JP2007265588A - Disk testing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a disk testing device capable of preventing an increase in temperature and preventing dust invasion. <P>SOLUTION: The disk testing device 10 for testing whether information is appropriately recorded on an optical disk comprises: a main body case 20 provided with an air inlet 34 for introducing air and an air outlet 22 for discharging air to the outside; an air cleaning means 30 installed at the air inlet 34 or an inhalation path 32 communicating with the air inlet 34 to remove dust; an inhaling means 40 installed inside the main body case 20 to provide an inhaling force to inhale air from the air inlet 34 through the air cleaning means 30; and a disk drive 50 that is cooled by the air inhaled by the inhaling means 40 and plays an optical disk. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a disk inspection apparatus for inspecting recording of information on an optical disk.

  For example, in a production line for optical discs such as DVD discs, Blu-ray discs, HD-DVDs and CDs, disc inspection apparatuses are generally used. This disc inspection device measures the warp and eccentricity of the optical disc, and measures the jitter, modulation rate, and reflectance while reproducing the information recorded on the optical disc, so that the information is recorded appropriately on the optical disc. It is possible to inspect whether or not.

  The disk inspection apparatus includes a case for protecting the internal configuration from external dust, and a disk drive including an optical pickup, a power supply unit, and the like are provided inside the case. A prior art related to such a disk inspection apparatus is disclosed in Patent Document 1.

Japanese Patent Laid-Open No. 11-31380 (see abstract, etc.)

  By the way, in the disk inspection apparatus described above, the temperature rise particularly in the disk drive is remarkable. Among these, the temperature rise in the vicinity of the optical pickup that irradiates the laser beam is more remarkable. When such a temperature rise occurs, a temperature change occurs in a laser diode or the like that emits a laser, and the amplitude or the like changes. In that case, there is a problem that the optical disk is not accurately inspected.

  Also, in the disk inspection apparatus, if dust enters the case, it will hinder the inspection of the optical disk. Therefore, it is necessary to prevent dust from entering in the disk inspection apparatus. However, the current disk inspection apparatus has only a rotary fan, and it is difficult to prevent dust from entering.

  The present invention has been made on the basis of the above circumstances, and an object of the present invention is to provide a disk inspection apparatus capable of preventing temperature rise and dust entry.

  In order to solve the above-described problems, the present invention provides a disk inspection apparatus for inspecting whether or not information is properly recorded on an optical disk, and an intake port for introducing air for cooling the inside of the disk inspection apparatus. A body case provided with a discharge port for discharging the air sucked from the intake port to the outside, an air cleaning means installed in the intake port or a suction path communicating with the intake port, and for removing dust; A suction unit that is installed inside the main body case and that applies a suction force for sucking air from the air inlet through the air cleaning unit, and is cooled by the air sucked by the suction unit, and for reproducing the optical disc A disk drive.

  In such a configuration, when the disk inspection apparatus is operated, the suction unit is operated, and air is sucked from the intake port by the operation of the suction unit. Here, the air sucked from the intake port is guided to the inside of the main body case after passing through the air cleaning means. Thus, when air passes through the air cleaning means, dust contained in the air is removed. Accordingly, it is possible to prevent dust from entering the inside of the main body case, and it is possible to prevent troubles in the inspection of the optical disc.

  The disk drive is cooled by the air sucked into the main body case by the suction means. Such cooling by air makes it possible to prevent the temperature increase in the disk drive, and to prevent the inspection accuracy of the optical disk from deteriorating.

  According to another invention, in addition to the above-described invention, the disk drive further includes a housing, and the entire disk drive is covered by the housing, and air sucked by the suction means flows into the housing. And an outflow hole for allowing air flowing in from the inflow hole to flow out.

  In such a configuration, since the inflow hole and the outflow hole are formed in the housing of the disk drive, it is possible to allow air to flow into the housing and to flow out of the air. As a result, the heat generated by the heat source such as the optical pickup, the turntable motor, the tracking mechanism, and the light receiving element provided in the disk drive is taken away by the air flowing into the housing and discharged to the outside of the housing. The In addition, compared to the case where the disk drive is cooled by colliding air with the outer surface of the housing, the heat source inside the housing can be directly cooled, and the cooling efficiency can be improved. Become.

