JP5050558B2 - Power supply system, power supply unit thereof, and power efficiency improvement method - Google Patents

Description

  The present invention relates to a power supply system, and more particularly to a power supply system that supplies output power to a common load such as an electric device by a plurality of power supply units (AC-DC converters or inverters), a power supply unit thereof, and a power efficiency improvement method.

  Various electric devices, electronic devices, and electronic application devices (hereinafter collectively referred to as “electric devices”) exhibit the functions intended by the electric devices, and thus operating power is supplied from the power supply unit. The power supply unit is generally an AC-DC converter or an inverter that receives a commercial power supply (AC power supply) and outputs a direct current (DC) voltage.

  In electrical equipment, especially IT equipment including computers, network (NW) communication equipment, etc., the load (power consumption) fluctuates according to the operating state, and as their functions (capacity) and capacity increase In general, related devices and peripheral devices are added sequentially, and the required maximum power consumption usually changes (increases). In addition, since these electrical devices are extremely close to daily work, inoperability due to power supply troubles can cause fatal damage to daily work. Therefore, the power supply unit of such an electric device has a redundant configuration with a plurality of power supply units, and can cope with switching even if a load (power consumption) fluctuates or a malfunction occurs in each power supply unit.

  In an N + M redundant configuration (N is the number of functional power supply units and M is the number of redundant power supply units), which is a redundant configuration when a large number of power supply units are used, if M is large, the redundancy increases, but one The load on the power supply unit will be reduced. Generally, the AC-DC conversion efficiency of the power supply unit varies depending on the load. It is well known to those skilled in the art that when the load is sufficiently light, the conversion efficiency is reduced, and most of the AC input power is wasted as loss (heat) during conversion.

  Such power supply systems for electric devices are disclosed in many documents. Multiple converters (inverters) are connected in parallel, and power conversion is performed with high conversion efficiency by determining and operating the number of inverters obtained by dividing the required power set for the load by the output power of the maximum conversion efficiency of each inverter. The power converter device which performs is disclosed (for example, refer to patent documents 1). In addition, when supplying the power of a plurality of processors that are in an operating state or a sleep state from a plurality of AC-DC power supplies connected in parallel, the number of AC-corresponding to the required power consumption according to the number of processors in the operating state. A composite computing device that determines a DC power source to prevent deterioration of power efficiency and a management method thereof are disclosed (for example, see Patent Document 2).

JP 2001-16859 A (page 3-4, FIG. 1) JP 2006-302059 A (page 9-10, FIG. 1)

  In the conventional power supply system as described above, the number of operating power supply units is selected so that each operating power supply unit does not exceed its rated output according to the load state (power consumption of the load). Is not always controlled to be the highest. In addition, in order to select and control the number of power supply units obtained by dividing the power consumption of the load by the output power of the maximum conversion efficiency of each power supply unit, it is necessary to use a predetermined power supply unit and The power supply unit cannot always be operated with the optimum conversion efficiency by the processing in the case where the number is fractional.

  The present invention has been made in view of the above-described problems of the prior art, and a main object of the present invention is to provide a power supply system, a power supply unit thereof, and a power efficiency improvement method capable of eliminating or reducing these problems.

  In order to solve the above-described problems and achieve the above-described object, the power supply system, the power supply unit, and the power efficiency improvement method of the present invention employ the following characteristic configuration.

