JP6765709B2 - lift device - Google Patents

Description

The present invention relates to an elevating device capable of holding a display device such as a liquid crystal display (monitor) stationary at an arbitrary position in the vertical direction as an elevating body.

Display devices such as liquid crystal displays (monitors), for example, elevating devices capable of stationaryly holding a large-sized display device at an arbitrary position in the vertical direction have been proposed (Patent Documents 1 and 2).

In these elevating devices, an elevating body such as a display device attached to a mounting bracket can be locked and held at a lower limit lock position and an upper limit lock position in the vertical direction by a lock mechanism. For example, when the operator pushes the lifted body locked at the lower limit lock position upward, the lock mechanism is unlocked and is urged by the spring force of the spring part to move upward with a light pushing force. .. Then, when the operator stops pushing up the lifting body, the friction force is used to stop the lifted body at that position.

When the operator pushes up or down the lifted body from an arbitrary stop position between the upper and lower lock positions to the upper or lower lock position, the lock mechanism operates and the mounting bracket is automatically locked to the lock position. At the upper limit lock position, the lock mechanism is not unlocked by the weight of the elevating body. Similarly, at the lower limit lock position, the lock mechanism is not unlocked by the spring force of the spring portion.

Japanese Unexamined Patent Publication No. 2006-153957 Japanese Unexamined Patent Publication No. 2003-295161

As disclosed in Patent Documents 1 and 2, the conventional lifting device is composed of parts such as a mounting bracket, a friction mechanism, a lock mechanism, and a spring portion.

An object of the present invention is to provide an elevating device capable of reducing the assembly process and cost by reducing the number of parts.

The first configuration of the elevating device that achieves the object of the present invention is an elevating device that can stop and hold the object to be elevated at an arbitrary position in the elevating direction, and extends in the elevating direction, and a strut wall portion along the elevating direction. In addition, a strut in which a plurality of click fitting portions forming lock positions are formed at one or vertically separated in the elevating direction, and a strut that is vertically arranged with respect to the strut, and is arranged in the elevating direction by a spring force upward in the elevating direction. A stop / lock component force generating portion that moves the moving member in a direction orthogonal to the above column to generate an outward component force from the inside to the outside of the column, and an outward component force provided at the tip of the moving member. At the position of the click fitting portion, the click fitting is click-fitted to the click fitting portion, and at an arbitrary position within the elevating range, the outward component force causes pressure contact with the inner wall surface of the support column wall portion. A convex portion, an elevating body mounting member provided on the stop / lock component force generating portion to attach the elevating body, and a spring that applies a spring force upward in the elevating direction to the stop / lock component generating portion. and parts, was closed, the stop-lock component force generating unit further said inner strut is movable up and down along the elevating direction, a first slider which the object lifting body mounting member is fixed, the first slider It has a second slider that forms a moving member arranged inside, and a third slider that abuts on the lower surface of the second slider and is applied with the spring force of the spring portion, and is of the second slider and the third slider. It is characterized in that the contact surfaces are formed on inclined surfaces parallel to each other.

The second configuration of the elevating device that realizes the object of the present invention is that in the above-mentioned first elevating device, the stop / lock component force generating portion can be moved up and down in the support column along the elevating direction, and the subject is covered. It has a first slider to which the elevating body mounting member is fixed, and a link mechanism that is arranged in the first slider and connects the link members along the elevating direction, and the spring portion is attached to the link member below the elevating direction. It is characterized in that the spring force of is applied.

The third configuration of the elevating device that realizes the object of the present invention is that in any of the elevating devices described above, the spring portion arranges a plurality of springs having different spring forces with the axes along the elevating direction as the same axis. It is characterized by that.

A fourth configuration of the elevating device that realizes the object of the present invention is characterized in that, in any of the above-mentioned elevating devices, the tip surface of the engaging convex portion is partially formed with a concave portion or a convex portion. And.

