JP5075179B2 - External device - Google Patents

Description

  The present invention relates to an external device that can be attached to and detached from a portable information device and can cool the portable information device.

  Conventionally, there is a so-called docking device for a notebook personal computer as an external device for cooling a portable information device from the outside (see, for example, Patent Document 1). This docking device is detachably attached to the notebook computer. When this docking device is attached to a notebook computer, various functions of the notebook computer can be expanded and the notebook computer can be cooled by a fan unit provided therein.

JP 2001-306186 A

  However, in recent years, the amount of heat generated by the notebook personal computer as a whole has increased along with an increase in power consumption due to an increase in CPU speed. Therefore, in order to cool this, it is necessary to rotate the fan of the notebook personal computer and the external device at a high speed, and there is a problem that the noise of the fan increases. Furthermore, with the downsizing of notebook computers, the cooling fans provided in notebook computers are also downsized. If it is attempted to perform the same cooling as a conventional fan with a small cooling fan, the fan rotates at high speed, and the noise of the fan tends to increase. In addition, there are many quiet environments such as offices and homes in which the notebook computer and the external device are used, and there is a problem that the noise of the fan of the laptop computer and the external device is noticeable.

  Accordingly, in view of such a conventional problem, the present invention provides an external device that can suitably cool a portable information device and can reduce fan noise generated from the portable information device and the external device. With the goal.

An external device according to the present invention for solving the above-described problems and achieving an intended object includes a cooling fan and a control unit that controls the fan to rotate at a target rotational speed corresponding to the temperature. , and a signal receiving unit for transmitting the signal to the control unit receives a signal from the outside, a portable information device having a be subject, an external device detachable to the portable information device, the external while the device is mounted on the portable information device, a cooling fan for cooling the portable information apparatus, in a state where the external device is attached to the portable information device, the internal temperature of the portable information device And the portable information device is sent at a rotational speed lower than the target rotational speed corresponding to the detected internal temperature by sending a signal to the control unit of the portable information device via the signal receiving unit. the fan Ru is rotated Both are characterized by having a, a fan controller for rotating the cooling fan at a lower rotational speed than the target speed.

  In addition to the above configuration, the external device of the present invention is characterized in that the fan control unit controls the rotational speed of the cooling fan so as to be equal to the rotational speed of the fan of the portable information device. .

  Further, in the external device of the present invention, in addition to the above configuration, the fan control unit makes the volume of sound generated from the fan of the portable information device equal to the volume of sound generated from the cooling fan. Thus, the number of rotations of the cooling fan is controlled.

In addition to the above configuration, the external device of the present invention further stores rotational speed sound information that is a relationship between the rotational speed of a fan provided in the portable information device and the volume of sound generated from the fan. The fan control unit includes information on a fan provided in the portable information device to which the external device is attached, and rotation speed information for each fan stored in the storage unit. Basically, the rotational speed of the fan and the rotational speed of the cooling fan are controlled.

  In addition to the above configuration, the external device of the present invention is characterized in that an air cooling unit for cooling the air passing through the cooling fan is provided in the ventilation path of the cooling fan.

  According to the present invention, a cooling fan, a control unit that controls the fan to rotate at a target rotational speed corresponding to the temperature, a signal receiving unit that receives a signal from the outside and transmits the signal to the control unit, An external device that can be attached to and detached from the portable information device, the cooling fan that cools the portable information device, and the portable information device that is attached to the portable information device. The internal temperature of the information device is detected, and a signal is sent to the control unit of the portable information device via the signal receiving unit so that the fan of the portable information device is rotated at a rotation speed lower than the target rotation speed corresponding to the internal temperature. And a fan control unit that rotates the cooling fan at a lower rotational speed than the target rotational speed, so that the sound generated from the fan of the portable information device can be reduced without lowering the ability to cool the portable information device. Reduce size Door can be.

FIG. 1 is a side view showing an external device according to an embodiment of the present invention. FIG. 2 is a perspective view showing the external device. FIG. 3 is a bottom view showing the external device. FIG. 4 is a control block diagram showing a state where the external device is connected to the portable information device. FIG. 5 is a graph showing the relationship between the fan speed, noise, and cooling air temperature when the external device is used.

  Hereinafter, embodiments of an external device according to the present invention will be described in detail with reference to FIGS. The external device 1 is detachably attached to a portable information device 101 such as a notebook personal computer.