(1) In a power supply system configured to selectively operate a plurality of power supply units, each of which converts an AC input into a DC output and is supplied to a common load.
Load detection means for monitoring and detecting power consumption of the load; and A power control unit including a selection means for selecting the power supply unit of
A power supply system for controlling the plurality of power supply units by the power supply control unit.
(2) The power supply unit includes a memory for storing load-to-conversion efficiency information of the power supply unit, and the information stored in the memory is configured to be accessible to the power supply control unit according to (1) Power system.
(3) The power supply unit has an N + M configuration (N and M are arbitrary positive integers), the N power supply units are always operated, and the M power supply units are operated according to the power consumption fluctuation of the load. The power supply system according to (1) or (2), wherein some of them are selected and used.
(4) In a power supply unit that converts AC input to DC output and supplies power to a common load in cooperation with one or more other power supply units,
A power supply unit including a memory for storing load-to-conversion efficiency information indicating a change characteristic of conversion efficiency with respect to a change in load, and configured to be able to access the load-to-conversion efficiency information from the outside.
(5) The power supply unit according to (4), further comprising output switching means for selectively turning ON / OFF the DC output by an external control signal.
(6) In a power efficiency method for efficiently supplying DC power from a plurality of power supply units each converting AC input to DC output to a load whose power consumption fluctuates,
Obtaining the load-to-conversion efficiency information of the power supply unit in advance;
Monitoring and detecting power consumption of the load;
Determining the number of power supply units that maximize conversion efficiency in correspondence with the power consumption detected in the power consumption monitoring detection step;
And a step of ON / OFF controlling the power supply units so that the number of units obtained in the step is obtained.
(7) The power efficiency improvement method according to (6), wherein the load-to-conversion efficiency information of the power supply unit is stored in a memory of the power supply unit.
(8) The power efficiency method according to (6) or (7), wherein the power consumption of the load is obtained by accessing the load from a power control unit at the time of startup.
(9) The power efficiency method according to (6) or (7), wherein the power consumption of the load is detected by monitoring the load every predetermined time.

  According to the power supply system, the power supply unit, and the power supply efficiency improvement system of the present invention, the following practical specific effects can be obtained. First, the conversion efficiency of each power supply unit is increased, so that loss (or heat generation) is suppressed, and the cooling cost of an electric device or the like that is a load driven thereby is reduced. In addition, the cost of consumed power can be reduced.

  Furthermore, since the load-to-conversion efficiency information is stored in the internal memory of the power supply unit when the load of the power supply unit (not only the output power at which the maximum conversion efficiency is obtained) varies from 0% to 100%, for example, The control unit can access the power supply unit and acquire this information, and can change or replace the power supply unit as necessary, which greatly improves the degree of freedom in system design.

  Next, a configuration and an operation of a preferred embodiment of a power supply system, a power supply unit thereof, and a power efficiency improvement method according to the present invention will be described in detail with reference to the accompanying drawings.

  First, a description will be given with reference to FIG. FIG. 1 is a system configuration diagram showing a configuration of a preferred embodiment of a power supply system according to the present invention. A power supply system 10 shown in FIG. 1 includes an AC input power 1, a DC output power 2, a plurality (N + M) power supply units 3 and a power supply control unit 4.

  As will be described later, each of the plurality of power supply units 3 has a built-in memory (not shown) and stores load-to-conversion efficiency information. That is, the AC-DC conversion efficiency characteristic when the load or output power is changed to, for example, 0% to 100% (maximum rated output) of the rated output is stored. The information stored in this memory is configured to be accessible from the outside.

  Here, the power supply unit 3 receives, for example, AC input power 1 supplied from a commercial power supply, and supplies an AC-DC converter (or a DC output power required by a load (not shown in FIG. 1)) (or Inverter). For example, N power supply units are always in operation, M power supply units are redundant power supplies, and support for an increase in backup or load when trouble occurs in any of the N power supply units Then, output power is supplied to the load. The power supply control unit 4 selects the number of operating power supply units 3 according to the state of the load 5 and the power supply unit 3 and controls the conversion efficiency so that it is always the highest.

  Next, FIG. 2 is a functional block diagram showing the configuration of the power supply system 10 according to the present invention shown in FIG. The plurality of power supply units 3 have an N + M redundant configuration in this specific embodiment, and are composed of N power supply units 31 and M redundant power supply units 32 configured to be connectable in parallel to the load 5. It is configured. The power control unit 4 is preferably composed of a CPU (Central Processing Unit), and includes an information reading means 41, a recording means 42, a power consumption monitoring (or detection) means 43, a power consumption calculation means 44 per unit, and an optimum conversion efficiency. A selection unit 45 and an ON / OFF control unit 46 of the power supply unit 3 are included.

