JP6735533B2 - Electronics - Google Patents

Description

The present invention relates to electronic devices such as rotary display devices, spotlight devices, and surveillance cameras.

For example, in a rotating display device, as described in Patent Document 1, a height adjusting mechanism is provided on a pedestal in order to switch the display screen of the display unit between a horizontally long state and a vertically long state so that it can be used. There is known a structure in which an elevation angle adjusting mechanism is provided above the height adjusting mechanism, the elevation adjusting mechanism is provided with a rotation adjusting mechanism, and the rotation adjusting mechanism is provided with a display section.

JP, 2014-41309, A

In such a rotary display device, when the display screen of the display unit is switched between the horizontally long state and the vertically long state, the height adjustment mechanism pushes up the elevation angle adjustment mechanism to move the lower portion of the display unit to above the pedestal. With the elevation angle adjustment mechanism, rotate the display unit in the front-back direction to separate the lower part of the display unit from the pedestal to the front, and in this state, rotate the display unit with the rotation adjustment mechanism, and display the display screen in landscape orientation and portrait orientation. It is configured to switch to the state.

However, in such an elevation angle adjusting mechanism of the rotary display device, in order to hold the display portion by tilting it at an arbitrary angle within a predetermined range, a frictional force is generated by a coil spring on the elevation rotating shaft. There is a problem that the structure for generating a frictional force on the rotary shaft becomes complicated, parts such as a coil spring are required, the number of parts increases, and the assembling work becomes complicated.

Further, in the rotation adjusting mechanism of this rotation display device, the rotating portion is provided by the flange portion in the cylindrical portion attached to the display portion, and the rotating portion is rotatably fitted in the groove portion provided in the cylindrical portion of the elevation angle adjusting mechanism. By doing so, the display unit is rotated together with the rotating member, and since the display screen of the display unit is switched between the horizontally long state and the vertically long state, there is a problem that the structure is complicated and the assembling work becomes complicated. When the display unit is turned in the horizontal direction, there is a problem that the entire device needs to be rotated in the horizontal direction.

The problem to be solved by the present invention is to provide an electronic device which has a simple structure in which the number of parts is suppressed and which can be easily assembled and has high productivity.

An electronic device according to the present invention includes a device mounting member for mounting a device, a pedestal located below the device mounting member, and the device mounting member attached to one end side of the device mounting member in a vertical direction. A rotation connecting member which is rotatably held and is attached to the other end of the device mounting member so as to be horizontally rotatable with respect to the pedestal, and the device mounting member has a rotation shaft for rotating in the vertical direction. Is provided with an elevation rack in which a plurality of first locking teeth are arranged along a first arc, and the pedestal is provided with a second arc centered on the rotation axis for rotating in the horizontal direction. A rotary rack in which a plurality of second locking teeth are arranged is provided, and the rotary connecting member has a plurality of first locking teeth in the elevation rack when moving along the first arc. Elevation angle elastic projections that are sequentially and elastically locked are provided at positions corresponding to the elevation angle rack, and when moving along the second arc, the plurality of second locking teeth of the rotary rack are provided. sequentially resiliently locked by rotating the elastic projection is provided at a position corresponding to said carousel, and wherein the.

According to the electronic device of the present invention, it is possible to easily perform the assembling work and improve the productivity with a simple structure in which the number of parts is suppressed.

1 is a perspective view showing an embodiment in which the present invention is applied to a rotary display device. It is an expanded sectional view in the AA arrow of the rotation display shown in FIG. FIG. 3 is an enlarged cross-sectional view showing a main part of the rotary display device shown in FIG. 2. 4 is an enlarged cross-sectional view of the rotary display device shown in FIG. FIG. 5 is an enlarged cross-sectional view of the rotation display device shown in FIG. 4 taken along the line C-C. FIG. 6 is an enlarged rear view showing a rotary connecting member of the rotary display device shown in FIG. 5. FIG. 6 is an enlarged perspective view showing exploded main parts of a rotary connecting member and a pedestal in the rotary display device shown in FIG. 5. FIG. 2 is a perspective view showing a state where the height of a device mounting member is increased by a first height adjustment support member in the rotary display device shown in FIG. 1. FIG. 3 is a perspective view showing a state where the height of a device mounting member is further increased by a second height adjustment supporting member in the rotary display device shown in FIG. 1. FIG. 9 is an enlarged cross-sectional view of the rotary display device shown in FIG. 8 taken along the line DD. FIG. 9 is an enlarged perspective view showing a first height adjustment supporting member of the rotary display device shown in FIG. 8. FIG. 12 is an enlarged perspective view showing exploded main parts of the upper portion of the first height adjustment support member and the rotary connection member shown in FIG. 11.

An embodiment in which the present invention is applied to a rotary display device will be described below with reference to FIGS.
As shown in FIGS. 1 and 2, this rotation display device includes a device mounting member 2 on which the display device 1 is mounted, a pedestal 3 located below the device mounting member 2, and a device mounting member 2 on the pedestal 3. And a rotary connection member 4 that is connected to.

The display device 1 includes a display panel 1a and a display circuit unit 1b, as shown in FIG. The display panel 1a includes a flat display element such as a liquid crystal display element and an EL (electroluminescence) display element, and is configured to electro-optically display various information such as an image and a sales amount. As shown in FIGS. 1 and 2, the device mounting member 2 is a case in which the display device 1 is mounted, and is formed of a hard synthetic resin such as ABS resin.

As shown in FIGS. 1 and 2, a display opening 2a for exposing the display panel 1a of the display device 1 is provided on the front surface (left side surface in FIG. 2) of the device mounting member 2. Further, a mounting portion 5 is integrally formed on the back surface (right side surface in FIG. 2) of the device mounting member 2 with the mounting portion 5 protruding rearward. The mounting portion 5 is formed so as to be open obliquely downward, and the upper portion of the rotary coupling member 4 is configured to be inserted and mounted from the lower side.

As shown in FIGS. 1 and 2, the pedestal 3 is a substantially trapezoidal case and is formed of a hard synthetic resin such as ABS resin, which is the same as the device mounting member 2. The pedestal 3 has an upper surface. The cylindrical fitting tubular portion 6 is integrally formed in the central portion of the above with protruding upward. The fitting tubular portion 6 is configured such that the lower portion of the rotary connecting member 4 is inserted from above, and in this state, the rotary connecting member 4 is attached rotatably in the horizontal direction about the axial center of the fitting tubular portion 6. Has been done.

As shown in FIGS. 2 to 6, the rotation connecting member 4 includes a vertical rotation mechanism portion 7 that holds the device mounting member 2 rotatably in the vertical direction, and a horizontal rotation that is rotatably mounted in the pedestal 3 in the horizontal direction. And a mechanical unit 8. The rotary connecting member 4 is made of a highly rigid synthetic resin such as polyacetal resin.

As shown in FIGS. 4 and 5, the vertical rotation mechanism portion 7 is provided with the bearing portion 9 provided on the device mounting member 2 and the rotation coupling member 4 and elastically deformed by the bearing portion 9 in the axial direction thereof. The elastic shaft portion 10 to be fitted is provided. In this case, a pair of U-shaped support arms 11 are integrally formed in the mounting portion 5 of the device mounting member 2 so as to face each other. The pair of support arms 11 are configured to be elastically deformed in a direction toward or away from each other. The bearing portions 9 are provided on the facing portions 11a of the pair of support arms 11 facing each other on the same axis.

Further, as shown in FIGS. 3 to 6, a pair of support protrusions 12 are integrally formed on both upper sides of the rotary connecting member 4 in a state of protruding upward. The pair of support protrusions 12 are configured to be arranged between the facing portions 11 a of the pair of support arms 11 provided in the mounting portion 5 of the device mounting member 2. The pair of support protrusions 12 are integrally formed with a pair of elastic shafts 10 that fit into the bearings 9 provided on the pair of support arms 11, respectively.

In this case, as shown in FIG. 5, slit holes 12a are provided in the pair of support protrusions 12 in an inverted U shape from the outer periphery of the upper portion of each elastic shaft portion 10 toward the lower side. That is, the lower end portions of the slit holes 12a are connected to the support protrusions 12. Thereby, the elastic shaft portion 10 is configured to be elastically deformed in the axial direction of the elastic shaft portion 10 centered between the lower ends thereof by the slit holes 12a.

Therefore, as shown in FIGS. 4 and 5, in the vertical rotation mechanism portion 7, the upper portion of the rotation coupling member 4 is inserted into the mounting portion 5 of the device mounting member 2 from the lower side, and the pair of support protrusion portions 12 is formed. When the pair of support arms 11 are arranged in the mounting portion 5, the slit holes 12 a of the pair of support protrusions 12 elastically deform the pair of elastic shaft portions 10 toward each other to support the pair of support arms 11. It is configured to be arranged between the facing portions 11 a of the arm 11.

Further, as shown in FIGS. 4 and 5, in the vertical rotation mechanism unit 7, the pair of elastic shaft portions 10 are arranged between the facing portions 11 a of the pair of support arms 11, and the pair of elastic shaft portions 10 are paired. When the bearings 9 of the support protrusions 12 of the pair are supported, the pair of elastic shafts 10 are elastically deformed in a direction away from each other, so that the pair of elastic shafts 10 each of the bearings 9 of the pair of support protrusions 12. Is rotatably fitted to the.

As a result, as shown in FIGS. 4 and 5, the up-and-down rotation mechanism section 7 includes a pair of elastic shaft sections 10 on each bearing section 9 of a pair of support arms 11 provided in the mounting section 5 of the device mounting member 2. Is rotatably fitted, the rotation connecting member 4 is rotatably connected to the device mounting member 2, and in this state, the device mounting member 2 is rotated around each elastic shaft portion 10 in the vertical direction. Has been done.