  The portable information device 101 receives a fan 102 that cools the portable information device 101, a control unit 103 that controls the fan 102, and a signal from outside the portable information device 101, and receives the signal from the control unit 103. And an interface (signal receiving unit) 104 for transmitting to the network. In addition, a temperature sensor 105 is installed inside the casing of the portable information device 101. The temperature sensor 105 is connected to the control unit 103. The fan 102 includes a rotary blade 102a and a fan driving unit 102b. The fan 102 rotates the rotating blade 102a by the fan driving unit 102b and blows air to cool the inside of the portable information device 101.

  The control unit 103 controls the fan 102 to rotate at a target rotational speed corresponding to the temperature. The target rotational speed is set for each temperature band. The control unit 103 rotates the fan 102 at a target rotational speed corresponding to the internal temperature detected by the temperature sensor 105 of the portable information device 101. In other words, the fan 102 is rotated at a higher rotational speed as the detected internal temperature is higher. The control unit 103 drives the fan 102 according to a signal given from the external device 1 via the interface 104 when the external device 1 described later is attached to the portable information device 101.

  The external device 1 includes a cooling fan 2, a fan control unit 3, a storage unit 4, an interface 5, an air cooling unit 6, and a casing 7 in which these are installed.

  The cooling fan 2 includes a rotary blade 2a and a fan driving unit 2b. The cooling fan 2 blows air by rotating the rotary blade 2a by the fan driving unit 2b. The cooling fan 2 can change the number of rotations of the rotating blade 2a (how many rotations per second) by the fan driving unit 2b. An air cooling unit 6 is disposed in the blowing direction of the cooling fan 2. That is, an air cooling unit for cooling the air passing through this path is disposed in the air blowing path of the cooling fan.

  The air cooling unit 6 is a part that cools air. The upper side of the air cooling unit 6 is a cooling unit 6a, and the lower side is a heat radiation unit 6b. The air cooling unit 6 is configured by a Peltier element. The Peltier element is formed in a substantially plate shape. When an electric current is passed, heat is generated on the plate surface on one side and heat is absorbed on the plate surface on the other side. The Peltier element is disposed inside the housing 7 such that the heat dissipation surface of the Peltier element faces the bottom surface side of the housing 7. Therefore, the heat absorption surface of the Peltier element faces the upper surface side of the housing 7. A plurality of columnar heat conductors project from a surface (heat radiating surface) where heat is radiated from the Peltier element and a surface (heat absorbing surface) where heat is absorbed. This heat conductor is formed of a material having high heat conductivity. Cooling efficiency and heat dissipation efficiency are enhanced by providing a plurality of columnar heat conductors on the heat absorption surface and heat dissipation surface of the Peltier element.

  The cooling part 6a of the air cooling part 6 is comprised from the heat absorption surface of a Peltier element, and the heat conductor protrudingly provided by the heat absorption surface. In the cooling unit 6a, heat is absorbed from the heat absorption surface and the surface of the heat conductor, and the air is cooled. The heat dissipating part 6b of the air cooling part 6 is composed of a heat dissipating surface of the Peltier element and a heat conductor protruding from the heat dissipating surface. The heat generated on the heat dissipation surface of the Peltier element is dissipated on the heat dissipation surface, is transmitted to the heat conductor on the heat dissipation surface side, and is also dissipated from the heat conductor. The Peltier element is a Peltier element formed in a plate shape by sandwiching a p-type semiconductor and an n-type semiconductor in a so-called π-type structure with electrodes between a pair of insulating heat conductive plates. The heat conduction plate on one side of the pair of heat conduction plates constitutes a heat dissipation surface, and the heat conduction plate on the other side constitutes a heat absorption surface. When a voltage is applied to the Peltier element configured as described above, heat is transferred from the heat conducting plate on the heat absorbing surface side to the heat conducting plate on the heat radiating surface side.

  The air sent out from the cooling fan 2 is cooled above the air cooling unit 6, that is, through the cooling unit 6a. And this cooled air blows off from the ventilation port 7a of the housing | casing 7 mentioned later. The cooled air hits the portable information device 101 to cool the portable information device 101.

  The fan control unit 3 is connected to the cooling fan 2 and controls the cooling fan 2. The cooling fan 2 is controlled by sending a signal to increase or decrease the number of rotations of the cooling fan 2 to the fan driving unit 2b. The fan control unit 3 is also connected to the interface 5 and the storage unit 4. Further, when the external device 1 is mounted on the portable information device 101, the fan control unit 3 sends a signal to the fan driving unit 102b via the interface 5, the interface 104, and the control unit 103, so that the portable information The fan 102 of the device 101 is controlled.