  The plurality of power supply units 3 include storage means such as a semiconductor memory, for example, and store load versus conversion efficiency information of the power supply unit. In other words, information on conversion efficiency characteristics when the load (output power) is changed from, for example, 0% to 100% of the rated output is stored, and the power supply control unit 4 accesses the memory to access the memory of the power supply unit 3. The load-to-conversion efficiency information can be acquired or read. The load-to-conversion efficiency of the power supply unit 3 does not necessarily reach the maximum value at the rated output (maximum output) due to heat generation or the like. For example, the maximum value is at 85% of the rating, and the conversion efficiency decreases even if it exceeds or falls below that However, the conversion efficiency at 80% of the rating is higher than that at the rating of 90%. The load-to-conversion efficiency characteristics of the power supply unit 3 are determined by the configuration of the power supply unit 3 and the design of materials used, and the measured values are stored and stored in a memory such as a ROM (Read Only Memory).

  Hereinafter, the operation of the power supply system 10 of the present invention will be described with reference to the flowchart of FIG. 3 together with FIGS. First, the information reading means 41 of the power supply control unit 4 accesses the above-mentioned memory built in the power supply unit 3 to read the conversion efficiency information (that is, load versus conversion efficiency information) (step S1). Next, the conversion efficiency information read in step S1 is recorded and stored in the recording means (memory) 42 (step S2).

  Next, the state of the load 5 is monitored by the power consumption monitoring means 43, and the power consumption is detected (step S3). Here, the monitoring or detection of power consumption is direct power detection means for measuring the power consumption of the load, for example, measurement of a voltage drop generated in a current detection resistor connected in series to the power source or of the power detection resistor connected to the load 5. You may detect by temperature measurement etc. When the load 5 is composed of a plurality of units that consume predetermined power, the power consumption can be obtained by monitoring the number of units that are actually operated.

  Next, the power consumption per unit when a plurality of power source units 3 are combined is calculated by the power consumption calculation means 44 per unit (step S4). For example, as shown in FIG. 2, when the power supply unit 3 is composed of N power supply units 31 and M redundant (or auxiliary) power supply units 32, the power supply units are, for example, N + 1, N + 2, N + 3,. ... Calculate the power consumption per power supply unit when N + M-1 and N + M are combined. Then, a combination of power supply units that provides the optimum (or highest) conversion efficiency is selected (step S5). Finally, the ON / OFF of each power supply unit is controlled by the ON / OFF control means 46 based on the combination of the power supply units that can obtain the optimum conversion efficiency, and the output power is supplied to the load 5 (step S6). .

  As described above, the load-to-conversion efficiency information when the load of the power supply unit 3 changes from 0% to 100% of the rating, for example, is stored in the memory and accessed by the information reading means 41 of the power supply control unit 4. Can be read. Therefore, for all combinations of a plurality of power supply units, it is possible to select and determine a combination of the power supply units 3 that provides the optimum conversion efficiency for all states (power consumption) of the load 5.

  After determining and selecting a combination of optimum conversion efficiencies of the plurality of power supply units 3 in steps S5 and S6 described above, for example, the process returns to step S3 at regular intervals to monitor the power consumption in the state of the load 5. However, when there is no load fluctuation after setting and starting up, the load power may be detected only at the time of starting and a combination of power supply units that can obtain the optimum conversion efficiency corresponding to the load 5 may be selected and determined. .

  Next, a description will be given based on a specific example. For example, the rated output of each power supply unit is 10 W (watts), and the conversion efficiency is maximum when it is 8.5 W, which is 85% of the rating (10 W), and it is 95% when it is 8 W, which is 80%. Assume higher than 9.5W. A case where the power consumption of the load 5 is 95 W will be described.

  In the above specific example, since 95/10 = 9.5, it is necessary to select 10 or more power supply units. In order to operate each power supply unit within the range not exceeding its rated output, when 10 power supply units are selected according to the conventional technology, the power consumption per power supply unit is a load state of 95/100 = 95%. . Further, according to the prior art disclosed in Patent Document 1 described above, 95 / 8.5 = 11.2 for each power supply unit to obtain an output power of 95 W at 8.5 W, which is the output power with the maximum conversion efficiency. It is necessary to operate 12 units, that is, 12 power supply units. In this case, the load state per power supply unit is 95/120 = 79%. However, since the power supply unit has the highest conversion efficiency when the load state is 85% as described above, in this case, the power supply unit cannot be operated at the highest conversion efficiency.

