JP4802649B2 - Information terminal equipment - Google Patents

Description

  The present invention includes a space capable of accommodating a battery serving as a power supply source, a battery accommodating portion provided with an opening capable of taking out the battery from the space, and a battery lid capable of closing the opening. The present invention relates to an information terminal device.

  An apparatus using a primary battery, a secondary battery, or the like as a main power supply generally includes a space that can accommodate these batteries. In general, a battery accommodated in such a space can be easily externally provided. The space is provided with an opening communicating with the external space, and a battery lid capable of closing the opening is provided. As a device constituting such a battery housing portion, for example, there is a “battery housing device” disclosed in Patent Documents 1 and 2 below.

  For example, in the “battery storage device” disclosed in Patent Document 1, a slidable knob is provided on the periphery of the battery storage part, and the engagement with the battery lid is achieved by sliding the knob in the opening direction. An inclined portion that is lifted and lifts the battery lid is formed on this knob. Thus, by sliding the knob in the opening direction, the battery lid can be pushed up and floated by the inclined portion provided on the knob, so that the battery lid can be easily taken out.

  Further, in the “battery storage device” disclosed in Patent Document 2, the battery cover is rotatably supported by the battery storage body, and the hinge portion is specified when a predetermined force is applied in the direction of opening the battery cover. A battery lid support means is provided that can be elastically deformed in a direction to separate the battery lid from the main body. As a result, when a predetermined force or more is applied in the direction of opening the battery lid, the battery lid support means elastically deforms the hinge portion in the predetermined direction to separate the battery lid from the main body. Can be prevented or reduced.

  By the way, in many information terminal devices using such a battery as a main power source, a microcomputer (hereinafter referred to as “microcomputer”) is used for the control. For this reason, if the battery is removed from the battery compartment while the microcomputer is receiving drive power from the battery, the power supplied to the microcomputer is suddenly cut off. The control program (system program) being executed may be abnormally terminated.

  For this reason, in such an information terminal device, a sensor unit capable of detecting the opening and closing of the battery cover is provided, and a software configuration capable of executing a control end process immediately when the sensor unit detects that the battery cover is opened. When the battery cover is open or the battery cover is open, a hardware configuration is adopted that can disable power-on of the device.

JP-A-5-89863 JP 9-46062 A

  However, according to the disclosed techniques exemplified in Patent Documents 1 and 2, neither of such sensor means is provided. Therefore, as described above, sensor means that can detect the opening / closing of the battery lid even if these disclosed techniques are simply applied to an information terminal device using such a battery as a main power source, as described above. A software configuration that can execute control termination processing as soon as it detects that the battery cover is opened, or a hardware configuration that can disable the power-on of the device when the battery cover is open I can't.

  In addition, when such sensor means is mechanically configured and provided around the battery lid, it is not possible to configure the sensor means mounting site and its surroundings, or the sensor means itself to be liquid-tight or air-tight. difficult. Therefore, when the device is placed in an environment where liquids such as water are likely to fall, the water or the like that has entered the device through these gaps will cause the circuit components of the electronic circuit mainly composed of the microcomputer. Since corrosion or a short circuit of a printed wiring board constituting an electronic circuit can be caused, the apparatus is likely to fail.

The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an information terminal device that can detect opening and closing of a battery lid and can easily remove the battery lid. There is to do.
Another object of the present invention is to provide an information terminal device that can prevent liquid such as water from the outside of the device from entering the device even if a means capable of detecting opening and closing of the battery lid is provided. There is to do.

In order to achieve the above object, the information terminal device according to claim 1 according to the claims includes a space that can accommodate a battery serving as a power supply source, and an opening that can take out the battery from the space. An information terminal device comprising: a battery housing portion; and a battery lid capable of closing the opening; and biasing means capable of biasing the battery lid closing the opening in a direction to open the battery lid, Whether the battery lid is open based on the drag of a member that can push up the battery lid by being pushed down in the closing direction of the battery lid to close the opening against the biasing force of the biasing means Sensor means capable of detecting whether or not the battery lid is closed, and the battery lid closing the opening can be prevented from being opened by a biasing force by the biasing means and can be operated by an external operation. Solve the block A locking means capable, in that it comprises the technical features.

  Further, in the information terminal device according to claim 2, when the battery cover is open, a part or all of the urging means can be exposed to an external space of the information terminal device. 2. The information terminal device according to claim 1, wherein liquid enters between the sensor means and the biasing means from the external space into the internal space of the information terminal device in which the sensor means is accommodated. A technical feature is that a waterproof member capable of preventing the above is provided.