On the other hand, as shown in FIGS. 2, 3, 5, and 7, the horizontal rotation mechanism portion 8 of the rotation connecting member 4 includes the fitting tubular portion 6 provided on the pedestal 3 and the fitting tubular portion 6. And a cylindrical shaft portion 13 that is rotatably inserted. The cylindrical shaft portion 13 is formed integrally with the lower end portions of the pair of support protrusions 12 of the rotary coupling member 4. The cylindrical shaft portion 13 is formed into a substantially cylindrical shape whose outer diameter is substantially the same as the inner diameter of the fitting cylindrical portion 6 of the pedestal 3.

In this case, an abutting portion 13a that abuts the upper end of the fitting tubular portion 6 of the pedestal 3 is formed on the outer periphery of the upper portion of the tubular shaft portion 13 as shown in FIGS. The outer diameter of the contact portion 13a is formed to be the same as the outer diameter of the upper end portion of the fitting tubular portion 6. Accordingly, the contact portion 13a is rotatably abutted on the upper end portion of the fitting tubular portion 6 when the tubular shaft portion 13 of the horizontal rotation mechanism portion 8 is inserted into the fitting tubular portion 6 of the pedestal 3 from above. By making contact with each other, the vertical position of the rotary connecting member 4 with respect to the pedestal 3 is regulated.

Thereby, as shown in FIGS. 1 and 2, the rotary connecting member 4 holds the device mounting member 2 rotatably in the vertical direction by the vertical rotating mechanism portion 7 provided on the upper portion thereof, and at the same time, the rotary connecting member 4 Is attached to the pedestal 3 rotatably in the horizontal direction around the axis of the fitting cylinder portion 6 by the horizontal rotation mechanism 8 provided in the lower part of the pedestal 3, thereby connecting the pedestal 3 and the device mounting member 2 in this state. Is configured to hold the device mounting member 2 above the pedestal 3.

By the way, as shown in FIGS. 3 and 5, the rotary connecting member 4 adjusts the elevation angle adjusting mechanism 14 for adjusting the vertical rotation angle of the device mounting member 2 and the horizontal rotation angle of the device mounting member 2. The rotation angle adjusting mechanism 15 is provided. The elevation angle adjusting mechanism 14 is provided in a pair of elevation angle racks 16 provided in the mounting portion 5 of the device mounting member 2 along an arc centered on the rotation center thereof, and in the vertical rotation mechanism portion 7 of the rotary connecting member 4. And a pair of elevation angle elastic protrusions 17 which are elastically locked sequentially while moving along the pair of elevation angle racks 16.

In this case, as shown in FIG. 3 and FIG. 5, the pair of elevation racks 16 includes the center of rotation of the vertical rotation mechanism 7, that is, the pair of support arms 11 provided in the mounting portion 5 of the device mounting member 2. It is integrally formed on the inner surface of the mounting portion 5 of the device mounting member 2 located on an arc centered on the pair of elastic shaft portions 10 of the rotary coupling member 4 fitted to the bearing portion 9.

That is, as shown in FIG. 3 and FIG. 5, the pair of elevation racks 16 includes the device mounting member 2 corresponding to each outer circumference of the pair of support protrusions 12 of the rotary coupling member 4 provided with the pair of elastic shafts 10. Are provided on the inner surface of the mounting portion 5. Each of the pair of elevation angle racks 16 is formed with a plurality of locking teeth 16a along the vertical direction of an arc centered on the pair of elastic shaft portions 10.

As shown in FIGS. 3, 5, and 6, the pair of elevation elastic protrusions 17 are integrally formed on the outer peripheries of the upper portions of the pair of support protrusions 12 of the rotary connecting member 4. The pair of elevation elastic protrusions 17 are formed in a thin, mountain-like shape, and the tips of the protrusions elastically engage any one of the plurality of locking teeth 16a of the pair of elevation racks 16. Is configured.

That is, as shown in FIGS. 3 and 5, the elevation elastic protrusion 17 elastically sequentially overcomes the plurality of locking teeth 16 a of the elevation rack 16 when moving relatively along the elevation rack 16. By elastically engaging any one of the plurality of locking teeth 16a, the rotation angle of the device mounting member 2 with respect to the rotary coupling member 4 in the vertical direction is regulated, and the elevation angle of the device mounting member 2 is adjusted. Is configured.

In this case, as shown in FIGS. 3 and 5, the elevation rack 16 has an inner surface of the mounting portion 5 of the device mounting member 2 along the circular arc centered on the pair of elastic shaft portions 10, which is the center of rotation, at 30 degrees. It is formed in an angle range of -60 degrees. In this case, it is desirable that the elevation rack 16 be formed with an angle range of about 45 degrees. The elevation elastic protrusions 17 are configured to hold the device mounting member 2 in a substantially vertical state when locked between the locking teeth 16a located at the top of the elevation rack 16.

Further, as shown in FIGS. 3 and 4, the elevation angle elastic protrusions 17 cause the device mounting member 2 to move at an angle of approximately 45 degrees when locked between the locking teeth 16a located at the bottom of the elevation angle rack 16. It is configured to be held in an inclined state. As a result, the elevation angle elastic protrusion 17 is elastically locked between any of the plurality of locking teeth 16a of the elevation angle rack 16 to incline the device mounting member 2 from a substantially vertical state by about 45 degrees. It is configured to adjust the tilt angle freely between the states.

On the other hand, as shown in FIGS. 3, 5 and 7, the rotation angle adjusting mechanism 15 includes the rotary rack 18 provided on the inner periphery of the fitting tubular portion 6 of the pedestal 3 and the tubular shaft portion of the rotary connecting member 4. The rotary elastic protrusion 19 is provided on the outer periphery of the rotary member 13 and is elastically locked sequentially while moving along the rotary rack 18. The rotary rack 18 is formed with a plurality of locking teeth 18 a along the entire circumference of the inner peripheral surface of the fitting tubular portion 6 of the pedestal 3.

As shown in FIG. 7, the rotary elastic protrusion 19 is provided on the outer periphery of the cylindrical shaft portion 13 so as to radially protrude from the outer peripheral surface thereof. In this case, slit holes 20 are formed in the outer peripheral portion of the cylindrical shaft portion 13 along the both sides of the rotary elastic protrusion 19 from the upper outer periphery of the rotary elastic protrusion 19. As a result, the rotary elastic protrusion 19 is configured to elastically deform in the radial direction from the outer peripheral surface of the cylindrical shaft portion 13 by the slit hole 20 formed along the outer periphery thereof.

Therefore, as shown in FIG. 3, FIG. 5 and FIG. 7, the rotary elastic protrusion 19 elastically sequentially overcomes the plurality of locking teeth 18a of the rotary rack 18 when moving along the rotary rack 18. By elastically engaging any one of the plurality of locking teeth 18a with each other, the horizontal rotation angle of the device mounting member 2 with respect to the pedestal 3 is regulated, and the horizontal rotation angle of the device mounting member 2 is controlled. Is configured to adjust.

In this case, the rotation angle adjusting mechanism 15 includes a rotation restricting portion 21 that restricts the rotation range of the rotation connecting member 4, as shown in FIGS. 3 and 5 to 7. The rotation restricting portion 21 is provided on the outer peripheral surface of the cylindrical shaft portion 13 and the inner peripheral surface of the fitting cylindrical portion 6 of the pedestal 3, and the restricting groove 23 into which the restricting protrusion 22 is movably inserted. And are equipped with.

As shown in FIGS. 6 and 7, the restriction protrusion 22 is provided on the outer periphery of the cylindrical shaft portion 13 so as to project radially from the outer peripheral surface thereof. In this case, slit holes 22 a are formed in the outer peripheral portion of the cylindrical shaft portion 13 from the upper outer periphery of the regulation protrusion 22 along both sides of the regulation protrusion 22. As a result, the restriction protrusion 22 is configured to elastically deform in the radial direction from the outer peripheral surface of the cylindrical shaft portion 13 by the slit hole 22a formed along the outer periphery thereof.

As shown in FIGS. 5 and 7, the restriction groove 23 is formed in the inner circumference of the fitting tubular portion 6 located on the lower side of the rotary rack 18 within an angle range of 180 degrees to 330 degrees. In this case, it is desirable that the angle range of the restriction groove 23 is formed in a range of 160 degrees in one side rotation and in a range of 320 degrees in both sides rotation. In this case, between the both ends of the regulation groove 23, as shown in FIG. 7, a stopper portion 23a with which the regulation projection 22 of the cylindrical shaft portion 13 abuts is provided.

Accordingly, the rotation restricting portion 21 is in a state in which the restricting protrusion 22 of the cylindrical shaft portion 13 is inserted into the restricting groove 23 of the fitting cylindrical portion 6 of the pedestal 3, as shown in FIGS. 3 and 5 to 7. When the rotary connecting member 4 rotates, the restricting protrusion 22 moves in the restricting groove 23, and when the rotary connecting member 4 rotates 320 degrees, the restricting protrusion 22 is located between the both ends of the restricting groove 23. The rotation connecting member 4 is configured so as not to rotate more than one rotation by abutting against.

Further, as shown in FIGS. 3, 6, and 7, the rotation angle adjusting mechanism 15 includes a lock mechanism portion 24 that rotatably locks the rotation connecting member 4 with respect to the base 3. The lock mechanism portion 24 is provided on the inner peripheral surface of the fitting tubular portion 6 of the pedestal 3 and the pair of upper elastic hook portions 25 provided on the lower portion of the tubular shaft portion 13 of the rotary coupling member 4. And a locking groove portion 26 for locking the elastic hook portion 25 so as to be movable in the circumferential direction.

