in S8, and the first switch 38
(S12), and the second switch 40 and the auxiliary switch 42 are turned on based on the arithmetic expression when I ₁ <I _2.
The control amounts of the time and the OFF time are respectively calculated (S13), and based on the control amounts, the second switch 40 is continuously CN / OFF controlled for a predetermined time, and the auxiliary switch 42 is also controlled for a predetermined time. ON / OFF control (S14), and returns to S3. As a result, the current is supplied to the second distribution line 32 from the second voltage line 26 during the ON time of the second switch 40 and to the current from the second voltage line 26 during the OFF time of the second switch 40. The current is continuously supplied from the first voltage line 24 via the auxiliary switch 42, and the equal average current ▲ and the average current ▲
Flows through the first breaker 6 and the second breaker 8, respectively. Therefore, even when the load current flowing through the first branch wiring 30 and the second branch wiring 32 fluctuates, the total load current becomes the maximum allowable current corresponding to twice the allowable current of the first breaker 6 and the second breaker 8. Until then, the breaker 4 can be reliably prevented from being shut off.

Incidentally, it is also possible to start the control when either one of the current of the first current I ₁ or the second current I ₂ exceeds a predetermined value (e.g., 30A). Further, it is also possible to start the control when the difference between the first current I ₁ and the second current I ₂ exceeds a predetermined value (e.g., 10A). Each switch
38, 40, and 42 may be configured by various switching circuits. The above embodiment is merely an example, and those skilled in the art can make various modifications without departing from the spirit of the present invention.

[Brief description of the drawings]

1 to 5 show an embodiment of the present invention.
FIG. 2 is a front view of the home switchboard device, FIG. 2 is a time chart showing operation characteristics of each of the first switch, the second switch, and the auxiliary switch. FIG. 3 is a block diagram of a control system related to current equalization control. FIG. 5 is a flowchart of a current equalization control routine, and FIG. 5 is a schematic front view of a home switchboard apparatus according to the related art. 2 home switchboard device, 4 main circuit breaker, 6 first breaker, 8 second breaker, 10 distribution line, 24 first voltage line, 26 second voltage line , 30... First branch wiring, 32... Second branch wiring, 34... First current detector 36... Second current detector 38.
1st switch, 40 ... second switch, 42 ... auxiliary switch, 44/46 ... breaker, 67 ... CPU, 68 ... ROM, 69 ... RAM, C ... control device.

Claims (1)

(57) [Claims] 1. A main circuit comprising a first breaker and a second breaker connected to one voltage line and the other voltage line of a single-phase three-wire distribution line to which AC power having an effective value of 100 V or 200 V is supplied, respectively. In a switchboard device provided with a circuit breaker, a first distribution line connected to the first breaker and distributing electric power via a plurality of breakers, respectively, and connected to the second breaker and individually supplied with electric power via a plurality of breakers , A first current detecting means for detecting a first current flowing from the first breaker to the first distribution line, and a second current from the second breaker.
A second current detecting means for detecting a second current flowing to the distribution wiring; a first switching means for opening and closing the first distribution wiring; a second switching means for opening and closing the second distribution wiring; An auxiliary switching means provided on a connection line connecting the first branch wiring and the second branch wiring on a side opposite to the first breaker and the second breaker with respect to the second switching means; The first switching means and the second switching means are arranged so that the average value of the first current and the average value of the second current are substantially equal based on the average values of the currents respectively detected by the second current detection means. A switchboard device comprising: a control unit that controls an auxiliary switching unit.