According to the first aspect of the present invention, the lock mechanism for locking the lifted body at a predetermined lock position and the friction mechanism for stopping the lifted body at an arbitrary lifting position other than the locked position within the lifting range are also used. The number of parts can be reduced, and the configuration can be simplified. Therefore, it is possible to reduce the assembly man-hours and the cost, and the friction mechanism and the lock mechanism are configured by utilizing the wedge effect with the three parts of the first slider, the second slider and the third slider. It is possible to surely generate an outward component force.

According to the invention of claim 2 , the friction mechanism and the lock mechanism can be configured by a simple configuration of a link mechanism.

According to the invention of claim 3 , the spring portion can be compactly configured, and the adjustment of the spring force can be finely set.

According to the invention of claim 4 , when the engaging convex portion acts as a friction mechanism, a high frictional force can be obtained.

It is a perspective view which shows the 1st Embodiment of the elevating device which concerns on this invention. It is an exploded perspective view of the elevating device shown in FIG. The first slider of FIG. 2 is shown, (a) is an external perspective view seen from the back side, and (b) is a cross-sectional view taken along the line AA of (a). The second slider of FIG. 2 is shown, (a) is an external perspective view seen from the back side, (b) is a top view of (a), and (c) is a view of arrow B (front view) of (a). (D) is the C arrow view (right side view) of (a). The third slider of FIG. 2 is shown, (a) is an external perspective view seen from the back side, (b) is a cross-sectional view taken along the line DD of (a), and (c) is a second slider and a third slider in a locked state. A vertical cross-sectional view showing the relationship with the three sliders, (d) is a vertical cross-sectional view showing the relationship between the second slider and the third slider in a stopped state at an arbitrary position. The cross-sectional view taken along the line EE of the lifting device shown in FIG. 1 shows a state in which the mounting bracket is locked at the upper limit lock position. FIG. 1 is a cross-sectional view taken along the line EE of the lifting device shown in FIG. 1, showing a state in which the mounting bracket is locked at the lower limit lock position. FIG. 1 is a cross-sectional view taken along the line EE of the lifting device shown in FIG. 1, showing a state in which the mounting bracket is frictionally held between the upper limit lock position and the lower limit lock position. It is a vertical sectional view which shows the 2nd Embodiment of the elevating device which concerns on this invention.

Hereinafter, the elevating device according to the present invention will be described in detail based on the embodiments shown in the drawings.

First Embodiment FIGS. 1 to 8 show a first embodiment of the present invention. In the figure, the three axes orthogonal to each other are the X-axis, the Y-axis, and the Z-axis, and in the elevating device 1, the X-axis direction is the width direction (sometimes referred to as the left-right direction), the Y-axis direction is the front-back direction, and Z. The axial direction is the ascending / descending direction (sometimes referred to as the vertical direction), the front side in the front-rear direction is FS, and the back side is RS. Further, the left-right direction is the left side and the right side when the rear side RS is viewed from the front side FS.

Overall Configuration of Lifting Device 1 FIG. 1 is a perspective view showing a first embodiment of the lifting device 1 according to the present invention, and FIG. 2 is an exploded perspective view thereof.

In FIGS. 1 and 2, the elevating device 1 includes a base member 10 for attaching an elevating body 2 such as a liquid crystal monitor, a spring guide cylinder 30, a first spring 35 of a compression coil spring, and a first spring of the compression coil spring. It has two springs 36, a first slider 40, a second slider 60 which is a moving member, a third slider 80, and a mounting bracket 100 which is a lifting body mounting member for mounting the lifting body 2. The elevating device 1 is installed on, for example, a dedicated mounting table A. The first slider 40, the second slider 60, and the third slider 80 integrally move up and down to form a stop / lock component force generating unit 3. Further, the first spring 35 and the second spring 36 form a spring portion 4 that urges the stop / lock component force generating portion 3 upward in the elevating direction.

