JP3544937B2 - Disk insertion / extraction device - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a disk insertion / extraction device having, as a part of an electronic apparatus, a storage unit that stores a disk device that can be inserted and removed, and a holding unit that holds a disk device mounted in the storage unit, and has a simple configuration. The present invention relates to a disk insertion / removal device that securely fixes a disk device and prevents operation failure of the disk device due to the influence of vibration.
[0002]
[Prior art]
Many disk devices (eg, HDDs) used in current server computers have an SCA interface. For this reason, a configuration is adopted in which a disk device is mounted on a plastic tray or the like and inserted into a disk bay so as to correspond to hot-line insertion and removal. FIG. 15 shows a perspective view of a conventional disk insertion / extraction device. FIG. 16 is a cross-sectional view in the front direction of a conventional disk insertion / extraction device.
1 is a housing (chassis), 2 is a disk device, 9 is a housing side connector (female), 10 is a disk device side connector (male), 11 is a square hole, 12 is a stopper, and 13 is The tray 14, 14 is a fixing screw, 15 is a back panel, and 101 and 102 are guides.
[0003]
The tray 13 carries the disk device 2 straight along the guides 101 and 102, and the connector 9 holds the connector 10 in the mounted state.
[0004]
However, in this example, the disk device is insufficiently fixed due to a gap between the tray and the guide. For this reason, the disk device is likely to be affected by self-vibration and the vibration of other mounted disk devices, and the operation is often unstable. Specifically, the retry mechanism in the disk device operates under the influence of the vibration, resulting in a read error or a write error.
In particular, recent disk devices have increased recording density and are more susceptible to vibration.
[0005]
[Problems to be solved by the invention]
The present invention has been made in order to eliminate the above-mentioned disadvantages of the prior art, and an object thereof is to provide a disk insertion / removal device corresponding to hot-line insertion / removal, by providing stable fixing means. It is an object of the present invention to eliminate the effects of self-vibration and vibrations caused by other mounted disk devices and to stabilize the operation of the mounted disk devices.
[0006]
[Means for Solving the Problems]
A disk insertion / removal device according to the present invention includes, as a part of an electronic device, a storage portion for storing a disk device that can be inserted and removed, and a disk device attached to the disk device and holding the disk device in a state of being mounted in the storage portion. A disk insertion / extraction device having a holding portion that performs the following operations.
(1) As a holding portion, a projection attached to the disk device so as to protrude in a swing direction in which the disk device swings in a mounted state,
(2) As a part of the storage portion, it serves as a guide for sliding the protrusion when inserting the disk device, and
It is inclined so as to protrude inside the storage section toward the insertion direction, and when the disk device is mounted, the protrusion is pressed inward in the swing direction to fix the disk device to the storage portion. Beam to do.
[0007]
The beam has elasticity, and the force that presses the protrusion in the swing direction increases as the inclination of the protrusion extending into the storage portion decreases.
[0008]
The beam generates a component force that presses from both sides inward in the direction of the disk rotation axis of the disk device as a portion that comes into contact with the protrusion when the disk device is mounted, and is inward with respect to the swing direction. Characterized by having a surface that generates a component force that presses the surface.
[0009]
The beam has a semicircular cross section.
[0010]
The beam is characterized in that it has a cross section composed of two sides excluding the base of the triangle.
[0011]
The beam is characterized in that it has a cross section of three sides excluding the base of the trapezoid.
[0012]
The beam has elasticity, and the force that presses the protrusion in the swing direction increases as the inclination of the protrusion extending into the storage portion decreases.
[0013]
Further, the disk insertion / extraction device is characterized in that it has a removal prevention unit for preventing the disk device inserted into the storage unit from coming out.
[0014]
The detachment preventing portion generates a resistance against a force in a detaching direction caused by the pressure contact between the beam and the protrusion.
[0015]
The pull-out preventing portion is configured by a convex portion attached to the disk device and a concave portion or a hole portion provided in a part of the storage portion, and the convex portion is hooked on the concave portion or the hole portion. It is characterized by generating drag.