In the first aspect of the invention, the urging means urges the battery lid that closes the opening in the opening direction, while the lock means causes the battery lid that closes the opening to Opening is blocked, and the blocking is canceled by an external operation. Whether or not the battery cover is open based on the drag of the member that can push up the battery cover by being pushed down in the closing direction of the battery cover to close the opening against the urging force by the urging means, or Whether the battery cover is closed is detected by the sensor means. Accordingly, the battery lid that closes the opening is urged in the opening direction by the urging means. Therefore, by releasing the lock means that prevents the battery lid from opening, the urging force of the urging means causes the battery The lid is opened. Therefore, it is possible to easily remove the battery lid while the opening and closing of the battery lid can be detected by the sensor means.

  In the invention of claim 2, a waterproof member is provided between the sensor means and the urging means, which can prevent liquid from entering the internal space of the information terminal device in which the sensor means is accommodated from the external space. Yes. As a result, even when a configuration in which part or all of the urging means can be exposed to the external space of the information terminal device when the battery cover is open, the intrusion of liquid from the external space to the internal space by the waterproof member Can be prevented. Therefore, even if sensor means capable of detecting opening and closing of the battery lid is provided, it is possible to prevent liquid such as water from the outside of the apparatus from entering the apparatus.

  Hereinafter, an embodiment in which an information terminal device of the present invention is applied to a barcode reader will be described with reference to the drawings. First, a configuration outline of the barcode reader 10 according to the present embodiment will be described with reference to FIG. FIG. 1 is a perspective view of the barcode reader 10 as viewed from the back surface 10a and shows a state in which the battery cover 30 is removed.

  As shown in FIG. 1, the external shape of the back surface 10 a of the barcode reader 10 is mainly composed of a main body housing 11, a reading port housing 12 and a battery cover 30. A reading port housing 12 having a reading port 12 a is attached to the upper end side 11 a of the main body housing 11, and a battery BAT (not shown) serving as a power supply source for the barcode reader 10 is connected to the lower end side 11 b of the main body housing 11. A battery box 20 is formed, which includes a space 21 that can accommodate the battery and an opening 22 through which the battery BAT can be taken out from the space 21. And the battery cover 30 is comprised so that the opening part 22 of this battery box 20 can be obstruct | occluded. The main body housing 11, the reading port housing 12, and the battery cover 30 are all made of synthetic resin such as ABS resin.

  In addition, a trigger switch 18 that is pressed when irradiating irradiation light is provided on the substantially central side surface of the main body housing 11, and the lower end side 11b of the main body housing 11 is provided with the bar code reader at the corner. A protector 19 is attached that can alleviate the impact received when 10 is dropped.

  Here, as can be understood from FIG. 1, the battery cover 30 is formed in a substantially rectangular flat plate shape. This is because when the battery cover 30 is attached to the main body housing 11, the front surface 30 a of the battery cover 30 is substantially flat so that the outer shape of the back surface 10 a can be formed on the same surface as the back surface 10 a of the barcode reader 10. Because it is designed. For this reason, even when the operator attempts to remove the battery cover 30 attached to the main body housing 11 when replacing the battery BAT, the surface 30a of the battery cover 30 has no protrusions that can be gripped from the outside. Therefore, it is difficult to remove the battery cover 30. Therefore, as will be described later, the barcode reader 10 of the present embodiment includes a jumping piece 52 that flips up the battery cover 30 when the lock of the battery cover 30 is released by operating the lock switch 47. .

  Although not shown in the figure, the bar code reader 10 reads a light source capable of emitting irradiated light in the main body housing 11 and reflected light reflected by the irradiated light on an information code such as a barcode. A light receiving element capable of receiving light through the opening 12a, an imaging optical system capable of condensing the reflected light to form an information code image on the light receiving surface of the light receiving element, and an image signal output from the light receiving element. A microcomputer capable of decoding, and other circuit components and optical components are provided, and driving power is supplied to the circuit components such as the microcomputer from the battery BAT accommodated in the battery box 20.

  Next, the structure of the battery box 20 is demonstrated with reference to FIG.2, FIG4 and FIG.5. FIG. 2 is a plan view showing the configuration of the barcode reader 10 on the back surface 10a side. As shown in FIG. 2, the battery box 20 includes a space portion 21 that can accommodate the battery BAT, and a mechanism accommodation portion 23 that can accommodate a lock mechanism 40 and a lifting mechanism 50 described later. The battery box 20 may correspond to a “battery housing portion” described in the claims.

  When the battery cover 30 is removed from the main body housing 11, the space portion 21 and the mechanism housing portion 23 are both exposed to the external space of the barcode reader 10 through the opening 22. The opening 22 is closed by the battery cover 30 so as to be isolated from the external space.