As shown in FIGS. 3 and 5 to 7, the pair of upper elastic hook portions 25 are formed so as to project in the radial direction from the lower portion of the tubular shaft portion 13 of the rotary connecting member 4, and the pair of upper elastic hook portions 25 are provided on both sides thereof. The slit hole 25a is configured to be provided along the axial direction. Thereby, the pair of upper elastic hook portions 25 is configured to be elastically deformed in the radial direction from the outer peripheral surface of the cylindrical shaft portion 13 by the pair of upper slit holes 25a.

As shown in FIGS. 3 and 7, the locking groove portion 26 is formed in a ring shape along the circumferential direction on the inner peripheral surface of the fitting tubular portion 6 of the pedestal 3. Accordingly, the locking groove portion 26 is locked by inserting the pair of upper elastic hook portions 25 when the cylindrical shaft portion 13 of the rotary coupling member 4 is inserted into the fitting cylindrical portion 6 of the pedestal 3 from above. Is configured to.

As a result, as shown in FIGS. 3 and 7, the lock mechanism portion 24 is in a state in which the pair of upper elastic hook portions 25 are inserted and locked in the locking groove portion 26, and the cylinder of the rotary coupling member 4 is locked. When the shaft portion 13 rotates within the fitting cylinder portion 6 of the pedestal 3, the pair of upper elastic hook portions 25 rotate and move along the inside of the locking groove portion 26, so that even if the rotation connecting member 4 rotates. The cylinder shaft portion 13 of the rotary connecting member 4 is configured so as not to come out of the fitting cylinder portion 6 of the pedestal 3.

Further, in this rotation display device, as shown in FIG. 2, the display circuit portion 1b of the display device 1 of the device mounting member 2 and the pedestal circuit portion 3a provided in the pedestal 3 are electrically connected by the connection cable 27. It is configured to be connected. That is, one end of the connection cable 27 is connected to the display circuit unit 1b of the display device 1, the other end thereof is extended into the cylindrical shaft portion 13 of the rotary coupling member 4, and the extended end is formed. The display side connector 27a is provided in the.

Further, as shown in FIG. 2, the pedestal circuit portion 3a in the pedestal 3 is provided with a pedestal side connector 27b in a state of being arranged in the fitting cylinder portion 6 of the pedestal 3. Accordingly, the display circuit unit 1b of the display device 1 and the pedestal circuit unit 3a provided in the pedestal 3 are connected by connecting the display-side connector 27a of the connection cable 27 to the pedestal-side connector 27b in the pedestal 3. It is configured to be electrically connected.

By the way, as shown in FIGS. 8 and 9, this rotation display device includes first and second height adjustment support members 30 and 31 for adjusting the height of the device mounting member 2 with respect to the pedestal 3. .. The first and second height adjustment support members 30 and 31 have the same configuration except that the vertical lengths thereof are different. That is, the first height adjustment support member 30 is formed such that its vertical length is shorter than the vertical length of the second height adjustment support member 31.

Therefore, in the following description, the first height adjustment support member 30 will be described. As shown in FIGS. 10 and 11, the first height adjustment support member 30 is formed in a substantially cylindrical shape as a whole, and is provided in the lower portion of the first height adjustment support member 30 to be detachably attached to the fitting cylinder portion 6 of the pedestal 3. And a lower attachment mechanism portion 32, and an upper attachment mechanism portion 33, which is provided on the upper portion and on which the rotation coupling member 4 is rotatably and detachably attached.

As shown in FIGS. 10 and 11, the lower mounting mechanism portion 32 of the first height adjustment support member 30 has a cylindrical fitting tubular portion 6 provided on the pedestal 3 and a first height adjusting member. A lower cylinder shaft portion 34 provided below the adjustment support member 30 and rotatably inserted into the fitting cylinder portion 6 is provided. In addition, the lower attachment mechanism portion 32 lowers the lower cylinder shaft portion 34 of the first height adjustment support member 30 in the fitting cylinder portion 6 of the pedestal 3 in a rotatable state with respect to the axial direction. A side lock mechanism portion 35 and a rotation stopper portion 45 that prevents rotation of the lower cylinder shaft portion 34 of the first height adjustment support member 30 with respect to the fitting cylinder portion 6 of the pedestal 3 are provided.

As shown in FIG. 10 and FIG. 11, the lower lock mechanism portion 35 of the lower attachment mechanism portion 32 includes a plurality of lower sides of the lower tubular shaft portion 34 of the first height adjustment support member 30. The elastic hook portion 36 and the engagement groove portion 26 that is a lower engagement groove portion that is provided in the fitting cylinder portion 6 of the pedestal 3 and that engages the lower elastic hook portion 36 in a disengageable manner are provided.

In this case, as shown in FIGS. 10 and 11, the plurality of lower elastic hook portions 36 are formed at the lower end of the lower tubular shaft portion 34 so as to project downward, and in this state, the lower tubular hook portion 36 is formed. The shaft portion 34 is configured to be elastically deformed in the radial direction. As a result, the elastic engaging force of the plurality of lower elastic hook portions 36 is formed to be larger than the elastic engaging force of the upper elastic hook portions 25.

Further, as shown in FIGS. 10 and 11, the rotation stopping portion 45 is provided below the rotation rack 18 provided on the inner peripheral surface of the fitting tubular portion 6 of the pedestal 3 and the first height adjustment supporting member 30. A fixed protrusion 46 provided on the outer peripheral surface of the side tubular shaft portion 34 and locked to the rotary rack 18 is provided. The fixing protrusion 46 is a mountain-shaped protrusion formed on the outer peripheral surface of the lower cylinder shaft portion 34, and is configured not to be elastically deformed in the radial direction of the lower cylinder shaft portion 34.

Thereby, as shown in FIGS. 10 and 11, the rotation stopping portion 45 is fitted into the fitting tubular portion 6 of the pedestal 3 by inserting the lower tubular shaft portion 34 of the first height adjustment support member 30. Then, the fixed projection 46 is locked between any of the plurality of locking teeth 18a of the rotary rack 18, and in this state the fixed projection 46 does not get over the plurality of locking teeth 18a of the rotary rack 18. By being fixed to the rotary rack 18, the lower cylinder shaft portion 34 of the first height adjustment support member 30 with respect to the fitting cylinder portion 6 of the pedestal 3 is prevented from rotating.

On the other hand, the upper attachment mechanism portion 33 of the first height adjustment support member 30 is provided on the upper portion of the first height adjustment support member 30 as shown in FIGS. A cylinder shaft portion 13 that is an upper cylinder shaft portion that is provided below the rotary coupling member 4 and that is rotatably inserted into the upper fitting cylinder portion 37 of the first height adjustment support member 30, and a first height. The upper fitting tubular portion 37 of the adjustment support member 30 is provided with an upper locking mechanism portion 38 that locks the tubular shaft portion 13 of the rotary coupling member 4 in the rotatable state in the axial direction.

As shown in FIG. 12, the upper lock mechanism portion 38 of the upper attachment mechanism portion 33 includes the upper elastic hook portion 25 provided on the cylindrical shaft portion 13 of the rotary coupling member 4 and the first height adjustment support member 30. An upper engaging groove portion 39 provided on the upper fitting tubular portion 37 for releasably engaging the upper elastic hook portion 25.

As shown in FIG. 12, the upper locking groove portion 39 is fitted to the upper side of the first height adjustment support member 30 similarly to the locking groove portion 26 provided on the inner peripheral surface of the fitting tubular portion 6 of the pedestal 3. It is formed in an annular shape on the inner peripheral surface of the coupling tube portion 37 along the circumferential direction thereof. As a result, the upper lock mechanism portion 38 is configured such that when the cylinder shaft portion 13 of the rotary coupling member 4 is inserted into the upper fitting cylinder portion 37 of the first height adjustment support member 30 from above, the pair of upper elastic hooks. The part 25 is configured to be inserted and locked.

Further, as shown in FIGS. 10 and 12, the upper lock mechanism portion 38 has the cylindrical shaft portion of the rotary coupling member 4 in a state in which the pair of upper elastic hook portions 25 are locked in the upper locking groove portion 39. When 13 rotates in the upper fitting tubular portion 37 of the first height adjustment support member 30, the pair of upper elastic hook portions 25 rotationally move along the upper locking groove portion 39, thereby rotationally coupling. Even if the member 4 rotates, the cylindrical shaft portion 13 of the rotary coupling member 4 is configured not to come out of the upper fitting cylindrical portion 37 of the first height adjustment support member 30.

Further, the upper mounting mechanism portion 33 also includes a rotation angle adjusting mechanism 40 and a rotation restricting portion 41, as shown in FIGS. The rotation angle adjusting mechanism 40 includes a rotary rack 42 provided on an inner peripheral surface of the upper fitting tubular portion 37 of the first height adjusting support member 30 along an arc centered on the rotation center thereof, and a rotary connecting member. The rotation elastic protrusion 19 is provided on the outer peripheral surface of the cylindrical shaft portion 13 and is elastically locked sequentially while moving along the rotation rack 42.

As shown in FIG. 12, the rotary rack 42 has a plurality of locking teeth 42 a formed on the entire inner peripheral surface of the upper fitting tubular portion 37 of the upper mounting mechanism portion 33. The rotary elastic protrusions 19 are configured to be elastically locked between the locking teeth 42a sequentially while moving along the rotary rack 42.

As a result, the rotation angle adjusting mechanism 40 elastically overcomes the plurality of locking teeth 42a of the rotary rack 42 sequentially and elastically moves between any of the plurality of locking teeth 42a, as shown in FIGS. The horizontal rotation angle of the device mounting member 2 with respect to the pedestal 3 is regulated by the positive engagement, and the horizontal rotation angle of the device mounting member 2 is adjusted.

