JP3284253B2 - Information processing device and information processing system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an information processing apparatus having a main unit and a main unit attached device, and an information processing system including the information processing unit.

[0002]

2. Description of the Related Art For example, in an information processing apparatus such as an image reading apparatus (hereinafter, referred to as an image scanner) and a printer apparatus, a main apparatus and an auxiliary apparatus (hereinafter, referred to as an optional apparatus) used by being connected to the main apparatus. Are known. Taking an image scanner as an example, such optional devices include a transparent original unit for irradiating light on the transparent original when reading the image of the transparent original, or a device for automatically setting the original at the reading position. An optional device called an automatic document feeder unit (hereinafter, referred to as an ADF unit) is known. Also, taking a printer device as an example, an optional device called an auto feeder unit is known.

[0003] Such an optional device is connected to the main unit using a connecting means such as a connector. The power for use of the optional device is supplied from the main unit via the connection means. In this case, taking an optional device called a transparent original unit as an example,
A high-voltage power supply for a lamp for irradiating light or a high-voltage power supply for a motor for moving a light source is required as a power supply for use. In the case of an optional device called an ADF unit, a high-voltage power supply for a motor for automatically setting a document is required as a power supply to be used. Therefore, the main unit needs to supply these high-voltage power supplies to the optional devices.

[0004]

However, in such an information processing apparatus, a circuit or the like in the information processing apparatus is operated by a high voltage of a high voltage power supply transmitted through a connector when the optional apparatus is connected to the main apparatus. There was a problem of being destroyed. For example, for the logic circuit in the main unit,
It was found to be destroyed as follows. That is, when the optional device is connected to the main device, a high voltage of, for example, 24 V is applied from the main device to the optional device by the high voltage power supply. And this applied 24V
Is applied to a signal line connected by a connector via circuits and elements in the optional device. This signal line is connected to a logic circuit in the main unit, which is driven by, for example, a 5V power supply and has a withstand voltage of only about 7.5V. Therefore, when a high voltage of 24 V is applied to this signal line, a situation occurs in which the logic circuit is destroyed by the high voltage of 24 V.

In order to prevent the destruction of the circuits and the like in the information processing device as described above, the power switch of the main device may be turned off when the optional device is connected to the main device. With this configuration, when the optional device is connected, a high voltage is not applied to the optional device, and a situation in which a high voltage is applied to the signal line via the optional device does not occur.

However, an information processing apparatus such as an image scanner is usually used by being connected to a predetermined network in an information processing system including a host device (hereinafter referred to as a host computer). In such a network, SCSI (Small C
output System Interface)
It is necessary to conform to the rules of the interface such as. For example, in the case of the SCSI interface, when the power of one connected information processing apparatus is turned off, it is basically necessary to turn off the power of the host computer. If the power of the image scanner is turned off while the power of the host computer is turned on, the data may be destroyed when the host computer is writing data to a hard disk or the like.

However, in order to turn off the power of the host computer, it is necessary to end all the programs such as application software and OS that are being executed in the host computer once. In particular, in recent years, the amount of data required for application software and OS has become enormous, and it is extremely difficult to terminate the execution of a program, turn off the power, turn on the power again, and restart the program. A lot of time and complicated work are required (several tens of seconds to several minutes). Therefore, it is not preferable to force the user to perform such a complicated and time-consuming operation every time the optional device is replaced.

Further, in a network in which a plurality of host computers are connected, if the execution of the program of one computer is terminated, a problem may occur in the network system.

As described above, in an information processing apparatus such as an image scanner connected via a predetermined network, even when an optional device is connected to the main unit of the image scanner, the power supply of the main unit is kept on. It is desirable to set up a system so that optional devices can be connected. For this purpose, it is desirable to provide a protection means for protecting circuits and elements in the information processing apparatus against a high voltage from a high voltage power supply. For example, in the field of IC, etc.,
2. Description of the Related Art There is known a conventional technique in which a protection means such as a protection diode is provided to protect an internal circuit from external static electricity or the like. However, these prior arts are not related to protection means when connecting to a device whose power is already turned on. Further, in these conventional techniques, there is a problem that the protection means must be provided for all of the plurality of signal input / output lines. For this reason, there is a problem that the circuit is enlarged due to the presence of the protection means.

Further, in an information processing apparatus having such a main unit and an optional device, the main unit and the optional device are connected by a connecting means such as a connector. The connecting means such as a connector has a plurality of power terminals and a plurality of signal terminals, and the user must manually connect the connector having the plurality of terminals to the connector.
For this reason, for example, there is a special situation that a high-voltage power supply terminal may be connected before a GND terminal among a plurality of power supply terminals is connected.

An object of the present invention is to solve the above problems, and an object of the present invention is to provide an information processing apparatus having a main unit and a main unit attached device, and an information processing apparatus including the information processing unit. It is an object of the present invention to provide an information processing apparatus and an information processing system that can connect a main body attached device while the power of the main body device is turned on.

[0012]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention provides a main unit, and at least a first power supply and a high-voltage power supply connected to the main unit. And a main unit attached to the main unit, the main unit being operated when the main unit is connected to the main unit. Protection means for protecting from a high voltage, wherein the protection means is means for connecting the second power supply after the first power supply is connected between the main body device and the main body attachment device. There is a feature.