  Furthermore, in another invention, in addition to the above-described invention, the inflow hole is disposed opposite to the exhaust port of the suction means. In such a configuration, when the suction means is activated, it is possible to allow most of the air exhausted from the suction means to flow in from the inflow hole. As a result, the cooling efficiency of the disk drive can be further improved, and the detection accuracy of the optical disk in the disk drive can be maintained better.

  Further, since the exhaust port of the suction means is arranged to face the inflow hole, the air sucked from the outside of the main body case by the suction means is not discharged directly to the outside of the main body case, but is discharged to the inside of the main body case. It will be in a state to be. Therefore, air is pushed into the main body case, and the internal pressure of the main body case can be increased. Thereby, air is discharged toward the outside from a slight gap existing in the main body case. For this reason, dust, dust, etc. existing outside the main body case are difficult to enter the main body case, and the main body case can be kept clean.

  In addition to the above-mentioned inventions, in another aspect of the invention, the intake port is provided on the front side of the main body case on the side where the tray provided in the disk drive is inserted and removed. It is provided in the cleaning means, and the discharge port is provided on the back side facing the front side of the main body case.

  In such a configuration, since the air intake port is provided on the front side of the main body case and the exhaust port is provided on the rear side of the main body case, the air flowing from the air intake port It flows through the inside and is discharged from the discharge port. Thereby, it is possible to prevent a portion where heat is accumulated inside the main body case, and it is possible to improve the cooling efficiency inside the main body case. Further, since the air inlet is provided on the front side of the main body case, and the suction port is provided in the air cleaning means, the air cleaning means after removing dust for a long time is provided. Maintenance becomes easy.

  Furthermore, in another invention, in addition to the above-described invention, the discharge port is composed of a plurality of holes, and these holes are formed on the upper side and the side edge side of the back side of the main body case. Of the holes arranged on the side edge side, the holes located on the lower end side are located with a space with respect to the lower side of the main body case.

  In such a configuration, since the discharge port is composed of a plurality of holes, the opening area of each hole can be reduced, compared with the case where a discharge port having a large opening is provided. Thus, it is possible to prevent foreign matter, dust and the like from entering the inside of the main body case. Further, the plurality of holes are arranged on the upper side of the back side of the main body case, and are also arranged on the side edge side. Here, since there is a space below the hole on the side edge side, the hole on the side edge side is provided in a state of being separated from the lower side of the main body case by a predetermined distance. . Thereby, compared with the case where the hole is arranged on the lower side of the main body case, it is possible to better prevent foreign matters, dust, and the like from entering the main body case through the hole. In addition, since the holes are arranged at a position near the upper side of the main body case, it is possible to take out heat from a heat source or the like of the disk drive and exhaust air that has risen in temperature satisfactorily.

  According to the present invention, it is possible to satisfactorily prevent an increase in temperature in a disk inspection apparatus. In addition, it is possible to prevent dust from entering the inside of the main body case through the air used for cooling.

  Hereinafter, a disk inspection apparatus 10 according to an embodiment of the present invention will be described with reference to FIGS. In the following description, in the disk inspection apparatus 10, the side where the bottom plate 21a is present when viewed from the top plate 21b is defined as the lower side, and the side where the top plate 21b is present when viewed from the bottom plate 21a is defined as the upper side. And Further, the side where the back plate 21d is present when viewed from the front plate 21c is the back side, and the side where the front plate 21c is present when viewed from the back plate 21d is the front side.

  The disc inspection apparatus 10 shown in FIGS. 1 to 4 and the like includes a main body case 20, a filter unit 30, a fan unit 40, a disc drive 50, and a power source. One or a plurality of the disk inspection apparatuses 10 are connected to a computer (not shown) via a network.

  Of the components of the disk inspection apparatus 10, the main body case 20 includes a frame body (not shown) and a plate member 21. Among these, the frame body is configured by a plurality of columnar members, and these columnar members are configured by screw fixing or fitting fixing to each other. Here, the columnar member is made of a metal member such as aluminum, for example, and is formed by forming appropriate screw holes, grooves and the like in the metal member.

