KR101286923B1 - Device for supplying direct current - Google Patents

Abstract

PURPOSE: A DC power supply device is provided to supply DC power of various voltages at the same time through integrated device, thereby increasing efficiency of cost and space application. CONSTITUTION: An input terminal part (110) is installed at a front side of a body part and receives DC power. An output terminal part (120) comprises multiple output terminals which output DC power. A lamp part (130) is connected to the output power of each output terminal and operates A control unit (180) comprises a switching unit (181), a transformer (182), a rectifier (183), and a loading control portion (184). The transformer converts voltage of AC power, which is supplied from switching unit, into set value. [Reference numerals] (110) Input terminal part; (120) Output terminal part; (130) Lamp part; (180) Control unit; (181) Switching unit; (182) Transformer; (183) Rectifier; (184) Loading control portion

Description

DC Power Supply {DEVICE FOR SUPPLYING DIRECT CURRENT}

The present invention relates to a power supply, and in detail, the DC power input through the switching circuit is adjusted to a plurality of the set voltage divided output, but the structure that can effectively discharge the internal heat that increases with the modularization, miniaturization and load increase It relates to a direct current power supply having.

Recently, due to industrial development, various kinds of devices using DC power are increasing in industrial sites. At this time, the commercial power is regulated and supplied to the required power using an adapter made for each device, but a plurality of adapters are required as the required voltage of each device varies, which is inconvenient for the processing of the adapter and the connection cable. Gave.

In order to eliminate such inconvenience, a DC power supply that can convert a converted DC power to a desired voltage through a switching circuit method has been developed in recent years. Therefore, it is gradually becoming smaller, lighter and thinner.

However, in recent years, the switching power supply has high efficiency and low noise characteristics, and the voltage stress of the main switching element is limited to the input voltage, thereby enabling the use of low voltage semiconductor switches with low on-resistance. There is a problem that heat generation becomes severe with miniaturization and high efficiency.

In particular, as the load of the connected DC equipment increases, the heating problem becomes more severe, which not only adversely affects the components in the power supply but also other devices in close proximity, and also due to the electromagnetic field generated by the characteristics of the work in voltage conversion. Problems such as being sufficiently separated from the high-precision circuit or requiring a separate shield treatment.

The present invention was created in order to solve the above problems, and an object of the present invention is to divide the output DC power by using a switching circuit to a plurality of set voltages, but to effectively discharge the heat generated and other It is to provide a DC power supply to the device to minimize the effects of heat and electromagnetic fields.

In order to achieve the above object, the present invention provides a DC power supply for converting a voltage of an input DC power and outputting it to another DC power. A space is formed therein, and a plurality of penetrating inner and outer surfaces of the bottom and upper sides are provided. Cooling hole is formed, the body portion having a structure spaced at a predetermined interval from the bottom surface of the installation place; An input terminal unit installed at the front of the body unit and receiving DC power; An output terminal unit installed at a rear side of the body unit, the output terminal unit including a plurality of output terminals for outputting DC power; A lamp unit installed on the side of the body part in the same number as the output terminals and operating in association with the output power of each output terminal; It is installed inside the body portion, and converts the DC power supplied from the input terminal portion into an AC power source, the switching unit having an input primary winding unit, and the secondary winding unit and the primary number provided in the number corresponding to the output terminal A transformer for converting the voltage of the AC power supplied from the switching unit into a set value having a core causing electromagnetic induction with the winding unit, and converting the AC power output from the transformer into DC power A control unit including a rectifying unit for outputting to an output terminal and a load control unit configured to sense a load connection state of the output terminal unit to block operation of the transformer unit when there is no connection; A heat dissipation unit made of copper or a copper alloy in which a plurality of air flow paths are formed from a lower side to an upper side to receive and release heat generated by surrounding the side of the control unit so as to smoothly move the air; And a control unit.

 At this time, the body portion further includes an auxiliary power terminal unit connected to the cable connected to the rechargeable battery unit, and a selection unit for selecting a power protection mode, the control unit is a direct current input through the input terminal unit by the operation of the selection unit; The apparatus may further include a power protection unit configured to charge the rechargeable battery unit through a power source and to receive the power charged in the rechargeable battery unit when the input terminal unit is powered off.

In addition, the body portion is a heat dissipation portion is formed on the side so that the heat dissipation portion is partially exposed to the outside, and further includes a temperature sensor unit and a small cooling fan installed inside the body portion, the control unit in the temperature sensor unit The temperature controller may further include a temperature controller configured to operate the cooling fan when the sensed temperature is higher than or equal to the set temperature.

In addition, the transformer may be composed of a number of secondary windings of one less than the number of the output terminal, the output terminal that is not associated with the transformer may be configured to be directly connected to the power from the input terminal.