According to the present invention, when the main unit is connected to the main unit, the first unit is connected between the main unit and the main unit.
After the power supply is connected, the second power supply is connected. This ensures that the first power supply is connected when the second power supply is connected. Accordingly, the high voltage applied by the second power supply is transmitted to the first power supply having extremely low input impedance, and this high voltage is transmitted through a power supply line, a signal line, or the like to a circuit or an element in the information processing apparatus. Is prevented from being transmitted. As a result, destruction of a circuit or an element in the information processing device due to a high voltage is effectively prevented.

Further, according to the present invention, the protection means includes a detection means for detecting whether the first power supply is connected between the main body device and the main body attachment device, and a detection means for detecting whether the first power supply is connected. Opening / closing means for opening / closing the connection of the second power supply between the main unit and the main unit attached device based on the result.

According to the present invention, whether or not the first power supply is connected between the main unit and the main unit is detected, and the connection of the second power supply is opened and closed based on the detection result.
This ensures that the first power supply is connected when the second power supply is connected, and prevents a circuit or an element in the information processing device from being damaged by a high voltage.

Further, according to the present invention, the detecting means may include a current flowing between the first and second power sources when the first power source is connected between the main device and the main unit auxiliary device. Means for generating a predetermined voltage based on the predetermined voltage, the switching means is turned on by the generated predetermined voltage, and the second power supply is connected between the main body device and the main body attachment device. And

According to the present invention, whether or not the first power supply is connected is determined by detecting a current flowing between the first and second power supplies. Then, the opening / closing means is turned on by the predetermined voltage generated based on the detected current, and the second power supply is connected between the main unit and the main unit. Thereby, the first power supply is connected when the second power supply is connected.
Of the information processing device is prevented from being destroyed by a high voltage.

[0018] The present invention is also directed to a switching device, wherein when the first power source is not connected between the main unit and the main unit auxiliary device and a current flows through the second power source, The above-mentioned predetermined voltage is set so as to be non-conductive.

According to the present invention, when a current flows from the second power supply to the second power supply while the first power supply is not connected, the opening / closing means is set so as to be non-conductive. Voltage is generated. Accordingly, even when a current flows between the third power supply or the like in the information processing apparatus and the second power supply in a state where the first power supply is not connected, for example, the predetermined voltage that does not conduct the switching means is maintained. It will be applied to the opening and closing means. As a result, the opening / closing means is prevented from conducting when the first power supply is not connected, and it is assured that the second power supply will not be connected unless the first power supply is connected.

Further, according to the present invention, when the first power source is not connected between the main unit and the main unit auxiliary device, a current flowing through the second power source is limited. And

According to the present invention, when the first power supply is not connected between the main device and the main device, the current flowing from or to the second power source is limited. You. This prevents a current from flowing between, for example, the third power supply or the like in the information processing apparatus and the second power supply in a state where the first power supply is not connected. As a result,
The opening / closing means is prevented from conducting when the first power supply is not connected, and it is guaranteed that the second power supply is not connected unless the first power supply is connected.

Further, the present invention includes a diode element as the detecting means and an FET transistor element as the switching means, wherein a first terminal of the diode element is connected to the first power supply, and a second terminal is When the first power supply is connected between the main body device and the main body auxiliary device, the resistance is set to the resistance when the first power supply is connected to the gate electrode of the FET transistor and is connected to the second power supply via a resistance element. Element, the first through the diode element,
A predetermined voltage is generated by the diode element based on a current flowing between the second power supplies, and the generated predetermined voltage causes the FET transistor element to conduct, thereby causing the FET device to conduct between the main body device and the main body auxiliary device. 2 is connected.

According to the present invention, when the first power supply is connected, a predetermined voltage is generated by the diode element based on the current flowing between the first and second power supplies, and the FET generates the predetermined voltage by the generated predetermined voltage. The transistor is turned on and the second
Is connected. In this case, the FET transistor is turned on / off by voltage control instead of current control. Therefore, even when a predetermined voltage for turning on the FET transistor is generated, it is not necessary to increase the current flowing through the diode element via the resistance element. As a result, power loss in the diode element can be reduced.

According to the present invention, there is provided an information processing apparatus including any one of the above information processing apparatuses and a host apparatus, the information being formed by connecting at least one or a plurality of the information processing apparatuses and the host apparatus by a predetermined network. A processing system,
The provision of the protection means enables connection and disconnection of the main body auxiliary device to and from the main body device while the power supply of the main body device is turned on.

According to the present invention, by providing the protection means in the information processing device, it is guaranteed that the second power source is connected after the first power source is connected. Circuit or element is protected from high voltage. As a result, it is possible to connect and disconnect the main unit attached to the main unit while the main unit is turned on. Therefore, it is not necessary to turn off the power of the host device on the network when connecting or disconnecting the attached device to / from the main device.

[0026]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below. In the following description, an image scanner will be described as an example of the information processing apparatus according to the present invention. However, the present invention is not limited to this, and can be applied to any type of information processing apparatus.

1. First Embodiment FIG. 2A is a perspective view of the image scanner according to the present embodiment when viewed from the front side. The image scanner includes a document table 10, a document cover 12, a carriage 14, a power switch 62, and the like. Here, an original such as a photographic paper, a photograph, or a printed material to be read is arranged on the original platen 10. The document cover 12 is used to block external light when reading a single-sheet document, for example. The carriage 14 is provided with a sensor and a fluorescent lamp for reading an image, and is used for moving and reading an image during a reading operation.
Further, the power switch 62 is used to turn on the power of the image scanner.

