KR102068823B1 - Peak power demand management apparatus using bandwidth control method - Google Patents

Abstract

In the present invention, the peak power demand management apparatus, the first, second, third single-phase load (51, 51-1, 51-2); First, second and third single-phase switch units 29, 29-1 and 29-2 for supplying power to the first, second and third single-phase loads 51, 51-1 and 51-2; A power stage current sensor 33 for detecting current of the single-phase AC power source 27; First, second, and third load stage current sensors (32,32-1,32-2) for detecting current in the first, second, and third single-phase loads (51, 51-1, 51-2); First, second and third current amplifiers 11, 11-1 and 11-2 for amplifying currents of the first, second and third load stage current sensors 32, 32-1 and 32-2; First and second lines 24 and 25 for connecting the first, second and third current amplifiers 11, 11-1, 11-2 and the main controller 80; A first relay (20) which determines whether or not a connection between the cut-off contact (X, X ') of the first line (24) and the cut-off contact (Y, Y') of the second line (25); When the first relay 20 is a contact A, current information of the first, second and third load stage current sensors 32, 32-1, and 32-2 is transmitted to the main controller 80. When the first relay 20 is a contact B, the first relay 20 is connected to the current upper limit control resistor 18 to convert the power of the first, second, and third single-phase loads 51, 51-1, and 51-2 into a band width. We propose a peak power demand management device characterized in that the control by).

Description

Peak power demand management apparatus using bandwidth control method

The present invention relates to a peak power demand management device that can be centrally integrated control. Recently, there is a case where the available power is very insufficient due to the excessive consumption of power consumed by the load such as cooling and heating, and in the present invention, the peak power is integrated centrally instead of individually controlled for each load in the peak power state. The present invention relates to a band width peak power demand management device capable of controlling peak power while having a simple bandwidth.

With the advent of smart buildings and the installation of system air conditioners that can control both cooling and heating at the same time, the need for technology to centrally control power is emerging.

To this end, as a method of controlling a plurality of multi-air conditioners, LG Electronics, a representative domestic electronics company, discloses Korean Patent Publication No. 10-1554180 (published 2015.09.18.) (Hereinafter referred to as [Patent Document 1]). The driving control apparatus and method of a plurality of air conditioner systems have been proposed.

In [Patent Document 1], the technical feature is that after the temperature is set for the indoor unit, a plurality of multi-air conditioners are controlled based on the speed at which the outside temperature estimates the indoor unit set temperature.

In addition, Samsung Electronics, another representative home appliance company in Korea, is a peak power operating device of a system air conditioner through the Republic of Korea Patent Publication No. 10-0794602 (notice date 2008.01.14.) (Hereinafter referred to as [Patent Document 2]) and its A control method was proposed.

[Patent Document 2] is a system air conditioner for determining whether the peak power by a method of controlling a plurality of system air conditioner, detect the current operation mode, room temperature, heat exchanger inlet and outlet temperature, and change the operation mode according to the determined operation mode A peak power operation mode of is proposed.

In addition, through the Republic of Korea Patent Publication No. 10-1835043 (notice date 2018.03.09.) (Hereinafter referred to as [Patent Document 3]) is characterized in that the real-time demand management and energy reduction method of the building through the predicted power profile. .

In [Patent Document 3], the energy demand management operation server generates a predicted power profile by using historical weather data identified in the meteorological office's weather data BS and historical power usage data used in a remote meter reading electricity meter. The technical features of the demand management and energy reduction method in real time by setting the.

Regarding the peak power demand management device, the following prior art documents exist.

[Patent Document 1] Republic of Korea Patent Publication No. 10-1554180, Publication Date 2015.09.18. [Patent Document 2] Republic of Korea Patent Publication No. 10-0794602, Publication Date 2008.01.14. [Patent Document 3] Republic of Korea Patent Publication No. 10-1835043, Publication Date 2018.03.09.

In the present invention, unlike the conventional peak power demand management device, it is possible to integrate the central control, and to propose a peak power demand management device controlled by the bandwidth (Band Width). The proposed peak power demand management device uses the power stage current information detected through the power stage current sensor 33 and the first, second, and third load stage current sensors 32, 32-1, and 32-2. It is an object of the present invention to control peak power at a bandwidth in the center when peak power is generated through current information.

In the present invention, the current information of each load is obtained through the power stage current information detected through the power stage current sensor 33 and the first, second and third load stage current sensors 32, 32-1 and 32-2. The first line 24 and the second line 25 of the first, second and third load stage current sensors 32, 32-1, and 32-2 are cut off, and the first line 24 is cut off. A current is generated by using only two relays of the first relay 20 and the second relay 21 between the contacts X, X 'and the cut contacts Y, Y' of the second line 25. It is a technical feature to set the upper limit of the upper limit of the upper limit. First of all, the first relay 20 determines that the main controller 80 is coupled to the first, second, and third load stage current sensors 32, 32-1, and 32-2, and the second relay 21 is a current. It determines the upper limit of the upper limit. At the same time, the power stage current sensor 33 detects the current of the current power stage and transfers it to the main controller 80. Through the peak current demand management device located between the main control unit 80 and the first, second and third load stage current sensors 32, 32-1 and 32-2, the power peak reference value PH In the present invention, it is possible to control power having a band width of the power reference value Pref.

The present invention cuts the first line 24 and the second line 25 of the first, second and third load stage current sensors 32, 32-1, and 32-2 connected to the main controller 80, The first relay 20 and the second relay 21 between the cut contacts X and X 'of the first line 24 and the cut contacts Y and Y' of the second line 25. It is a technical feature to insert a demand management device (90, 90-1, 90-2) using a bandwidth control method of setting the upper limit value of the current through only two relays of the (). Peak power demand management using the demand management device (90, 90-1, 90-2) using the bandwidth control method of the present invention is not using the main control unit 80, but the first, second, third load stage current sensor ( Demand management device (90,90-1,90-) using the bandwidth control method of the present invention is cut between the first and second lines (24,25) connected to the 32,32-1,32-2. 2) Inserting and installing is a technical feature. First, it is very easy to install the peak power demand management device using the bandwidth method. Second, the peak power demand management using the two relays (first and second relays 20 and 21), the current upper limit control resistors 18-1 and 18-2 and the relay controller 23 is the cheapest. Third, through the simple communication unit 26 connected to the main control unit 80, integrated control of the reference power (Pref) value of the demand management device (90, 90-1, 90-2) using all the bandwidth control method in the center Is possible. Fourth, there is an increased effect that can implement a band width peak power demand management device in a very simple manner.

