KR101644448B1 - Mobile modem system - Google Patents

Abstract

The mobile communication modem module includes a wireless communication unit for performing wireless transmission and reception, a capacitor charging current limiting unit connected to the power supply unit and for lowering a voltage output from the power supply unit, And a capacitor charging current limiting unit connected to the capacitor charging current limiting unit and configured to apply a driving voltage to the wireless communication unit using a voltage applied from the capacitor charging current limiting unit, Wherein the capacitor charge current restricting unit reduces the magnitude of the current consumed during the charging operation of the capacitor unit for the peak current to below the set current limit value. As a result, the magnitude of the current applied to the wireless communication unit of the mobile communication modem system is limited, and the magnitude of the current consumption consumed in the wireless transmission / reception operation by the wireless communication unit is reduced to a safe state. And the risk of explosion or fire caused by the propagation of the combustible material in the vicinity is reduced.

Description

[0001] MOBILE MODEM SYSTEM [0002]

The present invention relates to a mobile communication modem system, and a mobile communication modem system having an intrinsic safety function.

Today's mobile communications (CDMA, WCDMA, LTE, etc.) modem systems are intelligent networking technologies that give sensors and communication functions to our surrounding objects to interact and collect information like live organisms [eg, M2M (machine to machine), IOT (internet of things).

Therefore, a modem, which is a mobile communication unit, is attached to equipment necessary for control, smart grid, and crime prevention, and is connected to a network.

Generally, explosion-proof standards must be met so that electrical and electronic equipment such as mobile communication modem systems do not become ignition sources where explosion hazard exists due to flammable materials such as industrial sites or laboratories.

1, the conventional mobile communication modem system includes a power supply unit 10, a power supply unit 10, and a mobile communication modem module 20 connected to the socket 30.

The power supply unit 10 generates a DC voltage of a size required for the operation of the mobile communication modem module 20 and supplies the DC voltage to the mobile communication modem module 20.

At this time, the magnitude of the voltage output from the power supply unit 10 may be, for example, 5V to 12V.

The mobile communication modem module 20 includes a voltage regulator 21 connected to a power supply unit 10 and a wireless communication unit 22 connected to an input terminal of the voltage regulator 21 and having an output terminal connected to the socket 30 Respectively.

The voltage regulator 21 converts the voltage applied from the voltage supply unit 10 into a constant voltage of a predetermined magnitude (e.g., 3.3 V) and transmits the voltage to the wireless communication unit 22 stably.

The wireless communication unit 22 is a mobile communication modem operated by the voltage applied from the voltage regulator 21, and performs wireless transmission / reception of data, signals, etc. with an external device.

The socket 30 may also be a universal subscriber identity module (USIM) socket.

As described above, the conventional mobile communication modem module 20 includes only the voltage regulator 21 for the operation of the wireless communication unit 22, but does not have any other component that performs the intrinsic safety explosion function .

Generally, one of the methods for realizing the intrinsic safety explosion function is a method for limiting the total amount of energy supplied to the wireless communication unit 22. In this case, a method of limiting the total amount of energy in the circuit in which the driving voltage is fixed is .

However, when the consumption current of the mobile communication modem module 20 is limited, the output voltage of the voltage regulator 21 has a voltage drop period in which the voltage output from the voltage regulator 21 falls, as shown in FIG. 2, The rated voltage falls below the minimum operating voltage for the operation of the wireless communication unit 22 and causes malfunction of the wireless communication unit 22. [ Therefore, in the case of the mobile communication modem module 20 shown in Fig. 1, the method of limiting the consumption current is not suitable.

Therefore, since the conventional mobile communication modem system does not have a separate intrinsic safety explosion function, a high consumption current is generated when a wireless transmission / reception operation is performed using the conventional mobile communication modem system.

If there is a flammable substance in the vicinity of the conventional mobile communication modem system, the heat or flame will spread to surrounding combustible material, causing fire or explosion hazard .