Further, as shown in FIGS. 10 to 12, the rotation restricting part 41 of the upper mounting mechanism part 33 is provided on the restricting protrusion 22 provided on the outer periphery of the cylindrical shaft part 13 and on the inner periphery of the upper fitting cylindrical part 37. And a regulation groove 43 into which the regulation projection 22 is movably inserted. Like the restriction groove 23 provided in the fitting cylinder portion 6 of the pedestal 3, the restriction groove 43 has an angle of 180 to 330 degrees on the inner circumference of the upper fitting cylinder portion 37 located below the rotary rack 42. It is provided in the range.

Also in this case, it is desirable that the angle range is provided in the angle range of 320 degrees. Further, as shown in FIG. 12, a stopper portion 43a with which the regulation projection 22 of the cylindrical shaft portion 13 abuts is provided between both ends of the regulation groove 43. Accordingly, in the rotation restricting portion 41, when the rotation connecting member 4 rotates, the restriction protrusion 22 moves in the restriction groove 43, and when the rotation connecting member 4 rotates 320 degrees, the restriction protrusion 22 causes the restriction protrusion 22 to be a stopper of the restriction groove 43. By contacting the portion 43a, the rotation connecting member 4 is configured not to rotate more than one rotation.

Inside the first height adjustment support member 30, as shown in FIG. 10, an extension connection cable 44 is arranged. The extension connection cable 44 is formed so that its length is substantially the same as the vertical length of the first height adjustment support member 30. The extension connection cable 44 is configured such that the lower connector 44a provided at the lower end portion thereof is connected to the pedestal side connector 27b connected to the pedestal circuit portion 3a in the pedestal 3.

Further, in the extension connection cable 44, as shown in FIG. 10, the upper connector 44b provided at the upper end is connected to the display side connector 27a of the connection cable 27 connected to the display circuit unit 1b of the display device 1. Is configured to. Accordingly, the display circuit unit 1b of the display device 1 and the pedestal circuit unit 3a provided in the pedestal 3 are connected to the upper connector 44b of the extension connection cable 44 by connecting the display-side connector 27a of the connection cable 27 to the extension connector cable 44b. The lower connector 44a of 44 is connected to the pedestal side connector 27b in the pedestal 3 so as to be electrically connected.

Similarly, as shown in FIG. 9, the second height adjustment support member 31 is formed such that its vertical length is longer than the vertical length of the first height adjustment support member 30, Other than this, the structure is exactly the same as that of the first height adjustment support member 30. Also in this case, an extension connection cable (not shown) is arranged in the second height adjustment support member 31. This extension connection cable is formed such that its length is longer than that of the extension connection cable 44 of the first height adjustment support member 30, and other than this, the extension connection cable 44 of the first height adjustment support member 30 is used. It has the same configuration.

Next, the operation of such a rotary display device will be described.
First, a case where this rotary display device is assembled without using the first and second height adjustment support members 30 and 31 will be described. At this time, first, the display device 1 is assembled to the device mounting member 2, the connection cable 27 is connected to the display circuit unit 1a of the display device 1 in this state, and the connection cable 27 is connected from the mounting portion 5 of the device mounting member 2 to the device. Pull it out of the mounting member 2.

In this state, the rotation connecting member 4 is attached to the attachment portion 5 of the device mounting member 2. At this time, the display side connector 27a of the connection cable 27 is inserted into the rotary connecting member 4 and pulled out from the cylindrical shaft portion 13 of the rotary connecting member 4. Then, the pair of support protrusions 12 of the rotary coupling member 4 in the vertical rotation mechanism unit 7 are inserted into the mounting portion 5 of the device mounting member 2, and the pair of support protrusions 12 are provided in the mounting portion 5. It is arranged between the support arm portions 11 of.

At this time, the pair of elastic shaft portions 10 provided on the pair of support protrusions 12 of the vertical rotation mechanism portion 7 are pushed in the directions toward each other by the facing portions 11 a of the pair of support arm portions 11. For this reason, the pair of elastic shaft portions 10 in the vertical rotation mechanism portion 7 are elastically deformed in the direction toward each other by the slit holes 12a formed along the outer periphery of the pair of elastic shaft portions 10 and between the facing portions 11a of the pair of support arms 11. Is located in.

In this state, when the pair of elastic shaft portions 10 correspond to the bearing portions 9 of the pair of support protrusions 12, the pair of elastic shaft portions 10 are elastically deformed in the directions in which they are pushed apart to each other, and The portion 10 is rotatably inserted and fitted into each bearing portion 9 of the pair of support protrusions 12. As a result, the rotation connecting member 4 is rotatably connected to the device mounting member 2, and the vertical rotation mechanism unit 7 is configured. In this state, the device mounting member 2 rotates vertically about the pair of elastic shaft portions 10.

At this time, the pair of elevation angle elastic protrusions 17 are movably engaged with the pair of elevation angle racks 16 in the elevation angle adjusting mechanism 14. In other words, the pair of elevation angle racks 16 has an inner surface of the mounting portion 5 of the device mounting member 2 located on an arc centered on the pair of elastic shaft portions 10 that is the rotation center of the vertical rotation mechanism portion 7, that is, a pair of elastic shafts. It is integrally formed on the inner surface of the mounting portion 5 of the device mounting member 2 corresponding to the outer circumferences of the pair of support protrusions 12 of the rotary coupling member 4 provided with the portions 10.

On the other hand, the pair of elevation angle elastic protrusions 17 of the elevation angle adjusting mechanism 14 are integrally formed on the outer peripheries of the upper portions of the pair of support protrusions 12 of the rotary coupling member 4. For this reason, when the pair of elastic shaft portions 10 are rotatably fitted to the bearing portions 9 of the pair of support protrusion portions 12, the pair of elevation angle elastic protrusions 17 cause the plurality of locking teeth of the pair of elevation angle racks 16 to engage. Resiliently engage between any of 16a. As a result, the elevation angle adjusting mechanism 14 is configured, the vertical rotation angle of the device mounting member 2 with respect to the rotary coupling member 4 is restricted, and the elevation angle of the device mounting member 2 becomes adjustable.

Then, the rotary connecting member 4 is attached to the base 3. At this time, the display side connector 27a of the connection cable 27 is connected to the base side connector 27b of the base 3 in advance. Then, the tubular shaft portion 13 formed in the lower portion of the rotary coupling member 4 is inserted into the fitting tubular portion 6 provided on the pedestal 3 of the horizontal rotation mechanism portion 8 and rotatably attached.

At this time, the abutting portion 13a provided on the outer periphery of the upper portion of the tubular shaft portion 13 rotatably abuts on the upper end portion of the fitting tubular portion 6, and the vertical position of the rotary connecting member 4 with respect to the pedestal 3 is restricted. To be done. As a result, the horizontal rotation mechanism portion 8 is configured, and the rotation connecting member 4 is attached to the pedestal 3 in a rotatable state about the axis of the fitting cylinder portion 6 in the horizontal direction.

In this state, the device mounting member 2 is rotatably held by the rotary connecting member 4 in the vertical direction by the vertical rotating mechanism portion 7 provided on the upper part of the rotary connecting member 4, and provided on the lower part of the rotary connecting member 4. The rotation connecting member 4 is attached to the pedestal 3 rotatably in the horizontal direction around the axis of the fitting tubular portion 6 by the horizontal rotation mechanism portion 8 thus provided. As a result, the pedestal 3 and the device mounting member 2 are connected by the rotary connecting member 4, and the device mounting member 2 is held above the pedestal 3 in this state.

In this way, when the rotary connecting member 4 is rotatably attached to the pedestal 3 by the horizontal rotating mechanism portion 8, the rotary elastic projection 19 is movably engaged with the rotary rack 18 in the rotation angle adjusting mechanism 15. .. That is, the rotary rack 18 is integrally formed on the inner peripheral surface of the fitting tubular portion 6 of the pedestal 3. The rotary elastic protrusion 19 is integrally formed on the outer peripheral portion of the cylindrical shaft portion 13 of the rotary connecting member 4, and a slit hole 20 is provided from the outer periphery of the upper portion of the rotary elastic protrusion 19 to both sides of the rotary elastic protrusion 19. ..

Therefore, when the rotary connecting member 4 is rotatably attached to the pedestal 3, the rotary elastic protrusion 19 elastically engages with any one of the plurality of locking teeth 18 a of the rotary rack 18. .. Thereby, the rotation angle adjusting mechanism 15 is configured, the rotation angle of the rotation connecting member 4 with respect to the pedestal 3 in the horizontal direction is regulated, and the rotation angle of the device mounting member 2 in the horizontal direction becomes adjustable.

Further, at this time, the restriction protrusion 22 provided on the outer circumference of the cylindrical shaft portion 13 of the rotation restriction portion 21 is elastically deformed in the radial direction by the slit holes 22a formed along both sides of the restriction protrusion 22 from the upper outer circumference thereof. Then, the pedestal 3 is movably inserted into the restriction groove 23 provided on the inner circumference of the fitting tubular portion 6. That is, the restriction groove 23 is formed within the range of 320 degrees on the inner circumference of the fitting cylindrical portion 6 located on the lower side of the rotary rack 18, and the cylindrical shaft portion 13 is provided between both ends of the restriction groove 23. There is provided a stopper portion 23a with which the regulation projection 22 of FIG.