1 is a peak power demand management apparatus using a single-phase two-wire bandwidth control method (steady state mode, first embodiment)
Figure 2 is a peak power demand management device using a single-phase two-wire bandwidth control method (peak state mode, first embodiment)
Figure 3 is a peak power demand management apparatus using a single-phase two-wire bandwidth control method (steady state mode, second embodiment)
Figure 4 is a peak power demand management device using a single-phase two-wire bandwidth control method (peak state mode, second embodiment)
5 is a peak power demand management device using a three-phase three-wire bandwidth control method (steady state mode, first embodiment)
Figure 6 is a peak power demand management device using a three-phase three-wire bandwidth control method (peak state mode, first embodiment)
7 is a peak power demand management device using a three-phase three-wire bandwidth control method (steady state mode, second embodiment)
8 is a peak power demand management apparatus using a three-phase three-wire bandwidth control method (peak state mode, second embodiment)
9 is a peak power demand management device using a three-phase four-wire bandwidth control method (steady state mode, first embodiment)
10 is a peak power demand management apparatus using a three-phase four-wire bandwidth control method (peak state mode, first embodiment)
11 is a peak power demand management device using a three-phase four-wire bandwidth control method (steady state mode, second embodiment)
12 is a peak power demand management device using a three-phase four-wire bandwidth control method (peak state mode, second embodiment)
13 is a detailed circuit diagram of the peak power demand management device using a single-phase two-wire bandwidth control method;
14 is a detailed circuit diagram of a peak power demand management device using a three-phase three-wire system of bandwidth control;
15 is a detailed circuit diagram of the peak power demand management device using a three-phase four-wire bandwidth control method
16 is a state detection circuit diagram of a relay in the single-phase two-wire system;
17 is a state detection circuit diagram of a three-phase three-wire relay;
18 is a state detection circuit diagram of a three-phase four-wire relay;
19 is a peak power control diagram of a power stage

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Fig. 1 shows a peak power demand management device (steady state mode, first embodiment) using a single-phase two-wire bandwidth control method. 1, the first line 24 and the second line connecting the main controller 80 and the first, second, and third load stage current sensors 32, 32-1, and 32-2 are provided. 25) the band width control method proposed in the present invention between the cut contacts (X, X ') of the first line 24 and the cut contacts (Y, Y') of the second line 25 Inserting the demand management device (90, 90-1, 90-2) is a technical feature of the present invention. The demand management device (90, 90-1, 90-2) using the bandwidth control method is simply two relays of the first relay 20, the second relay 21 and the current upper limit control resistor (18). And a relay driving IC 22 for controlling the first and second relays 20 and 21, a relay controller 23, a main controller 80, and a communication unit 26 for connecting external communication with the main controller 80. It is characterized by the technical features.

The biggest advantage of the peak power demand management device using the single-phase two-wire bandwidth control method of Figure 1 is the installation of the demand management device (90, 90-1, 90-2) using the bandwidth control method and It is very easy to remove. That is, the first line 24 and the second line 25 connecting the main controller 80 and the first, second, and third load stage current sensors 32, 32-1, and 32-2 are cut, and the band Demand management device (90, 90-1, 90-2) using the width control method is easy to install and dismantle, because it is a very simple structure, the price is also very affordable.

Therefore, the peak power consumed by the first, second, and third single-phase loads 51, 51-1, and 51-2 can be managed very efficiently, and the power can be managed in a range of band widths. It is the biggest feature, and it can effectively manage peak power and save energy.

Referring to the detailed operation of FIG. 1, the first relay 20 is a contact point A, and the second relay 21 is technically connected to the contact point A. 3 It is a technical feature that it is normally connected to the load stage current sensors 32, 32-1 and 32-2, and is specified among the first, second and third single phase loads 51, 51-1 and 51-2. This is a normal state when the load is less than the peak power and the power supply stage power is less than the peak power, and all the single-phase switch sections 29, 29-1, and 29-2 are turned on.

When the specific load is less than the peak power, the first, second and third single-phase loads 51, 51-1, through the first, second and third load stage current sensors 32, 32-1, and 32-2. The current control unit 51-2 detects the current information by the main control unit 80.

Fig. 2 shows a peak power demand management device (peak state mode, first embodiment) using a single phase two wire type bandwidth control method. 2, the first, second, and third single-phase loads 51, 51-1, detected through the first, second, and third load stage current sensors 32, 32-1, and 32-2 are described. 51-2), when the power of a specific load exceeds the peak power, the first relay 20 moves from contact A to contact B at the specified load, and the second relay 21 It is connected to the contact A, and at the same time, the single-phase switch of a specific load is turned off.

In addition, when the power stage power exceeds the peak power PH through the power stage current sensor 33, the most current flows among the first, second and third single phase loads 51, 51-1, 51-2. At a specific load, the first relay 20 moves from contact A to contact B, the second relay 21 is connected to contact A, and at the same time the single phase switch of the specified load is turned off. ) State. Even in the above state, when the power stage power exceeds the peak power PH through the power stage current sensor 33, the first relay 20 is A at a specific load through which the most current flows among the remaining single phase loads. The second relay 21 is connected to the contact A, and at the same time, the single-phase switch of the specific load is turned off.

In this case, the specific load is connected to the main control unit 80 and the demand management devices 90, 90-1, 90-2 using the bandwidth control method, so that the reference current is the current upper limit control resistor 18. It is set to the resistance value of.

At the same time, when the total power stage power becomes less than the peak power PH and gradually decreases to reach the reference power Pref, the first, second, and third single phase loads 51, 51-1, 51-2 Demand management device (90,90-1,90-2) by turning on all single-phase switch unit (29, 29-1, 29-2), and at the same time using the first, second, third bandwidth control method All of the first relay 20 is characterized in that the movement from the contact B to the contact A.

Therefore, the peak power demand management apparatus using the bandwidth control method in the present invention operates as follows.

(1) When peak power (PH) is reached in a demand management device using a specific bandwidth control method, the first relay 20 moves from contact A to contact B, and a switch unit connected to a specific load is connected. On to off.

(2) When the reference power (Pref) is reached in the demand management device using a specific bandwidth control method, the first relay 20 moves from the B contact to the A contact, and the switch unit connected to the specific load is connected. It turns on from off.

(3) Since power is controlled based on the state of (1) and (2), power can be managed in a range of band widths.

For reference, since the voltage of the power supply is generally constant, the upper limit of the current set by the current upper limit control resistor 18 in the demand management apparatus 90, 90-1, 90-2 using the bandwidth control method is equal to Since it is the same as the upper limit of the power set by the load (the product of voltage and current), it performs substantially the same function as controlling the peak power. Also,

In the first embodiment of FIGS. 1 and 2, when the peak power PH is reached, the first relay 20 moves from the A contact to the B contact, and the switch connected to the specific load is turned off on. When the reference power Pref is reached, the first relay 20 moves from the B contact to the A contact, and the switch connected to the specific load is turned on from off.

In addition, the first relay 20 is moved from the contact A to the contact B, and at the same time, when the second relay 21 is connected to the contact A, the main control unit 20 inputs a current upper limit control resistor 18 value. When the second relay 21 is connected to the contact A, the main controller 20 is substantially the same as that of the infinite resistance value is input, and the switch unit connected to the specific load maintains the off state. The biggest technical feature.

Fig. 3 shows a peak power demand management device (steady state mode, second embodiment) using a single phase two wire type bandwidth control method. 3, the first line 24 and the second line connecting the main controller 80 and the first, second, and third load stage current sensors 32, 32-1, and 32-2 are provided. 25) the band width control method proposed in the present invention between the cut contacts (X, X ') of the first line 24 and the cut contacts (Y, Y') of the second line 25 Inserting the demand management device (90, 90-1, 90-2) is a technical feature of the present invention. The demand management apparatus 90, 90-1, 90-2 using the bandwidth control method simply relays the first relay 20, the current upper limit control resistor 18, and the first relay 20. The driving IC 22 and the relay controller 23 and the main control unit 80, the main control unit 80 and the communication unit 26 for connecting the external communication is characterized by a technical feature.