  The space 21 is a space having a rectangular parallelepiped that is slightly larger than the outer shape of the battery BAT to be accommodated, and is partitioned by a wall 24 formed in a box shape without a rectangular lid. An annular groove 24a is formed on the entire periphery of the outer peripheral edge of the wall portion 24 that divides the space portion 21, and an annular drip-proof rubber 25 is fitted into the annular groove 24a (see FIG. 5).

  The mechanism housing portion 23 is formed by raising the wall portion 24 forming the space portion 21 toward the opening portion 22 and extending the wall portion 24 to the upper end side 11 a of the body housing 11, thereby The lock mechanism 40 and the jumping mechanism 50 are configured to be accommodated in the upper end side 11 a of the housing 11. In addition to the first engagement hole 15 and the second engagement hole 16 being formed in the mechanism housing portion 23, the concave portion 23 a from which the jumping piece 52 jumps out, the hole portion 23 b, and the raising mechanism 50 A rectangular tube portion 23c to which the waterproof cover 56 can be attached is formed (see FIGS. 4 and 5).

  The first engagement hole 15 and the second engagement hole 16 are L-shaped holes, and are formed in a shape through which a first engagement portion 32 and a second engagement portion 33 of the battery cover 30 described later can penetrate. ing. Further, as shown in FIGS. 4A and 4B, the recess 23a is a groove having a substantially square planar shape, and the jumping piece 52 constituting the jumping mechanism 50 is at the center of the recess 23a. A hole 23b through which can penetrate is formed.

  Further, as shown in FIGS. 5 (A) and 5 (B), when the printed wiring board PCB is assembled in the main body housing 11, it is positioned above the switch SW mounted on the printed wiring board PCB. In addition, a rectangular tube portion 23c is formed. The switch SW can correspond to “sensor means” described in the claims.

  The rectangular tube portion 23c includes a cylindrical inner cylinder. The inner cylinder has an inner diameter that allows the jumping piece 52 of the jumping mechanism 50 to move in the axial direction (from the outer diameter of the base 52a of the jumping piece 52). Is also set to a slightly larger diameter). At the bottom of the inner cylinder, a hole 23b formed in the recess 23a is located substantially at the center. In addition, the outer peripheral shape of the rectangular tube portion 23c is formed in a substantially square shape whose cross-sectional shape is capable of liquid-tightly attaching the waterproof cover 56 of the flip-up mechanism 50. The details of the jumping mechanism 50 will be described later.

  In addition, a long hole 17 extending in the width direction of the main body housing 11 is formed in the main body housing 11 shown in FIG. The long hole 17 is a hole through which a lock switch 47 capable of setting on / off of a lock mechanism 40, which will be described later, is exposed. On the upper end side 11a of the long hole 17, "LOCK >>" indicating the direction of the lock operation is the main body. It is clearly shown on the housing 11.

  Next, the configuration of the battery cover 30 will be described with reference to FIG. 3A is a plan view showing the back surface 30b side of the battery cover 30, FIG. 3B is a side view of the battery cover 30 viewed from the 3B direction shown in FIG. 3A, and FIG. The plan view showing the engagement plate 41 is shown respectively.

  As shown in FIGS. 3A and 3B, a claw portion 31 is formed on one end of the back surface 30b of the battery cover 30 formed in a substantially rectangular flat plate shape. A first engaging portion 32, a second engaging portion 33, a triangular convex portion 34, and a contact post 35 are formed on the end side. A rubber presser 36 that protrudes in the thickness direction of the battery cover 30 and that is continuous in a substantially rectangular ring shape is formed in the vicinity of the inner periphery of the back surface 30b.

  The claw portion 31 is a protrusion formed in a shape that can be inserted into a long hole (not shown) formed at two positions on the lower end side 11 b of the main body housing 11 of the battery box 20, and is an end on one end side of the battery cover 30. It is formed in the part. The claw portion 31 is inserted into the elongated hole when the battery cover 30 is attached to the main body housing 11, thereby enabling alignment of one end side of the battery cover 30 and further fixing of the one end side. ing.

  The first engagement portion 32 is a member having an engagement groove 32a formed on the other end side of the back surface 30b of the battery cover 30 so as to protrude in the thickness direction of the battery cover 30, as shown in FIG. In addition, on the side surface viewed from the 3B direction shown in FIG. 3 (A), the engagement groove 32a is formed in an L shape. That is, when an engagement plate 41 described later moves in the short direction of the battery cover 30, the engagement groove 32 a is formed so that the first locking portion 42 of the engagement plate 41 can engage with the first engagement portion 32. Yes. The engagement groove 32a is set to have a larger groove length than an engagement groove 33a of the second engagement portion 33 described below.