As a result, when the rotation connecting member 4 rotates with the restriction protrusion 22 of the cylinder shaft portion 13 inserted in the restriction groove 23 of the fitting cylinder portion 6 of the pedestal 3, the restriction protrusion 22 causes the restriction protrusion 22 to rotate. Move in. Then, when the rotary connecting member 4 is rotated by 320 degrees, the regulation projection 22 comes into contact with the stopper portion 23 a located between both ends of the regulation groove 23. This prevents the rotary connecting member 4 from rotating more than once.

Further, when the rotary connecting member 4 is rotatably attached to the pedestal 3 by the horizontal rotating mechanism portion 8, a pair of upper sides provided in the lower portion of the cylindrical shaft portion 13 of the rotary connecting member 4 in the lock mechanism portion 24. The elastic hook portion 25 is locked in a locking groove portion 26 provided on the inner peripheral surface of the fitting tubular portion 6 of the pedestal 3 so as to be movable in the circumferential direction.

That is, the pair of upper elastic hook portions 25 are formed so as to project in the radial direction from the lower portion of the cylindrical shaft portion 13 of the rotary coupling member 4, and the pair of upper slit holes 25a are provided on both sides thereof along the axial direction. There is. Therefore, the pair of upper elastic hook portions 25 are elastically deformed in the radial direction from the outer peripheral surface of the cylindrical shaft portion 13 by the pair of upper slit holes 25a. Further, the locking groove portion 26 is formed in a ring shape along the circumferential direction on the inner peripheral surface of the fitting cylindrical portion 6 of the pedestal 3.

As a result, the pair of upper elastic hook portions 25 are provided with a pair of upper slit holes 25a so that the tubular shaft portion 13 of the rotary coupling member 4 is inserted into the fitting tubular portion 6 of the pedestal 3 from above. The outer peripheral surface is elastically deformed in the radial direction and is inserted into the locking groove portion 26 and locked. In this state, when the cylindrical shaft portion 13 of the rotary coupling member 4 rotates in the fitting cylindrical portion 6 of the pedestal 3, even if the pair of upper elastic hook portions 25 rotationally move along the locking groove portion 26. The cylinder shaft portion 13 of the rotary connecting member 4 does not come out of the fitting cylinder portion 6 of the pedestal 3.

Next, the operation of the rotary display device thus assembled will be described.
First, when the display device 1 is tilted in the front-rear direction, the device mounting member 2 is moved to the vertical rotation mechanism portion 7 against the engaging force of the pair of elevation angle elastic projections 17 with respect to the pair of elevation angle racks 16 of the elevation angle adjustment mechanism 14. It may be rotated in the vertical direction about the center of rotation.

For example, when the display device 1 is erected in a substantially vertical state, the lower part of the device mounting member 2 is pushed toward the rotary connecting member 4. Then, the device mounting member 2 rotates counterclockwise in FIG. 5 to stand up about the pair of elastic shaft portions 10 of the rotation connecting member 4 which is the rotation center of the vertical rotation mechanism portion 7. At this time, the pair of elevation angle elastic protrusions 17 of the rotary coupling member 4 in the elevation angle adjusting mechanism 14 relatively move along the pair of elevation angle racks 16 of the device mounting member 2.

That is, as shown in FIG. 5, the elevation elastic protrusion 17 elastically sequentially overcomes the plurality of locking teeth 16 a of the elevation rack 16 while moving relatively counterclockwise along the elevation rack 16 to obtain the elevation angle. The rack 16 is locked between the locking teeth 16 a located at the top. Thereby, the rotation angle of the device mounting member 2 in the vertical direction with respect to the rotary connecting member 4 is restricted, and the device mounting member 2 is held in a substantially vertical state.

In addition, when the display device 1 is tilted at an angle that is easy to see, the upper part of the device mounting member 2 is pushed toward the upper side of the rotary connecting member 4, and the device mounting member 2 rotates as the center of rotation of the vertical rotation mechanism unit 7. The pair of elastic shaft portions 10 of the connecting member 4 are rotated clockwise in FIG. 5 and tilted. Also at this time, the pair of elevation angle elastic protrusions 17 of the rotary coupling member 4 in the elevation angle adjusting mechanism 14 relatively move along the pair of elevation angle racks 16 of the device mounting member 2.

That is, as shown in FIG. 5, the elevation angle elastic protrusion 17 elastically sequentially overcomes the plurality of locking teeth 16 a of the elevation angle rack 16 while moving relatively clockwise along the elevation angle rack 16 to sequentially move the elevation angle rack 16. It is locked between the locking teeth 16 a located on the lower side of 16. As a result, the vertical rotation angle of the device mounting member 2 with respect to the rotary connecting member 4 is restricted, and the device mounting member 2 is held in a state of being inclined at a predetermined angle.

On the other hand, when the display device 1 is rotated in the horizontal direction, the device mounting member 2 is rotated about the rotation center of the horizontal rotation mechanism portion 8 against the engagement force of the rotation elastic projection 19 with respect to the rotation rack 18 of the rotation angle adjustment mechanism 15. It may be rotated in the horizontal direction around. For example, when rotating the display device 1 in either the left or right direction, either the left or right side portion of the device mounting member 2 is pushed rearward. Then, the device mounting member 2 rotates above the pedestal 3 about the axis center of the cylindrical shaft portion 13 of the rotation connecting member 4, which is the rotation center of the horizontal rotation mechanism portion 8.

At this time, the rotation elastic protrusion 19 of the cylinder shaft portion 13 of the rotation connecting member 4 in the rotation adjusting mechanism 15 moves along the rotary rack 18 of the fitting cylinder portion 6 of the pedestal 3. That is, when the rotary elastic projection 19 moves along the rotary rack 18, the rotary elastic projection 19 elastically sequentially and sequentially surpasses the plurality of locking teeth 18 a of the rotary rack 18 and any one of the plurality of locking teeth 18 a. Elastically engages between. Thereby, the horizontal rotation angle of the device mounting member 2 with respect to the pedestal 3 is regulated, and the horizontal rotation angle of the device mounting member 2 is adjusted.

In this case, when the device mounting member 2 rotates about the rotation center of the horizontal rotation mechanism unit 8, the rotation restricting unit 21 of the rotation angle adjusting mechanism 15 restricts the rotation range of the device mounting member 2. That is, in the rotation restricting portion 21, the rotation connecting member 4 rotates in a state in which the restricting protrusion 22 of the cylindrical shaft portion 13 is inserted into the restricting groove 23 of the fitting cylindrical portion 6 of the pedestal 3.

At this time, the restriction protrusion 22 moves in the restriction groove 23, and when the rotation connecting member 4 rotates 320 degrees, the restriction protrusion 22 contacts the stopper portion 23 a located between both ends of the restriction groove 23. This prevents the rotary connecting member 4 from rotating more than once. Therefore, the connection cable 27 that connects the display circuit unit 1b of the display device 1 and the pedestal circuit unit 3a of the pedestal 3 does not twist more than one rotation.

By the way, when the rotary display device is used at a checkout place where a register is arranged, for example, when the display device 1 is used toward the user of the register, it is not necessary to move the pedestal 3, and the device mounting member 2 The display device 1 can be turned to the user only by horizontally rotating the display device 1 by the horizontal rotation mechanism portion 8. In this case, when the height of the display device 1 is too low and the display device 1 is difficult to see, the device mounting member 2 is rotated in the vertical direction by the vertical rotation mechanism unit 7 and the device mounting member 2 is tilted upward, so that it is easy to see. can do.

Further, even when the display device 1 is used for the customer, it is not necessary to move the pedestal 3, and the display device 1 is turned to the customer only by rotating the device mounting member 2 in the horizontal direction by the horizontal rotation mechanism section 8. be able to. In this case, when the height of the display device 1 is too low and it is difficult for the customer to see the display device 1, the device mounting member 2 is rotated in the vertical direction by the vertical rotation mechanism unit 7 and the device mounting member 2 is tilted upward. , Can be made easier to see.

Next, in this rotation display device, the case of adjusting the height of the display device 1 will be described.
In this case, the rotation connecting member 4 is removed from the pedestal 3, and the first height adjustment support member of the first and second height adjustment support members 30 and 31 that matches the height of the display device 1, for example. The member 30 is attached to the base 3. At this time, first, when the rotary connecting member 4 is removed from the pedestal 3, the display side connector 27a of the connection cable 27 is removed from the pedestal side connector 27b of the pedestal 3.

Then, the lower connector 44a of the extension connection cable 44 having substantially the same length as the vertical length of the first height adjustment support member 30 is connected to the pedestal side connector 27b of the pedestal 3, and the extension connection cable 44 is The upper connector 44b of the extension connection cable 44 is pulled out from the upper end portion of the first height adjustment support member 30 by inserting it into the first height adjustment support member 30. In this state, the first height adjustment support member 30 is attached to the base 3.

At this time, the lower cylinder shaft portion 34 of the lower attachment mechanism portion 32 of the first height adjustment support member 30 is inserted into the fitting cylinder portion 6 of the pedestal 3 and fitted therein, and the lower lock of the lower attachment mechanism portion 32 is locked. The mechanical portion 35 locks the lower tubular shaft portion 34 of the first height adjustment support member 30 to the fitting tubular portion 6 of the pedestal 3, and the rotation stopper portion 45 lowers the pedestal 3 relative to the fitting tubular portion 6. The rotation of the lower cylinder shaft portion 34 of the attachment mechanism portion 32 is prevented.

That is, when the lower cylinder shaft portion 34 is inserted into the fitting cylinder portion 6 of the pedestal 3, the lower elastic hook portion 36 of the lower lock mechanism portion 35 is attached to the fitting cylinder portion 6 of the pedestal 3. It is elastically inserted and locked in the locking groove 26 that is the side locking groove. As a result, the first height adjustment support member 30 does not accidentally slip out of the fitting cylinder portion 6 of the pedestal 3 and is attached to the fitting cylinder portion 6 of the pedestal 3 in a standing state.