  On the other hand, according to the power supply system 10 of the present invention, as described above, the load-to-conversion efficiency information in a wide range of load states of the power supply unit is read, and 11 units with the highest conversion efficiency per power supply unit are selected. Then, the load 5 of 95 W is driven with the rated output power 110 W. In this case, the load state of each power supply unit is 95/110 = 86%, and it is possible to operate with substantially the highest conversion efficiency.

  The preferred embodiments of the power supply system, the power supply unit, and the power efficiency improvement method of the present invention have been described in detail above. However, such an embodiment is merely an example of the present invention and does not limit the present invention. Those skilled in the art will readily understand that various modifications and changes can be made in accordance with a specific application without departing from the gist and spirit of the present invention. For example, when the power supply units constituting the power supply unit 3 are determined in advance, the load-to-conversion efficiency information may be stored in advance in the memory of the power supply control unit 4. Further, when a trouble occurs in a specific power supply unit among the plurality of power supply units, the power supply control unit 4 can detect this and immediately switch to one of the redundant power supply units 32 for backup. .

  Further, as understood from the above description, the power supply system, the power supply unit, and the power efficiency improvement method of the present invention are configured such that the power supply unit portion in the electrical equipment is distributed power supply by power supply from a plurality of power supply units. It can be applied to any electrical equipment.

It is a block diagram of suitable embodiment of the power supply system by this invention. It is a functional block diagram of the power supply system shown in FIG. It is a flowchart which shows operation | movement of the power supply system by this invention.

Explanation of symbols

1 AC (AC) input 2 DC (DC) output 3 Power supply unit (AC-DC converter)
4 Power control unit 5 Load 10 Power supply system 41 Information reading means 42 Recording means 43 Power consumption monitoring means 44 Power consumption calculation means 45 per power supply unit 45 Optimal conversion efficiency selection means 46 Power supply unit ON / OFF control means

Claims (9)

In a power supply system configured to selectively operate a plurality of power supply units each converting an AC input into a DC output and supplied to a common load,
A load detecting means for detecting monitoring the power consumption of the load, based on said load versus conversion efficiency information of each power supply unit, to the power consumption of the detected load by the load detecting means, said power supply unit per vehicle A power control unit including a selection unit that calculates the power consumption of and selects a combination of the plurality of power supply units with the highest conversion efficiency,
A power supply system that controls the plurality of power supply units by the power supply control unit.   The power supply unit includes a memory for storing load-to-conversion efficiency information of the power supply unit, and the power supply control unit is configured to be accessible to the information stored in the memory. Power supply system as described in.   The power supply unit has an N + M configuration (N and M are arbitrary positive integers), and the N power supply units are always operated, and some of the M power supply units are changed according to power consumption fluctuations of the load. The power supply system according to claim 1, wherein the power supply system is selected and used. In a power supply unit that converts AC input to DC output and supplies power to a common load in cooperation with one or more other power supply units,
A power supply unit comprising a memory for storing load-to-conversion efficiency information indicating a change characteristic of conversion efficiency with respect to a change in load, and configured to be accessible from the outside.   5. The power supply unit according to claim 4, further comprising output switching means for selectively turning on / off the DC output by a control signal from the outside. In a power efficiency method for efficiently supplying DC power from a plurality of power supply units each converting AC input to DC output to a load whose power consumption varies,
Obtaining the load-to-conversion efficiency information of the power supply unit in advance;
Monitoring and detecting power consumption of the load;
Corresponding to the power consumption detected in the power consumption monitoring detection step, calculating the power consumption per one power supply unit and selecting the combination of the plurality of power supply units that maximizes the conversion efficiency;
And a step of ON / OFF controlling the plurality of power supply units so as to obtain the combination obtained in the step.   The power efficiency improvement method according to claim 6, wherein the load-to-conversion efficiency information of the power supply unit is stored in a memory of the power supply unit.   The power efficiency method according to claim 6 or 7, wherein the power consumption of the load is obtained by accessing the load from a power control unit at the time of startup.   The power efficiency method according to claim 6 or 7, wherein the power consumption of the load is detected by monitoring the load at predetermined time intervals.

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