  The second engagement portion 33 is configured in substantially the same manner as the first engagement portion 32, aligned in the short direction of the first engagement portion 32 and the battery cover 30. That is, the other end of the back surface 30b of the battery cover 30 has an engaging groove 33a formed so as to protrude in the thickness direction of the battery cover 30, and this engaging groove 33a is also as shown in FIG. In addition, it is formed to have an L shape. As a result, similarly to the first engagement portion 32, when an engagement plate 41 described later moves in the short direction of the battery cover 30, the second locking portion 43 of the engagement plate 41 becomes the second engagement portion 33. An engagement groove 33a is formed so as to be engageable. The engagement groove 33a is set to have a groove length smaller than the engagement groove 32a of the first engagement portion 32 described above.

  One triangular protrusion 34 is located in the vicinity of the short side of the battery cover 30 with respect to each of the first engaging part 32 and the second engaging part 33, and the thickness direction of the battery cover 30 is A vertical cross-sectional shape projecting into a triangular shape is provided (FIG. 3 (B)). Thereby, when the engagement plate 41 described later moves in the short direction of the battery cover 30, the first locking portion 42 and the second locking portion 43 of the engagement plate 41 correspond to the slopes of the corresponding triangular convex portions 34. Get on or go down.

  The contact post 35 is a columnar protrusion formed at the other end side corner of the back surface 30b of the battery cover 30 so as to protrude in the thickness direction of the battery cover 30, and has a cross-shaped base portion at the base end thereof. Is formed. The cross-shaped base portion is for preventing deformation such as bending or breaking of the cylindrical protrusion. In the present embodiment, the height of the contact post 35 is set higher than the triangular protrusion 34 and lower than the first engagement part 32 and the second engagement part 33.

  The rubber retainer 36 is an annular protrusion that can press the drip-proof rubber 25 over almost the entire circumference when the opening 22 of the battery box 20 is closed with the battery cover 30, and the back surface 30 b of the battery cover 30. Further, it is formed in a rectangular ring shape that substantially matches the ring shape of the annular groove 24a of the wall 24. The state in which the drip-proof rubber 25 is pressed by the rubber presser 36 is shown in FIG.

  Next, the configuration of the lock mechanism 40 will be described with reference to FIGS. 2, 3 (C) and 4. 4 (A) and 4 (B) each show a state in which the battery cover 30 is mounted on the main body housing 11, but these figures are formed on the back surface 30b of the battery cover 30. It should be noted that the first engaging portion 32, the second engaging portion 33, the triangular convex portion 34, and the contact post 35 are shown in a transparent state.

  The lock mechanism 40 includes an engagement plate 41, and the engagement plate 41 is accommodated in a lock mechanism accommodation portion 28 that is partitioned by a later-described jumping mechanism holder 13 and a mechanism accommodation portion 23. The locking mechanism 40 may correspond to “locking means” recited in the claims. Here, the configuration of the engagement plate 41 will be described with reference to FIG.

  As shown in FIG. 3 (C), the engaging plate 41 is made of synthetic resin and is formed in a thin plate shape based on a rectangular shape. A plate-like first locking portion 42 extending in the short direction is formed on one end side of the engagement plate 41, and a plate-like second locking portion 43 extending in the short direction is formed on the other end side. Is formed. The first engaging portion 42 and the second engaging portion 43 are respectively provided in the first engaging portion 32 and the second engaging portion 33 of the battery cover 30 when the battery cover 30 is attached to the main body housing 11. The first locking portion 42 is in the engaging groove 32a of the first engaging portion 32, and the second locking portion 43 is in the engaging groove 33a of the second engaging portion 33, respectively. It is formed in a size and shape that can be engaged.

  A guide 44 and a lock switch 47 are formed at a position closer to the other end side where the second locking portion 43 is formed from the longitudinal center of the engagement plate 41. The guide 44 is substantially L-shaped, the long side of the L is along the longitudinal direction of the engagement plate 41, and the short side of the L is the first locking part 42 or the second locking part. It is formed extending in the same short direction as the direction in which 43 is formed. The lock switch 47 is a convex portion having an oval shape and is formed on the surface of the engagement plate 41 (the surface shown in FIG. 3C) so as to protrude in the plate thickness direction.