At this time, the lower tubular shaft portion of the lower mounting mechanism portion 32 is placed between any of the plurality of locking teeth 18a of the rotary rack 18 provided on the inner peripheral surface of the fitting tubular portion 6 of the pedestal 3. A fixing protrusion 46 provided on the outer peripheral surface of the gear 34 meshes with and is locked. As a result, the fixed protrusion 46 is fixed to the rotary rack 18 without getting over the plurality of locking teeth 18a of the rotary rack 18, and thus the first height with respect to the fitting tubular portion 6 of the pedestal 3 is increased. The lower cylinder shaft portion 34 of the adjustment support member 30 does not rotate in the axial direction.

In this state, the rotary connection member 4 is attached to the first height adjustment support member 30. At this time, first, the display side connector 27a of the connection cable 27 connected to the display circuit unit 1b of the display device 1 is connected to the upper connector 44b of the extension connection cable 44 located on the upper end side of the first height adjustment support member 30. Connect to. In this state, the tubular shaft portion 13 which is the upper tubular shaft portion of the rotary coupling member 4 is inserted into the upper fitting tubular portion 37 of the upper attachment mechanism portion 33 of the first height adjustment support member 30 so as to be rotatably attached.

At this time, the cylinder shaft portion 13 of the rotary coupling member 4 is locked to the upper fitting cylinder portion 37 of the first height adjustment support member 30 by the upper lock mechanism portion 38 of the upper attachment mechanism portion 33. That is, when the tubular shaft portion 13 of the rotary coupling member 4 is inserted into the upper fitting tubular portion 37 of the first height adjustment support member 30, the upper elastic side provided on the tubular shaft portion 13 of the rotary coupling member 4 is inserted. The hook portion 25 is elastically inserted and locked in the upper locking groove portion 39 of the upper fitting tubular portion 37. As a result, the cylinder shaft portion 13 of the rotary coupling member 4 does not accidentally slip out of the upper fitting cylinder portion 37.

Further, when the rotary connection member 4 is attached to the first height adjustment support member 30 in this way, the upper fitting tubular portion 37 of the first height adjustment support member 30 of the rotation angle adjustment mechanism 40 is attached. The rotary elastic projection 19 provided on the outer peripheral surface of the cylindrical shaft portion 13 of the rotary connecting member 4 is locked to the rotary rack 42 provided on the inner peripheral surface so as to be movable along the rotary rack 42.

That is, the rotation angle adjusting mechanism 40 does not rotate the lower cylinder shaft portion 34 with respect to the fitting cylinder portion 6 of the pedestal 3 by the rotation stopper portion 45 of the lower attachment mechanism portion 32. The plurality of locking teeth 42a are elastically overcome in sequence to elastically engage between any of the plurality of locking teeth 42a. As a result, the horizontal rotation angle of the device mounting member 2 with respect to the pedestal 3 is regulated, and the horizontal rotation angle of the device mounting member 2 is adjusted.

Further, at this time, the rotation restricting portion 41 of the upper mounting mechanism portion 33 restricts the rotation range of the rotation connecting member 4 with respect to the first height adjustment supporting member 30. That is, in the rotation restricting portion 41, the restricting protrusion 22 provided on the outer circumference of the cylinder shaft portion 13 of the rotation connecting member 4 is provided on the inner circumference of the upper fitting cylinder portion 37 of the first height adjustment supporting member 30. The rotation connecting member 4 rotates while being inserted into the restriction groove 43.

At this time, the restriction protrusion 22 moves in the restriction groove 43, and when the rotary connecting member 4 rotates 320 degrees, the restriction protrusion 22 comes into contact with the stopper portion 43 a located between both ends of the restriction groove 43. This prevents the rotary connecting member 4 from rotating more than once. Therefore, the extension connection cable 44 arranged in the first height adjustment support member 30 and the connection cable 27 connected to the extension connection cable 44 are not twisted more than once.

As a result, even when the first height adjustment support member 30 is attached to the pedestal 3 to adjust the height of the display device 1, it is not necessary to move the pedestal 3, and the device mounting member 2 is moved by the upper attachment mechanism portion 33. By simply rotating the display device 1 in the horizontal direction, it is possible to rotate the display device 1 in the horizontal direction and change the display device 1 to a direction that is easy to see. Also in this case, the device mounting member 2 can be rotated in the vertical direction by the vertical rotation mechanism portion 7 to tilt the device mounting member 2 in a direction that is easy to see.

By the way, in the case of further adjusting the height of the display device 1 in this rotary display device, the first height adjustment support member 30 may be removed and replaced with the second height adjustment support member 31. That is, when removing the first height adjustment support member 30, the upper fitting cylinder portion 37 of the upper attachment mechanism portion 33 of the first height adjustment support member 30 to the upper cylinder shaft portion of the rotary coupling member 4 is removed. A certain cylinder shaft portion 13 is removed.

At this time, the attachment/detachment force of the lower attachment mechanism portion 32 detachably attached to the pedestal 3 is larger than the attachment/detachment force of the upper attachment mechanism portion 33 detachably attached to the rotary coupling member 4. Therefore, when removing the cylinder shaft portion 13, which is the upper cylinder shaft portion of the rotary coupling member 4, from the upper fitting cylinder portion 37 of the first height adjustment support member 30 of the upper attachment mechanism portion 33, the lower attachment The lower cylinder shaft portion 34 of the mechanism portion 32 does not slip out of the fitting cylinder portion 6 of the pedestal 3, and the cylinder shaft portion 13 of the rotary coupling member 4 is connected to the upper fitting cylinder portion of the first height adjustment support member 30. It can be removed from 37.

That is, the lower elastic hook portion 36 provided on the lower cylinder shaft portion 34 of the lower attachment mechanism portion 32 is not provided with the slit hole on the upper side thereof, and is provided on the cylinder shaft portion 13 of the rotary coupling member 4. The upper elastic hook portion 25 thus formed has an upper slit hole 25a formed on the upper side thereof along the axial direction. Therefore, the elastic engaging force of the lower elastic hook portion 36 is formed to be larger than the elastic engaging force of the upper elastic hook portion 25.

As a result, when the device mounting member 2 is removed from the first height adjustment support member 30, the lower cylinder shaft portion 34 of the first height adjustment support member 30 comes out of the fitting cylinder portion 6 of the pedestal 3. It is possible to remove the cylinder shaft portion 13 of the rotary coupling member 4 from the upper fitting cylinder portion 37 of the first height adjustment support member 30 without the need for the above.

As described above, when the rotary connecting member 4 attached to the device mounting member 2 is removed from the first height adjustment supporting member 30, the cylindrical shaft portion 13 of the rotary connecting member 4 is always supported by the first height adjusting support member 30. Since the device mounting member 2 can be removed from the upper fitting tubular portion 37 of the member 30, it is possible to safely remove the device mounting member 2 from the first height adjustment support member 30. Easy to use because there is no risk of damaging the.

Thus, after removing the first height adjustment support member 30, the second height adjustment support member 31 can be attached to the pedestal 3 in the same manner as the first height adjustment support member 30. The rotation connecting member 4 can be attached to the upper portion of the second height adjustment support member 31. Thereby, the height of the display device 1 can be further increased. Also at this time, the extension connection cable 44 may be replaced with an extension connection cable (not shown) having the same length as the vertical length of the second adjustment support member 31.

As described above, according to the elevation angle adjustment mechanism 14 of the rotary display device, the device mounting member 2 on which the display device 1 is mounted, the pedestal 3 located below the device mounting member 2, and the device mounting member 2 are vertically moved. A rotation connecting member 4 which is rotatably held in a direction and is attached to the pedestal 3, and an elevation rack 16 which is provided on the equipment mounting member 2 along an arc centered on a rotation center in the vertical direction, By providing the elevation angle elastic protrusions 17 which are provided on the connecting member 4 and which are elastically locked sequentially while moving along the elevation angle rack 16, a simple structure in which the number of parts is suppressed is provided, and another component is separately provided. Assembling work can be done easily without needing, and productivity can be improved.

That is, in the elevation angle adjusting mechanism 14 of the rotation display device, when the rotation connecting member 4 is rotatably attached to the device mounting member 2, the elevation elastic protrusion 17 is movable along the elevation rack 16. Since it can be elastically locked to the elevation rack 16, the device mounting member 2 can be tilted at an arbitrary angle. For this reason, the structure is simple and no separate parts are required. Therefore, the number of parts can be reduced, which facilitates the assembly work and improves the productivity.

In this case, the elevation angle adjusting mechanism 14 includes a bearing portion 9 provided on the device mounting member 2, and an elastic shaft portion 10 provided on the rotation connecting member 4 and elastically deformed and fitted into the bearing portion 9 in the axial direction. , And by including the vertical rotation mechanism unit 7 for rotating the device mounting member 2 in the up-down direction about the elastic shaft unit 10, when the rotation connecting member 4 is connected to the device mounting member 2, Since the elastic shaft portion 10 of the connecting member 4 can be elastically deformed, the elastic shaft portion 10 can be easily and easily fitted to the bearing portion 9 of the device mounting member 2 by the elastic deformation of the elastic shaft portion 10. it can.

For this reason, in the elevation angle adjusting mechanism 14, when the rotary connecting member 4 is connected to the device mounting member 2, the elastic shaft portion 10 of the rotary connecting member 4 is elastically deformed so that the bearing portion 9 of the device mounting member 2 can be easily mounted. In addition, since it can be easily fitted, and the elevation elastic projection 17 can be elastically locked to the elevation rack 16 while being movable along the elevation rack 16, the assembly workability is further improved. Good and productivity can be improved.