[0016]
The detachment prevention portion is configured by a concave portion or a hole portion attached to the disk device, and a convex portion provided on a part of the storage portion, and the convex portion is hooked on the concave portion or the hole portion, thereby It is characterized by generating drag.
[0017]
The projection is fixed to a mounting hole provided on a surface of the disk device that is perpendicular to the swing direction.
[0018]
The width of the beam as a guide decreases in the insertion direction, and the projection presses the projection from both sides with respect to the rotation axis direction of the disk of the disk device when the disk device is mounted. .
[0019]
The disk insertion / extraction device is configured such that, when the disk device is mounted, the protrusion is higher than the rear protrusion, and the width of the protrusion is higher than the rear protrusion. And has at least two projections on the front side of the storage section, the front side being pressed by the beam.
[0020]
The storage section has a similar beam facing the beam on a surface facing the beam.
[0021]
The storage section has a guide facing the insertion direction on a surface facing the beam.
[0022]
The disc insertion / removal device has at least two protrusions as the protrusions: a rear protrusion which is pressed against the rear side of the storage unit and a front protrusion which is pressed against the front side of the storage unit when the disk device is mounted. Has,
Furthermore, at least two beams are provided as the beam, a back beam that presses the rear projection and a front beam that presses the front projection when the disk device is mounted.
[0023]
BEST MODE FOR CARRYING OUT THE INVENTION
Embodiment 1 FIG.
Hereinafter, the present invention will be described based on embodiments shown in the drawings. FIG. 1 is a perspective view of the disk insertion / extraction device according to the first embodiment.
1 is a housing (chassis), 2 is a disk device, 3 is a front projection, 4 is a rear projection, 5 is a front projection, 6 is a rear projection, 7 is an upper beam, 8 is a lower beam, 9 is a connector (female) on the storage body side, 10 is a connector (male) on the disk device side, 11 is a square hole, 12 is a stopper, 13 is a tray, and 14 is a back. The panel 15 is a fixing screw.
[0024]
The storage body 1 is configured to store a removable disk device 2 as a part of an electronic device (for example, a server computer device). The housing 1 has a back panel 14 on the back, and the back panel 14 is provided with a connector 9 for electrically connecting to the disk device 2.
[0025]
A beam 7 is provided on the upper surface, and a beam 8 is provided on the lower surface. The beam 7 and the beam 8 form a pair and have a function of guiding the protrusions 3 to 6 attached to the disk device 2 and a function of pressing the protrusions 3 to 6 to fix the disk device 2. I have. In many cases, a plurality of disk devices 2 can be mounted according to the demand for expandability and maintainability of the electronic device. However, the present invention is effective even when a single disk device 2 is mounted.
[0026]
FIG. 2 is a plan view of the storage unit according to the first embodiment. As shown in the figure, the width of the beam 7 as a guide decreases in the insertion direction. Thereby, the pushed-in projection can be pressed from both sides.
[0027]
FIG. 3 is a side sectional view of the disk insertion / extraction device according to the first embodiment. As shown in the figure, the beam 7 is inclined so as to protrude inside the storage section 1 in the insertion direction. Thus, in the mounted state, the protrusions 3 and 4 can be pressed inward with respect to the swing direction (vertical direction in this figure). The relationship between the beam 8 and the projections 5 and 6 is the same. The beam 7 is generated by cutting out the upper surface of the chassis which is usually the storage body 1 and performing plastic working by pressing, so that the production cost can be kept low. Further, it is configured using a material having elasticity. Therefore, the smaller the inclination of the protrusion that protrudes into the storage unit 1, the greater the force that presses the protrusion.
[0028]
FIG. 4 is a front sectional view of the disk insertion / extraction device according to the first embodiment. As shown in the figure, the beam 7 and the beam 8 face each other, and apply pressure to the near-side protrusion 3 and the near-side protrusion 5, respectively.
[0029]
Next, the disk device 2 will be described.