  In the present embodiment, a total of 12 columnar members can be provided in order to form the cubic main body case 20, for example. However, the number of columnar members is not limited to this number, and can be variously modified.

  Moreover, the plate member 21 is attached to the above-mentioned frame body. The plate member 21 includes a bottom plate 21a, a top plate 21b, a front plate 21c, a back plate 21d, and a side plate 21e. Of these, the bottom plate 21a is a member that is attached to the bottom side (lower side) of the plate member 21, and is provided to support a filter unit 30, a fan unit 40, a power supply unit 60, and the like, which will be described later. Yes. The top plate 21b is provided above the bottom plate 21a. In the present embodiment, the top plate 21b is provided with heat radiating fins, so that heat generated inside the main body case 20 can be released to the outside satisfactorily.

  Further, the front plate 21 c is located on the front side of the main body case 20. The front plate 21c is provided with a plurality of openings. Of these, the upper opening is attached with the front side of the disk drive 50 exposed. With this attachment, the operation buttons and the like existing on the front side of the disk drive 50 (the side on which the tray on which the optical disk is placed) are exposed are exposed from the front plate 21c, and the user can operate the buttons. Further, as will be described later in a modification, a plurality of disk drives 50 may be attached to the main body case 20. In that case, the front plate 21c may have a case where the area occupied on the front side of the main body case 20 is small, and in some cases, a configuration in which the front plate 21c does not exist may be employed.

  A front panel 33 of the filter unit 30 is attached to the lower opening. By attaching the front plate 21c, the front portion of the disk drive 50, and the front panel 33, the front portion of the disk inspection apparatus 10 is provided to be substantially flush.

  Further, a side plate 21e is attached to the side portion of the frame body. Note that the side plate 21e is not limited to the configuration including the single plate member 21 and may be configured of the two plate members 21. A back plate 21d is attached to the back surface portion of the frame body. Here, as shown in FIG. 5 and the like, a discharge port 22 is provided in the back plate 21d. The discharge port 22 is a portion that discharges air (clean air after the temperature rise) from the inside of the main body case 20 toward the outside.

  In the present embodiment, the discharge port 22 is composed of a plurality of vent holes 22a (corresponding to the holes). The plurality of vent holes 22a are arranged in a substantially U-shape. That is, on the upper side of the back plate 21d, the air holes 22a are arranged along the width direction. Moreover, in the edge part (side edge part) of the width direction of the backplate 21d, the ventilation hole 22a is arrange | positioned so that it may go to the downward side from the edge part of the arrangement | positioning along a width direction. In addition, the end of the vent hole 22a toward the lower side extends to the middle part in the vertical direction of the back plate 21d. Therefore, a predetermined space exists between the vent hole 22a on the lower end side and the installation surface (surface on which the bottom plate 21a is installed).

  Moreover, as shown to FIGS. 1-4 etc., the filter unit 30 is arrange | positioned in the downward direction and the front side among the main body cases 20. FIG. The filter unit 30 has an air filter 31 (see FIG. 4) corresponding to the air cleaning means and having a fine mesh through which air can pass, such as a hepa filter. In the filter unit 30, the air filter 31 is arranged in a state of blocking the air suction path 32 existing in the filter unit 30. The air filter 31 may employ a configuration in which only one air filter 31 is disposed, or may employ a configuration in which two or more air filters 31 are disposed. In the present embodiment, the suction path 32 is arranged so as to go from the near side to the far side.

  The filter unit 30 has a front panel 33 as shown in FIGS. The front panel 33 is provided with an air inlet 34 that communicates with the air filter 31 described above. Further, portions of the front panel 33 other than the air inlet 34 are provided so as to be flush with the above-described front plate 21c and the like. Further, in the filter unit 30, a discharge hole 35 is provided in a portion on the back side (end portion on the back side of the suction path 32).

  In the present embodiment, a fan unit 40 is provided on the back side of the filter unit 30. The fan unit 40 corresponds to a suction unit. Further, the fan unit 40, for example, as a centrifugal fan, sucks air from the filter unit 30 side using centrifugal force, and also draws the air to the disk drive 50 side (in this embodiment, the upper side). The structure which discharges toward is adopted.