The biggest advantage of the peak power demand management device using the single-phase two-wire bandwidth control method of FIG. 3 is, among other things, the installation of the demand management device (90, 90-1, 90-2) using the bandwidth control method and It is very easy to remove. That is, the first line 24 and the second line 25 connecting the main controller 80 and the first, second, and third load stage current sensors 32, 32-1, and 32-2 are cut, and the band Demand management device (90, 90-1, 90-2) using the width control method is easy to install and dismantle, because it is a very simple structure, the price is also very affordable.

Therefore, the peak power consumed by the first, second, and third single-phase loads 51, 51-1, and 51-2 can be managed very efficiently, and the power can be managed in a range of band widths. It is the biggest feature, and it can effectively manage peak power and save energy.

Referring to the detailed operation of FIG. 3, if the first relay 20 is a contact A, the main controller 80 may be connected to the first, second, and third load stage current sensors 32, 32-1, and 32-2. It is a technical feature that it is normally connected, and it is normal when the specified load is less than the peak power among the first, second, and third single-phase loads 51, 51-1, and 51-2, and the power stage power is less than the peak power. In this state, all of the single-phase switch units 29, 29-1, 29-2 are turned on.

When the specific load is less than the peak power, the first, second and third single-phase loads 51, 51-1, through the first, second and third load stage current sensors 32, 32-1, and 32-2. The current control unit 51-2 detects the current information by the main control unit 80.

Fig. 4 shows a peak power demand management device (peak state mode, second embodiment) using a single-phase two-wire bandwidth control method. 4, the first, second, and third single-phase loads 51, 51-1, which are detected through the first, second, and third load stage current sensors 32, 32-1, and 32-2 are described. 51-2), when the power of a specific load exceeds the peak power, the first relay 20 moves from the contact A to the contact B at the specified load, and at the same time, The single-phase switch is turned off.

In addition, when the power stage power exceeds the peak power PH through the power stage current sensor 33, the most current flows among the first, second and third single phase loads 51, 51-1, 51-2. At a specific load, the first relay 20 moves from contact A to contact B, and at the same time, the single-phase switch of the specified load is turned off. Even in the above state, when the power stage power exceeds the peak power PH through the power stage current sensor 33, the first relay 20 is A at a specific load through which the most current flows among the remaining single phase loads. It moves from the contact to the contact B, and at the same time, the single-phase switch of the specific load is turned off.

In this case, the specific load is connected to the main control unit 80 and the demand management devices 90, 90-1, 90-2 using the bandwidth control method, so that the reference current is the current upper limit control resistor 18. It is set to the resistance value of.

At the same time, when the total power stage power becomes less than the peak power PH and gradually decreases to reach the reference power Pref, the first, second, and third single phase loads 51, 51-1, 51-2 Demand management device (90,90-1,90-2) by turning on all single-phase switch unit (29, 29-1, 29-2), and at the same time using the first, second, third bandwidth control method All of the first relay 20 is characterized in that the movement from the contact B to the contact A.

Therefore, the peak power demand management apparatus using the bandwidth control method in the present invention operates as follows.

(1) When peak power (PH) is reached in a demand management device using a specific bandwidth control method, the first relay 20 moves from contact A to contact B, and a switch unit connected to a specific load is connected. On to off.

(2) When the reference power (Pref) is reached in the demand management device using a specific bandwidth control method, the first relay 20 moves from the B contact to the A contact, and the switch unit connected to the specific load is connected. It turns on from off.

(3) Since power is controlled based on the state of (1) and (2), power can be managed in a range of band widths.

For reference, since the voltage of the power supply is generally constant, the upper limit of the current set by the current upper limit control resistor 18 in the demand management apparatus 90, 90-1, 90-2 using the bandwidth control method is equal to Since it is the same as the upper limit of the power set by the load (the product of voltage and current), it performs substantially the same function as controlling the peak power. Also,

In the second embodiment of FIGS. 3 and 4, when the peak power PH is reached, the first relay 20 moves from contact A to contact B, and the switch connected to a specific load is turned off from on. When the reference power Pref is reached, the first relay 20 moves from the B contact to the A contact, and the switch connected to the specific load is turned on from off.

In addition, since the first relay 20 is moved from the contact A to the contact B, the main control unit 20 has the biggest technical feature that the value of the current upper limit control resistor 18 is input.

Fig. 5 shows a peak power demand management device (steady state mode, first embodiment) using a three-phase three-wire bandwidth control method. 5, the first line 24 and the second line connecting the main controller 80 and the first, second, and third load stage current sensors 32, 32-1, and 32-2. 25) the band width control method proposed in the present invention between the cut contacts (X, X ') of the first line 24 and the cut contacts (Y, Y') of the second line 25 Inserting the demand management device (90, 90-1, 90-2) is a technical feature of the present invention. The demand management device (90, 90-1, 90-2) using the bandwidth control method is simply two relays of the first relay 20, the second relay 21 and the current upper limit control resistor (18). And a relay driving IC 22 for controlling the first and second relays 20 and 21, a relay controller 23, a main controller 80, and a communication unit 26 for connecting external communication with the main controller 80. It is characterized by the technical features.

The biggest advantage of the peak power demand management device using the three-phase three-wire bandwidth control method of Figure 5 is, first of all, the installation of the demand management device (90, 90-1, 90-2) using the bandwidth control method And there is an advantage that the removal is very easy. That is, the first line 24 and the second line 25 connecting the main controller 80 and the first, second, and third load stage current sensors 32, 32-1, and 32-2 are cut, and the band Demand management device (90, 90-1, 90-2) using the width control method is easy to install and dismantle, because it is a very simple structure, the price is also very affordable.

Therefore, the peak power consumed by the first, second, and third three-phase three-wire loads 52, 52-1, and 52-2 can be managed very efficiently, and the power can be managed in the range of the band width. The biggest feature is that it can effectively manage peak power and save energy.

Referring to the detailed operation of FIG. 5, the first relay 20 is a contact point A, and the second relay 21 is technically connected to a contact point A. It is a technical feature that it is normally connected to the three load stage current sensors 32, 32-1, 32-2, and is specified among the first, second, and third three-phase three-wire loads 52, 52-1, 52-2. (Specific) When the load is less than the peak power, the power supply stage power is less than the peak power, and all three-phase three-wire switch units 30, 30-1, and 30-2 are turned on. to be.

When the specific load is less than the peak power, the first, second and third three-phase three-wire loads 52, 52 through the first, second and third load stage current sensors 32, 32-1 and 32-2. It is a technical feature that the current control unit 80 detects current information of -1, 52-2.

Fig. 6 shows a peak power demand management device (peak state mode, first embodiment) using a three-phase three-wire bandwidth control method. 6, the first, second, and third three-phase three-wire loads 52 and 52 detected through the first, second, and third load stage current sensors 32, 32-1, and 32-2. When the power of a specific load exceeds the peak power among -1,52-2), at the specific load, the first relay 20 moves from the contact A to the contact B, and the second relay ( 21 is connected to contact A, and at the same time, the single-phase switch of the specific load is turned off.