  The storage unit 4 is a part for storing information on the fan 102 provided in the portable information device 101. That is, the rotational speed (rotational speed sound information) of the fan 102 having the same loudness as that when the cooling fan 2 of the external device 1 rotates at a predetermined rotational speed is stored in the storage unit 4. Then, the fan control unit 3 outputs the rotational speeds of the fan 102 and the cooling fan 2 of the portable information device 101 based on the rotational speed. For each type of fan 102, the relationship between the rotation speed of the fan 102 and the loudness of the sound generated by the fan 102 at that rotation speed (rotational speed sound information) may be stored. In this case, the relationship between the number of rotations of the cooling fan 2 and the loudness of the cooling fan 2 generated at the number of rotations is also stored in the storage unit 4, and the fan control unit 102 and the cooling fan are controlled by the fan control unit based on these information. A rotational speed of 2 is set.

  The interface 5 is a part that transmits and receives signals to and from the interface 104 of the portable information device 101. The interface 5 transmits the signal sent from the fan control unit 3 to the interface 104 of the portable information device 101. In addition, a signal transmitted from the portable information device 101 via the interface 104 is transmitted to the fan control unit 3. The interface 5 and the interface 104 may be physically connected or may be wirelessly connected.

  The housing 7 is formed in a box shape. A cooling fan 2, an air cooling unit 6, a fan control unit 3, a storage unit 4, and an interface 5 are installed in the housing 7. A blower opening 7 a is opened on the upper surface of the housing 7 so that air blown from the cooling fan 2 is blown out. An air inlet 7 b is opened at least on the bottom surface of the housing 7 so that air can be taken into the housing 7. In addition, a heat radiation port 7 c is formed on the bottom surface of the air cooling unit 6. The air passing through the heat radiation part 6b of the air cooling part 6 is discharged from the heat radiation port 7c. Further, a leg portion 7 d is formed at the peripheral portion of the bottom surface of the housing 7. When the external device 1 is installed on a desk or the like, a predetermined interval is formed between the bottom surface of the housing 7 and the installation surface on which the housing 7 is installed by the legs 7d, and the air inlet 7b In addition, air can enter and exit through the heat radiation port 7c. Note that the air blowing port 7 a may be formed at a position that coincides with the air intake port formed on the bottom surface of the portable information device 101 when the external device 1 is attached to the portable information device 101. By doing so, the cooling air enters the portable information device 101, and the portable information device 101 can be further cooled.

  The external device 1 includes a power source (not shown) inside. Further, it can be connected to an external power source. In addition, the external device 1 includes various modules that extend the functions of the portable information device 101, such as a hard disk and a graphic board (not shown).

  The external device 1 configured as described above is attached to the portable information device 101. The state in which the external device 1 is attached to the portable information device 101 means that at least signals can be transmitted to and received from the portable information device 101, and the air blown by the cooling fan 2 hits the portable information device 101. In this state, the device 101 can be cooled.

  Control of the cooling fan 2 and the fan 102 by the fan control unit 3 will be described. First, in a state where the external device 1 is mounted on the portable information device 101, the fan control unit 3 acquires information on the fan 102 of the portable information device 101. The timing for acquiring the information of the fan 102 may be any time, but may be when the external device 1 is turned on and the portable information device 101 is activated. The control of the fan 102 and the cooling fan 2 of the portable information device 101 by the fan control unit 3 of the external device 1 is naturally performed when the external device 1 and the portable information device 101 are activated.

  Next, the fan control unit 3 of the external device 1 acquires the internal temperature of the portable information device 101. This internal temperature is detected by a temperature sensor 105 provided inside the portable information device 101. The initial timing for acquiring the internal temperature is preferably when the portable information device 101 is activated.

  The fan control unit 3 outputs the rotation speed of the fan 102 of the portable information device 101 corresponding to the acquired internal temperature based on the information of the fan 102. The output rotation number is transmitted to the control unit 103 of the portable information device 101 via the interface 5 of the external device 1 and the interface 104 of the portable information device 101. The control unit 103 of the portable information device 101 outputs this rotational speed to the fan drive unit 102b. Then, the fan 102 of the portable information device 101 rotates at the output rotation speed. Further, the fan control unit 3 outputs the number of rotations of the cooling fan 2 of the external device 1 corresponding to the acquired internal temperature to the fan driving unit 2b. Then, the cooling fan 2 rotates at the output rotational speed.