FIG. 2B is a perspective view of the image scanner viewed from the rear side. As shown in FIG. 2B, a power connector 18, SCSI connectors 20, 22, an optional control connector 24, and a bidirectional parallel connector 26 are provided on the back side of the image scanner. Here, the power connector 18 is a connector for connecting a power cable for supplying power to the image scanner. Also, the SCSI connectors 20, 22
Is a connector for connecting a SCSI cable.
The method of connecting the SCSI cable will be described later.
The bidirectional parallel connector 26 is a connector for connecting a parallel interface cable.
Further, the option control connector 24 is a connector for connecting the ADF unit and the transparent original unit when using the ADF unit and the transparent original unit which are optional devices. FIG. 3A is a perspective view of the ADF unit, and FIG. 3B is a perspective view of the transparent original unit.

The ADF unit is used for automatically setting a plurality of originals at the reading position when there are many originals to be read by the image scanner.
When the ADF unit is used, the connector cable 32 is connected to the optional control connector 24 of the main unit.
Connect to This allows connection of power and signals to and from the main unit. When loading the ADF unit, the document cover 12 is removed, and the ADF unit is placed on the document table 10 instead. The ADF unit has a paper tray 28 and a document draw-in unit 30, and a plurality of documents to be read are set on the paper tray 28. Then, the original set on the paper tray 28 is pulled in by the original drawer 30 and set at the original reading position of the original platen 10. In this case, the document draw-in unit 30 has a motor circuit (not shown).

The transparent original unit is used for reading a transparent original such as a film. This transparent original unit is used by connecting a connector cable 36 to the option control connector 24 of the main body device, removing the original cover 12 and installing the original cover on the original table 10. Further, a lamp (not shown) for irradiating the original is stored in the lamp storage section 34 of the transparent original unit, so that an image of an original which cannot be read by reflection of light can be read.

FIG. 4 shows an example of an information processing system formed by connecting information processing apparatuses such as an image scanner through a predetermined network. This information processing system includes a host computer 40, a hard disk 44,
Hard disk controllers 48 and 5 for controlling 46
0, an image scanner 55 composed of a main body device 52 and an optional device 54. These devices are connected by SCSI cables 64-68. For example, taking the SCSI cables 66 and 68 as an example, the SCSI cable 66 is connected to the SCSI connector 20 of the main unit, and the SCSI cable 68 is
It is connected to the I connector 22 (see FIG. 2B). By connecting the devices in a daisy chain with the SCSI cables 64-68 in this manner, the SCSI (or S
A network conforming to the CSI2 standard is formed.

Each device of this information processing system is provided with power switches 56 to 62, and these power switches enable the power of each device to be turned on and off independently. According to the present invention, as will be described later, by providing predetermined protection means,
The optional device 54 can be connected to and disconnected from the main unit 52 while the power switch 62 of the main unit 52 is kept on. Therefore, the power switch 62 does not need to be turned off when the optional device 54 is connected / disconnected. For example, even when the host computer 40 is accessing data on the hard disks 44 and 46, The connection / disconnection or replacement of the device 54 can be performed. Furthermore, optional device 5
In connection with 4, for example, there is no need to end the execution of programs such as application software and OS in the host computer 40 and turn off the power switch 56.
This eliminates the need for the user to require cumbersome and time-consuming labor, thereby increasing the convenience of the information processing system.

In particular, in an interface such as SCSI, the ID of each device on the bus is set when the power is turned on. Therefore, it is not preferable to turn off the power of one of the devices after the power of the entire system is turned on.

In many image scanners, one image scanner is commonly used by a plurality of host computers. Therefore, in this case, even if the user using one host computer connects / disconnects or changes the optional device 54 of the image scanner 55, the user using the other host computer can use his / her own computer. There is an advantage that the host computer need not be turned off. In this case, for example, a network is formed by connecting the first host computer to the SCSI connector 20 of the image scanner 55 and connecting the second host computer to the bidirectional parallel connector 26 of the image scanner 55. It is good also as a structure which performs.

FIG. 5A is a block diagram schematically showing an internal circuit of an information processing apparatus such as a conventional image scanner. From the main unit to the optional device, a GND power supply, a 5V power supply,
A 4V power supply and a predetermined signal are supplied. That is, the GND power supply line 72, 5V
Power supply line 76, 24V power supply line 80, signal line 8
4 is a GND power line 74, 5V on the optional device side
Power line 78, 24V power line 82, signal line 8
6 will be connected. Here, the 5V power supply is a power supply supplied to the logic ICs 88 and 90 in the device. The 24V power supply is a power supply supplied to the high voltage drive unit 86 in the device. The high-voltage driving section 86 includes the motor circuit and lamp in the above-described ADF unit and transparent original unit, or a circuit and an element for driving these.

Now, it has been found that in the conventional image scanner, when an optional device is connected while the power supply of the main unit is turned on, a problem occurs that the logic IC 88 and the like in the main unit are destroyed. This destruction occurs as follows. Now, for example, consider the case where the 24V (high voltage) power lines 80 and 82, the signal lines 84 and 86, etc. are connected first before the GND power lines 72 and 74 are connected by the connection of the connector unit 70. . In such a case, there is a possibility that a loop circuit shown by a thick line in FIG. That is, it is a loop circuit that continues from the 24V power supply lines 80 and 82 to the high voltage driver 86, IC 90, signal lines 86, 84, and IC 88.