Therefore, the mobile communication modem system which does not have the intrinsic safety explosion function is not applicable to the equipment operated in the fire danger area or the explosion dangerous area, and thus the use thereof is limited.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above problems, and an object of the present invention is to provide a mobile communication modem system with an intrinsic safety explosion function, thereby enhancing the satisfaction level of a user and a manufacturer by enlarging a use area of the mobile communication modem system.

Another object of the present invention is to improve the reliability of operation of the wireless communication unit by stably maintaining the voltage state supplied to the wireless communication unit.

A mobile communication modem system according to an aspect of the present invention is a mobile communication modem system including a mobile communication modem module, wherein the mobile communication modem module is connected to a wireless communication unit and a power supply unit for wireless transmission and reception, And a capacitor charging current limiting unit connected to the capacitor charging current limiting unit and performing a charging operation using a voltage applied from the capacitor charging current limiting unit to apply a driving voltage to the wireless communication unit And a capacitor for a peak current for reducing the magnitude of the consumption current to a value equal to or smaller than the set current limit value. At this time, the capacitor charge current restricting unit reduces the magnitude of the current consumed in the charging operation of the peak current capacitor unit to be less than the set current limit value.

Wherein the mobile communication modem module comprises: a voltage measuring unit connected to the peak current capacitor unit for comparing a voltage output from the peak current capacitor unit with a reference voltage to output an output signal of the corresponding state; And a power switch unit connected to the wireless communication unit and the peak current capacitor unit to apply or cut off the drive voltage output from the peak current capacitor unit according to the state of the output signal output from the voltage measurement unit .

The power switch unit may be a transistor having a control terminal connected to the voltage measuring unit, an input terminal connected to the peak current capacitor unit, and an output terminal connected to the wireless communication unit.

The mobile communication modem module further includes a voltage regulator located between the power supply unit and the capacitor charging current limiting unit and converting the magnitude of the voltage applied from the power supply unit to a predetermined magnitude and outputting the magnitude to the capacitor charging current limiting unit .

The mobile communication modem module further includes a first reverse current prevention unit connected between the power supply unit and the voltage regulator and a second reverse current prevention unit connected between the capacitor charging current limit unit and the peak current capacitor unit can do.

The mobile communication modem system according to the present invention is characterized in that it comprises a molding part surrounding a mobile communication modem printed circuit board on which the mobile communication modem module is mounted, and a socket disposed above the mobile communication modem module and the molding part, And a connection part located between the first and second connection parts.

The connection unit may include a plurality of connection terminals spaced apart from each other between the mobile communication modem module and the socket, or may include a terminal printed circuit board on which a plurality of connection terminal patterns are printed.

The molding part may be made of epoxy, urethane or silicone.

A mobile communication modem system according to another embodiment of the present invention is a mobile communication modem system including a mobile communication modem printed circuit board. The mobile communication modem system includes a molding part surrounding the mobile communication PCB, And a connector positioned between the communication modem printed circuit board and a socket located above the molding part to provide an electrical connection between the mobile communication modem printed circuit board and the molding part.

The connection unit may include a plurality of connection terminals spaced apart from each other between the mobile communication modem module and the socket, or may include a terminal printed circuit board on which a plurality of connection terminal patterns are printed.

The molding part may be made of epoxy, urethane or silicone.

According to this aspect, since the magnitude of the current applied to the wireless communication unit of the mobile communication modem system is limited, the magnitude of the current consumption consumed in the wireless transmission / reception operation by the wireless communication unit is reduced to a safe state.

This reduces the risk of explosion or fire resulting from the flame or high temperature generated by high current consumption being propagated to nearby combustible materials.

Accordingly, the mobile communication modem system can be stably installed in an explosion hazardous area such as a region where a combustible material such as an explosive substance, a flammable liquid, or a gas exists or a high temperature region such as a desert.

As a result, the mobile communication modem system can be installed in the monitoring, measuring, weighing, and control equipment without being limited to the installation area and thus, the mobile communication modem system of this example is applied to the intelligent equipment and system do.