  In addition, on the surface of the engaging plate 41, a minute circular protrusion 41a and a long rod-shaped protrusion 41b are formed. Thereby, when the engagement plate 41 is assembled to the main body housing 11, the contact area between the inner wall surface of the main body housing 11 and the surface of the engagement plate 41 is reduced, and the sliding movement of the engagement plate 41 is made smooth.

  By assembling the engaging plate 41 formed in this way into the main body housing 11, the battery cover 30 attached to the main body housing 11, that is, the battery cover 30 that closes the space portion 21 of the battery box 20 does not open. It becomes possible to.

  Specifically, as shown in FIG. 2, the first locking portion 42 is exposed from the first engagement hole 15 of the main body housing 11, and the second locking portion 43 is exposed from the second engagement hole 16. Further, the engagement plate 41 is set in the main body housing 11 so that the lock switch 47 protrudes from the long hole 17, and is sandwiched between the main body housing 11 and the lifting mechanism holder 13 and accommodated in the lock mechanism accommodating portion 28. (See FIG. 5).

  4A, when the battery cover 30 is attached to the main body housing 11, the first engagement portion 32 of the battery cover 30 is also inserted into the first engagement hole 15 of the main body housing 11. Since the second engagement portion 33 of the battery cover 30 is inserted into the second engagement hole 16 of the main body housing 11, the inserted first engagement portion 32 and second engagement portion 33 are connected to the engagement plate 41. Lock by.

  That is, by moving the lock switch 47 of the engagement plate 41 in the locking direction (the arrow direction of “LOCK >>” shown in FIG. 4A), the engagement plate 41 slides in the same direction. The first locking portion 42 formed on the plywood 41 engages with the engaging groove 32 a of the first engaging portion 32 that enters the main body housing 11 from the first engaging hole 15, and is formed on the engaging plate 41. The second engaging portion 43 thus engaged engages with the engaging groove 33 a of the second engaging portion 33 that enters the main body housing 11 from the second engaging hole 16. As a result, the first engagement portion 32 and the second engagement portion 33 of the battery cover 30 are locked by the engagement plate 41, so that the battery cover 30 is locked (hereinafter referred to as “locked state”). .

  On the other hand, as shown in FIG. 4 (B), the lock switch 47 of the engagement plate 41 is moved in the unlocking direction (the direction opposite to the “LOCK >>” arrow shown in FIG. 4 (B)). Since the engaging plate 41 slides in the same direction, the first locking portion 42 engaged with the engaging groove 32a of the first engaging portion 32 in the locked state (the state shown in FIG. 4A). However, the second engaging portion 43 that has been engaged with the engaging groove 33a of the second engaging portion 33 is released from the engaging groove 33a. As a result, the first engagement portion 32 and the second engagement portion 33 of the battery cover 30 that have been locked by the engagement plate 41 are released, and the lock of the battery cover 30 is released. It becomes a released state (hereinafter referred to as “release state”).

  In the released state, the first locking portion 42 and the second locking portion 43 of the engagement plate 41 ride on the triangular convex portion 34 of the battery cover 30, respectively. Thereby, since these triangular convex parts 34 give resistance to the sliding movement of the engagement plate 41, it is possible to prevent the engagement plate 41 from easily moving in the locking direction due to gravity or vibration.

  Subsequently, the configuration of the jumping mechanism 50 will be described with reference to FIGS. 4 and 5. FIG. 5 is an explanatory view showing the position of each part by the flip-up mechanism. FIG. 5 (A) shows a case where the battery cover is closed by a cross section taken along line 5A-5A shown in FIG. 4 (A). Further, FIG. 5B shows a case where the battery cover is flipped up and the battery box is opened by a cross section taken along line 5B-5B shown in FIG. 4B. Note that reference numeral PCB shown in FIGS. 5A and 5B denotes a printed wiring board on which an electronic circuit mainly composed of an unillustrated microcomputer is mounted.

  As shown in FIGS. 5A and 5B, the jumping mechanism 50 is a mechanism that urges the battery cover 30 that closes the opening 22 of the battery box 20 in the opening direction, and the jumping piece 52. , A spring 53, a pressing piece 54, and a waterproof cover 56.

  The jumping piece 52 is an integrally formed shaft member made of synthetic resin and includes a base portion 52a on one end side and a top portion 52b on the other end side. The base 52a is formed so as to have a disk shape having a larger diameter than the other parts, and the top 52b is formed so as to have a tapered truncated cone shape. A cylindrical portion having a shape is formed. The pressing piece 54 is also formed in the same shape as the jumping piece 52. Thus, since the jumping piece 52 and the pressing piece 54 are set to the same material and the same shape, both can be shared, so that the types of parts can be reduced.