In FIG. 2, the base member 10 and the mounting bracket 100 are represented with the front side FS facing the front side, but the first slider 40, the second slider 60, and the third slider 80 are characterized by the back side RS. Therefore, the rear side RS is shown facing the front side.

Examples of the lifting body 2 include, but are not limited to, a display device such as a liquid crystal display (monitor).

Configuration of Base Member 10 The base member 10 is erected on a bottom plate 11 mounted on a dedicated mounting table A on which the elevating device 1 is installed with mounting screws (not shown), and on the back RS of the bottom plate 11. It has a support column 12 formed in a box-shaped tubular shape extending in the elevating direction. The support column 12 has a back wall 13 and left and right side walls 14 and 15 on both sides in the width direction bent from the left and right sides of the back wall 13 toward the front side. The left and right flange walls 16 and 17 are bent so as to face each other from the front surface of the left side wall 14 and the right side wall 15 toward the inside in the width direction. An opening surface 18 having a predetermined width is formed between the left flange wall 16 and the right flange wall 17.

By communicating the inside and outside of the support column 12 via the opening surface 18, the mounting bracket 100 described later can be moved up and down with respect to the support column 12. Stopper screws 10a and 10a are attached to the upper end ends of the left and right side walls 14 and 15 of the support column 12, and the upper end portions of the first slider 40 come into contact with the stopper screws 10a and 10a to enter the support column 12. The arranged parts that move up and down are prevented from coming off. Instead of the stopper pin screws 10a and 10a, a lid member (not shown) may be fixed to the upper end of the support column 12.

The support column 12 is formed in the shape of a box-shaped tubular so-called C-shaped steel (lip channel steel) having an opening surface 18 formed on the front side FS, but may be cylindrical or elliptical.

In the back wall 13 forming the support column wall portion of the base member 10, the first lock recess 19 and the second lock recess 20 which are click fitting portions constituting the lock mechanism are vertically spaced at the center in the width direction. Is formed. The first lock recess 19 is for determining the upper limit lock position of the elevating device 1, and the second lock recess 20 is for determining the lower limit lock position of the elevating device 1, and is a trapezoidal shape of the second slider 60 described later. The convex portion 73 can be engaged.

As shown in FIGS. 5 (c) and 5 (d) and FIGS. 6 to 8, the first lock recess 19 and the second lock recess 20 are formed in a trapezoidal concave shape in vertical cross section. The upper and lower facing inner surfaces 21 and 22 of the first lock recess 19 and the second lock recess 20 have opposite lengths as they face rearward in the front-rear direction in accordance with the outer shape of the engaging convex portion 73 of the second slider 60 described later. It is formed on an inclined surface that shortens the length.

In the present embodiment, the first lock recess 19 and the second lock recess 20 facing each other on the left and right sides in the width direction are engaged with the second slider 60 described later, similarly to the upper and lower facing inner surfaces 21 and 22. It is formed on an inclined surface whose facing length becomes shorter toward the rear in the front-rear direction according to the outer shape of the convex portion 73.

Configuration of Spring Guide Cylinder 30 and Spring Part 4 (First Spring 35, Second Spring 36) The spring guide cylinder 30 is integrally formed with a cylindrical portion 31 having a bottom portion with an open upper end and a bottom portion of the cylindrical portion 31. It has a mounting flange portion 32 that has been formed. The spring guide cylinder 30 is located at the central portion in the column 12, and the mounting flange portion 32 is attached to the bottom plate 11 of the base member 10 by screws and nuts (not shown).

In the spring portion 4, the second spring 36 is installed in the first spring 35. The first spring 35 and the second spring 36 play a role of cushioning the load W of the elevating body 2 and a rearward component force required to hold the elevating body 2 at an arbitrary position in the elevating direction, which will be described later. It has a role of generating and a role of playing a supporting force when moving the elevating body 2 upward in the elevating direction.