Further, since the driving voltage is applied to the wireless communication unit only when the state of the driving voltage applied to the wireless communication unit is checked and the driving voltage is in the normal state, excessive power consumption due to an operation attempt of the wireless communication unit due to an abnormal driving voltage .

As a result, it is possible to prevent repetitive malfunction of the wireless communication unit, thereby securing the charging time of the capacitor for the peak current and ensuring a stable current consumption pattern.

In addition, since the molding thickness satisfying the intrinsic safety explosion-proof structure is ensured by separating the wireless communication part and the socket part, the current limiting power supply circuit is not provided in order to realize intrinsic safety explosion-proof function, System is implemented.

1 is a block diagram of a conventional mobile communication modem system.
2 is a graph showing an example of a voltage drop characteristic of a voltage regulator when a current is limited in the mobile communication modem system of FIG.
3 is a block diagram of a mobile communication modem system in accordance with an embodiment of the present invention.
4A is a graph illustrating an example of current consumption characteristics when the peak current capacitor is not used in the mobile communication modem system shown in FIG.
FIG. 4B is a graph showing an example of a limiting characteristic of a peak current by a capacitor for a peak current when a capacitor for a peak current is applied in a system in the mobile communication modem system shown in FIG.
FIG. 4C is a graph showing an example of the characteristics of current consumption during charging of the capacitor for peak current when the capacitor charge current limiting unit is not applied in the mobile communication modem system shown in FIG.
FIG. 4D is a graph showing an example of the consumption current characteristic when the capacitor for the peak current is charged when the capacitor charging current limiting unit is applied in the mobile communication modem system shown in FIG.
5 and 6 are cross-sectional views of a mobile communication modem system according to another embodiment of the present invention, respectively.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

In the drawings, the thickness is enlarged to clearly represent the layers and regions. When a layer, film, region, plate, or the like is referred to as being "on" another portion, it includes not only the case directly above another portion but also the case where there is another portion in between. Conversely, when a part is "directly over" another part, it means that there is no other part in the middle.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, but it should be understood that there may be other elements in between do. On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

Hereinafter, a mobile communication modem system according to an embodiment of the present invention will be described with reference to the accompanying drawings.

First, a mobile communication modem system according to an embodiment of the present invention will be described in detail with reference to FIG.

The mobile communication modem system shown in FIG. 3 includes a power supply unit 100, a current limiting unit 201 connected to the power supply unit 100, and a wireless communication unit And a mobile communication modem module 200 having a mobile communication module 202.

As described above with reference to FIG. 1, the mobile communication modem module 200 is connected to a socket 300 such as a universal subscriber identity module (USIM) socket.

The power supply unit 100 generates a DC voltage of about 5 to 12 V and supplies the generated DC voltage to the current limiting unit 201 and the wireless communication unit 202 and operates as a component of the current limiting unit 201 and the wireless communication unit 202 Provide the required voltage.

The power supply unit 100 may be located within the mobile communication modem module 200, unlike FIG.

The current limiting unit 201 includes a first reverse current prevention unit 211 connected to the power supply unit 100, a voltage regulator 212 connected to the first reverse current prevention unit 211, a voltage regulator 212, A second reverse current prevention unit 214 connected to the capacitor charge current restricting unit 213 and a capacitor unit 215 for peak current connected to the second reverse current prevention unit 214, A voltage measurement unit 216 connected to the peak current capacitor unit 215 and a power switch unit 217 connected to the peak current capacitor unit 215, the voltage measurement unit 216 and the wireless communication unit 202 Respectively.

The first and second reverse current blocking portions 211 and 214 prevent current flow in the reverse direction and each of the first and second reverse current blocking portions 211 and 214 includes at least one diode D21 and D22 .

The diode D21 is connected between the power supply unit 100 and the voltage regulator 212 in a forward direction and the diode D22 is connected between the capacitor charge current restricting unit 213 and the peak current capacitor unit 215 It is connected in the forward direction.