In addition, each of the secondary windings may be formed in a different standard, and may be configured to reverse the winding direction of the selected secondary winding.

Through the present invention, it is possible to easily supply the power required for the DC device without a separate adapter, it is possible to supply a DC power of various voltage at the same time through a single device is increased efficiency in space utilization and cost.

In addition, the heat dissipation part made of a material having excellent thermal conductivity and shielding ability of the electromagnetic field together with a cooling structure that maximizes the convection property of the heat can effectively block the effect of electromagnetic field due to switching action and voltage conversion.

1 is an exploded perspective view showing the appearance according to a preferred embodiment of the present invention,
2 is a perspective view showing a side view according to a preferred embodiment of the present invention,
3 is a block diagram showing a connection relationship between components according to a preferred embodiment of the present invention;
Figure 4 is an exploded perspective view showing the appearance according to another embodiment of the present invention,
5 is a block diagram illustrating a connection relationship between components according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of the present invention DC power supply.

The present invention is a DC power supply for converting the voltage of the input DC power supply and outputs to another DC power supply, Figure 1 is an exploded perspective view showing the appearance according to a preferred embodiment of the present invention, Figure 2 is a preferred embodiment of the present invention Figure 3 is a perspective view showing a side according to, Figure 3 is a block diagram showing the connection between the components according to a preferred embodiment of the present invention, the body portion 100 and the input terminal portion 110 as shown in Figures 1 to 3 The main configuration includes the output terminal 120, the lamp 130, the controller 180, and the heat dissipation unit 190.

The body portion 100 is a case in which a space in which the control unit 180 and the heat dissipation unit 190 may be formed is formed, and a plurality of cooling holes 101 penetrating the inner side and the outer side are formed at the bottom and the upper side thereof. Each is formed. That is, since a lot of heat is generated in the control unit 180 inside the body portion 100 as the DC power supply device of the present invention is discharged to the outside of the body portion 100 through the cooling hole (101).

At this time, since the heat moves from the lower side to the upper side by the convection of the air inside the body part 100, the body part 100 of the body part 100 so as to generate a smooth flow of air from the lower side to the upper side inside the body part 100 as shown in FIG. A plurality of cooling holes 101 are formed on the bottom and the upper side, and the heat generated from the controller 180 escapes through the cooling holes 101 of the upper side of the body portion 100 and the bottom of the body portion 100. Cooled air is sucked through the cooling hole 101. In addition, the body portion 100 has a foot 103 spaced apart at a predetermined interval from the bottom surface of the installation place so that air flows smoothly through the cooling hole 101 of the bottom of the body portion 100 and The same structure is formed.

The input terminal unit 110 is installed on the front of the body portion 100 is configured to receive an external DC power supply is made of a terminal that can be connected to a conventional DC power cable, the voltage is selected according to the user's needs It can be supplied with DC power supply, and normally it receives DC 28 volt which is used a lot.

The output terminal unit 120 is installed at the rear of the body portion 100, the output terminal 121 is input through the input terminal unit 110 and outputs a DC power converted voltage through the control unit 180 It consists of. That is, in the present invention, as described below, since the DC power of different voltages is output through the plurality of transformers 182, the output terminal unit 120 includes a plurality of output terminals 121. The number of output terminals 121 that are configured may be configured as needed, but the embodiment of the present invention suggests a form in which six output terminals 121 are configured, but is not limited thereto.

The lamp unit 130 is a configuration for easily confirming the operation state of the DC power supply of the present invention, by the same number as the number of the output terminal 121 on the side of the body portion 100 using an LED or the like. It is installed, and is operated in connection with the output power of each output terminal 121. That is, when six output terminals 121 are provided as in the present invention, six lamp units 130 are provided in the same manner, which are connected to each output terminal 121 and thus operate at an output terminal at which the current voltage is output ( The lamp unit 130 associated with 121 is lit.

The controller 180 is configured to control the voltage conversion operation. As shown in FIG. 3, the controller 180 includes a switching unit 181, a transformer unit 182, a rectifier unit 183, and a load control unit 184.

The switching unit 181 converts the DC power supplied from the input terminal unit 110 into an AC power source. The switching unit 181 interrupts the DC with a switching element such as a transistor or a thyristor to make a square wave AC. It is applied to the primary winding corresponding to the primary side. Since various techniques have been developed for converting direct current into alternating current using a switching element, detailed descriptions are omitted.

The transformer 182 is a part for converting the voltage of the AC power converted by the switching unit 181 to a set value, and is made in the same principle as a transformer for controlling the voltage of the AC power using the turns ratio of the input side and the output side. And a core for generating electromotive force in the secondary winding part by electromagnetic induction from the primary winding part and the number of secondary winding parts corresponding to the output terminal 121 according to the required output voltage. .