The free heights of the first spring 35 and the second spring 36 in the elevating direction are set higher than the heights of the columns 12 in the elevating direction, but the height is not limited to this. Further, the first spring 35 has a longer free height in the ascending / descending direction than the second spring 36. Further, the load required to compress the first spring 35 and the second spring 36 to the same height in the elevating direction is larger for the first spring 35 than for the second spring 36.

A first spring 35 having a spring force F1 and a second spring 36 having a spring force F2 (F1> F2) are installed in the cylindrical portion 31 of the spring guide cylinder 30. In a state where the first spring 35 and the second spring 36 are housed in the cylindrical portion 31, the upper ends of the first spring 36 and the second spring 36 in the elevating direction project upward from the upper ends of the cylindrical portion 31.

The first spring 35 and the second spring 36 come into contact with the third slider 80, and each spring force (F1, F2) acts upward in the elevating direction.

Configuration of First Slider 40 and Mounting Bracket 100 FIG. 3 shows the first slider 40, (a) is an external perspective view seen from the rear side, and (b) is a cross-sectional view taken along the line AA of (a). ..

The first slider 40 has a first main body portion 41 having a rectangular parallelepiped outer shape. The first main body 41 is housed inside the support column 12 without play and is movable in the ascending / descending direction. The first main body portion 41 is surrounded by a top wall portion 42, a front wall portion 43, a back wall portion 44, and left and right side wall portions 45, 46, and is formed in a hollow shape with an opening on the bottom surface side.

As shown in FIG. 3, the mounting bracket 100 includes a fixing plate portion 101 screwed to the top wall portion 42 of the first main body portion 41, a mounting plate portion 102 to which the lifting body 2 is mounted, and a mounting plate portion 102. A guide plate portion 103 extending rearward from the rear end and inserted into the opening surface 18 of the support column 12, and a connection plate portion 104 connecting the guide plate portion 103 and the fixed plate portion 101 with a step in the ascending / descending direction. Have.

As shown in FIG. 3B, the mounting bracket 100 has a hook plate portion 101a formed by bending downward from the rear end of the fixing plate portion 101 in the elevating direction on the top wall portion 42 of the first main body portion 41. It is inserted into the formed engaging recess 54 without play in the left-right direction. The mounting bracket 100 is mounted on the first slider 30 so that the front wall portion 43 of the first main body portion 41 is located on the back side of the connection plate portion 104 of the mounting bracket 100.

A guide hole 47 is formed in the top wall portion 42 of the first main body portion 41. The guide hole 47 guides the slide guide cylinder 82 of the third slider 80, which will be described later, so as to be slidable in the elevating direction. Screw holes 48 and 49 are formed in the top wall portion 42 in the left-right direction of the guide hole 47. The left and right screw through holes 105 and 106 formed in the fixing plate portion 101 of the mounting bracket 100 are located above the left and right screw holes 48 and 49.

As shown in FIG. 3B, the mounting bracket 100 is fixed to the first slider 40 by screwing the screw 109 into the left and right screw holes 48 and 49 through the left and right screw through holes 105 and 106. At that time, the positioning protrusions 50 formed by projecting from the front wall portion 43 of the first main body portion 41 in the left-right direction are engaged with the positioning holes 107 and 108 formed in the connection plate portion 104 for positioning.

Therefore, the first slider 40 and the lifting body 2 move up and down integrally via the mounting bracket 100.

The back wall portion 44 of the first main body portion 41 is formed with an elongated rectangular opening window 51 along the left-right direction. The opening window 51 is formed so that the upper edge of the opening substantially coincides with the lower surface of the top wall portion 42. The engaging convex portion 73 of the second slider 60, which will be described later, is fitted into the opening window 51 so as to be movable along the front-rear direction. When the first slider 40 moves up and down in the support column 12 of the base member 10, the opening window 51 faces the first lock recess 19 and the second lock recess 20.