At this time, the first reverse current prevention unit 211 prevents the output current of the voltage regulator 212 from flowing back to the power supply unit 100, and the second reverse current prevention unit 214 prevents the output current of the capacitor unit for the peak current 215 from flowing back to the capacitor charge current restricting portion 213 side.

Due to the voltage drop caused by the consumption of the peak current by the first and second reverse current prevention parts 211 and 214, the voltage regulator 212 is turned to the power supply part 100 side and the peak current The current is prevented from flowing in the capacitor unit 215 in the reverse direction toward the voltage regulator 212. [

As a result, the charge amount of the peak current capacitor section 50 is supplied only to the radio communication section 80, so that the operating characteristics of the radio communication section 80 are improved.

The voltage regulator 20 converts the voltage (for example, 5 V to 12 V) of the power supply unit 100 applied through the first reverse current prevention unit 211 to a predetermined fixed size (e.g., 3.3 V) and outputs the converted voltage.

The capacitor charge current limiting unit 213 includes a resistor R21 connected in series between the voltage regulator 212 and the second reverse current prevention unit 214

The capacitor charging current limiting unit 213 drops a voltage of a predetermined magnitude (for example, 3.3 V) output from the voltage regulator 212 and supplies the voltage to the peak current capacitor unit 215 via the second reverse current prevention unit 214 .

The peak current capacitor unit 215 includes at least one capacitor C21 and C22 connected in parallel between the second reverse current prevention unit 214 and the ground.

The peak current capacitor unit 215 performs a charging operation and a charging voltage discharging operation on the voltage applied through the second reverse current prevention unit 214 according to the operation state of the wireless communication unit 202, 202 as shown in FIG.

Therefore, the voltage applied through the capacitor charging current restricting section 213 is supplied to the radio communication section 202 after being charged in the capacitor section 215 for the peak current. Therefore, by the charging operation of the capacitor section 215 for peak current The charge current to be charged in the peak current capacitor section 215 is applied to the radio communication section 80. [

The charging voltage charged in the capacitors C21 and C22 of the peak current capacitor unit 215 is applied to the driving voltage of the wireless communication unit 202 so that the magnitude of the current flowing to the wireless communication unit 202 is supplied to the capacitors C21 and C22, C22) to reduce the consumption current characteristic of the wireless communication unit 202 to the intrinsic safety explosion current limit value (i.e., the set current limit value).

The output voltage of the voltage regulator 212 falls and the voltage applied to the wireless communication unit 202 is supplied to the wireless communication unit 202 202, it is ensured that the operation of the wireless communication unit 202 is stable.

At this time, although the consumption current which increases during the charging operation of the peak current capacitor section 215 may exceed the intrinsic safety explosion current limit value, the capacitor current limiting section 213 has already passed the peak current capacitor section 215 The consumed current consumed in the charge operation of the capacitor charge current limiting unit 213 also does not exceed the intrinsic safe explosion current limit value since the applied voltage is in the lowered state.

In addition, due to the second reverse current prevention portion 214, current is prevented from flowing to the voltage regulator 212, which is the reverse direction in the charging operation of the capacitor portion 215 for peak current.

Therefore, the resistance value of the capacitor charge current limiting unit 213 (for example, the value of the resistor R21) is determined according to the intrinsic safety explosion current limit value.

The capacitors C21 and C22 used in the peak current capacitor portion 215 of this embodiment are large-capacity capacitors, which enable quick charging and discharging operations to be performed.

The voltage measuring unit 216 measures the voltage output from the capacitor unit 215 for peak current and compares it with a predetermined reference voltage (that is, the rated driving voltage of the wireless communication unit 202) (For example, a high-level signal H) to operate the power switch section 217 only when the power switch section 217 is brought into the power switch section 217, To the power switch unit 217, a control signal (e.g., a low-level signal L) in a state in which the operation of the unit 217 is stopped.

The voltage measuring unit 216 receives the output voltage of the capacitor unit 215 for peak current from one of two input terminals (for example, a non-inverting input terminal) and applies the reference voltage to the remaining input terminal And may be an applied comparator.