Here, in the high voltage driving section 86, the loop circuit is formed through a circuit in the high voltage driving section 86 or a resistance element. Also, I
The reason why such a loop circuit is formed in C90 is as follows. That is, FIG. 5B shows an example of the internal circuit of the IC 88, but the IC 88 has a logic circuit 92.
, A diode 94 for input protection is arranged at the front stage. Accordingly, a path shown by a thick line in FIG. 5B is generated, and a loop circuit extending from the GND power supply line 74 to the signal line 86 is formed.

When the above-described loop circuit occurs, a high voltage of 24 V supplied from a high voltage power supply is directly applied to the IC 88. This IC88
It is an IC for logic and has a withstand voltage of only about 7.5V. Therefore, when such a high voltage of 24 V is applied to the IC 88, a situation occurs in which the IC 88 is destroyed.

FIG. 1 is a block diagram schematically showing an internal circuit of the image scanner according to the first embodiment. In the present embodiment, after the GND power supply is connected, 24V
By providing a protection means for connecting a power supply, the above-described destruction is prevented. The protection means in this embodiment includes a detection means 100 and an opening / closing means 102 as shown in FIG. Here, the detecting means 100
Is for detecting whether or not the GND power supply lines 104 and 106 are connected between the main device and the optional device. Then, based on the detection result, the opening / closing means 102
Is opened and closed to connect the 24V power supply lines 112 and 114.
Disconnection occurs. Specifically, the GND power supply line 10
Until the terminals 4 and 106 are connected, the 24V power supply lines 112 and 114 are disconnected by the opening / closing means 102.
When the GND power lines 104 and 106 are connected, 24
The V power lines 112 and 114 are connected.

With the above configuration, FIG.
The formation of a loop circuit as shown in FIG.
Is prevented from being destroyed. That is, according to the configuration of the present embodiment, it is guaranteed that the GND power supply is connected when the 24 V power supply is connected. Therefore, the high voltage transmitted via the 24V power supply line, the opening / closing means 102, and the high voltage driving unit 124 is applied to the IC 122 having a high input impedance,
The GND power supply line 106, which is not transmitted to the path of the signal lines 118 and 116 and has an extremely low input impedance,
This is because it is transmitted to 104.

In order to prevent the destruction of the IC 120, a configuration in which a protection diode is provided between the signal lines 116 and 118 is also conceivable. However, with such a configuration, the protection diode must absorb all of the 24 V voltage, which is problematic in terms of the withstand voltage of the diode. Further, according to this configuration, diodes must be provided for all signal lines, which is disadvantageous in terms of increasing the circuit scale. On the other hand, in the present embodiment, the opening / closing means 102
Are provided at only one location, which is advantageous in terms of downsizing the circuit.

2. Second Embodiment FIG. 6A is a block diagram schematically showing an internal circuit of an image scanner according to a second embodiment. The second to fourth embodiments described below are embodiments relating to specific examples of the detecting means and the opening / closing means shown in FIG.

In the second embodiment, a diode 130, an FET transistor 134 and the like are included as detection means and switching means. When the GND power supply lines 104 and 106 are connected, the diode 130
It has a function of applying voltage to the gate electrode of the transistor 134. The FET transistor 134 has a gate voltage V
24V power supply line 112, 1
It has a function to open and close the connection between the 14.

Next, the operation of the second embodiment will be described.

First, when the 24V power lines 112 and 114 are connected, the GND power lines 104 and
Consider the case where 6 is not connected. In this case, since there is no current path flowing to the GND power supply line via the resistor 132 and the diode 130, no current flows through the resistor 132. Therefore, the source-gate voltage VSG of the FET transistor 134 is equal to VS -VG. Becomes 0V. Here, as shown in FIG.
4 is turned off when the source-gate voltage VSG is 3 V or less. Therefore, the GND power supply lines 104, 10
6 is not connected, the FET transistor 13
4 is turned off. Thereby, 24V power supply line 1
12 and 114 are not connected, and 2
4V power is not supplied.

Next, consider the case where the GND power supply lines 104 and 106 are connected. In this case, the resistor 132,
Since a current flows to the GND power supply line via the diode 130, a voltage difference occurs between both ends of the resistor 132. In this case, for example, if the Zener voltage VZ of the reverse characteristic of the diode 130 is set to 19V, a voltage difference of 24V-19V = 5V occurs between both ends of the resistor 132. As a result, the VSG of the FET transistor 134 becomes 5 V, and as is apparent from FIG.
Is turned on. Thereby, the 24V power supply line 11
2 and 114 are connected, and 24V power is supplied to the optional device side.

In this embodiment, the diode 1
A problem is how to set the zener voltage VZ to 30. The reason is as follows. That is,
The voltage of the 24V power supply for the high-voltage drive unit (lamp, motor) 124 has a tolerance of ± 5% due to cost, manufacturing problems, etc., and the voltage of the 24V power supply is 22.8V to 22.8V.
Variation occurs in the range of 5.2V. Therefore, even if such a variation occurs, the connection of the GND power supply line,
This is because it is necessary to appropriately set the value of the zener voltage VZ so that the FET transistor 134 normally turns on and off without connection. Also, the GND power supply lines 104, 1
Even when 06 is not connected, there may be a current path from the 24V power supply line 112 to the 5V power supply lines 110 and 108 via the resistor 132, the diode 130, and the IC 122 (arrows in FIG. 6A). Current path indicated by). When such a current path occurs, G
Even when the ND power supply lines 104 and 106 are not connected, a current flows, and a voltage difference is generated between both ends of the resistor 132 so that FE
There is a case where the T transistor 134 is turned on. Therefore, in order to prevent such a situation, it is necessary to appropriately set the value of the Zener voltage VZ so that the anode voltage VA of the diode 130 when the GND power supply lines 104 and 106 are not connected is 5 V. is there.
This is because if the value of VZ is set so that VA becomes 5 V, the above-described current path does not occur.