Further, in the elevation angle adjusting mechanism 14, the elevation angle rack 16 is provided in the equipment mounting member 2 along the arc centered on the rotation center thereof within an angle range of 30 degrees to 60 degrees, so that the equipment mounting is carried out more than necessary. Since the member 2 does not tilt in the vertical direction, the device mounting member 2 can be tilted at a favorable angle. In this case, since the elevation rack 16 is formed in the angle range of 45 degrees, the equipment mounting member 2 can be reliably and satisfactorily supported while the equipment mounting member 2 is tilted at an angle of 45 degrees from a substantially vertical state. Can be leaned to.

Further, according to the rotation angle adjusting mechanism 15 of the rotary display device, the device mounting member 2 on which the display device 1 is mounted, the pedestal 3 located below the device mounting member 2, and the device mounting member 2 are held. A rotary connecting member 4 attached to the base 3 so as to be rotatable in the horizontal direction, a rotary rack 18 provided on the base 3 along an arc centered on a horizontal rotation center of the rotary connecting member 4, and a rotary connecting member 4. And a rotary elastic projection 19 that is elastically locked sequentially while moving along the rotary rack 18, and has a simple structure that suppresses the number of parts, and does not require separate parts. Therefore, the assembling work can be easily performed and the productivity can be improved.

That is, in the rotation angle adjusting mechanism 15 of this rotation display device, when the rotation connecting member 4 is rotatably attached to the pedestal 3, the rotation elastic protrusion 19 is rotated along the rotation rack 18 while being rotatable. Since it can be elastically locked to the rack 18, the device mounting member 2 can be rotated in any horizontal direction. For this reason, the structure is simple and no separate parts are required. Therefore, the number of parts can be reduced, which facilitates the assembly work and improves the productivity.

In this case, the rotation angle adjusting mechanism 15 includes a cylindrical fitting cylinder portion 6 provided on the pedestal 3 and a cylinder provided on the rotation connecting member 4 and rotatably inserted into the fitting cylinder portion 6 of the pedestal 3. The rotation connecting member 4 is provided by including the horizontal rotation mechanism portion 8 that has the shaft portion 13 and rotates the rotation connecting member 4 in the horizontal direction about the axis center of the fitting cylinder portion 6 of the pedestal 3. When connecting to the pedestal 3, the tubular shaft portion 13 of the rotary coupling member 4 is simply inserted into the fitting tubular portion 6 of the pedestal 3 so that the tubular shaft portion 13 of the rotary coupling member 4 is fitted to the fitting tubular portion 6 of the pedestal 3. It can be fitted easily and easily.

Therefore, in the rotation angle adjusting mechanism 15, the rotary rack 18 is provided along the inner peripheral surface of the fitting cylindrical portion 6 of the pedestal 3, and the rotation elastic protrusion 19 is the outer peripheral surface of the cylindrical shaft portion 13 of the rotary coupling member 4. When the rotary coupling member 4 is coupled to the device mounting member 2, the cylindrical shaft portion 13 of the rotary coupling member 4 is fitted to the fitting tubular portion 6 of the pedestal 3 by elastically protruding in the radial direction. The cylindrical shaft portion 13 of the rotary coupling member 4 can be fitted into the fitting cylindrical portion 6 of the pedestal 3 and the rotary elastic protrusion 19 can be elastically locked to the rotary rack 18 by simply inserting the rotary elastic member 19 into the rotary cylinder 18. Therefore, the assembling workability is further improved and the productivity can be improved.

In this case, in the rotation angle adjusting mechanism 15, even if the rotation rack 18 and the rotation elastic projection 19 are provided, not only the number of parts does not increase, but also when the rotation connection member 4 is connected to the device mounting member 2, the rotation connection is performed. The rotational elastic protrusion 19 is formed only by inserting the tubular shaft portion 13 of the member 4 into the fitting tubular portion 6 of the pedestal 3 and fitting the tubular shaft portion 13 of the rotary connecting member 4 into the fitting tubular portion 6 of the pedestal 3. It can be easily and surely locked to the carousel 18.

Further, in the rotation angle adjusting mechanism 15, the pedestal 3 is provided with the lock mechanism portion 24 that locks the rotation connecting member 4 in the axial direction in a rotatable state, so that the cylindrical shaft portion 13 of the rotation connecting member 4 is provided. When the plug is inserted into the fitting cylinder portion 6 of the pedestal 3, the lock shaft 24 locks the cylinder shaft portion 13 of the rotary coupling member 4 to the fitting cylinder portion 6 of the pedestal 3 in the axial direction by the lock mechanism portion 24. Therefore, it is possible to prevent the cylinder shaft portion 13 of the rotary coupling member 4 from being accidentally pulled out from the fitting cylinder portion 6 of the pedestal 3.

That is, the lock mechanism portion 24 is provided on the upper elastic hook portion 25 provided on the outer periphery of the lower portion of the rotary coupling member 4 and the fitting cylindrical portion 6 of the pedestal 3 so that the upper elastic hook portion 25 can be rotated. And the engaging groove portion 26 that is axially engaged with the upper elastic hook portion 25 when the tubular shaft portion 13 of the rotary coupling member 4 is inserted into the fitting tubular portion 6 of the pedestal 3. Since it can be deformed and inserted into the locking groove portion 26, the upper elastic hook portion 25 can be locked easily and reliably in the locking groove portion 26.

In addition, since the rotation angle adjusting mechanism 15 includes the rotation restricting portion 21 that restricts the rotation range of the rotation connecting member 4, the rotation range of the rotation connecting member 4 can be position regulated within a predetermined angle range. .. That is, the rotation restricting portion 21 has the restricting protrusion 22 when the rotating connecting member 4 rotates while the restricting protrusion 22 of the cylinder shaft portion 13 is inserted into the restricting groove 23 of the fitting cylindrical portion 6 of the pedestal 3. By bringing 22 into contact with the stopper portion 23a located between both ends of the regulation groove 23, the rotation range of the rotary coupling member 4 can be regulated within a predetermined angle range.

In this case, the rotation restricting unit 21 restricts the rotation range of the rotation connecting member 4 in the angular range of 180 to 330 degrees, preferably in the angular range of 320 degrees, so that the device mounting member 2 is in the predetermined angular range. It is possible to satisfactorily rotate in the horizontal direction in the inside, and it is possible to prevent the rotation connecting member 4 from rotating more than one rotation, whereby the display circuit unit 1b of the display device 1 and the pedestal circuit unit 3a of the base 3 are It is possible to prevent the connection cable 27 that connects the components from being twisted more than once.

As described above, according to this rotation display device, the device mounting member 2 on which the display device 1 which is a device is mounted, the pedestal 3 located below the device mounting member 2, and the device mounting member 2 in the vertical direction. The rotation connecting member 4 which is rotatably held and rotatably attached to the pedestal 3 in a horizontal direction, the elevation angle adjusting mechanism 14 for adjusting the vertical rotation angle of the device mounting member 2, and the device mounting member 2 Since the rotation angle adjusting mechanism 15 for adjusting the rotation angle in the horizontal direction is provided, when the pedestal 3 and the device mounting member 2 are connected by the rotation connecting member 4, no separate component is needed, The elevation angle adjusting mechanism 14 and the rotation angle adjusting mechanism 15 can be incorporated.

Therefore, in this rotation display device, the pedestal 3 and the device mounting member 2 can be reliably and satisfactorily connected to each other with the minimum necessary number of components of the rotation connecting member 4 alone. The device mounting member 2 can be properly held, and the vertical angle of the device mounting member 2 can be adjusted by the elevation angle adjusting mechanism 14 to properly adjust the tilt of the display device 1 in the vertical direction. It is possible to adjust the horizontal rotation angle of the device mounting member 2 by the rotation angle adjusting mechanism 15 and adjust the horizontal direction of the display device 1 at any time and at any time.

In the embodiment described above, the pair of elevation angle racks 16 of the elevation angle adjustment mechanism 14 are provided on the mounting portion 5 of the device mounting member 2, and the pair of elevation angle elastic projections 17 are provided on the pair of support projection portions 12 of the rotary coupling member 4. However, the present invention is not limited to this, and the pair of elevation angle racks 16 are provided on the pair of support protrusions 12 of the rotary coupling member 4, and the pair of elevation angle elastic protrusions 17 are attached to the mounting portion 5 of the device mounting member 2. May be provided in the above.

Further, in the above-described embodiment, the rotary rack 18 of the rotation angle adjusting mechanism 15 is provided on the inner circumference of the fitting tubular portion 6 of the pedestal 3, and the rotary elastic protrusion 19 is provided on the outer circumference of the tubular shaft portion 13 of the rotary coupling member 4. However, the present invention is not limited to this, but the rotary rack 18 is provided on the outer circumference of the cylindrical shaft portion 13 of the rotary coupling member 4, and the rotary elastic projection 19 is provided on the inner circumference of the fitting cylindrical portion 6 of the pedestal 3. It may be provided.

In addition, in the above-described embodiment, the rotation stopping portion 45 includes the rotation rack 18 provided on the inner peripheral surface of the fitting tubular portion 6 of the pedestal 3 and the first and second height adjustment support members 30 and 31. Although the case where the fixing protrusion 46 provided on the outer peripheral surface of the lower cylinder shaft portion 34 and locked to the rotary rack 18 is provided has been described, the present invention is not limited to this, and the fitting cylinder portion 6 of the pedestal 3 is not limited thereto. A configuration in which a locking recess is provided on the inner peripheral surface, and elastic protrusions that are locked in the locking recess are provided on the outer peripheral surface of the lower cylindrical shaft portion 34 of the first and second height adjustment supporting members 30 and 31. May be

Furthermore, in the above-described embodiment and each modification thereof, the case where the invention is applied to the rotary display device including the display device 1 is described, but the rotary display device is not necessarily required and the rotary illumination device including, for example, a spotlight. The present invention can be widely applied to various rotary electronic devices such as a surveillance camera device including a camera and a rotary audio device including a speaker.