  The fan unit 40 includes a motor 41, a wing member 42 that is rotatably attached to a rotation shaft 41 a of the motor 41, and a blower 43 that covers the wing member 42. Among these, the blower 43 has a substantially spiral appearance. The blower 43 is provided with a center hole 43 a centering on the rotation center of the wing member 42. For this reason, when the wing member 42 rotates, air is sucked into the blower 43 through the center hole 43a. An exhaust port 43b is provided in the outermost diameter portion of the spiral blower 43. Here, in this Embodiment, the exhaust port 43b is opened toward the upper side. Therefore, when air is discharged through the exhaust port 43b, the air is exhausted upward.

  A disk drive 50 is provided above the fan unit 40. The internal configuration of the disk drive 50 is covered by a housing 51. In addition, a turntable, an optical pickup, a tracking mechanism, a light receiving element, and the like (not shown) are provided inside the housing 51 of the disk drive 50.

  In addition, as shown in FIG. 4, the housing 51 is provided with an inflow hole 52. In the present embodiment, a predetermined number of inflow holes 52 (five in the present embodiment) are provided on the lower surface of the housing 51. Air is introduced into the disk drive 50 through the inflow hole 52. In addition, an outflow hole 53 is provided on the rear side and the upper surface side of the housing 51. From this outflow hole 53, air introduced through the inflow hole 52 flows out of the housing 51. In addition, the opening area of the inflow hole 52 and the outflow hole 53 is provided smaller than the opening area of the exhaust port 43b.

  Here, as shown in FIG. 4, the inflow hole 52 is disposed above the exhaust port 43b by a predetermined dimension (as an example, 3 cm in the present embodiment). Thereby, the ratio of clean air discharged from the exhaust port 43b to the inside of the housing 51 through the inflow hole 52 is increased. However, since the inflow hole 52 has an opening area smaller than that of the exhaust port 43b, only a predetermined proportion of clean air is introduced into the housing 51, and other clean air collides with the housing 51. Later, it moves mainly in the direction (power supply unit 60 side) indicated by the arrow in FIG.

  Further, a power supply unit 60 is attached to the rear end side of the bottom plate 21a with respect to the fan unit 40. The power supply unit 60 is for supplying, for example, commercial AC power from the outside and supplying power after a predetermined voltage conversion to the fan unit 40 and the disk drive 50. The power supply unit 60 may adopt a configuration including an uninterruptible power supply (UPS) in response to a power failure.

  How the heat is released in the disk inspection apparatus 10 having the above configuration will be described.

  When the power of the disk inspection device 10 is turned on and the operation of the disk inspection device 10 is started, the disk drive 50 and the fan unit 40 also start operation. Here, when the fan unit 40 starts to operate, the air inside the blower 43 is exhausted from the exhaust port 43 b by the rotation of the wing member 42. Thereby, in the blower 43, the vicinity of the center hole 43a becomes a negative pressure. Therefore, in the vicinity of the center hole 43a, the pressure is lower than the outside of the main body case 20, so that intake through the filter unit 30 is started.

  When such intake is started, air existing outside the main body case 20 is introduced from the intake port 34. Then, in the inside of the main body case 20, on the side where clean air is discharged from the exhaust port 43 b, the pressure becomes higher than the inside of the main body case 20 due to the introduction of air from the outside. Thereby, at the joints of the main body case 20 and the like, clean air is discharged toward the outside, but the air hardly enters from the outside toward the inside of the main body case 20.

  Further, the air sucked from the intake port 34 reaches the air filter 31 in the suction path 32. Here, when the suction air passes through the air filter 31, the dust contained in the suction air cannot pass through the fine mesh constituting the air filter 31, and only the air passes through the mesh. . That is, dust contained in the suction air is supplemented by the air filter 31. Therefore, the air passing through the air filter 31 is in a clean state from which dust has been removed. In the following description, the air after dust is removed is referred to as clean air.