Next, a method of setting the zener voltage VZ in the second embodiment will be described.

First, the lower limit of the Zener voltage VZ is determined.
To find the lower limit of VZ, the voltage of the 24V power supply must be 25.
When the power supply voltage varies to 2V, the GND power supply line 10
It is sufficient to determine a condition that the FET transistors 134 and 106 are not connected and the FET transistor 134 is not turned on. In order for the FET transistor 134 not to turn on, the source-gate voltage V
SG needs to be 3 V or less (see FIG. 6B). The source voltage VS is the voltage of the 24V power supply.
It is set to 2V. Therefore, the gate voltage VG is 2
It must be 2.2 V or more. In this case, it is necessary to set the anodic voltage VA to 5 V so that a current path indicated by an arrow in FIG. 6A does not occur. From the above, the Zener voltage VZ is VZ ≧ 25.2-3-5 = 17.2V.

Next, the upper limit value of VZ is determined. In order to obtain the upper limit value of VZ, the GND power supply lines 104 and 106 are used when the voltage of the 24V power supply varies to 22.8V.
The condition for turning on the FET transistor 134 when is connected may be determined. FET transistor 134
Is turned on, the source-gate voltage VSG must be 3V
It is necessary to be above. The source voltage VS is 24
It is set to 22.8 V, which is the voltage of the V power supply. Therefore, the gate voltage VG must be 19.8 V or less. At this time, the anodic voltage VA is 0V. From the above, the Zener voltage VZ is VZ≤22.8-3 = 19.8V.

As described above, it is desirable that the Zener voltage VZ is not less than 17.2 V and not more than 19.8 V under the above conditions. Then, the variation in the Zener voltage in manufacturing is ±
Considering that it is about 5%, the zener voltage VZ is more preferably set to about 18.5V.

In this embodiment, the current flowing through the diode 130 when the zener voltage is generated can be controlled by changing the resistance value R of the resistor 132. For example, when it is desired to set the current IZ flowing through the diode 130 to 5 mA when VZ = 18.5 V, the resistance value R is as follows: R = (22.8-18.5) /0.005=860Ω.

When the voltage of the 24V power source fluctuates to 25.2V, the power loss PZ in the diode 130 is reduced.
Pz = VZ × Iz = 18.5 × (25.2-18.5)
/ 860 = 144 mw.

As described above, in the second embodiment, the power loss in the diode 130 can be made very small.
In this respect, the configuration is superior to the third and fourth embodiments described later.

Further, in the second embodiment, the value of the Zener voltage VZ can be set smaller than that of the third embodiment described later (18.5 V in the second embodiment, 2 z in the third embodiment).
0.9V). As described above, the zener voltage has a variation of ± 5% in manufacturing, but the actual variation value increases as the value of the zener voltage increases. Therefore, the second embodiment in which the value of the Zener voltage Vz can be set smaller is
The actual variation value can be made smaller than that of a third embodiment described later (18.5 ± 0.925 in the second embodiment).
V, 20.9 ± 1.045 V in the third embodiment), which facilitates selection of the diode. In this sense, the second embodiment is more advantageous than the third embodiment.

3. Third Embodiment FIG. 7 is a block diagram schematically showing an internal circuit of an image scanner according to a third embodiment.

In the third embodiment, the diode 140 and the bipolar transistor 14
4 is different from the second embodiment in that the FET transistor 134 is a bipolar transistor 144. Also, the arrangement of the resistors 142 and 143 is different.

Next, the operation of the third embodiment will be briefly described.

When the GND power lines 104 and 106 are not connected, the resistors 142 and 143 and the diode 1
Since there is no current path flowing through the GND power supply line through the base 40, no base current flows through the bipolar transistor 144. Therefore, the bipolar transistor 14
4 is turned off, and 24 V power is not supplied to the optional device side.

When the GND power supply lines 104 and 106 are connected, a current flows through the GND power supply line via the resistors 142 and 143 and the diode 140, so that a predetermined base current flows through the bipolar transistor 144.
As a result, the bipolar transistor 144 is turned on, and 24 V power is supplied to the option device side.

Next, a method of setting the zener voltage VZ in the third embodiment will be described.

First, the lower limit of the zener voltage VZ is determined.
To find the lower limit of VZ, the voltage of the 24V power supply must be 25.
When the power supply voltage varies to 2V, the GND power supply line 10
A condition may be determined so that the bipolar transistors 144 are not connected and the bipolar transistor 144 is not turned on. In order for the bipolar transistor 144 not to be turned on, it is sufficient to prevent the base current from flowing through the bipolar transistor 144. To this end, the emitter-base voltage VEB is set to 0.6.
V or less. And the emitter voltage VE is 2
It is set to 25.2V, which is the voltage of the 4V power supply. Therefore, the base voltage VB must be 24.6 V or more. In this case, to prevent the current path shown by the arrow in FIG.
Must be set to From the above, the Zener voltage VZ is VZ≥25.2-0.6-5 = 19.6V.