  The spring 53 is a compression coil spring, and the spring diameter is larger than the outer diameter of the cylindrical portion of the pressing piece 54 (the jumping piece 52) and more than the outer diameter of the base 52a of the jumping piece 52 (the pressing piece 54). Is also set to a small diameter. The spring length is set to be equivalent to the depth of the waterproof cover 56. Note that the jumping piece 52, the spring 53, and the pressing piece 54 can correspond to “biasing means” described in the claims.

  The waterproof cover 56 is a bottomed cylindrical member formed of a synthetic or natural rubber in the shape of a square cylinder, the depth of which is twice the thickness of the base 52 a of the jumping piece 52 and the natural thickness of the spring 53. The length is set to the length of the added length (FIG. 5 (B)). That is, the cylindrical axial length is set so that the base 54 a of the pressing piece 54 accommodated in the waterproof cover 56 can come into contact with the bottom of the waterproof cover 56 without being pressed by the battery cover 30 or the like. ing.

  Further, the opening shape of the waterproof cover 56 is similar to the transverse cross-sectional shape of the rectangular tube portion 23c of the mechanism housing portion 23 described above, and has a flange portion that extends outward over the entire circumference while being slightly smaller. Is formed. As a result, the opening is brought into close contact with the rectangular tube portion 23c of the mechanism housing portion 23 so that it can be mounted in a liquid-tight manner. Further, by sandwiching the flange portion between the mechanism housing portion 23 and the jumping mechanism holder 13, the liquid tightness between the two is further improved. The waterproof cover 56 may correspond to a “waterproof member” recited in the claims.

  The bottom portion of the waterproof cover 56 has a bellows structure portion that is formed thinner than the side wall portion, unlike a simple flat one. Therefore, as will be described later, when the pressing piece 54 is pressed in the direction of the bottom by the jumping piece 52 accommodated therein, the bottom is moved in the external direction (the switch SW direction in FIGS. 5A and 5B). It is possible to push out and project.

  The flip-up mechanism 50 configured as described above is assembled in the jump-up mechanism holder 13 so as to be positioned on the switch SW mounted on the printed wiring board PCB in the main body housing 11, so that the battery cover 30 jumps. It is possible to detect raising and opening / closing of the battery cover 30.

  Specifically, for example, in a state where the battery cover 30 is not attached to the main body housing 11 (the state shown in FIG. 5B), the jumping piece 52 is placed in the rectangular tube portion 23c of the mechanism housing portion 23. Insert from the direction. Then, the thrown-up piece 52 is inserted into the hole portion 23b formed in the bottom portion of the rectangular tube portion 23c from the top portion 52b, and the base portion 52a comes into contact with the bottom portion, thereby being held by the rectangular tube portion 23c ( FIG. 5 (B)).

  Next, the spring 53 is inserted into the rectangular tube portion 23 c so that one end side of the spring 53 contacts the back side of the base 52 a of the jumping piece 52, and further pressed into the spring 53 from the other end side of the spring 53. Insert the piece 54. And the waterproof cover 56 is covered from the base 54a side of the press piece 54 so that these are accommodated in the inside of the waterproof cover 56, and the waterproof cover 56 is stuck to the outer periphery of the rectangular tube part 23c. The “lifting piece 52, the spring 53 and the pressing piece 54” thus covered with the waterproof cover 56 are further fixed to the main body housing 11 by the jumping mechanism holder 13 from above the waterproof cover 56. At this time, the waterproof ring 14 is interposed between the main body housing 11 and the jumping mechanism holder 13.

  By being configured and assembled in this manner, the flip-up mechanism 50 not only flips up the battery cover 30 but also the jump-up mechanism holder on the switch SW mounted on the printed wiring board PCB in the main body housing 11. 13, the button top BP of the switch SW can be pressed. Further, since the waterproof cover 56 is interposed between the jumping piece 52, the spring 53 and the pressing piece 54, and the switch SW, liquid such as water from the external space of the main body housing 11 is allowed to flow. It is possible to prevent intrusion into the internal space of the main body housing 11 through 53 and the pressing piece 54.

  That is, as shown in FIG. 5A, when the battery cover 30 is attached to the main body housing 11 and in the locked state, the contact post 35 formed on the battery cover 30 is lifted up by the jumping mechanism 50. The piece 52 is pushed down in the direction of the pressing piece 54 against the biasing force of the spring 53. For this reason, since the pressing piece 54 is pushed out toward the bottom of the waterproof cover 56 via the spring 53, the base 54 a of the pressing piece 54 presses the button top BP of the switch SW via the bottom of the waterproof cover 56. Accordingly, since the switch SW shifts from the off (on) state to the on (off) state, the battery cover 30 is attached to the main body housing 11 when the microcomputer detects the on (off) state of the switch SW. That is, it is possible to detect that the battery cover 30 is closed.