  The clean air that has passed through the air filter 31 reaches the discharge hole 35 and the central hole 43 a adjacent to the discharge hole 35 and is introduced into the blower 43. Then, since the wing member 42 is rotating inside the blower 43, clean air is exhausted to the exhaust port 43b by the rotation of the wing member 42.

  When clean air is exhausted from the exhaust port 43b, the clean air subsequently reaches the housing 51. Here, a predetermined proportion of clean air flows into the inflow hole 52 located above. Further, the clean air that has not flowed into the inflow hole 52 is mainly guided in the direction indicated by the arrow in FIG.

  When clean air flows into the housing 51 through the inflow hole 52, the clean air flows from the inflow hole 52 toward the outflow hole 53. Here, various heat sources such as a laser diode are provided inside the housing 51. Therefore, in the operating state of the disk drive 50, the temperature of the housing 51 and the air (clean air) existing inside the housing 51 is raised by the heat generation source. However, clean air before the temperature rises flows into the housing 51, and clean air deprived of heat from the heat generation source flows out from the outflow hole 53.

  Thereby, even if the temperature rises in the clean air flowing into the housing 51, the clean air is sequentially exhausted from the outflow hole 53. In addition, clean air having a lower temperature than the inside of the housing 51 is sequentially introduced through the inflow hole 52. For this reason, the disk drive 50 is cooled by clean air, and the temperature rise inside the housing 51 can be prevented.

  As shown in FIG. 4, clean air that does not flow into the housing 51 travels mainly toward the back side after colliding with the outer surface of the housing 51. Here, when clean air collides with the outer surface of the housing 51, heat is taken from the surface of the housing 51 and the housing 51 is cooled at the time of the collision. This also cools the disk drive 50. The clean air after the collision with the housing 51 reaches the upper surface of the power supply unit 60 while passing through the lower surface of the housing 51.

  Here, when clean air reaches the upper surface of the power supply unit 60, heat from the upper surface (front surface) of the power supply unit 60 is taken away by the clean air. That is, as with the disk drive 50, the power supply unit 60 is cooled by clean air.

  Then, the clean air that has cooled the disk drive 50 and the power supply unit 60 (heat has been removed from the disk drive 50 and the power supply unit 60) flows inside the main body case 20. Here, the operation of the fan unit 40 causes the internal pressure of the main body case 20 to be higher than the pressure outside the main body case 20 except for the air inflow side such as the center hole 43a. Due to this pressure difference, the clean air inside the main body case 20 is mainly discharged from the discharge port 22 to the outside and gradually discharged. Further, a part of the clean air existing inside the main body case 20 flows toward the outside through a slight gap such as a joint existing between the frame body and the plate member 21 or the like.

  As described above, the air existing outside the main body case 20 is sent into the main body case 20, deprived of the heat inside, and then released to the outside.

  According to the disk inspection apparatus 10 having such a configuration, the fan unit 40 is provided inside the main body case 20. For this reason, when the fan unit 40 is activated, air is pushed into the inside of the main body case 20 at a portion other than a part such as the suction passage 32 and the internal pressure of the main body case 20 can be increased. It becomes. Thereby, air (clean air) is discharged toward the outside of the main body case 20 through the discharge port 22 and a slight gap (a joint) between the frame body and the plate member 21 and the like. For this reason, it is difficult for dust, dust, and the like existing outside the main body case 20 to enter the main body case 20, and the inside of the main body case 20 can be kept clean.

  Further, clean air from which dust has been removed after passing through the filter unit 30 is introduced into the main body case 20. That is, the dust contained in the air outside the main body case 20 is removed by passing through the air filter 31. Accordingly, it is possible to prevent dust from entering the inside of the main body case 20, and it is possible to prevent troubles from occurring during the inspection of the optical disc.

  The disk drive 50 is cooled by the air sucked into the main body case 20 by the suction operation of the fan unit 40. In particular, in this embodiment, the housing 51 is provided with an inflow hole 52 and an outflow hole 53, and the disk drive 50 is cooled by clean air introduced from the inflow hole 52. As a result, the disk drive 50 can be cooled more satisfactorily.