A pair of guide rails 52 are formed on the left and right sides of the guide holes 47 along the front-rear direction on the lower surface of the top wall portion 42 of the first main body portion 41. A pair of guide grooves 71 and 72 provided on the left and right sides of the second slider 60, which will be described later, are slidably fitted to the pair of guide rails 52. A second slider 60, which will be described later, is housed slidably in the front-rear direction, and a third slider 80 is housed so as to be movable in the up-and-down direction in the inner 53 formed in the empty space of the first main body 41. ..

Configuration of Second Slider 60 and Third Slider 80 FIG. 4 shows a second slider 60, (a) is an external perspective view seen from the rear side, (b) is a top view of (a), and (c) is (c). The B arrow view (front view) of a) and (d) show the C arrow view (right side view) of (a). FIG. 5 shows a third slider, (a) is an external perspective view seen from the rear side, (b) is a cross-sectional view taken along the line DD of (a), and (c) is a stop / lock component in a locked state. A vertical cross-sectional view showing the relationship between the second slider and the third slider constituting the generating unit 3, (d) shows the second slider and the third slider forming the stop / lock component force generating unit 3 in the stopped state at an arbitrary position. It is a vertical sectional view which shows the relationship with a slider.

The second slider 60 and the third slider 80 are housed in the inner 53 of the first slider 40 so as to overlap each other in the vertical direction. The upper surface of the third slider 80 slidably contacts the lower surface of the second slider 60. The movement of the third slider 80 in the front-rear direction and the left-right direction is restricted within the inside 53 of the first main body 41 of the first slider 40, and the movement in the ascending / descending direction is permitted.

The second slider 60 is movable in the inside 53 of the first main body 41 of the first slider 40 along the front-rear direction, and the movement in the left-right direction is restricted. The second slider 60 is located between the third slider 80, which is urged upward by the spring forces (F1, F2) of the first spring 35 and the second spring 36, and the lower surface of the top wall portion 42 of the first main body 41. It is sandwiched between and held under pressure. Therefore, the first slider that receives the load W of the lifting body 2 and the second slider 60 move integrally along the vertical direction in the vertical direction.

The contact surface between the lower surface of the second slider 60 and the upper surface of the third slider 80 is in contact with each other on an inclined surface, and when a spring force (F1, F2) upward in the ascending / descending direction acts on the third slider 80, the amount generated at the contact surface. The force acts on the second slider 60 toward the rear in the front-rear direction.

On the other hand, when the first slider 40 is pushed downward in the ascending / descending direction, the second slider 60 moves downward in the ascending / descending direction integrally with the first slider 40. The operating state of the second slider 60 and the third slider 80 at this time will be described later.

Before explaining the second slider 60, the third slider 80 will be described first.

5A and 5B show a third slider 80, FIG. 5A is an external perspective view seen from the rear side, FIG. 5B is a sectional view taken along the line DD of FIG. 5A, and FIG. 5C is a second slider 60 in a locked state. A vertical cross-sectional view showing the relationship between the second slider 60 and the third slider 80, (d) is a vertical cross-sectional view showing the relationship between the second slider 60 and the third slider 80 in a stopped state at an arbitrary position. In FIGS. 5 (c) and 5 (d), the first slider 40 shows the EE cross section of FIG. 3 (a) (corresponding to the EE cross section of FIG. 1), and the second slider 60 , The EE cross section of FIG. 4 (b) is shown (corresponding to the EE cross section of FIG. 1), and the third slider 80 is the EE cross section of FIG. 5 (a) (FIG. 1). (Corresponding to the cross section seen by EE) is shown.

The third slider 80 has an inclined base portion 81 having a substantially rectangular shape elongated in the left-right direction, and a cylindrical slide cylinder portion 82 extending upward from the inclined base 81 along the elevating direction.