Next, the upper limit value of VZ is determined. In order to obtain the upper limit value of VZ, the GND power supply lines 104 and 106 are used when the voltage of the 24V power supply varies to 22.8V.
The condition for turning on the bipolar transistor 144 when is connected may be determined. In order for the bipolar transistor 144 to be turned on, a base current only needs to flow through the bipolar transistor 144, and for that purpose, the emitter-base voltage VEB needs to be 0.6V. 22. The emitter voltage VE is the voltage of the 24V power supply.
It is set to 8V. Therefore, the base voltage VB is 2
It must be less than 2.2V. At this time,
The anodic voltage VA is 0V. From the above, the Zener voltage VZ is VZ ≦ 22.8−0.6 = 22.2V.

As described above, it is desirable that the Zener voltage VZ be 19.6 V or more and 22.2 V or less under the above conditions. Then, the variation in the Zener voltage in manufacturing is ±
Considering that it is about 5%, the zener voltage VZ is more preferably set to about 20.9V.

When VZ is set to 20.9 V and the base current is set to 20 mA as described above, the resistance value R1 of the resistor 142 becomes R1 = (22.8-0.6-20. 9) /0.02=6
5Ω.

Therefore, when the voltage of the 24V power supply varies to 25.2V, the current IZ flowing through the diode 140
Is: Iz = (25.2-0.6-20.9) / 65 = 57m
A

As described above, in the third embodiment, the current flowing through the diode 140 is larger than that in the second embodiment. As a result, the power loss in the diode 140 increases, and the variation value of VZ is large as described above, making it difficult to select VZ. Therefore, the configuration is more disadvantageous than the second embodiment in this point. However, a bipolar transistor can pass more current than a FET transistor for its cost. Therefore, in this sense, the third embodiment is an advantageous configuration.

4. Fourth Embodiment FIG. 8 is a block diagram schematically showing an internal circuit of an image scanner according to a fourth embodiment.

In the fourth embodiment, a resistor 150, an inductance 152, a relay 15
4 is included.

Next, the operation of the fourth embodiment will be briefly described.

When the GND power supply lines 104 and 106 are not connected, the inductance 152 and the resistance 150
No current flows through the inductance 152 because there is no current path flowing to the GND power supply line via the. Therefore, the relay 154 is turned off, and no 24 V power is supplied to the optional device.

When the GND power supply lines 104 and 106 are connected, they flow through the inductance 152 and the resistor 150 to the GND power supply line.
2, a current flows. Therefore, the relay 154 is turned on, and 24 V power is supplied to the optional device.

In the fourth embodiment, the problem is how to set the resistance value R3 of the resistor 150. In other words, when the voltage of the 24V power supply varies to 25.2V, it is necessary to select the resistance value R3 so that the GND power supply lines 104 and 106 are not connected and the relay 154 does not turn on. Further, when the voltage of the 24V power supply varies to 22.8V, the GND power supply lines 104, 106
It is necessary to select the resistance value R3 so that the relay 154 is turned on when is connected.

As described above, in the fourth embodiment, the resistance 150
Is difficult to set the resistance value R3, the power loss in the resistor 150 is relatively large, and the relay 154
It is disadvantageous in comparison with the second embodiment in that it is relatively expensive. But relay 1
Since the switching is performed by mechanical contact, the switching characteristic parameter does not have a temperature characteristic unlike a transistor. In addition, the on-resistance in the on-state is small. Therefore, the fourth embodiment is advantageous in this sense.

The present invention is not limited to the above embodiment, and various modifications can be made within the scope of the present invention.

For example, the configuration of the protection means in the present invention is not limited to those shown in the first to fourth embodiments as long as the second power supply can be connected after the first power supply is connected. Instead, various configurations can be considered.

Further, in the above-described embodiment, the description has been given of the case where the high voltage is a positive voltage as an example. However, the present invention is not limited to this and can be naturally applied to the case of a negative voltage. Further, the number of power supplies is not limited to two or three, but can be naturally applied to four or more.

The detection means in the present invention includes:
The invention is not limited to the diodes and resistors as in the above-described embodiments, but various types can be considered. For example, those using an operational amplifier or the like can be considered. Also, the means for generating the predetermined voltage is not limited to a diode, a resistor or the like, and various means can be considered.

The device attached to the main body according to the present invention is not limited to the device described in the above embodiment, but may be of any type as long as it is connected to the main device and operated by being supplied with power. it can.

The form and network of the information processing system according to the present invention are not limited to those described in the above embodiments. For example, the present invention can be naturally applied to not only a network based on SCSI but also a network based on a bidirectional parallel interface.

[0081]

According to the present invention, a high voltage of the second power supply is prevented from being transmitted to a circuit or an element in the information processing apparatus via a power supply line, a signal line, or the like. Destruction of circuits or elements in the device is effectively prevented. As a result, it is possible to freely connect / disconnect the main unit attached device to / from the main unit while the power supply of the main unit is turned on. Further, the protection means of the present invention has an advantageous configuration in terms of circuit size, cost, reliability, and the like, as compared with the case where a diode element or the like is provided on a signal line or the like.

According to the present invention, detection means such as a diode, a resistor, an inductance, an operational amplifier, and the like;
By using switching means such as a transistor and a relay, it is possible to guarantee that the second power supply is connected after the first power supply is connected. This effectively prevents a circuit or an element in the information processing device from being destroyed due to a high voltage, and improves the reliability of the device.