For example, when the power from the input terminal unit 110 is to be converted into six different voltages to be output through the output terminal unit 120, the secondary winding units may be provided with six to be connected to each output terminal.

In another manner, the transformer unit 182 includes one secondary winding unit having a number less than the number of the output terminals, and directly outputs power from the input terminal unit 110 to an output terminal that is not associated with the transformer unit 182. It may be configured to be connected.

That is, when the output terminal unit 120 is composed of six output terminals 121, the DC output of a voltage different from that input to the input terminal unit 110 is output from the five output terminals, the input terminal unit ( The DC power of the same voltage as that input to 110 is output, and is configured to use not only the converted power but also the original voltage.

In addition, each of the secondary windings may be formed in a different standard, and may be configured to reverse the winding direction of the selected secondary winding. This makes it possible to compensate for minute voltages and currents by generating a difference in resistance during voltage conversion by using windings having different diameters in each of the secondary windings, and also reverses the winding direction of the secondary windings so that DC power in the opposite direction This is to allow the output of a voltage of opposite polarity by being applied. That is, according to the needs of the load connected to the output terminal, it is possible to apply a negative voltage.

The rectifier 183 converts the AC power output from the transformer unit 182 back to DC power and outputs the outputs to the associated output terminals 121. Similarly, various technologies have been developed. It consists of negative and load resistance.

The load control unit 180 is connected to the transformer unit 182 to sense the connection of the load connected to the output terminal unit 120 to control the operation of the transformer 182. That is, when the load device is not connected to the output terminal unit 120, the operation of the transformer unit 182 becomes an element of unnecessary heat, including power consumption, so that the transformer is not operated when the load device is not connected to the output terminal unit. To block.

The heat dissipation unit 190 is configured to receive and smoothly dissipate heat generated by the control unit 180 and has a form surrounding the side surface of the control unit 180 to maximize a contact surface with the control unit 180. In this case, it is preferable to have a shape in which a part of the body part 100 is cut away, not a shape that completely surrounds the controller 180 according to the shape of the inner space and the shape of other components.

In addition, the heat dissipation unit 190 is configured to smoothly move the air from the lower side to the upper side so that the cooling hole 101 conforms to the shape so as to guide the flow of air from the bottom surface of the body portion 100 to the upper side. A plurality of air passages 190 are formed. This not only facilitates the flow of air but also widens the contact area with the air, thereby making the cooling more smooth.

In addition, the heat dissipation unit 190 is made of copper or copper alloy having excellent thermal conductivity as well as shielding effect of the electromagnetic field so that the influence of the electromagnetic field that may be a problem in a conventional transformer is blocked in the present invention.

Figure 4 is an exploded perspective view showing the appearance according to another embodiment of the present invention, Figure 5 is a block diagram showing the connection relationship between the components according to another embodiment of the present invention, the auxiliary power supply on the side of the body portion 100 The terminal unit 140 and the selection unit 150 are further formed.

The auxiliary power terminal unit 140 is a configuration for connecting the rechargeable battery unit 200, according to the purpose of the present invention to solve the heat problem according to the high efficiency and miniaturization to embed the battery as in other conventional power supply It has a structure that connects to the outside through the cable 210 rather than the structure.

The rechargeable battery unit 200 not only serves to maintain the output power by continuously supplying power when input power is unexpectedly cut off, but also charges the input DC voltage and does not require external input power as necessary. By converting the voltage of the rechargeable battery unit 200 into different DC voltages and outputting them through various types of output connection means, various sounds such as mobile phones, digital cameras, PDAs, MP3s, PMPs, pocket PCs, hard disks, etc. DC voltage can be supplied to electronic devices such as devices, digital cameras, and mobile phones to greatly improve portability, usability, and compatibility.

The selector 150 is a configuration of a conventional switch type that can be arbitrarily manipulated by a user and is configured to select a power hobo mode when the rechargeable battery unit 200 is connected to the auxiliary power terminal 140. . In this case, the power protection mode refers to a function of constantly charging the rechargeable battery unit 200 through an external DC power and automatically supplying the charged power to the rechargeable battery unit 200 when the external DC power is cut off. . In addition, if the rechargeable battery unit 200 is to be used as a power supply to the power of the rechargeable battery without supplying external power in the state of being charged in the same way.

At this time, the controller 180 is operated by the operation of the selection unit 150 to charge the rechargeable battery unit 200 through the DC power input through the input terminal unit 110, the input terminal unit 110 of The power protection unit 185 may further include a power protection unit 185 which serves to supply the power charged in the rechargeable battery unit 200 to the switching unit 181 when the power is cut off.