The inclined base portion 81 is formed in a shape whose outer contour substantially matches the inner contour of the inner 53 of the first main body 41 of the first slider 40, and is movably fitted only in the elevating direction. The upper wall portion 83 of the tilt base portion 81 is formed on an inclined surface having a high front side FS and a low back side RS. A pair of guide rails 84 are formed on the left and right sides of the inclined upper wall portion 83 along the inclined direction. The inclined base portion 81 is formed in a lattice structure in which ribs 81a and 81b are formed at predetermined intervals in the front-rear direction and the left-right direction.

The upper end of the slide cylinder portion 82 is closed by the ceiling portion 85, and the lower end is open. The slide cylinder portion 82 is arranged at a substantially central position in the left-right direction of the tilt base portion 81, and is consumed upward from the upper wall portion 83 of the inclined surface.

The slide cylinder portion 82 is attached to the spring guide cylinder 30 in a state of being lowered to the lower end position in the elevating direction. The upper end of the first spring 35 and the upper end of the second spring 36 are in contact with each other inside the slide cylinder portion 82, and the spring forces F1 and F2 directed upward in the elevating direction act on the third slider 80.

4A and 4B show a second slider 60, where FIG. 4A is an external perspective view seen from the rear side, FIG. 4B is a top view of FIG. 4A, and FIG. 4C is an arrow view of arrow B of FIG. , (D) are the C arrow view (right side view) of (a).

The second slider 60, which is a moving member, has a second main body portion 61 whose upper surface is formed in a substantially rectangular shape. The second main body 61 is formed in a length that is accommodated in the inner 53 of the first main body 41 of the first slider 40 without play in the left-right direction, and has a clearance that can be moved in the front-rear direction. It is formed to the length of. The length of the second main body 61 in the front-rear direction is shorter than the length of the tilting base 81 of the third slider 80 in the front-rear direction.

The second main body portion 61 includes a flat upper end upper wall portion 62, a back wall portion 63 of the back side RS, left and right side wall portions 64 and 65, a front wall portion 66 of the front side FS, and a bottom of an inclined surface. It has a wall portion 67.

The upper wall portion 62 is formed with a U-shaped notch portion 68 that opens the front side FS. The notch portion 68 has an arc portion 69 having a radius R and an opening 70 having a width of 2R in the left-right direction. The outer diameter of the slide cylinder portion 82 of the third slider 80 is formed to be equal to the opening width 2R of the opening 70 of the notch portion 68. The notch portion 68 of the second slider 60 is slidably fitted to the slide cylinder portion 82 of the third slider 80 along the front-rear direction.

The upper wall portion 62 is formed with guide grooves 71 and 72 extending in the front-rear direction on both the left and right sides of the notch portion 68. The guide grooves 71 and 72 are fitted into the pair of guide rails 52 shown in FIG. 4B while being arranged in the first slider 40 to ensure smooth movement of the second slider 60 in the front-rear direction. ..

A trapezoidal engaging convex portion 73 projects rearward in the front-rear direction from the back wall portion 63. The engaging convex portion 73 is formed in a tapered shape in which the facing widths of the two opposing side surfaces on the upper and lower sides and the facing widths of the two facing side surfaces on the left and right sides become narrower toward the rear in the front-rear direction. It is desirable that the width of the engaging convex portion 73 in the left-right direction is long, and the width is set so as to slidably enter the opening window 51 of the first slider 40. The engaging convex portion 73 is replaceably attached to the back wall portion 63.

Further, as shown in FIG. 5 (c), the second main body 61 of the second slider 60 has the first slider so that the protruding length of the engaging convex portion 73 of the second slider 60 projects rearward in the front-rear direction. In a state of being in contact with the back wall portion 44 of 40 (a state in which the second slider 60 is most moved rearward in the front-rear direction), it penetrates the opening window 51 formed in the back wall portion 44, and further, a support of the base member 10. The length is set to reach the bottom surface of the first lock recess 19 (second lock recess 20) formed in the back wall 13 of the twelve.