In addition, when the power stage power exceeds the peak power PH through the power stage current sensor 33, the most among the first, second and third three-phase three-wire loads 52, 52-1, 52-2. In a specific load through which current flows, the first relay 20 moves from contact A to contact B, and the second relay 21 is connected to contact A, and at the same time a three-phase three-wire switch of the specified load. The part is turned off. Even in the above state, when the power stage power exceeds the peak power PH through the power stage current sensor 33, the first relay 20 is at a specific load through which the most current flows among the remaining three-phase loads. Moving from contact A to contact B, the second relay 21 is connected to contact A, and at the same time, the three-phase three-wire switch unit of a specific load is turned off.

In this case, the specific load is connected to the main control unit 80 and the demand management devices 90, 90-1, 90-2 using the bandwidth control method, so that the reference current is the current upper limit control resistor 18. It is set to the resistance value of.

At the same time, when the overall power stage power becomes less than the peak power PH and gradually decreases to reach the reference power Pref, the first, second, and three phase three-wire loads 52, 52-1, 52- Turn on all three-phase three-wire switch units 30, 30-1, and 30-2 of 2), and at the same time, a demand management device using the first, second, and third bandwidth control methods (90,90-). All of the first relay 20 of 1,90-2 is characterized by moving from the contact B to the contact A.

Therefore, the peak power demand management apparatus using the bandwidth control method in the present invention operates as follows.

(1) When peak power (PH) is reached in a demand management device using a specific bandwidth control method, the first relay 20 moves from contact A to contact B, and a switch unit connected to a specific load is connected. On to off.

(2) When the reference power (Pref) is reached in the demand management device using a specific bandwidth control method, the first relay 20 moves from the B contact to the A contact, and the switch unit connected to the specific load is connected. It turns on from off.

(3) Since power is controlled based on the state of (1) and (2), power can be managed in a range of band widths.

For reference, since the voltage of the power supply is generally constant, the upper limit of the current set by the current upper limit control resistor 18 in the demand management apparatus 90, 90-1, 90-2 using the bandwidth control method is equal to Since it is the same as the upper limit of the power set by the load (the product of voltage and current), it performs substantially the same function as controlling the peak power. Also,

In the first embodiment of FIGS. 5 and 6, when the peak power PH is reached, the first relay 20 moves from contact A to contact B, and the switch connected to a specific load is turned off from on. When the reference power Pref is reached, the first relay 20 moves from the B contact to the A contact, and the switch connected to the specific load is turned on from off.

In addition, the first relay 20 is moved from the contact A to the contact B, and at the same time, when the second relay 21 is connected to the contact A, the main control unit 20 inputs a current upper limit control resistor 18 value. When the second relay 21 is connected to the contact A, the main controller 20 is substantially the same as that of the infinite resistance value is input, and the switch unit connected to the specific load maintains the off state. The biggest technical feature.

Fig. 7 shows a peak power demand management device (steady state mode, second embodiment) using a three-phase three-wire bandwidth control method. 7, the first line 24 and the second line connecting the main controller 80 and the first, second, and third load stage current sensors 32, 32-1, and 32-2. 25) the band width control method proposed in the present invention between the cut contacts (X, X ') of the first line 24 and the cut contacts (Y, Y') of the second line 25 Inserting the demand management device (90, 90-1, 90-2) is a technical feature of the present invention. The demand management apparatus 90, 90-1, 90-2 using the bandwidth control method simply relays the first relay 20, the current upper limit control resistor 18, and the first relay 20. The driving IC 22 and the relay controller 23 and the main control unit 80, the main control unit 80 and the communication unit 26 for connecting the external communication is characterized by a technical feature.

The biggest advantage of the peak power demand management device using the three-phase three-wire bandwidth control method of Figure 7 above, installation of the demand management device (90, 90-1, 90-2) using the bandwidth control method And there is an advantage that the removal is very easy. That is, the first line 24 and the second line 25 connecting the main controller 80 and the first, second, and third load stage current sensors 32, 32-1, and 32-2 are cut, and the band Demand management device (90, 90-1, 90-2) using the width control method is easy to install and dismantle, because it is a very simple structure, the price is also very affordable.

Therefore, the peak power consumed by the first, second, and third three-phase three-wire loads 52, 52-1, and 52-2 can be managed very efficiently, and the power can be managed in the range of the band width. The biggest feature is that it can effectively manage peak power and save energy.

Referring to the detailed operation of FIG. 7, if the first relay 20 is the contact A, the main controller 80 may be connected to the first, second, and third load stage current sensors 32, 32-1, and 32-2. It is a technical feature that the connection is normally performed, and among the first, second and third three-phase three-wire loads 52, 52-1 and 52-2, the specific load is less than the peak power, and the power supply power is less than the peak power. In this case, all three-phase three-wire switch units 30, 30-1, and 30-2 are turned on.

When the specific load is less than the peak power, the first, second and third three-phase three-wire loads 52, 52 through the first, second and third load stage current sensors 32, 32-1 and 32-2. It is a technical feature that the current control unit 80 detects current information of -1, 52-2.

Fig. 8 shows a peak power demand management device (peak state mode, second embodiment) using a three-phase three-wire bandwidth control method. 8, the first, second and third three-phase three-wire loads 52 and 52 detected through the first, second and third load stage current sensors 32, 32-1 and 32-2. When the power of a specific load exceeds the peak power among -1, 52-2), at the specific load, the first relay 20 moves from the contact A to the contact B, and at the same time, ) The single-phase switch of the load is turned off.

In addition, when the power stage power exceeds the peak power PH through the power stage current sensor 33, the most among the first, second and third three-phase three-wire loads 52, 52-1, 52-2. The first relay 20 moves from contact A to contact B at a specific load through which current flows, and at the same time, the three-phase three-wire switch unit of the specified load is turned off. Even in the above state, when the power stage power exceeds the peak power PH through the power stage current sensor 33, the first relay 20 is at a specific load through which the most current flows among the remaining three-phase loads. The three-phase three-wire switch unit of a specific load is turned off at the same time as it moves from the contact A to the contact B.

In this case, the specific load is connected to the main control unit 80 and the demand management devices 90, 90-1, 90-2 using the bandwidth control method, so that the reference current is the current upper limit control resistor 18. It is set to the resistance value of.

At the same time, when the overall power stage power becomes less than the peak power PH and gradually decreases to reach the reference power Pref, the first, second, and three phase three-wire loads 52, 52-1, 52- Turn on all three-phase three-wire switch units 30, 30-1, and 30-2 of 2), and at the same time, a demand management device using the first, second, and third bandwidth control methods (90,90-). All of the first relay 20 of 1,90-2 is characterized by moving from the contact B to the contact A.

Therefore, the peak power demand management apparatus using the bandwidth control method in the present invention operates as follows.

(1) When peak power (PH) is reached in a demand management device using a specific bandwidth control method, the first relay 20 moves from contact A to contact B, and a switch unit connected to a specific load is connected. On to off.