The power switch unit 217 is a switching device that is turned on or turned off in a state of a control signal output from the voltage measuring unit 216. In this example, a metal oxide semiconductor field effect transistor, but is not limited thereto.

The power switch unit 217 has a control terminal (e.g., a gate terminal) connected to an output terminal of the voltage measuring unit 216 and an input terminal (e.g., a source terminal) is connected to an output terminal of the peak current capacitor unit 50. [ And an output terminal (e.g., a drain terminal) is connected to an input terminal of the wireless communication unit 60. [

The power switch unit 217 is turned on when the control signal of the high level state is input from the voltage measurement unit 60 to the control terminal and transmits the output voltage of the peak current capacitor unit 215 to the wireless communication unit 202, Level control signal is input from the measuring unit 60 to the control terminal, the output voltage of the peak current capacitor unit 215, which is turned off and transmitted to the wireless communication unit 202, is cut off.

The operation of the power switch unit 217 allows the output of the peak current capacitor unit 50 to be supplied to the wireless communication unit 80 only when the output voltage of the peak current capacitor unit 50 is in a safe state, (202) is also performed stably.

4A to 4D are graphs showing the characteristics of the consumption current consumed at the rear end of the power supply unit 100. FIG. 4A is a waveform of the consumption current when the peak current capacitor unit 215 of the present example is not applied 4C is a waveform of the consumption current when the capacitor charging current limiting unit 213 of this embodiment is not applied.

4A, when the peak current capacitor unit 215 is not applied, the peak value of the current consumed when the wireless communication unit 202 is operated (i.e., during wireless transmission / reception) is smaller than the limit value of intrinsic safety explosion current Has occurred.

4C, when the charging operation of the capacitor unit 215 for peak current is performed, the capacitor unit 215 for peak current is applied but the capacitor charging current limiting unit 213 is not applied The peak value of the consumption current exceeded the limit value of intrinsic safety explosion current.

However, as shown in FIG. 4B, when the peak current capacitor 215 is applied, even when the wireless communication unit 202 is operated by the current limiting function by the capacitor unit 215 for peak current, The safety explosion current limit is not exceeded.

As shown in FIG. 4D, when the capacitor charging current limiting unit 213 is applied, the peak value of the consumed current consumed in the period during which the peak current capacitor unit 215 performs the charging operation exceeds the limit of the intrinsic safety explosion current It can be understood that a stable intrinsic safety explosion function is exhibited.

Next, an example of a mobile communication modem system according to another embodiment of the present invention will be described with reference to FIGs. 5 and 6. FIG.

In this embodiment, the intrinsically safe explosion-proof function is realized by using the molding part 50 that prevents the heat or energy emitted from the mobile communication modem module 200 from being diverted to the outside.

Next, an example of a mobile communication modem system according to the present embodiment will be described with reference to FIG.

The mobile communication modem system shown in FIG. 5 also includes a power supply unit 100, a mobile communication modem module, and a socket 300 connected to the mobile communication modem module, as shown in FIG.

3, the mobile communication modem module may be a mobile communication modem module 200 having a current limiting unit 201 or a component 211-217 of the current limiting unit 201 And may be a mobile communication modem module that does not include at least one.

The power supply unit 100 and the mobile communication modem module 200 are mounted on a single printed circuit board (PCB) to form a mobile communication modem printed circuit board 200a. Accordingly, the mobile communication modem printed circuit board 200a also constitutes a part of the mobile communication modem system according to the present embodiment.

The socket 300 is the same socket as the socket shown in FIG.

3, the mobile communication modem system according to the present embodiment includes a molding housing 400 having a built-in mobile communication modem printed circuit board 200a, and a molding housing 400 that is filled in the molding housing 400 and is located in the molding housing 400 A mobile communication modem printed circuit board 200a which is embedded in a molding part 500 and a socket 300 which is placed on the molding part 500 and which surrounds the mobile communication modem printed circuit board 200a, And a plurality of connection terminals 600 that are located between the molding part 500 and the connecting part 600.