  Here, the rotation speed of the fan 102 and the cooling fan 2 corresponding to the acquired temperature will be described. The rotational speed of the fan 102 of the portable information device 101 is set lower than the rotational speed of the fan 102 when the external device 1 is not provided. In other words, the fan control unit 3 controls the rotation speeds of the fan 102 and the cooling fan 2 to rotate at a rotation speed lower than the target rotation speed described above. That is, when comparing at the rotation speed corresponding to the same temperature, the rotation is performed at a rotation speed lower than the target rotation speed.

  The number of rotations of the cooling fan 2 of the external device 1 is set so that the sound generated from the cooling fan 2 is the same or smaller than the sound generated from the fan 102 of the portable information device 101. These rotational speeds are set based on the information of the fan 102 of the portable information device 101 and the information stored in the storage unit 4. Of course, if the fan 102 of the portable information device 101 and the cooling fan 2 of the external device 1 are the same, it is preferable that the rotation speed be the same. The fan control unit 3 periodically acquires the internal temperature of the portable information device 101 and repeats the above.

The external device 1 includes a cooling fan 2 that cools the portable information device 101 and a fan control unit 3 that controls the fan 102 of the portable information device 101. Therefore, the rotational speed of the fan 102 of the portable information device 101 can be reduced without reducing the cooling power. When the rotational speed of the fan 102 of the portable information device 101 decreases, the noise of the fan 102 generated from the fan 102 of the portable information device 101 is also reduced. Naturally, the cooling fan 2 of the external device 1 is rotated with lower noise than the fan 102 of the portable information device 101. In addition, since the external device 1 includes the storage unit 4, it can support a plurality of types of fans 102. That is, a plurality of types of portable information devices 101 can be handled.

FIG. 5 shows that the fan 102 of the portable information device 101 and the cooling fan 2 of the external device 1 are the same, and the cooling temperature of the blown air when the rotation speed is controlled to the same, the speed of the fan 102 and the fan 102. It is a graph which shows the noise. In the figure, the “design criteria” is a case where the fan 102 of the portable information device 101, that is, the case where the external device 1 is not used, and the portable device so as to have a cooling power equivalent to the case where the external device 1 is used. The noise and the rotation speed when the fan 102 of the information device 101 is rotated are shown.

  As shown in FIG. 5, even when the air temperature is 25 degrees in a normal use environment, that is, even when the air cooling unit 6 is not started and the air to be blown is not cooled, Noise can be reduced by lowering the speed (rotational speed) of the fan 102 than the “design standard”.

  When the fan 102 provided in the portable information device 101 to which the external device 1 is mounted and the cooling fan 2 of the external device 1 are the same, the storage unit 4 is not necessary.

DESCRIPTION OF SYMBOLS 1 External device 2 Cooling fan 2a Rotor blade 2b Fan drive part 3 Fan control part 4 Memory | storage part 5 Interface 6 Air cooling part 6a Cooling part 6b Heat radiating part 7 Case 7a Air blowing port 7b Air inlet 7c Heat radiating port 7d Leg part 101 Portable type Information device 102 Fan 102a Rotary blade 102b Fan drive unit 103 Control unit 104 Interface 105 Temperature sensor

Claims (5)

A cooling fan, a control unit that controls the fan to rotate at a target rotational speed corresponding to the temperature, and a signal receiving unit that receives a signal from the outside and transmits the signal to the control unit An external device that is applicable to a portable information device and is detachable from the portable information device,
A cooling fan for cooling the portable information device in a state where the external device is mounted on the portable information device;
By detecting the internal temperature of the portable information device while the external device is attached to the portable information device, and sending a signal to the control unit of the portable information device via the signal receiving unit, both the in the detected lower rotational speed than the target rotational speed corresponding to the internal temperature Ru rotate the fan of the portable information device, a fan for rotating the cooling fan at a lower rotational speed than the target rotational speed An external device comprising: a control unit;   The external device according to claim 1, wherein the fan control unit controls the number of rotations of the cooling fan to be equal to the number of rotations of the fan of the portable information device.   The fan control unit controls the number of rotations of the cooling fan so that the volume of sound generated from the fan of the portable information device is equal to the volume of sound generated from the cooling fan. The external device according to claim 1. The external device further includes a storage unit that stores rotational speed sound information that is a relationship between the rotational speed of the fan provided in the portable information device and the volume of sound generated from the fan,
The fan control unit, and the information of the fan to which the external device is provided in a portable information device is attached, based on the rotational speed sound information, the per fan stored in the storage unit, of the fan The external device according to claim 1 , wherein a rotational speed and a rotational speed of the cooling fan are controlled.   The external device according to any one of claims 1 to 4, further comprising an air cooling unit for cooling air passing through the air flow path of the cooling fan.

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