(2) When the reference power (Pref) is reached in the demand management device using a specific bandwidth control method, the first relay 20 moves from the B contact to the A contact, and the switch unit connected to the specific load is connected. It turns on from off.

(3) Since power is controlled based on the state of (1) and (2), power can be managed in a range of band widths.

For reference, since the voltage of the power supply is generally constant, the upper limit of the current set by the current upper limit control resistor 18 in the demand management apparatus 90, 90-1, 90-2 using the bandwidth control method is equal to Since it is the same as the upper limit of the power set by the load (the product of voltage and current), it performs substantially the same function as controlling the peak power. Also,

In the second embodiment of FIGS. 7 and 8, when the peak power PH is reached, the first relay 20 moves from contact A to contact B, and the switch unit connected to the specific load is turned off on. When the reference power Pref is reached, the first relay 20 moves from the B contact to the A contact, and the switch connected to the specific load is turned on from off.

In addition, since the first relay 20 is moved from the contact A to the contact B, the main control unit 20 has the biggest technical feature that the value of the current upper limit control resistor 18 is input.

Fig. 9 shows a peak power demand management device (steady state mode, first embodiment) using a three-phase four-wire bandwidth control method. 9, the first line 24 and the second line connecting the main controller 80 and the first, second, and third load stage current sensors 32, 32-1, and 32-2 are provided. 25) the band width control method proposed in the present invention between the cut contacts (X, X ') of the first line 24 and the cut contacts (Y, Y') of the second line 25 Inserting the demand management device (90, 90-1, 90-2) is a technical feature of the present invention. The demand management device (90, 90-1, 90-2) using the bandwidth control method is simply two relays of the first relay 20, the second relay 21 and the current upper limit control resistor (18). And a relay driving IC 22 for controlling the first and second relays 20 and 21, a relay controller 23, a main controller 80, and a communication unit 26 for connecting external communication with the main controller 80. It is characterized by the technical features.

The biggest advantage of the peak power demand management device using the three-phase four-wire bandwidth control method of Figure 9 is, first of all, the installation of the demand management device (90, 90-1, 90-2) using the bandwidth control method And there is an advantage that the removal is very easy. That is, the first line 24 and the second line 25 connecting the main controller 80 and the first, second, and third load stage current sensors 32, 32-1, and 32-2 are cut, and the band Demand management device (90, 90-1, 90-2) using the width control method is easy to install and dismantle, because it is a very simple structure, the price is also very affordable.

Therefore, the peak power consumed by the first, second, and third three-phase four-wire loads 53, 53-1, and 53-2 can be managed very efficiently, and the power can be managed in a range of band widths. The biggest feature is that it can effectively manage peak power and save energy.

Referring to the detailed operation of FIG. 9, the first relay 20 is a contact point A, and the second relay 21 is technically connected to a contact point A. 3 It is a technical feature that it is normally connected to the load stage current sensor (32,32-1,32-2), specific among the first, second, third three-phase four-wire load (53, 53-1, 53-2) (Specific) When the load is less than the peak power, the power supply stage power is less than the peak power, and all three-phase four-wire switch units 31, 31-1, and 31-2 are turned on. to be.

When the specified load is less than the peak power, the first, second and third three-phase four-wire loads 53 and 53 through the first, second and third load stage current sensors 32, 32-1 and 32-2. It is a technical feature that the current control unit 80 detects current information of -1, 53-2.

Fig. 10 shows a peak power demand management device (peak state mode, first embodiment) using a three-phase four-wire bandwidth control method. 10, the first, second and third three-phase four-wire loads 53 and 53 detected through the first, second and third load stage current sensors 32, 32-1 and 32-2. When the power of a specific load exceeds the peak power among -1,53-2), at the specific load, the first relay 20 moves from the contact A to the contact B, and the second relay ( 21 is connected to contact A, and at the same time, the single-phase switch of the specific load is turned off.

In addition, when the power stage power exceeds the peak power PH through the power stage current sensor 33, the most among the first, second and third three-phase four-wire loads 53, 53-1, 53-2. In a specific load through which current flows, the first relay 20 moves from contact A to contact B, and the second relay 21 is connected to contact A, and at the same time, a three-phase four-wire switch of the specified load. The part is turned off. Even in the above state, when the power stage power exceeds the peak power PH through the power stage current sensor 33, the first relay 20 is at a specific load through which the most current flows among the remaining three-phase loads. Moving from contact A to contact B, the second relay 21 is connected to contact A, and at the same time, the three-phase four-wire switch unit of a specific load is turned off.

In this case, the specific load is connected to the main control unit 80 and the demand management devices 90, 90-1, 90-2 using the bandwidth control method, so that the reference current is the current upper limit control resistor 18. It is set to the resistance value of.

At the same time, when the total power stage power becomes less than the peak power PH and gradually decreases to reach the reference power Pref, the first, second, and three phase four-wire loads 53, 53-1, 53- Turn on all three-phase four-wire switch units 31, 31-1, and 31-2 of 2), and at the same time, a demand management device using the first, second, and third bandwidth control methods (90, 90-). All of the first relay 20 of 1,90-2 is characterized by moving from the contact B to the contact A.

Therefore, the peak power demand management apparatus using the bandwidth control method in the present invention operates as follows.

(1) When peak power (PH) is reached in a demand management device using a specific bandwidth control method, the first relay 20 moves from contact A to contact B, and a switch unit connected to a specific load is connected. On to off.

(2) When the reference power (Pref) is reached in the demand management device using a specific bandwidth control method, the first relay 20 moves from the B contact to the A contact, and the switch unit connected to the specific load is connected. It turns on from off.

(3) Since power is controlled based on the state of (1) and (2), power can be managed in a range of band widths.

For reference, since the voltage of the power supply is generally constant, the upper limit of the current set by the current upper limit control resistor 18 in the demand management apparatus 90, 90-1, 90-2 using the bandwidth control method is equal to Since it is the same as the upper limit of the power set by the load (the product of voltage and current), it performs substantially the same function as controlling the peak power. Also,

In the first embodiment of FIGS. 9 and 10, when the peak power PH is reached, the first relay 20 moves from the A contact to the B contact, and the switch connected to the specific load is turned off on. When the reference power Pref is reached, the first relay 20 moves from the B contact to the A contact, and the switch connected to the specific load is turned on from off.

In addition, the first relay 20 is moved from the contact A to the contact B, and at the same time, when the second relay 21 is connected to the contact A, the main control unit 20 inputs a current upper limit control resistor 18 value. When the second relay 21 is connected to the contact A, the main controller 20 is substantially the same as that of the infinite resistance value is input, and the switch unit connected to the specific load maintains the off state. The biggest technical feature.

Fig. 11 shows a peak power demand management device (steady state mode, second embodiment) using a three-phase four-wire bandwidth control method. 11, the first line 24 and the second line connecting the main controller 80 and the first, second, and third load stage current sensors 32, 32-1, and 32-2. 25) the band width control method proposed in the present invention between the cut contacts (X, X ') of the first line 24 and the cut contacts (Y, Y') of the second line 25 Inserting the demand management device (90, 90-1, 90-2) is a technical feature of the present invention. The demand management apparatus 90, 90-1, 90-2 using the bandwidth control method simply relays the first relay 20, the current upper limit control resistor 18, and the first relay 20. The driving IC 22 and the relay controller 23 and the main control unit 80, the main control unit 80 and the communication unit 26 for connecting the external communication is characterized by a technical feature.