According to the present invention, the current flowing between the first and second power supplies when the first power supply is connected is detected by using, for example, a diode element, a resistor, an inductance, an operational amplifier, and the like. At the same time, a predetermined voltage is generated, and the switching means such as a transistor and a relay are turned on at the predetermined voltage to connect the second power supply. Thus, according to the method of detecting the current flowing between the first and second power supplies, it is possible to reliably detect whether or not the first power supply is connected.

Further, according to the present invention, even when a current flows between, for example, a third power supply or the like in the information processing apparatus and the second power supply in a state where the first power supply is not connected, The opening / closing means can be reliably turned off, and it can be ensured that the second power supply is not connected unless the first power supply is connected. Thus, it is possible to more reliably prevent a circuit or the like in the information processing device from being destroyed by the high voltage.

Further, according to the present invention, it is possible to prevent a current from flowing between, for example, the third power supply or the like in the information processing apparatus and the second power supply when the first power supply is not connected. Therefore, it is possible to guarantee that the second power supply is not connected unless the first power supply is connected. Thus, it is possible to more reliably prevent a circuit or the like in the information processing device from being destroyed by the high voltage.

According to the present invention, when a predetermined voltage for turning on the FET transistor is generated, the current flowing through the diode element via the resistance element can be reduced, and the power loss in the diode element can be reduced. It becomes possible. This facilitates the selection of the diode element and improves the reliability.

Further, according to the present invention, it is possible to connect and disconnect the main unit attached device while the power of the main unit is turned on. There is no need to turn off the power. Thereby, the application software in the host device, O
Since it is not necessary to terminate the execution of the program such as S and turn off the power, it is not necessary to request the user for complicated and time-consuming work. As a result, the convenience of the information processing system can be greatly increased.

[Brief description of the drawings]

FIG. 1 is a block diagram schematically showing an internal circuit of an image scanner according to a first embodiment of the present invention.

FIGS. 2A and 2B are perspective views when the image scanner according to the present embodiment is viewed from the front side and the rear side. FIG.

FIGS. 3A and 3B are perspective views of an ADF unit and a transparent original unit.

FIG. 4 is an example of an information processing system formed by connecting an image scanner and the like via a predetermined network.

FIG. 5A is a block diagram schematically showing an internal circuit of a conventional image scanner, and FIG. 5B is an example of an internal circuit diagram of an IC 88;

FIG. 6A is a block diagram schematically showing an internal circuit of the image scanner according to the second embodiment;
(B) is a characteristic diagram of the FET transistor.

FIG. 7 is a block diagram schematically illustrating an internal circuit of an image scanner according to a third embodiment.

FIG. 8 is a block diagram schematically showing an internal circuit of an image scanner according to a fourth embodiment.

[Explanation of symbols]

 20, 22 SCSI connector 24 Option control connector 26 Bidirectional parallel connector 40 Host computer 44, 46 Hard disk 48, 50 Hard disk controller 52 Main unit 54 Optional device 55 Image scanner 56, 58, 60, 62 Power switch 64, 66, 68 SCSI Cable 99 Connector unit 100 Detecting means 102 Opening / closing means 104, 106 GND power supply line 108, 110 5V power supply line 112, 114 24V power supply line 120, 122 IC 124 High voltage driver 130, 140 Diode 132, 142, 143, 150 Resistance 134 FET transistor 144 Bipolar transistor 152 Inductance 154 Relay

Claims (7)