Although one embodiment of the present invention has been described above, the present invention is not limited to this, and includes the invention described in the claims and the scope equivalent thereto.
The inventions described in the claims of the present application will be additionally described below.

(Appendix)
The invention according to claim 1 holds a device mounting member on which a device is mounted, a pedestal located below the device mounting member, the device mounting member rotatably in the vertical direction, and with respect to the pedestal. Attached to the device mounting member, an elevation rack provided on one of the device mounting member and the rotary connecting member along an arc centered on the vertical center of rotation of the device mounting member, and the device mounting member. And an elevation angle elastic protrusion that is provided on the other side of the rotation connecting member and that is elastically locked sequentially while moving along the elevation angle rack, and is an elevation angle adjustment mechanism.

According to a second aspect of the present invention, in the elevation angle adjusting mechanism according to the first aspect, a bearing portion provided on the device mounting member and an elastic deformation of the bearing portion provided on the rotary coupling member in the axial direction thereof. And an elastic shaft part that fits together, and the device mounting member rotates in the vertical direction about the elastic shaft part.

According to a third aspect of the present invention, in the elevation angle adjusting mechanism according to the first or second aspect, the elevation angle rack is 30 degrees to 60 degrees along an arc centered on a rotation center of the equipment mounting member. The elevation angle adjusting mechanism is provided in the angle range of.

According to a fourth aspect of the present invention, a device mounting member for mounting a device, a pedestal located below the device mounting member, and a device holding the device mounting member are attached to the pedestal so as to be rotatable in a horizontal direction. A rotary connecting member, a rotary rack provided on one of the pedestal and the rotary connecting member along an arc centered on a horizontal rotation center of the rotary connecting member, and the pedestal and the rotary connecting member. The rotation angle adjusting mechanism is provided on the other side, and is provided with a rotation elastic projection that is elastically locked sequentially while moving along the rotation rack.

According to a fifth aspect of the present invention, in the rotation angle adjusting mechanism according to the fourth aspect, the cylindrical fitting cylinder portion provided on the pedestal and the fitting of the pedestal provided on the rotary coupling member are provided. A rotation angle adjusting mechanism, comprising: a cylindrical shaft portion that is rotatably inserted into a cylindrical portion, wherein the rotation connecting member rotates in a horizontal direction about an axis center of the fitting cylindrical portion of the pedestal. is there.

According to a sixth aspect of the present invention, in the rotation angle adjusting mechanism according to the fourth or fifth aspect, the rotary rack is provided along an inner peripheral surface of the fitting tubular portion of the pedestal, The rotation elastic protrusion is provided on the outer peripheral surface of the cylindrical shaft portion of the rotation connecting member so as to elastically protrude in the radial direction thereof.

According to a seventh aspect of the present invention, in the rotation angle adjusting mechanism according to any of the fourth to sixth aspects, the rotation connecting member is axially locked in a rotatable state with respect to the pedestal. A rotation angle adjusting mechanism including a lock mechanism portion.

According to an eighth aspect of the invention, in the rotation angle adjusting mechanism according to the seventh aspect, the lock mechanism portion includes a hook portion provided on an outer periphery of a lower portion of the cylindrical shaft portion of the rotary connecting member, and the pedestal. A rotation angle adjusting mechanism, comprising: a locking portion that is provided on an inner peripheral surface of the fitting cylindrical portion and that locks the hook portion in an axial direction in a rotatable state. is there.

According to a ninth aspect of the present invention, in the rotation angle adjusting mechanism according to any of the fourth to eighth aspects, a rotation restricting portion that restricts a rotation range of the rotation connecting member is provided. It is a rotation angle adjusting mechanism.

According to a tenth aspect of the present invention, in the rotation angle adjusting mechanism according to the ninth aspect, the rotation regulating portion regulates the position of the rotation range of the rotation connecting member within an angle range of 180 degrees to 330 degrees. Is a rotation angle adjusting mechanism.

According to an eleventh aspect of the present invention, a device mounting member for mounting a device, a pedestal located below the device mounting member, the device mounting member rotatably held in the vertical direction, and the pedestal with respect to the pedestal And a rotation coupling member that is rotatably attached in a horizontal direction, an elevation angle adjustment mechanism that adjusts a vertical rotation angle of the device mounting member, and a rotation angle adjustment mechanism that adjusts a horizontal rotation angle of the device mounting member. And an electronic device.

According to a twelfth aspect of the present invention, in the electronic device according to the eleventh aspect, the elevation angle adjusting mechanism has a center of rotation in a vertical direction of the device mounting member on one of the device mounting member and the rotation connecting member. And an elevation angle elastic protrusion provided on the other of the equipment mounting member and the rotation connecting member and sequentially elastically locked while moving along the elevation angle rack. And an electronic device.

According to a thirteenth aspect of the present invention, in the electronic device according to the eleventh aspect or the twelfth aspect, the rotation angle adjusting mechanism rotates the rotation connecting member in one of the pedestal and the rotation connecting member in a horizontal direction. A rotary rack provided along an arc centered on the center, and a rotary elastic protrusion provided on the other of the pedestal and the rotary connecting member and sequentially elastically locked while moving along the rotary rack. And an electronic device.

The invention according to claim 14 is the electronic device according to any one of claims 11 to 13, wherein the device mounted on the device mounting member is a display device. is there.

DESCRIPTION OF SYMBOLS 1 display device 2 equipment mounting member 3 pedestal 4 rotation connecting member 5 mounting portion 6 fitting cylinder portion 7 vertical rotation mechanism portion 8 horizontal rotation mechanism portion 9 bearing portion 10 elastic shaft portion 11 support arm 12 support protrusion portion 12a slit hole 13 cylinder Shaft part 14 Elevation angle adjustment mechanism 15, 40 Rotation angle adjustment mechanism 16 Elevation angle rack 16a Locking teeth 17 Elevation angle elastic protrusions 18, 42 Rotation racks 18a, 42a Locking teeth 19 Rotation elastic protrusions 20 Slit holes 21, 41 Rotation regulation part 22 Regulation Protrusions 23, 43 Restriction grooves 23a, 43a Stopper portion 24 Lock mechanism portion 25 Upper elastic hook portion 25a Upper slit hole 26 Locking groove portion 27 Connection cable 30, 31 First and second height adjustment support member 32 Lower attachment mechanism Part 33 Upper mounting mechanism part 34 Lower cylinder shaft part 35 Lower lock mechanism part 36 Lower elastic hook part 37 Upper fitting cylinder part 38 Upper locking mechanism part 39 Upper locking groove part 44 Extension connection cable 45 Rotation stop part 46 Fixed Protrusion

Claims (7)

A device mounting member for mounting a device,
A pedestal located below the device mounting member,
A rotation connecting member that holds the device mounting member rotatably in the vertical direction by mounting the device mounting member on one end side, and is mounted on the other end side so as to be rotatable horizontally with respect to the pedestal.
Equipped with
The equipment mounting member is provided with an elevation rack in which a plurality of first locking teeth are arranged along a first arc centered on a rotation axis for rotating in the vertical direction,
The pedestal is provided with a carousel in which a plurality of second locking teeth are arranged along a second arc centered on the rotation axis for rotating in the horizontal direction,
In the rotation connecting member, an elevation elastic protrusion sequentially elastically locked to the plurality of first locking teeth of the elevation rack when moving along the first arc corresponds to the elevation rack. And a rotational elastic protrusion that is sequentially elastically locked to the plurality of second locking teeth of the rotary rack when moving along the second circular arc corresponds to the rotary rack. It is provided to,
An electronic device characterized by the above. The electronic device according to claim 1,
A bearing portion provided on the device mounting member,
An elastic shaft portion provided on the rotation connecting member and elastically deformed and fitted into the bearing portion in the axial direction thereof,
Equipped with
The device mounting member rotates in the vertical direction using the elastic shaft portion as a rotation shaft for rotating the elastic shaft in the vertical direction,
An electronic device characterized by the above. In the electronic device according to claim 1 or 2,
In the elevation rack, the plurality of first locking teeth are arranged in an angle range of an inclination angle of 30 degrees to 60 degrees along the first arc centered on a rotation axis for rotating in the vertical direction . ,
An electronic device characterized by the above. The electronic device according to any one of claims 1 to 3,
A cylindrical fitting tubular portion provided on the pedestal,
A tubular shaft portion provided on the rotary connecting member and rotatably inserted into the fitting tubular portion of the pedestal;
Equipped with
The rotation connecting member rotates in the horizontal direction with a rotation axis for rotating the shaft center of the fitting tubular portion of the pedestal in the horizontal direction,
An electronic device characterized by the above. The electronic device according to claim 4,
The plurality of second locking teeth are provided along the inner peripheral surface of the fitting tubular portion of the pedestal,
The rotary elastic projection is provided on the outer peripheral surface of the cylindrical shaft portion of the rotary connecting member so as to elastically project in the radial direction thereof.
An electronic device characterized by the above. The electronic device according to any one of claims 1 to 5,
In a state in which the rotary connecting member is rotatable with respect to the pedestal, a lock mechanism unit for fixing the position of the rotary connecting member with respect to the pedestal in a direction along a rotation axis for rotating in the horizontal direction is provided. Is
An electronic device characterized by the above. The electronic device according to any one of claims 1 to 6,
The device mounted on the device mounting member is a display device,
An electronic device characterized by the above.

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