The biggest advantage of the peak power demand management device using the three-phase four-wire bandwidth control method of FIG. 11 is, among other things, the installation of the demand management devices 90, 90-1, 90-2 using the bandwidth control method. And there is an advantage that the removal is very easy. That is, the first line 24 and the second line 25 connecting the main controller 80 and the first, second, and third load stage current sensors 32, 32-1, and 32-2 are cut, and the band Demand management device (90, 90-1, 90-2) using the width control method is easy to install and dismantle, because it is a very simple structure, the price is also very affordable.

Therefore, the peak power consumed by the first, second, and third three-phase four-wire loads 53, 53-1, and 53-2 can be managed very efficiently, and the power can be managed in a range of band widths. The biggest feature is that it can effectively manage peak power and save energy.

Referring to the detailed operation of FIG. 11, when the first relay 20 is a contact A, the main controller 80 may be connected to the first, second, and third load stage current sensors 32, 32-1, and 32-2. It is a technical feature that the connection is normally performed, and among the first, second and third three-phase four-wire loads 53, 53-1 and 53-2, the specific load is less than the peak power, and the power supply power is less than the peak power. In this case, all three-phase four-wire switch units 31, 31-1, and 31-2 are turned on.

When the specified load is less than the peak power, the first, second and third three-phase four-wire loads 53 and 53 through the first, second and third load stage current sensors 32, 32-1 and 32-2. It is a technical feature that the current control unit 80 detects current information of -1, 53-2.

Fig. 12 shows a peak power demand management device (peak state mode, second embodiment) using a three-phase four-wire bandwidth control method. 12, the first, second and third three-phase four-wire loads 53 and 53 detected through the first, second and third load stage current sensors 32, 32-1 and 32-2 are described. When the power of a specific load exceeds the peak power among -1,53-2), at the specific load, the first relay 20 moves from the contact A to the contact B, and at the same time, ) The single-phase switch of the load is turned off.

In addition, when the power stage power exceeds the peak power PH through the power stage current sensor 33, the most among the first, second and third three-phase four-wire loads 53, 53-1, 53-2. The first relay 20 moves from contact A to contact B at a specific load through which current flows, and at the same time, the three-phase four-wire switch unit of the specified load is turned off. Even in the above state, when the power stage power exceeds the peak power PH through the power stage current sensor 33, the first relay 20 is at a specific load through which the most current flows among the remaining three-phase loads. The three-phase four-wire switch of a specific load is turned off at the same time as it moves from contact A to contact B.

In this case, the specific load is connected to the main control unit 80 and the demand management devices 90, 90-1, 90-2 using the bandwidth control method, so that the reference current is the current upper limit control resistor 18. It is set to the resistance value of.

At the same time, when the total power stage power becomes less than the peak power PH and gradually decreases to reach the reference power Pref, the first, second, and three phase four-wire loads 53, 53-1, 53- Turn on all three-phase four-wire switch units 31, 31-1, and 31-2 of 2), and at the same time, a demand management device using the first, second, and third bandwidth control methods (90, 90-). All of the first relay 20 of 1,90-2 is characterized by moving from the contact B to the contact A.

Therefore, the peak power demand management apparatus using the bandwidth control method in the present invention operates as follows.

(1) When peak power (PH) is reached in a demand management device using a specific bandwidth control method, the first relay 20 moves from contact A to contact B, and a switch unit connected to a specific load is connected. On to off.

(2) When the reference power (Pref) is reached in the demand management device using a specific bandwidth control method, the first relay 20 moves from the B contact to the A contact, and the switch unit connected to the specific load is connected. It turns on from off.

(3) Since power is controlled based on the state of (1) and (2), power can be managed in a range of band widths.

For reference, since the voltage of the power supply is generally constant, the upper limit of the current set by the current upper limit control resistor 18 in the demand management apparatus 90, 90-1, 90-2 using the bandwidth control method is equal to Since it is the same as the upper limit of the power set by the load (the product of voltage and current), it performs substantially the same function as controlling the peak power. Also,

In the second embodiment of FIGS. 11 and 12, when the peak power PH is reached, the first relay 20 moves from contact A to contact B, and the switch unit connected to a specific load is turned off on. When the reference power Pref is reached, the first relay 20 moves from the B contact to the A contact, and the switch connected to the specific load is turned on from off.

In addition, since the first relay 20 is moved from the contact A to the contact B, the main control unit 20 has the biggest technical feature that the value of the current upper limit control resistor 18 is input.

FIG. 13 shows a detailed circuit diagram of the peak power demand management device using the single-phase two-wire bandwidth control method, and FIG. 14 shows a detailed circuit diagram of the peak power demand management device using the three-phase three-wire bandwidth control method. 15 shows a detailed circuit diagram of the peak power demand management device using a three-phase four-wire bandwidth control method.

13 to 15 show a detailed circuit diagram. Here, the first power source Vcc1 is 5 [V] to 12 [V], and the first and second resistors 37 and 47 and the first and second LEDs 38 and 48 are the first and second relays 20 and 21. It is a technical feature to indicate whether or not to operate.

In the present invention, a Panasonic DS2Y relay is used as an element of the first and second relays 20 and 21, but all relays in which two switches operate in the A contact or the B contact at the same time are applied in the present invention. This is possible.

Fig. 16 shows a state detection circuit diagram of a relay in single-phase two-wire, Fig. 17 shows a state detection circuit diagram of a three-phase three-wire relay, and Fig. 18 shows a state detection circuit diagram of a three-phase four-wire relay.

16 to 18, the detection of whether the first relay 20 is an A contact or a B contact is performed through the first and second photocouplers 111 and 211. Detection of whether the contact point A or B of the first switch unit 12 of the first relay is detected by the first photocoupler 111 through the sixteenth resistor 107 and the eleventh variable resistor 108. . In addition, detection of whether the contact point A or B of the second switch unit 13 of the first relay is detected by the second photocoupler 211 through the 26th resistor 207 and the 21st variable resistor 208. The detected information is transmitted to the main controller 80. Accordingly, the main controller 80 receives the reference power Pref from the center through the communication unit 26, and whether the first relay 20 is the contact A or the contact B through the first and second photocouplers 111 and 211. The control is characterized in that the power is controlled by the band width (Band Width) between the peak power (PH) and the reference power (Pref) at the same time.

19 shows a peak power control diagram of a power supply stage.

The upper limit value of the peak power PH may be varied by the variable upper limit control resistor 18-1 of the current upper limit control resistor 18. The reference power Pref may be controlled by the main controller 80. It is also possible to input in advance, and the technical features that can be collectively transmitted through the communication unit 26.