The molding module 500 of the mobile communication modem module 200a prevents heat or energy emitted from the mobile communication modem module 200a from being emitted to the outside as described above.

The molding part 500 is made of a material having a heat-resistant function, an insulating function and an impermeability function such as epoxy, urethane, or silicon.

At this time, the thickness T1 of the molding part 500 surrounding the mobile communication modem module 200a, that is, the distance between the molding housing 400 and the mobile communication modem module 200a, It is the thickness required by the intrinsic stability explosion standard.

The thickness T1 may be at least 2 mm.

The molding housing 400 incorporates a mobile communication modem 200a to protect the mobile communication modem 200a located inside the mobile communication modem 200a from an external impact and stably protect the molding part 500 as a filling material.

The material of the molding housing 400 may be a material such as a metal that can protect the molding part 500 and the mobile communication modem module 200a that are packed therein.

The plurality of connection terminals 600 are disposed between the mobile communication modem module 200a and the socket 300 and are made of a conductive material such as copper or the like and include a power terminal, do.

Since each of the plurality of connection terminals 600 is directly connected to a corresponding terminal formed on the mobile communication modem printed circuit board 200a and the socket 300 through solder or the like, The mobile communication modem printed circuit board 200a and the socket 300 are electrically and physically connected to each other through the power supply lines 600 and 600 so that power supply and signal transmission operations are performed.

The plurality of connection terminals 600 are formed in the same shape and each of the plurality of connection terminals 600 is connected to the mobile communication modem printed circuit board 200a and the socket 300 in a straight line (e.g., perpendicular to the outer surface of the mobile communication modem module 200a) In the form of a bar connecting them to each other, and are located apart from each other.

At this time, the interval between the adjacent connection terminals 600 is also in accordance with intrinsic safety explosion standard.

Therefore, signals and voltages output from the mobile communication modem printed circuit board 200a through the plurality of connection terminals 600 are directly transmitted to the sockets 300. [

Due to the plurality of connection terminals 600, the mobile communication modem module 200a is surrounded by the molding part 500 except for a portion contacting the plurality of terminals 600. [

As shown in FIG. 5A, the socket 300 is positioned directly on the outer surface of the molding part 500 and is connected to a plurality of connection terminals 600 located below the socket 300.

Therefore, the entire outer surface of the molding part 500 excluding the part where the socket 300 is located is covered with the molding housing 400.

As described above, the mobile communication modem module 200a, in which heat or energy is emitted to the outside, is surrounded by a molding part 500 made of a material having a heat-resistant function, an insulating function and an impermeability function. Accordingly, heat or energy emitted from the mobile communication modem printed circuit board 200a is prevented from being output to the outside, and the intrinsically safe explosion-proof function is performed by the molding part 500. [

Another example of the mobile communication modem system according to the present embodiment shown in Fig. 6 has a similar structure as compared with Fig. 5, components having the same structure and performing the same function are denoted by the same reference numerals as those in FIG. 5, and a detailed description thereof will be omitted.

That is, the mobile communication modem system shown in FIG. 6 includes a mobile communication modem printed circuit board 200a, a molding part 500 surrounding the mobile communication modem printed circuit board 200a, and a molding part 500 A molding housing 400 and a socket 300 directly located on the molding part 500 and directly connected to the mobile communication modem printed circuit board 200a through the molding part 500. [

5, instead of using a plurality of connection terminals 600 for electrical and physical connection between the socket 300 and the mobile communication modem printed circuit board 200a, a plurality of connection terminal patterns 601 are printed A terminal printed circuit board 700 is used.

Since each of the plurality of connection terminal patterns 601 made of a conductive material is directly connected to terminals formed on the mobile communication modem printed circuit board 200a and the socket 300 via solder or the like, Electrical connection such as power supply and signal transfer operation between the mobile communication modem printed circuit board 200a and the socket 300 is performed through the antenna.