The disk device 2 is electrically connected to an electronic device. Therefore, it has a connector 10 that is gripped by the connector 9 and connects the conductors.
[0030]
In addition, the disc device 2 is fixed to the tray 13 so that an operator can perform an insertion / removal operation during insertion / extraction. Further, projections 3 to 6 for holding the disk device 2 in the housing 1 in the mounted state are attached.
[0031]
FIG. 5 is a view showing a mounting instruction of the tray and the protrusion according to the first embodiment. The disk device 2 is provided with screw holes 16 to 18 for attachment in advance. The tray 13 is fixed to the screw hole 16 using the fixing screw 15 as shown in the figure. The front projection 3 is attached to the screw hole 17, and the rear projection 4 is attached to the screw hole 18. Similarly, the front projection 5 and the rear projection 6 are attached to the opposite surface.
[0032]
Further, the present disk insertion / extraction device is provided with a removal prevention unit. In this example, it is constituted by a square hole 11 provided in the storage body 1 and a stopper 12 (convex portion) provided in the tray 13. A recess may be used instead of the square hole 11. The stopper 12 is configured to hook on the square hole 11 or the concave portion in the inserted state. Thereby, it is possible to prevent the disk device 2 from slipping out.
Contrary to this example, the same effect can be obtained by providing a hole or a concave portion in the tray 13 and providing a convex portion in the storage body 1 so that the convex portion of the storage body 1 hangs over the hole or concave portion of the tray 13. Can be provided. In addition, the removal prevention portion is not limited to these configurations, and is effective as long as it can resist the force in the direction in which the disk device 2 relatively comes out of the housing 1 in the inserted state.
[0033]
The operation of inserting the disk device 2 will be described. The operator holds the handle portion of the tray 13 and first puts the rear projection 4 inside the beam 7, and similarly puts the rear projection 6 inside the beam 8.
[0034]
In this state, the back projection 4 and the back projection 6 are arranged along the beam 7 and the beam 8, and the disk device 2 is pushed toward the back of the housing 1.
[0035]
The smaller the inclination of the projecting portion inside the storage portion 1 is, the greater the force of the beam 7 pressing the projection in the swinging direction is. Therefore, the resistance force associated with the insertion is small in the initial stage of the insertion. Therefore, in the initial stage, it is easy to perform the operation of following the guide. In other words, the operation of following the guide can be easily started even from a slightly twisted state or a laterally displaced state, and the range of the track that can be inserted normally is widened. In addition, the resistance generated when the guide is removed and inserted is easily recognized as a sense of incongruity that does not occur during normal operation. This facilitates the insertion operation. In addition, the work at the time of extraction becomes easy.
[0036]
In the final stage, the connector 10 is engaged with the connector 9 and is gripped. At the same time, the stopper 12 enters the square hole 11 and is caught. Thus, the insertion operation is completed. At this time, the projections 3 to 6 serve to hold the disk device 2 inside the housing 1.
[0037]
When the disk device 2 is operated in this state, the disk device 2 is swung up and down around the joint between the connector 9 and the connector 10 with the operation inside the disk device 2.
[0038]
FIG. 6 is an enlarged side view of the press contact portion in the first embodiment. In the illustrated plane, the beams 7 apply pressures 21 and 22 to the front projection 3 and the rear projection 4. As shown in the figure, when the beam 7 is tilted inside the housing 1, the pressures 21 and 22 are generated by tilting forward. Therefore, in addition to the vertical component forces 23 and 25 applied so as to suppress the swing, component components 24 and 26 in the pushing direction are applied.
Therefore, there is a problem that the disk device gradually comes out due to its own swing and the electrical connection of the connector part cannot be maintained. However, in the present invention, the disk device has a pull-out preventing portion, so that such a problem is prevented. it can.
[0039]
FIG. 7 is an enlarged front view of the press-contact portion in the first embodiment. In the plane shown, the beam 7 is exerting pressure on the front projection 3. Assuming that the curvature of the beam 7 and that of the near side projection 3 are the same, the two contact linearly, and pressure is applied to each point on the line.