In the present invention, the peak power demand management apparatus, the first, second, third single-phase load (51, 51-1, 51-2); First, second and third single-phase switch units 29, 29-1 and 29-2 for supplying power to the first, second and third single-phase loads 51, 51-1 and 51-2; A power stage current sensor 33 for detecting current of the single-phase AC power source 27; First, second, and third load stage current sensors (32,32-1,32-2) for detecting current in the first, second, and third single-phase loads (51, 51-1, 51-2); First, second and third current amplifiers 11, 11-1 and 11-2 for amplifying currents of the first, second and third load stage current sensors 32, 32-1 and 32-2; First and second lines 24 and 25 for connecting the first, second and third current amplifiers 11, 11-1, 11-2 and the main controller 80; A first relay (20) which determines whether or not a connection between the cut-off contact (X, X ') of the first line (24) and the cut-off contact (Y, Y') of the second line (25); When the first relay 20 is a contact A, current information of the first, second and third load stage current sensors 32, 32-1, and 32-2 is transmitted to the main controller 80. When the first relay 20 is a contact B, the first relay 20 is connected to the current upper limit control resistor 18 to convert the power of the first, second, and third single-phase loads 51, 51-1, and 51-2 into a band width. We propose a peak power demand management device characterized in that the control by).

In the present invention, the peak power demand management apparatus, the first, second, third three-phase three-wire load (52, 52-1, 52-2); First, second, third three-phase three-wire switch unit for determining the supply of power to the first, second, third three-phase three-wire load (52, 52-1, 52-2) (30, 30-1, 30) -2); A power stage current sensor 33 for detecting current of the three-phase three-wire AC power source 27-1; First, second, and third load stage current sensors (32,32-1,32-2) for detecting current in the first, second, and third three-phase three-wire loads (52, 52-1, 52-2); First, second and third current amplifiers 11, 11-1 and 11-2 for amplifying currents of the first, second and third load stage current sensors 32, 32-1 and 32-2; First and second lines 24 and 25 for connecting the first, second and third current amplifiers 11, 11-1, 11-2 and the main controller 80; A first relay (20) which determines whether or not a connection between the cut-off contact (X, X ') of the first line (24) and the cut-off contact (Y, Y') of the second line (25); When the first relay 20 is a contact A, current information of the first, second and third load stage current sensors 32, 32-1, and 32-2 is transmitted to the main controller 80. When the first relay 20 is a contact B, the first relay 20 is connected to the current upper limit control resistor 18 so that the power of the first, second and third three-phase three-wire loads 52, 52-1, and 52-2 is reduced. The present invention proposes a peak power demand management apparatus characterized by controlling by (Band Width).

Finally, in the present invention, the peak power demand management device, the first, second, third three-phase four-wire load (53, 53-1, 53-2); First, second and third three-phase four-wire switch units 31, 31-1 and 31 for determining power supply to the first, second and third three-phase four-wire loads 53, 53-1 and 53-2. -2); A power stage current sensor 33 for detecting current of the three-phase four-wire AC power source 27-2; First, second, and third load stage current sensors (32,32-1,32-2) for detecting current in the first, second, and third three-phase three-wire loads (52, 52-1, 52-2); First, second and third current amplifiers 11, 11-1 and 11-2 for amplifying currents of the first, second and third load stage current sensors 32, 32-1 and 32-2; First and second lines 24 and 25 for connecting the first, second and third current amplifiers 11, 11-1, 11-2 and the main controller 80; A first relay (20) which determines whether or not a connection between the cut-off contact (X, X ') of the first line (24) and the cut-off contact (Y, Y') of the second line (25); When the first relay 20 is a contact A, current information of the first, second and third load stage current sensors 32, 32-1, and 32-2 is transmitted to the main controller 80. When the first relay 20 is a contact B, the first relay 20 is connected to the current upper limit control resistor 18 so that the power of the first, second and third three-phase four-wire loads 53, 53-1, 53-2 is reduced. The present invention proposes a peak power demand management apparatus characterized by controlling by (Band Width).

The present invention can be applied to the peak power demand management device using a bandwidth control method by a person skilled in the art by various modifications, the technical scope that can be easily modified also belongs to the scope of the patent You will have to admit that.

10: main stage current amplifier
11: first current amplifier
11-1: second current amplifier
11-2: third current amplifier
12: first switch of the first relay
13: second switch unit of the first relay
14: first relay control electromagnet
15: first switch of the second relay
16: second switch unit of the second relay
17: electromagnet for second relay control
18: Current upper limit control resistor
18-1: Variable resistor for current upper limit control
18-2: Fixed resistance for current upper limit control
20: first relay
21: second relay
22: relay drive IC
23: relay controller
24: first track
25: second track
26: communication unit
27: single phase AC power
27-1: three-phase three-wire AC power supply
27-2: 3-phase 4-wire AC power supply
29: first single-phase switch unit
29-1: second single-phase switch unit
29-2: third single-phase switch unit
30: first three-phase three-wire switch unit
30-1: Second three-phase three-wire switch unit
30-2: 3rd 3-phase 3-wire switch unit
31: First three-phase four-wire switch unit
31-1: Second three-phase four-wire switch unit
31-2: 3rd 3-phase 4-wire switch unit
32: first load current sensor
32-1: Second load stage current sensor
32-2: third load current sensor
33: power supply current sensor
35: first capacitor
36: first inductor
37: first resistance
38: first LED
45: second capacitor
46: second inductor
47: second resistance
48: second LED
51: first single-phase load
51-1: Second single-phase load
51-2: third single-phase load
52: first three-phase three-wire load
52-1: Second three-phase three-wire load
52-2: Third three-phase three-wire load
53: first three-phase four-wire load
53-1: Second three-phase four-wire load
53-2: 3rd 3 phase 4 wire load
80: main control unit
90: demand management device using the first bandwidth control method
90-1: Demand Management Device Using Second Bandwidth Control Method
90-2: Demand management device using third bandwidth control method
95: first relay operation detection unit
95-1: second relay operation detection unit
95-2: third relay operation detection unit
100: 1-1 relay operation detection unit
101: the eleventh capacitor
102: the eleventh resistance
103: 12th resistance
104: thirteenth resistance
105: 14th resistance
106: the fifteenth resistor
107th resistance
108: eleventh variable resistor
109: eleventh inductor
111: first photocoupler
112: 11th LED
200: 1-2 relay operation detection unit
201: 21st capacitor
202: resistance 21
203: 22nd Resistance
204: 23rd resistance
205: 24th Resistance
206: 25th resistance
207th resistance
208: Variable resistor 21
209: 21st inductor
211: second photo coupler
212: 21st LED
A: contact A of the 1st, 2nd relay
B: B contact of the 1st, 2nd relay
PH: Power Peak Reference Value
Pref: Power Reference Value
Vcc1: first power source (5 [V] to 12 [V])
Vcc2: second power source (2.5 [V] to 3.3 [V])
X, X ': Cut contact of the first line
Y, Y ': the cut contact of the second line

Claims (8)