  Here, in the conventional disk inspection apparatus, a fan is provided on the back side of the main body case, and cooling is performed by rotation of the fan. However, in the configuration in which the inflow hole 52 and the outflow hole 53 are provided in the housing 51 as in the present embodiment, a configuration in which clean air flows through the housing 51 can be adopted. Thereby, the inside of the disk drive 50 having heat sources such as an optical pickup, a turntable motor, a tracking mechanism, and a light receiving element can be efficiently cooled. That is, compared with the case where the disk drive 50 is cooled only by causing clean air to collide with the outer surface of the housing 51, the above-described heat source can be directly cooled, and the cooling efficiency is further improved. It is possible to make it.

  In addition, as described above, by introducing clean air into the disk drive 50 and cooling the inside well, it is possible to suppress the temperature rise of the laser diode or the like existing inside the disk drive 50. It becomes. Thereby, it is possible to prevent the amplitude of the laser beam emitted from the laser diode from fluctuating. For this reason, it is possible to maintain a state in which the inspection accuracy of the optical disk is good for a long time.

  Furthermore, in the present embodiment, the inflow hole 52 is disposed in the state of being in close proximity to the exhaust port 43b. Therefore, when the fan unit 40 is operated, it is possible to allow most of the clean air exhausted from the exhaust port 43b to flow from the inflow hole 52. As a result, the cooling efficiency of the disk drive 50 can be further improved, and the detection accuracy of the optical disk in the disk drive 50 can be maintained better.

  In the present embodiment, the air inlet 34 is provided in the front plate 21c. In addition, the air inlet 34 is provided in the filter unit 30. Therefore, the maintenance of the filter unit 30 after removing dust for a long time can be easily performed. That is, it is possible to easily perform operations such as removing the filter unit 30 from the main body case 20, and it is also possible to easily replace the air filter 31 after the removal.

  In addition, an intake port 34 is provided in the front plate 21c, and an exhaust port 22 is provided in the back plate 21d. As a result, the air flowing in from the intake port 34 flows transversely inside the main body case 20 and is discharged from the discharge port 22. Thereby, it is possible to prevent a portion where heat is accumulated in the main body case 20 and to improve the cooling efficiency inside the main body case 20.

  Further, the discharge port 22 includes a plurality of vent holes 22 a, and these vent holes 22 a are arranged on the upper side and the side edge side of the back side of the main body case 20. Thereby, the vent hole 22a which comprises the discharge port 22 can make each opening area small. Therefore, it is possible to prevent foreign matters, dust, and the like from entering the inside of the main body case 20 as compared with the case where the discharge port 22 is configured by an opening having a large opening area.

  Further, the plurality of vent holes 22a are arranged on the upper side of the back side of the main body case 20, and are also arranged on the side edge side. Here, since there is a space below the side-hole side vent hole 22a, the vent hole 22a is separated from the lower side of the main body case 20 by a predetermined distance. Yes. As a result, compared to the case where the air holes 22a are arranged on the lower side of the main body case 20, it is possible to satisfactorily prevent foreign matters, dust, and the like from entering the inside of the main body case 20 through the air holes 22a. Become. Further, since the air holes 22a are arranged in the upper part of the main body case 20, the temperature rises and becomes light, and the air (clean air) moving upward can be discharged well. It becomes.

  The disk inspection apparatus 10 according to the embodiment of the present invention has been described above, but the present invention can be variously modified in addition to these. This will be described below.

  In the above-described embodiment, a guide member for guiding clean air may be disposed inside the main body case 20. Thereby, for example, even when the exhaust port 43b and the inflow hole 52 are separated from each other, clean air can be satisfactorily introduced into the inflow hole 52. Further, when the guide member is provided, clean air can be well guided to the inside of the housing 51, the surface of the power supply unit 60, and the like, and the cooling efficiency can be improved. Note that a fin, a duct, or the like can be used as the guide member.

  Moreover, in the above-mentioned embodiment, the case where the filter unit 30 is used as the air cleaning means has been described. However, as the air cleaning means, a configuration including an ionizer or the like in addition to the filter unit 30 may be employed. Further, as the air filter 31 provided in the filter unit 30, a filter other than a hepa filter may be used. Examples of filters other than hepa filters include chemical filters and UPLA (Ultra Low Penetration Air) filters.