[0040]
For example, near the contact point where the inclination of the tangent is 45 degrees, a pressure as indicated by 31 is applied. The pressure 31 is divided into a vertical partial pressure 32 and a horizontal partial pressure 33. The partial pressure 32 is a component applied to suppress the swing, but the partial pressure 33 is a force that suppresses the near-side protrusion 3 toward the center line. Since such a force is applied to the left and right objects, the force is applied from both sides. Further, when the front side projection 3 is shifted laterally, the magnitude of the partial pressure in the direction of returning the deviation increases, and the effect of returning to the original position works.
As described above, the vertical partial pressure 32 generates a component force that presses the protrusion inward with respect to the swinging direction, and the horizontal partial pressure 33 presses the protrusion inward in the disk rotation axis direction from both sides. Create a component force.
[0041]
In particular, a component force that presses the protrusions from both sides inward in the direction of the disk rotation axis can prevent longitudinal twisting and lateral displacement caused by the operation of the disk device. Thereby, the physical load on the connector can be reduced.
[0042]
Near the tangent where the inclination of the tangent is 90 degrees, no vertical force is applied from the beam 7 except for the frictional force. However, since the width as the guide is equal to the width of the front-side protrusion 3, a drag is generated when a force to shift the front-side protrusion 3 to the side is applied. Therefore, a force for returning to a small displacement is generated.
[0043]
Since the above-mentioned pull-out preventing portion generates a resistance against a force in a direction in which the disk device comes out, it is possible to apply a high pressure from the beam, and it is possible to further stabilize the disk device. At this time, not only the swing direction but also the partial pressure in the direction of the rotation axis of the disk can be increased, and the prevention of twisting and the like can be ensured.
[0044]
Embodiment 2 FIG.
In the above-described embodiment, an example has been described in which the beam has a semicircular cross-section and the protrusion has a hemispherical head whose curvature is adapted to have a continuous semicircular contact with the beam. .
In the present embodiment, various beam configurations and projection configurations will be described, and further, the operation when these are combined will be described.
[0045]
FIG. 8 is a diagram illustrating a beam shape. The front view and side view of each beam are shown. Reference numeral 41 has a semicircular cross section, similarly to the beam used in the above embodiment. Reference numeral 42 has a cross section composed of two sides excluding the base of the triangle. Reference numeral 43 has a cross section including three sides excluding the base of the trapezoid.
[0046]
Each beam is common in that it inclines inside the housing and has a tapered width as a guide. However, even if the taper is not tapered, the disk device can be fixed and effective if the protrusion does not shift laterally in the mounted state.
[0047]
FIG. 9 is a diagram showing the shape of the projection. Each projection is a rotating body. Also, a fixing screw is provided at the lower part. 51 and 52 have hemispherical heads, and 53 has a planar head. 51 has a vertical side surface, and 52 and 53 have hakama-shaped side surfaces with widened skirts. These projections are examples, and may be other than a rotating body. Further, the shape of the head is not limited to these examples.
[0048]
Next, these combinations will be described. An example is shown in the figure. FIG. 10 is a diagram illustrating a first example of a combination of a beam and a protrusion according to the second embodiment. FIG. 11 is a diagram illustrating a second example of a combination of a beam and a protrusion according to the second embodiment.
In these examples, the protrusion receives an inwardly inclined pressure from the side portion of the inwardly inclined beam. Therefore, a vertical component force and a horizontal component force are received, and the same operation and effect as in the first embodiment can be obtained.
[0049]
If the height of the projection is different, the displacement of the beam is different, and the applied pressure is also different. Therefore, the pressure can be adjusted by the height of the projection. The partial pressure in the direction of sandwiching from both sides can also be adjusted.
[0050]
Embodiment 3 FIG.
An embodiment in which a guide facing the insertion direction is provided on a surface of the storage unit facing the beam will be described.
[0051]
FIG. 12 is a front sectional view of the disk insertion / extraction device according to the third embodiment. The configuration of the guide may be the same as the configuration of the conventional guide. The guide has no elasticity and does not displace even under pressure.