Further, as for the length of the second main body 61 in the front-rear direction, as shown in FIG. 5 (d), the tip surface 73a of the engaging convex portion 73 is shown in FIG. 5 (c) inside the first slider 40. It suffices if the length can be set so as to be able to retract at least forward in the front-rear direction from the position shown in In the present embodiment, in order to allow the second slider 60 to be mounted inside the inner 53 of the first slider 40, the length of the inner 53 in the front-rear direction including the length of the second main body 61 and the engaging convex portion 73 is included. It is set slightly shorter than the slider.

A plurality of recesses (recesses) 76 are partially formed on the tip surface 73a of the engaging protrusions 73 of the second main body 61. As shown in FIG. 5D, in a state where the engaging convex portion 73 is in pressure contact with the back wall 13 of the support column 12 by the component force of the spring force (F1, F2), the tip is in the presence of the recessed portion 76. The contact area where the surface 73a contacts the back wall 13 decreases, but on the contrary, the pressing force concentrates on the contacted portion and the frictional force increases. Therefore, when the lifting body 2 attached to the mounting bracket 100 is stopped by a frictional force at an arbitrary position between the first lock recess 19 and the second lock recess 20, it can be stopped and held by a strong frictional force. it can. The tip surface 73a of the engaging convex portion 73 may be provided with a convex portion instead of a concave portion.

A plurality of recesses 76 are also formed in the back wall portion 63 of the second main body portion 61 and the left and right side wall portions 64 and 65, respectively. This is because the back wall portion 63 and the left and right side wall portions 64, 65 are brought into pressure contact with the inner peripheral wall surface of the first main body 41 of the first slider 40 with a high frictional force. As a result, the relative rattling of the first slider 40 and the second slider 60 in the front-rear direction and the elevating direction is prevented. The recessed portions 76 formed in the left and right side wall portions 64 and 65 reach at least the guide grooves 71 and 72 along the left and right directions.

The bottom wall portion 67 is formed on an inclined surface that is inclined upward toward the front in the front-rear direction. That is, the lower end of the back wall portion 63 is located below the lower end of the front wall portion 61 in the ascending / descending direction, and the bottom wall portion 67 is on an inclined surface inclined from the lower end of the back wall portion 63 toward the lower end of the front wall portion 61. Is formed. The inclined surface of the bottom wall portion 67 is formed parallel to the inclined surface of the inclined base portion 81 of the third slider 80.

Guide grooves 74 and 75 are formed in the bottom wall portion 67 along the front-rear direction on both the left and right sides of the notch portion 68. The guide grooves 74 and 75 fit into the guide rail 84 formed on the upper wall portion 83 when the bottom wall portion 67 of the second slider 60 is brought into contact with the upper wall portion 83 of the third slider 80. As a result, the second slider 60 and the third slider 80 are guaranteed to move smoothly in the front-rear direction.

In the present embodiment, the support is covered by the support column 12, the first spring 35 (spring force F1), the second spring 36 (spring force F2), the first slider 40, the second slider 60, and the third slider 80. A friction mechanism is configured to stop and hold the elevating body 2 at an arbitrary position in the elevating direction by using frictional force.

Further, the support is raised and lowered by the first lock recess 19, the second lock recess 20, the first spring 35, the second spring 36, the first slider 40, the second slider 60, and the third slider 80. A lock mechanism for fixing the body 2 to the first lock recess 19 or the second lock recess 20 is configured.

That is, in the present embodiment, the friction mechanism and the lock mechanism are used in combination, and when the engaging protrusion 73 of the second slider 60 engages with the first lock recess 19 or the second lock recess 20, it acts as a lock mechanism. However, when it comes into pressure contact with the back wall 13 of the support column 12, it acts as a friction mechanism.

FIG. 5C shows a case where it acts as a locking mechanism, and FIG. 5D shows a case where it acts as a friction mechanism.