  On the other hand, as shown in FIG. 5B, when the lock by the lock mechanism 40 is released and the locked state is shifted to the released state, the jumping piece 52 is pressed in the direction of the pressing piece 54 until then. Further, the pressing force by the contact post 35 of the battery cover 30 becomes almost zero almost simultaneously with the release of the lock. For this reason, the jumping piece 52 biased in the direction of the battery cover 30 by the biasing force of the spring 53 protrudes vigorously in the direction of the battery cover 30, so that the jumping piece 52 protruding from the hole 23 b of the recess 23 a is The contact post 35 is pushed up instantaneously. Thereby, since the battery cover 30 is flipped up by the jumping piece 52, the battery cover 30 can be easily removed.

  Further, almost simultaneously with the release of the lock, the pressing piece 54 that has been pushed toward the bottom of the waterproof cover 56 in the locked state can also move in the direction of the jumping piece 52 due to the protrusion of the jumping piece 52. For this reason, the button top BP of the switch SW that has been pressed by the base portion 54a of the pressing piece 54 through the waterproof cover 56 so far pushes the pressing piece 54 back toward the jumping piece 52 by the urging force of the spring member incorporated therein. Thus, since the switch SW shifts from the on (off) state to the off (on) state, the battery cover 30 is attached to the main body housing 11 when the microcomputer detects the off (on) state of the switch SW. It is possible to detect that the battery cover 30 is not open.

  In the present embodiment, as shown in FIG. 5A, in a state where the battery cover 30 is mounted on the main body housing 11, the jumping piece 52 pressed against the contact post 35 of the battery cover 30 is provided. However, the axial lengths of the jumping piece 52 and the pressing piece 54 and the spring pressure of the spring 53 are set so as not to contact the pressing piece 54.

  That is, even if the jumping piece 52 moves most in the direction of the pressing piece 54 due to the pressing by the battery cover 30, the spring is prevented so that the pressing piece 54 accommodated in the waterproof cover 56 is not excessively pushed out to the switch SW side. The spring pressure of 53 is set, and the axial lengths are set so that the jumping piece 52 and the pressing piece 54 do not contact each other (see FIG. 5A). This prevents the pressing piece 54 from being excessively pushed out by the pressing force of the battery cover 30 and breaking through the waterproof cover 56.

  As described above, according to the barcode reader 10 according to the present embodiment, the opening 22 of the battery box 20 is formed by the jumping piece 52, the spring 53, and the pressing piece 54 (hereinafter referred to as “the jumping piece 52 etc.”). While the closed battery cover 30 is urged in the opening direction, the lock mechanism 40 prevents the battery cover 30 closing the opening 22 from being opened by the urging force of the jumping piece 52 or the like, and from the outside. The lock is released by operating the lock switch 47 of the above. Then, whether or not the battery cover 30 is open or whether or not the battery cover 30 is closed through a drag in the closing direction of the battery cover 30 that closes the opening 22 against the urging force of the jumping piece 52 or the like. Is detected by the switch SW.

  As a result, the battery cover 30 that closes the opening 22 is biased in the opening direction by the jumping piece 52 or the like, so that the jumping piece is released by releasing the lock mechanism 40 that prevents the battery cover 30 from opening. The battery cover 30 is opened by the urging force of 52 or the like. Therefore, as shown in FIG. 1, even if the surface 30a of the battery cover 30 is substantially flat so as to be substantially flush with the back surface 10a of the barcode reader 10, the lock mechanism 40 releases the lock. At the same time, since the battery cover 30 is automatically flipped up by the jumping piece 52, the operator who handles the barcode reader 10 can easily open the battery cover 30 and remove it. For this reason, workability at the time of exchanging the battery BAT can be improved.

  Further, according to the barcode reader 10 according to the present embodiment, a waterproof cover capable of preventing liquid from entering the internal space in which the switch SW is accommodated from the external space between the switch SW and the jumping piece 52 and the like. 56 is provided. Thereby, when the battery cover 30 is open, even if a configuration in which a part or all of the jumping piece 52 and the like can be exposed to the external space of the barcode reader 10 is taken out from the external space by the waterproof cover 56. The liquid can be prevented from entering the internal space. Therefore, even if the switch SW capable of detecting opening / closing of the battery cover 30 is provided, it is possible to prevent liquid such as water from the outside of the barcode reader 10 from entering the barcode reader 10.