In peak power demand management device,
First, second and third single phase loads 51, 51-1 and 51-2;
First, second and third single-phase switch units 29, 29-1 and 29-2 for supplying power to the first, second and third single-phase loads 51, 51-1 and 51-2;
A power stage current sensor 33 for detecting current of the single-phase AC power source 27;
First, second, and third load stage current sensors (32,32-1,32-2) for detecting current in the first, second, and third single-phase loads (51, 51-1, 51-2);
First, second and third current amplifiers 11, 11-1 and 11-2 for amplifying currents of the first, second and third load stage current sensors 32, 32-1 and 32-2;
First and second lines 24 and 25 for connecting the first, second and third current amplifiers 11, 11-1, 11-2 and the main controller 80;
A first relay (20) for determining whether a connection between the cut contacts (X, X ') of the first line (24) and the cut contacts (Y, Y') of the second line (25);
When the first relay 20 is a contact A, current information of the first, second and third load stage current sensors 32, 32-1, and 32-2 is transmitted to the main controller 80. When the first relay 20 is a contact B, the first relay 20 is connected to the current upper limit control resistor 18 to convert the power of the first, second, and third single-phase loads 51, 51-1, and 51-2 into a band width. Peak power demand management device characterized in that the control In peak power demand management device,
1, 2, 3 three-phase three-wire loads 52, 52-1, 52-2;
First, second, third three-phase three-wire switch unit for determining the supply of power to the first, second, third three-phase three-wire load (52, 52-1, 52-2) (30, 30-1, 30) -2);
A power stage current sensor 33 for detecting current of the three-phase three-wire AC power source 27-1;
First, second, and third load stage current sensors (32,32-1,32-2) for detecting current in the first, second, and third three-phase three-wire loads (52, 52-1, 52-2);
First, second and third current amplifiers 11, 11-1 and 11-2 for amplifying currents of the first, second and third load stage current sensors 32, 32-1 and 32-2;
First and second lines 24 and 25 for connecting the first, second and third current amplifiers 11, 11-1, 11-2 and the main controller 80;
A first relay (20) for determining whether a connection between the cut contacts (X, X ') of the first line (24) and the cut contacts (Y, Y') of the second line (25);
When the first relay 20 is a contact A, current information of the first, second and third load stage current sensors 32, 32-1, and 32-2 is transmitted to the main controller 80. When the first relay 20 is a contact B, the first relay 20 is connected to the current upper limit control resistor 18 so that the power of the first, second and third three-phase three-wire loads 52, 52-1, and 52-2 is reduced. Peak power demand management device characterized in that the control by (Band Width) In peak power demand management device,
1, 2, 3 three-phase four-wire loads 53, 53-1, 53-2;
First, second and third three-phase four-wire switch units 31, 31-1 and 31 for determining power supply to the first, second and third three-phase four-wire loads 53, 53-1 and 53-2. -2);
A power stage current sensor 33 for detecting current of the three-phase four-wire AC power source 27-2;
First, second, and third load stage current sensors (32,32-1,32-2) for detecting current in the first, second, and third three-phase four-wire loads (53, 53-1, 53-2);
First, second and third current amplifiers 11, 11-1 and 11-2 for amplifying currents of the first, second and third load stage current sensors 32, 32-1 and 32-2;
First and second lines 24 and 25 for connecting the first, second and third current amplifiers 11, 11-1, 11-2 and the main controller 80;
A first relay (20) for determining whether a connection between the cut contacts (X, X ') of the first line (24) and the cut contacts (Y, Y') of the second line (25);
When the first relay 20 is a contact A, current information of the first, second and third load stage current sensors 32, 32-1, and 32-2 is transmitted to the main controller 80. When the first relay 20 is a contact B, the first relay 20 is connected to the current upper limit control resistor 18 so that the power of the first, second and third three-phase four-wire loads 53, 53-1, 53-2 is reduced. Peak power demand management device characterized in that the control by (Band Width) The method according to any one of claims 1 to 3,
The first relay 20 is a peak power demand management device, characterized in that the two switches in one relay at the same time operating as a contact A or B contact relay The method according to any one of claims 1 to 3,
The detection of whether the contact point A or the contact point B of the first switch unit 12 of the first relay is detected by the first photocoupler 111, and whether the contact point A of the second switch unit 13 of the first relay is detected. Or the peak power demand management device characterized in that the detection of the contact B is detected by the second photocoupler 211 and the detected information is transmitted to the main control unit 80. In peak power demand management device,
First, second and third single phase loads 51, 51-1 and 51-2;
First, second and third single-phase switch units 29, 29-1 and 29-2 for supplying power to the first, second and third single-phase loads 51, 51-1 and 51-2;
A power stage current sensor 33 for detecting current of the single-phase AC power source 27;
First, second, and third load stage current sensors (32,32-1,32-2) for detecting current in the first, second, and third single-phase loads (51, 51-1, 51-2);
First, second and third current amplifiers 11, 11-1 and 11-2 for amplifying currents of the first, second and third load stage current sensors 32, 32-1 and 32-2;
First and second lines 24 and 25 for connecting the first, second and third current amplifiers 11, 11-1, 11-2 and the main controller 80;
A first relay (20) for determining whether a connection between the cut contacts (X, X ') of the first line (24) and the cut contacts (Y, Y') of the second line (25);
A second relay 21 determining whether to connect with the current upper limit control resistor 18;
The first relay 20 is composed of a first switch portion 12 of the first relay and a second switch portion 13 of the first relay;
The second relay (21) is composed of a first switch section (15) of a second relay and a second switch section (16) of a second relay;
A first relay control electromagnet 14 for controlling the first switch unit 12 of the first relay of the first relay 20 and the second switch unit 13 of the first relay to an A contact or a B contact;
A second relay control electromagnet 17 for controlling the first switch unit 15 of the second relay of the second relay 21 and the second switch unit 16 of the second relay to contact A or contact B;
A relay driving IC 22 for driving the first and second relays 20 and 21;
Peak power demand management device, characterized in that the reference power (Pref) is set (set) from the communication unit 26 is controlled by the band width (Band Width) between the peak power (PH) and the reference power (Pref) In peak power demand management device,
First, second and third single phase loads 51, 51-1 and 51-2;
First, second and third single-phase switch units 29, 29-1 and 29-2 for supplying power to the first, second and third single-phase loads 51, 51-1 and 51-2;
A power stage current sensor 33 for detecting current of the single-phase AC power source 27;
First, second, and third load stage current sensors (32,32-1,32-2) for detecting current in the first, second, and third single-phase loads (51, 51-1, 51-2);
First, second and third current amplifiers 11, 11-1 and 11-2 for amplifying currents of the first, second and third load stage current sensors 32, 32-1 and 32-2;
First and second lines 24 and 25 for connecting the first, second and third current amplifiers 11, 11-1, 11-2 and the main controller 80;
A first relay (20) for determining whether a connection between the cut contacts (X, X ') of the first line (24) and the cut contacts (Y, Y') of the second line (25);
A second relay 21 determining whether to connect with the current upper limit control resistor 18;
The first relay 20 is composed of a first switch unit 12 of the first relay and a second switch unit 13 of the first relay, and the second relay 21 is a first switch of the second relay. Peak power demand management device, characterized in that the unit 15 and the second switch unit 16 of the second relay The method according to claim 6 or 7,
The detection of whether the contact point A or the contact point B of the first switch unit 12 of the first relay is detected by the first photocoupler 111, and whether the contact point A of the second switch unit 13 of the first relay is detected. Or the peak power demand management device characterized in that the detection of the contact B is detected by the second photocoupler 211 and the detected information is transmitted to the main control unit 80.

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