[0052]
Since the guides are provided on opposing surfaces in the storage unit 1, the disk device is fixed at at least three points. Therefore, it is possible to withstand the positive and negative rotational moments in the plane of the disk, and it is possible to reduce the physical load on the connector. Further, since the guide is not displaced by the pressure from the disk device generated by the pressure of the beam, the position of the connector 10 of the disk device can be specified with reference to the guide, and the accuracy of the positional relationship between the connectors 9 and 10 in the joining can be improved. it can.
[0053]
Embodiment 4 FIG.
A description will be given of a mode in which the storage body has, as beams, a rear beam that presses the rear projection and a front beam that presses the front projection.
[0054]
FIG. 13 is a plan view of a storage section according to the fourth embodiment. FIG. 14 is a side sectional view of a storage section according to the fourth embodiment.
[0055]
The disk device 2, the tray 13, and the projections 3 to 6 to be mounted are the same as in the first embodiment. When the disk device 2 is mounted, the rear beam 16 on the rear side of the storage unit 1 presses the rear projection 4, and the manual beam 17 on the front side of the storage unit 1 presses the front projection 3. I do.
[0056]
In a case where two projections are fixed by one beam, when one pressure increases due to a shape error, the other pressure decreases and influences each other. However, in the present embodiment, the rear projection and the front projection are provided, and pressure is applied by separate beams. Therefore, compared to the case of pressing with the same beam, the pressure of the projection or the beam due to the shape error of the beam is reduced. The error is reduced.
[0057]
In the above example, the case where the disk device is mounted vertically has been described. However, the present invention is effective even when the disk device is mounted horizontally.
[0058]
【The invention's effect】
In the present invention, the projection mounted so as to protrude in the swinging direction is pressed against by the beam also serving as a guide, so that the disk device is fixed to the storage portion in a close contact state with a simple configuration, and The effect on the disk device due to movement can be eliminated.
[0059]
Due to the elasticity of the beam, the smaller the inclination that protrudes into the storage section, the greater the force that presses the projection in the swinging direction.Therefore, the resistance force accompanying insertion increases in the final stage of insertion, Initially small. Therefore, in the initial stage, it is easy to perform the operation of following the guide, and it is easy to recognize the resistance generated when the guide is removed and inserted as a sense of incongruity that does not normally occur. For this reason, an erroneous insertion operation deviating from a normal trajectory can be prevented.
Further, the pressure can be adjusted by changing the height of the projection.
[0060]
Further, since the beam has a surface that generates a component force that presses from both sides inward in the disk rotation axis direction with respect to the protrusion, it is possible to prevent the disk device from being twisted or laterally displaced. This is particularly effective when the rocking causes a rotational moment in the disk device about the longitudinal direction or when the center of gravity moves in the rotational axis direction. Preventing small movements such as twisting and lateral displacement stabilizes the operation of the disk drive, reduces the load on the connector, and stabilizes the electrical connection. Furthermore, it helps to simplify the configuration of the connector.
[0061]
Since the beam has a semi-circular cross-section, it can generate the above-described component force that presses from both sides.
[0062]
Since the beam has a cross-section consisting of two sides excluding the base of the triangle, it is possible to generate the above-described component force for pressing from both sides.
[0063]
Since the beam has a cross-section consisting of three sides excluding the base of the trapezoid, it is possible to generate the above-described component force for pressing from both sides.
[0064]
Due to the elasticity of the beam, the smaller the inclination that protrudes into the storage unit, the greater the force that presses the protrusion in the swinging direction, so the component force that presses the protrusion from both sides also increases at the final stage of insertion, In the early stages of small. Therefore, in the initial stage, the operation of easily following the guide can be started even from a slightly twisted state or a laterally displaced state, and can be fixed at a predetermined position in the final stage. As described above, the range of the track that can be normally inserted is widened, and the insertion operation is facilitated. In addition, the work at the time of extraction becomes easy.