(57) [Claims] 1. An information processing apparatus comprising: a main unit; and an auxiliary unit connected to the main unit and operated by receiving at least a first power supply and a second power supply as a high-voltage power supply from the main unit. an apparatus, wherein a means for protecting the circuits or elements in the information processing apparatus from the high voltage of the second power supply to connect the main accessory device to the main unit, the main unit and the body attachment device includes protection means for connecting said second power after the first power supply is connected between said protection means, said first conductive between said main device and said main attachment device
Detecting means for detecting whether or not a power source is connected;
The main unit and the main unit based on the detection result from the means.
Opening / closing for opening and closing the connection of the second power supply to / from an attached device
Means, wherein the detecting means is a diode element, and
An FET transistor, and a first terminal of the diode element is connected to the first power supply.
A second terminal of the diode element is connected to the FET
Connected to the gate electrode of the transistor
Connected to the second power supply through a
The first power source is connected to the main unit attachment device;
In the case where the resistance element and the diode element
The die based on a current flowing between the first and second power supplies;
A predetermined voltage is generated by the auto element, and
The constant voltage causes the FET transistor element to conduct and the
The second power supply between the main unit and the main unit attached device;
An information processing device, wherein a connection is made . 2. An information processing apparatus comprising: a main unit; and an auxiliary unit connected to the main unit and operated by being supplied with at least a first power supply and a second power supply as a high-voltage power supply from the main unit. an apparatus, wherein a means for protecting the circuits or elements in the information processing apparatus from the high voltage of the second power supply to connect the main accessory device to the main unit, the main unit and the body attachment device includes protection means for connecting said second power after the first power supply is connected between said protection means, said first conductive between said main device and said main attachment device
Detecting means for detecting whether or not a power source is connected;
The main unit and the main unit based on the detection result from the means.
Opening / closing for opening and closing the connection of the second power supply to / from an attached device
Means, wherein the detection means is a diode element,
The switching means is a bipolar transistor, and a first terminal of the diode element is connected to the first power supply.
The second terminal is connected to the bypass via a second resistance element.
Connected to the base electrode of the polar transistor
Connected to the second power supply via first and second resistance elements.
Between the main body device and the main body attachment device.
The first and second resistance elements when the power supply of
Between the first and second power supplies via the diode element
Predetermined by the diode element based on the current flowing through
A voltage is generated, and the predetermined voltage is used to generate the voltage.
The polar transistor element becomes conductive and the main unit and the book
An information processing apparatus , wherein the second power supply is connected to a body attachment device. 3. A main unit which is connected to the main unit and operates by being supplied with at least a first power supply, a second power supply as a high-voltage power supply, and a third power supply. An information processing device including an accessory device, wherein when connecting the main unit accessory device to the main device, a circuit or an element in the information processing device is protected from a high voltage of the second power supply , Protection means for connecting the second power supply after the first power supply is connected between the main body device and the main body attachment device, wherein the protection means is provided between the main body device and the main body attachment device. And the first
Detecting means for detecting whether or not a power source is connected;
The main unit and the main unit based on the detection result from the means.
Opening / closing for opening and closing the connection of the second power supply to / from an attached device
Means, the detecting means, the main unit and the main unit attachment device
When the first power supply is connected between the first and second power supplies.
Generates a predetermined voltage based on the current flowing between power supplies
Means for opening and closing said switching means by said generated predetermined voltage.
Wherein between but conduction and the present body apparatus and the main accessory device
The second power supply is connected, and the first power supply is connected between the main unit and the main unit.
The second power supply and the third power supply in a state where the power supply is not connected.
Even when current flows between the power source and the
The information processing apparatus , wherein the predetermined voltage is set so as to allow the communication . 4. Information formed by connecting at least one or a plurality of said information processing apparatuses and said host apparatus by a predetermined network, comprising the information processing apparatus according to claim 1 and a host apparatus. A processing system, comprising: providing the protection means so that connection and disconnection of the main unit attached device to the main unit can be performed while the main unit is powered on. system. 5. A device connected to the main unit and having a small
At least the first power supply and the second power supply which is a high voltage power supply
A main body auxiliary device that is supplied and operates, and is connected to the main body device when the main body auxiliary device is connected to the main body device.
Protecting the circuit or element in the device from the high voltage of the second power supply
Means between the main unit and the main unit auxiliary device.
Connect the second power supply after the first power supply is connected
Includes protection means for said protection means, said first power supply between the main unit and the main body accessory device
Detecting means for detecting whether or not the connection is established; and the detecting means
The main unit and the main unit auxiliary device based on the detection result from
Opening and closing means for opening and closing the connection of the second power supply between
Wherein the detection means is a diode element, and the switching means is
An FET transistor, and a first terminal of the diode element is connected to the first power supply.
A second terminal of the diode element is connected to the FET
Connected to the gate electrode of the transistor
Connected to the second power supply through a
When the first power supply is connected to the main unit attached device
Through the resistance element and the diode element.
1, based on the current flowing between the second power supply,
A predetermined voltage is generated by the load element, and the generated predetermined voltage is generated.
The voltage causes the FET transistor element to conduct and the book
The connection of the second power supply between the body device and the body attachment device
A main body attachment device characterized by being performed. 6. A device connected to a main unit and having a small
At least the first power supply and the second power supply which is a high voltage power supply
A main body auxiliary device that is supplied and operates, and is connected to the main body device when the main body auxiliary device is connected to the main body device.
Protecting the circuit or element in the device from the high voltage of the second power supply
Means between the main unit and the main unit auxiliary device.
Connect the second power supply after the first power supply is connected
Includes protection means for said protection means, said first power supply between the main unit and the main body accessory device
Detecting means for detecting whether or not the connection is established; and the detecting means
The main unit and the main unit auxiliary device based on the detection result from
Opening and closing means for opening and closing the connection of the second power supply between
Wherein the detection means is a diode element, and the switching means is
A first terminal of the diode element connected to the first power supply;
The second terminal is connected to the bypass via a second resistance element.
Connected to the base electrode of the polar transistor
Connected to the second power supply via first and second resistance elements.
The first power supply between the main unit and the main unit attached device.
The first and second resistance elements when a source is connected;
A current flows between the first and second power supplies via a diode element.
A predetermined voltage based on the current
Is generated, and the bipolar voltage is generated by the generated predetermined voltage.
The transistor device becomes conductive and the main unit and the main unit are attached.
Connection of the second power supply to the power supply.
And the main unit attached to it. 7. A device connected to a main unit and having a small
At least a first power supply and a second power supply which is a high voltage power supply
And the third power supply is supplied to operate the main body attached device
There, Supplied instrumentation when connecting body attachment device to the main device
Protecting the circuit or element in the device from the high voltage of the second power supply
Means between the main unit and the main unit auxiliary device.
Connect the second power supply after the first power supply is connected
Includes protection means for said protection means, said first power supply between the main unit and the main body accessory device
Detecting means for detecting whether or not the connection is established; and the detecting means
The main unit and the main unit auxiliary device based on the detection result from
Opening and closing means for opening and closing the connection of the second power supply between
Wherein the detecting means is provided between the main body device and the main body auxiliary device.
When the first power source is connected, the first and second power sources are connected.
Means for generating a predetermined voltage based on current flowing between sources
And the opening / closing means is guided by the generated predetermined voltage.
The second power supply between the main unit and the main unit attached device.
And the first power source is connected between the main unit and the main unit.
When the second power supply and the third power supply are not connected,
Even when a current flows between the switches, the switching means is turned off.
The predetermined voltage is set so that
Main unit attached to