  In the above-described embodiment, the part cooled by the fan unit 40 may be a part other than the disk drive 50 and the power supply unit 60. Examples of parts other than the disk drive 50 and the power supply unit 60 include a circuit board (not shown).

  Further, in the above-described embodiment, a case where only one disk drive 50 is provided has been described. However, the configuration is not limited to the case where only one disk drive 50 is provided, and a configuration in which two or more disk drives are provided may be employed. When two or more disk drives 50 are provided, it is preferable to provide a guide member for guiding clean air so that clean air can be distributed to all the disk drives 50.

  Moreover, in the above-mentioned embodiment, you may comprise so that a control means for controlling the action | operation of the fan unit 40 may be provided. In this case, a measuring unit for detecting a temperature rise or a load increase of the motor 41 (an increase in current) due to clogging of the air filter 31 or the like is provided, and based on the detection result of the detecting unit, You may comprise so that the action | operation of the motor 41 may be controlled.

  Further, in the case where the detection means as described above is provided, if the detection result of the detection means exceeds a certain threshold value, it is notified to the outside that the time for maintenance (such as replacement of the air filter 31) has come. Anyway. This notification may be performed by, for example, providing a lamp such as an LED on the front plate 21c and turning on this lamp, or via a computer separately connected to the disk inspection apparatus 10 (for example, a warning on the display). For example, displaying a screen).

  The disc inspection apparatus of the present invention can be used in the field of manufacturing optical discs.

It is a perspective view which shows the structure of the disc inspection apparatus which concerns on one embodiment of this invention. FIG. 2 is a perspective view showing an internal configuration in a state where a main body case is seen through in the disk inspection apparatus of FIG. 1. 2 is a side view showing the internal configuration of the disk inspection apparatus of FIG. FIG. 2 is a side sectional view showing an internal configuration of a lower side of a main body case in the disk inspection apparatus of FIG. 1. FIG. 2 is a partial perspective view showing a configuration of a back plate in the disk inspection apparatus of FIG. 1.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Disc inspection apparatus 20 ... Main body case 22 ... Discharge port 22a ... Ventilation hole (corresponding to a hole)
30 ... Filter unit (corresponding to air cleaning means)
32 ... Suction path 34 ... Air intake 40 ... Fan unit (corresponding to suction means)
43 ... Blower 50 ... Disk drive 51 ... Housing 52 ... Inflow hole 53 ... Outflow hole 60 ... Power supply unit

Claims (5)

In a disk inspection apparatus for inspecting whether or not information recording on an optical disk is properly performed,
A main body case including an intake port for introducing air for cooling the inside and an exhaust port for discharging air sucked from the intake port to the outside;
An air cleaning means for removing dust and being installed in the intake port or the intake passage communicating with the intake port;
A suction unit that is installed inside the main body case, and that applies a suction force for sucking air from the intake port through the air cleaning unit;
A disk drive for cooling by the air sucked by the suction means and for reproducing the optical disk;
A disk inspection apparatus comprising: The disk drive includes a housing, and the housing covers the entire disk drive,
The said housing is provided with the inflow hole for flowing in the air attracted | sucked by the said suction means, and the outflow hole for making the air flowed in from the said inflow hole flow out. Disk inspection device.   3. The disk inspection apparatus according to claim 2, wherein the inflow hole is disposed opposite to an exhaust port of the suction means. The air inlet is provided on the front side of the main body case, which is the side where the tray of the disk drive is provided, and the air inlet is provided in the air cleaning means.
4. The disk inspection apparatus according to claim 1, wherein the discharge port is provided on a back side of the main body case that faces the front side. 5. The discharge port is composed of a plurality of holes, and these holes are arranged on the upper side and the side edge side of the back side of the main body case,
Of the holes arranged on the side edge side, the hole located on the lower end side is located with a space with respect to the lower side of the main body case.
The disk inspection apparatus according to claim 1, wherein the disk inspection apparatus is a disk inspection apparatus.

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