Further, by changing the height of the projection, the pressure in the direction of the rotation axis of the disk can be adjusted.
[0065]
When the beam is inclined inward in the mounted state, the beam generates a component force in a direction for pushing the disk device. For this reason, the disk device gradually comes out with the swing of the disk device itself, which may cause a problem that the electrical connection of the connector portion cannot be maintained. In the present invention, such a problem can be prevented since the pull-out preventing portion is provided.
[0066]
Further, since the pull-out preventing portion generates a resistance against the force in the direction of pulling out, it is possible to apply a higher pressure to the beam, and it is possible to further stabilize the disk device. At this time, not only the swing direction but also the partial pressure in the rotation axis direction can be increased, and the prevention of twisting and the like can be ensured.
[0067]
Further, since the convex portion attached to the disk device is engaged with the concave portion or the hole provided in a part of the storage portion, the above-described drag can be generated.
[0068]
Further, since the concave portion or the hole portion attached to the disk device is engaged with the convex portion provided in a part of the storage portion, the above-described drag can be generated.
[0069]
Since the projection is fixed to a mounting hole provided in advance assuming mounting, the disk device can be stabilized according to its characteristics. In addition, since the interval between the beam and the disk is short, the effect of shaking due to expansion and contraction or deformation of the holding unit itself does not occur.
[0070]
The beam has a tapered width as a guide in the insertion direction, and presses the projection from both sides in the rotation axis direction in the mounted state. Therefore, it is possible to prevent the disk device from being twisted or laterally displaced.
[0071]
Since the rear projection and the front projection are provided, the swing can be stopped with a larger force.
[0072]
Since similar beams are provided on the opposing surfaces in the storage section, the disk device can be fixed at four points. Therefore, it is possible to withstand the positive and negative rotational moments in the plane of the disk, and it is possible to reduce the physical load on the connector.
[0073]
Since similar guides are provided on the opposing surfaces in the storage section, the disk device is fixed at at least three points. Therefore, it is possible to withstand the positive and negative rotational moments in the plane of the disk, and it is possible to reduce the physical load on the connector. In addition, since the guide is not displaced by the pressure from the disk device generated by the pressure of the beam, the connector position of the disk device can be specified based on the guide, and the accuracy of the positional relationship between the connectors in joining can be improved.
[0074]
Since the rear projection and the front projection are provided and pressure is applied by separate beams, an error in pressure due to a shape error of the projection and the beam is reduced as compared with a case where pressure is applied by the same beam.
[Brief description of the drawings]
FIG. 1 is a perspective view of a disk insertion / extraction device according to a first embodiment.
FIG. 2 is a plan view of a storage section according to the first embodiment.
FIG. 3 is a side sectional view of the disk insertion / extraction device according to the first embodiment.
FIG. 4 is a cross-sectional view in the front direction of the disk insertion / extraction device according to the first embodiment.
FIG. 5 is an instruction diagram for attaching a tray and a projection according to the first embodiment.
FIG. 6 is an enlarged side view of a press contact portion in the first embodiment.
FIG. 7 is an enlarged front view of a press-contact portion according to the first embodiment.
FIG. 8 is a diagram showing a beam shape.
FIG. 9 is a view showing a shape of a projection.
FIG. 10 is a diagram showing a first example of a combination of a beam and a projection in the second embodiment.
FIG. 11 is a diagram showing a second example of a combination of a beam and a projection in the second embodiment.
FIG. 12 is a front sectional view of a disk insertion / extraction device according to a third embodiment.
FIG. 13 is a plan view of a storage section according to the fourth embodiment.
FIG. 14 is a side sectional view of a storage section according to a fourth embodiment.
FIG. 15 is a perspective view of a conventional disk insertion / extraction device.
FIG. 16 is a front sectional view of a disk insertion / extraction device according to the related art.
[Explanation of symbols]
1 storage unit (chassis), 2 disk unit, 3 front projection, 4 rear projection, 5 front projection, 6 rear projection, 7 top beam, 8 bottom beam, 9 storage unit side connector (female), 10 Disk device side connector (male), 11 square hole, 12 stopper, 13 tray, 14 back panel, 15 fixing screw, 101, 102 guide.