At this time, the interval between the adjacent connection terminal patterns 601 also conforms to the intrinsic safety explosion standard.

When the terminal printed circuit board 700 is used in place of the plurality of connection terminals 600, the electrical connection state between the socket 300 and the mobile communication modem printed circuit board 200a can be more stably performed, 300 and the mobile communication modem printed circuit board 200a can be performed more easily and quickly.

In order to manufacture the mobile communication modem system shown in FIGS. 5 and 6, first, a mobile communication modem printed circuit board 200a connected to the inside and the outside of the molding housing 400 through the connectors 600 and 700, Place the socket (300).

Then, a liquid molding solution is injected through an inlet (not shown) formed in the molding housing 400 to fill the molding solution into the molding housing 400. At this time, the injection operation of the molding solution continues until the molding solution is discharged toward the outlet (not shown) formed in the molding housing 400.

Then, the molding solution 500 in the solution state is converted into a solid state through heat treatment or the like to form the molding part 500.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

100: Power supply unit 200: Mobile communication modem module
200a: Mobile communication modem printed circuit board
201: current limiting unit 202: wireless communication unit
211, 214: reverse current prevention unit 212: voltage regulator
213: Capacitor charging current limiting unit
215: capacitor unit for peak current 216: voltage measuring unit
217: Power switch unit 300: Socket
400: molding housing 500: molding part
600: connection terminal 700: terminal printed circuit board

Claims (13)

In a mobile communication modem system including a mobile communication modem module,
The mobile communication modem module includes:
A wireless communication unit for performing wireless transmission / reception,
A capacitor charge current limiting unit connected to the power supply unit and configured to decrease a voltage output from the power supply unit,
A capacitor charging current limiting unit connected to the capacitor charging current limiting unit to charge the capacitor using the voltage applied from the capacitor charging current limiting unit to apply a driving voltage to the wireless communication unit, The capacitor unit for peak current
Lt; / RTI >
The capacitor charge current restricting unit may reduce the magnitude of the current consumed during the charging operation of the peak current capacitor unit to be less than or equal to the set current limit value
Mobile communication modem system. The method of claim 1,
The mobile communication modem module includes:
A voltage measuring unit connected to the peak current capacitor unit for comparing the voltage output from the peak current capacitor unit with a reference voltage to output an output signal of the corresponding state,
And a control unit coupled to the voltage measuring unit, the wireless communication unit, and the peak current capacitor unit, for applying a driving voltage output from the peak current capacitor unit to the wireless communication unit according to a state of the output signal output from the voltage measurement unit A power switch section
The mobile communication system further comprising: 3. The method of claim 2,
Wherein the power switch unit is a transistor having a control terminal connected to the voltage measuring unit, an input terminal connected to the peak current capacitor unit, and an output terminal connected to the wireless communication unit. The method of claim 1,
The mobile communication modem module further includes a voltage regulator located between the power supply unit and the capacitor charging current limiting unit and converting the magnitude of a voltage applied from the power supply unit to a predetermined magnitude and outputting the magnitude to the capacitor charging current limiting unit Mobile communication modem system. 5. The method of claim 4,
The mobile communication modem module includes:
A first reverse current blocking unit connected between the power supply unit and the voltage regulator,
And a second reverse current blocking part connected between the capacitor charge current restricting part and the capacitor for the peak current,
The mobile communication system further comprising: 6. The method according to any one of claims 1 to 5,
A molding part surrounding the mobile communication modem printed circuit board on which the mobile communication modem module is mounted,
And a connection portion disposed between the mobile communication modem module and the socket located above the molding portion,
The mobile communication system further comprising: The method of claim 6,
Wherein the connection unit includes a plurality of connection terminals spaced apart from each other between the mobile communication modem module and the socket. The method of claim 6,
Wherein the connection unit is a mobile communication modem system including a terminal printed circuit board on which a plurality of connection terminal patterns are printed, The method of claim 6,
Wherein the molding part is made of epoxy, urethane or silicone. delete delete delete delete

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