  As shown in FIG. 6A, the battery cover 30 ′ may be bent in a convex arc shape in the longitudinal direction with respect to the drip-proof rubber 25 provided in the main body housing 11. As a result, as shown in FIG. 6B, the adhesion to the drip-proof rubber 25 can be improved as compared with the case where the battery cover 30 without such warpage is used.

  That is, in the barcode reader 10, when the battery cover 30 is attached to the main body housing 11, the longitudinal ends of the battery cover 30 are fixed by the claw portion 31, the first engagement portion 32, and the second engagement portion 33. Is adopted. For this reason, the position in the thickness direction, that is, the pressure applied to the drip-proof rubber 25 tends to be weaker in the vicinity of the center in the longitudinal direction of the battery cover 30 than at both ends.

  Therefore, as shown in FIG. 6A, by adding a bow-like warp such that the vicinity of the center in the longitudinal direction of the battery cover 30 ′ warps in the direction of the back surface 30′b (opposite side of the front surface 30′a). Since the pressure applied to the drip-proof rubber 25 near the center in the longitudinal direction when the battery cover 30 is attached to the main body housing 11 can be increased, the adhesion to the drip-proof rubber 25 can be improved.

  In the above-described embodiment, the barcode reader 10 has been described as an example of the information terminal device. However, the information terminal device is not limited thereto, and the information is provided with a battery accommodating unit that can accommodate a battery as a power supply source. If it is a terminal device capable of processing, for example, even a PDA, a handy terminal, a handheld computer, a notebook personal computer or the like can obtain the same operations and effects as described above.

The perspective view which looked at the barcode reader which concerns on one Embodiment of this invention from the back surface, shows the state which removed the battery cover. It is a top view which shows the structure of the back surface side of the barcode reader which concerns on this embodiment. 3A and 3B are diagrams showing members constituting the barcode reader according to the present embodiment, in which FIG. 3A is a plan view showing the back side of the battery cover, and FIG. 3B is a view from the 3B direction shown in FIG. FIG. 3C is a plan view showing the engagement plate. FIG. 4A shows a case where the lock is actuated, and FIG. 4B shows a case where the lock is released. FIG. 5 (A) shows a case where the battery cover is closed by a section taken along line 5A-5A shown in FIG. 4 (A), and FIG. A case where the battery cover is flipped up and opened by a cross section taken along line 5B-5B shown in FIG. 6A and 6B are explanatory diagrams showing a schematic configuration of the battery cover as viewed from the side in the short direction. FIG. 6A shows the case where the battery cover is warped, and FIG. 6B shows the case where the battery cover is not warped. Show.

Explanation of symbols

10: Bar code reader (information terminal device)
DESCRIPTION OF SYMBOLS 10a ... Back surface 11 ... Main body housing 13 ... Jumping-up mechanism holder 15 ... 1st engagement hole 16 ... 2nd engagement hole 20 ... Battery box (battery accommodating part)
DESCRIPTION OF SYMBOLS 21 ... Space part 22 ... Opening part 23 ... Mechanism accommodating part 28 ... Locking mechanism accommodating part 30 ... Battery cover (battery cover)
30a ... front surface 30b ... back surface 32 ... first engagement portion 33 ... second engagement portion 35 ... abutment post 40 ... lock mechanism 41 ... engagement plate (locking means)
42 ... 1st latching | locking part 43 ... 2nd latching | locking part 47 ... Lock switch 50 ... Lifting mechanism 52 ... Jumping piece (biasing means)
53 ... Spring (biasing means)
54 ... Pressing piece (biasing means)
56 ... Waterproof cover (waterproof means)
PCB ... Printed wiring board SW ... Switch SW (sensor means)

Claims (2)

An information terminal device comprising: a space that can accommodate a battery that serves as a power supply source; a battery housing that includes an opening from which the battery can be removed; and a battery lid that can close the opening. Because
A biasing means capable of biasing in a direction of opening the battery lid closing the opening;
Whether the battery lid is open based on the drag of a member that can push up the battery lid by being pushed down in the closing direction of the battery lid to close the opening against the biasing force of the biasing means Sensor means capable of detecting whether or not the battery lid is closed;
Lock means capable of preventing the battery lid closing the opening from being opened by an urging force of the urging means and capable of releasing the inhibition by an external operation;
An information terminal device comprising: The information terminal device according to claim 1, wherein when the battery cover is open, a part or all of the urging means can be exposed to an external space of the information terminal device.
Between the sensor means and the biasing means, there is provided a waterproofing member capable of preventing liquid from entering the internal space of the information terminal device in which the sensor means is accommodated from the external space. A characteristic information terminal device.

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