Claims (17)

A disk insertion / extraction device including, as a part of an electronic device, a storage unit that stores a disk device that can be inserted and removed, and a holding unit that is attached to the disk device and holds the disk device in a state of being mounted in the storage unit. And a disk insertion / removal device (1) having the following elements, mounted on the disk device so as to protrude in a swinging direction in which the disk device swings in a mounted state. Projections,
(2) As a part of the storage portion, it serves as a guide for sliding the protrusion when inserting the disk device, and
It is inclined so as to protrude inside the storage section toward the insertion direction, and when the disk device is mounted, the protrusion is pressed inward in the swing direction to fix the disk device to the storage portion. Beam to do. 2. The disk insertion / removal device according to claim 1, wherein the beam has elasticity, and the force of pressing the projection in the swinging direction increases as the inclination of the projection extending into the storage portion decreases. . The beam generates a component force that presses from both sides inward in the direction of the disk rotation axis of the disk device as a portion that comes into contact with the protrusion when the disk device is mounted, and is inward with respect to the swing direction. 2. The disk insertion / removal device according to claim 1, further comprising a surface for generating a component force for pressing the disk. 4. The disk insertion / extraction device according to claim 3, wherein the beam has a semicircular cross section. 4. The disk insertion / extraction device according to claim 3, wherein the beam has a cross section including two sides excluding the base of the triangle. 4. The disk insertion / extraction device according to claim 3, wherein the beam has a cross section including three sides excluding the base of the trapezoid. 4. The disk insertion / removal device according to claim 3, wherein the beam has elasticity, and the force of pressing the projection in the swinging direction increases as the inclination of the projection extending into the storage portion decreases. . 4. The disk insertion / extraction device according to claim 1, wherein the disk insertion / extraction device has a removal prevention unit that prevents the disk device inserted into the storage unit from coming out. 9. The disk insertion / removal device according to claim 8, wherein the removal prevention portion generates a resistance against a force in a detaching direction generated by the pressure contact between the beam and the protrusion. The pull-out preventing portion is configured by a convex portion attached to the disk device and a concave portion or a hole portion provided in a part of the storage portion, and the convex portion is hooked on the concave portion or the hole portion. 10. The disk insertion / extraction device according to claim 9, wherein a drag is generated. The detachment prevention portion is configured by a concave portion or a hole portion attached to the disk device, and a convex portion provided on a part of the storage portion, and the convex portion is hooked on the concave portion or the hole portion, thereby 10. The disk insertion / extraction device according to claim 9, wherein a drag is generated. The disk insertion / extraction device according to claim 1, wherein the projection is fixed to a mounting hole provided on a surface of the disk device perpendicular to the swing direction. The width of the beam as a guide decreases in the insertion direction, and the projection presses the projection from both sides with respect to the rotation axis direction of the disk of the disk device when the disk device is mounted. The disk insertion / extraction device according to claim 1. The disk insertion / extraction device is configured such that, when the disk device is mounted, the protrusion is higher than the rear protrusion, and the width of the protrusion is higher than the rear protrusion. 14. The disc insertion / removal device according to claim 13, wherein the disc insertion / removal device is wide and has at least two protrusions on the front side of the storage portion, the front side being pressed by the beam. 4. The disk insertion / removal device according to claim 1, wherein the storage section has a similar beam facing the beam on a surface facing the beam. 2. The disk insertion / extraction device according to claim 1, wherein the storage section has a guide facing the insertion direction on a surface facing the beam. The disk insertion / extraction device has at least two protrusions as the protrusions: a rear protrusion pressed against the rear of the storage unit and a front protrusion pressed against the front of the storage unit when the disk device is mounted. Has,
Further, the beam has at least two beams of a rear beam that presses the rear projection and a front beam that presses the front projection when the disc device is mounted. Item 6. The disk insertion / extraction device according to item 1 or 3.

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