In addition, as shown in FIG. 4, the heat dissipation unit 190 may be partially exposed to the outside of the body portion 100 to further increase the cooling efficiency. To this end, the body portion 100 is formed with a heat dissipation portion 102 of the form cut so that the heat dissipation portion 190 is partially exposed through the side, the heat of the heat dissipation portion 102 Through it is to be able to be released directly to the body portion 100 outside.

In addition, a temperature sensor unit 160 capable of measuring temperature in the inner space of the body part 100 and a small cooling fan 170 for forcibly circulating air are additionally installed, and the controller 180 is When the temperature sensed by the temperature sensor unit 160 is more than the set temperature may further include a temperature control unit 186 configured to operate the cooling fan 170.

That is, since the heat generation is relatively increased as the load of power supplied through the output terminal unit 120 increases, when the heat generation is small, the cooling fan 170 is stopped to suppress power consumption and noise generation, and heat generation Only in this case, the cooling fan 170 is operated through the temperature control unit 186 to forcibly release heat.

It is to be understood that the invention is not limited to the disclosed embodiment, but is capable of many modifications and variations within the scope of the appended claims. It is self-evident.

100: body 101: cooling hole
102: heat dissipation unit 103: leg
110: input terminal portion 120: output terminal portion
121: output terminal 130: lamp unit
140: auxiliary power terminal unit 150: selection unit
160: temperature sensor unit 170: cooling fan
180: control unit 181: switching unit
182: transformer 183: rectifier
184: load control unit 185: power protection unit
186: temperature control unit 190: heat dissipation unit
191: Euro 190 200: Battery unit
210: cable

Claims (5)

In the DC power supply for converting the voltage of the input DC power supply and output to another DC power supply,
A body portion 100 having a structure formed therein and having a plurality of cooling holes 101 passing through the inner side and the outer side at the bottom and the upper side thereof, and having a structure spaced apart at a predetermined interval from a bottom surface of a place where the space is installed;
An input terminal unit 110 installed at the front of the body unit 100 and receiving DC power;
An output terminal unit 120 installed at a rear surface of the body unit 100 and including a plurality of output terminals 121 for outputting DC power;
A lamp unit 130 installed on the side of the body unit 100 in the same number as the number of the output terminals 121 and operating in association with the output power of each of the output terminals 121;
A switching unit 181 installed inside the body part 100 and converting the DC power supplied from the input terminal unit 110 into AC power and having an input primary winding part, and corresponding to the output terminal 121. A transformer unit 182 having a number of secondary winding units provided in number and a core causing electromagnetic induction phenomenon between the primary winding units and converting the voltage of the AC power supplied from the switching unit 181 to a set value; The rectification unit 183 converts the AC power output from the transformer unit 182 into DC power and outputs the output to each of the connected output terminals 121 and the connection by sensing the load connection state of the output terminal unit 120. Control unit 180 including a load control unit 184 is configured to block the operation of the transformer unit 182 when not there;
A heat dissipation unit 190 made of copper or a copper alloy in which a plurality of air flow paths 190 are formed from the lower side to the upper side to receive and release heat generated by wrapping the side surface of the control unit 180 to allow smooth movement of air; DC power supply, characterized in that comprises a.
The method of claim 1,
The body portion 100 further includes an auxiliary power terminal unit 140 to which a cable 210 connected to the rechargeable battery unit 200 is connected to a side thereof, and a selection unit 150 for selecting a power protection mode.
The controller 180 charges the rechargeable battery unit 200 through a DC power input through the input terminal unit 110 by the operation of the selector 150 and turns off the power of the input terminal unit 110. DC power supply characterized in that it further comprises a power protection unit (185) configured to receive the power charged in the rechargeable battery unit 200 to the switching unit (181).
The method of claim 1,
The body portion 100 has a heat dissipation portion 102 is formed on the side surface so that the heat dissipation portion 190 is partially exposed to the outside, and the temperature sensor unit 160 is installed inside the body portion 100 and Further comprising a small cooling fan 170,
The control unit 180 further includes a temperature control unit 186 configured to operate the cooling fan 170 when the temperature sensed by the temperature sensor unit 160 is equal to or higher than a set temperature. Feeder.
The method of claim 1,
The transformer unit 182 is composed of a number of secondary windings one less than the number of output terminals,
DC power supply, characterized in that the output terminal is not associated with the transformer unit 182 is configured to be directly connected to the power from the input terminal unit (110).
The method of claim 1,
Each of the secondary windings is formed to a different standard, DC power supply characterized in that the configuration is configured to reverse the winding direction of the selected secondary winding portion.

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