In the locked state shown in FIG. 5 (c), the spring force F1 of the first spring 35 and the spring force F2 of the second spring 36 are applied to the third slider 80 in the ascending / descending direction. Due to the contact between the inclined surfaces, a component force (hereinafter, referred to as a rear component force FR) directed to the rear in the front-rear direction acts on the second slider 60.

The second slider 60 on which the rear component force FR acts is directed backward in the front-rear direction to the first slide position where the back wall portion 63 of the second main body portion 61 abuts on the inner surface of the back wall portion 44 of the first slider 40. Slide to move. At the first slide position, the engaging convex portion 73 of the second slider 60 penetrates the opening window 51 of the first slider 40 and is inserted into, for example, the first lock recess 19 of the support column 12 to engage. In order to release the engaged state at the locked position, for example, a pushing force F0 is applied downward in the ascending / descending direction to the first slider 40. The pushing force F0 acts on the second slider 60 and is transmitted to the engaging convex portion 73. A component force toward the front in the front-rear direction (hereinafter, referred to as a front component force FF) acts on the engaging convex portion 73 by pressure contact between the inclined surfaces with the first lock recess 19.

When the front component force FF is larger than the rear component force FR (FF> FR), the first slider 40 moves downward in the ascending / descending direction, and the second slider 60 moves forward in the front-rear direction. , The engaging convex portion 73 moves to the second slide position where the engaging convex portion 73 disengages from the engagement with the first lock concave portion 19. Then, the front component force FF becomes zero, and the engaging convex portion 73 comes into pressure contact with the inner wall surface of the support column wall portion of the back wall surface 13 of the support column 12 by the rear component force FR.

The lifting body 2 is held in a stationary state at a position where the pushing force F0 is released by the frictional force F3 generated by the contact between the engaging convex portion 73 and the inner wall surface of the back wall surface 13 due to the rear component force FR.

On the other hand, when the pushing force F4 is applied to the first slider 40 in the ascending / descending direction from the stationary holding state of the elevating body 2 shown in FIG. 5D, the first slider 40 moves upward in the ascending / descending direction. Then, when the engaging convex portion 73 reaches the first lock recess 19 which is the click fitting portion, the engaging convex portion 73 is fitted into the first lock recess 19 with a click feeling due to the rear component force FR.

The operation of the elevating device according to the above-described embodiment will be described with reference to FIGS. 6 to 8. 6 to 8 show a cross-sectional view taken along the line EE of the elevating device 1 shown in FIG. 1, and the first slider 40 shows a cross-sectional view taken along the line EE shown in FIG. 3A. The slider 60 shows the cross section taken along the line EE of FIG. 4 (b), and the third slider 80 shows the cross section taken along the line EE of FIG. 5 (a).

FIG. 6 is a vertical cross-sectional view of the lifting device 1, showing a state in which the mounting bracket 100 is locked at the upper limit lock position, FIG. 7 shows a state in which the mounting bracket 100 is locked at the lower limit lock position, and FIG. Indicates a state in which the mounting bracket 100 is frictionally held between the upper limit lock position and the lower limit lock position.

As shown in FIG. 6, in the lifting device 1, the second slider 60 is moved to the first slide position by the rear component force FR by the operation of the click fitting type lock mechanism, and is engaged with the first lock recess 19. The portion 73 engages. The first spring 35 and the second spring 36 are in a long stretched state. The spring force in this state is the smallest within the elevating range. However, the spring forces of the first spring 35 and the second spring 36 are set so that the front component force FF generated by the load W of the lifting body 2 exceeds the rear component force FR and the lock is not released.

When the mounting bracket 100 is locked at the lower limit position in the elevating direction shown in FIG. 6, the first spring 35 and the second spring 36 are in the most contracted state within the elevating range. In this state, the rear component force FR is prevented from being unlocked by the spring force F1 of the first spring 35 and the spring force F2 of the second spring 36 with respect to the mounting bracket 100 to which the lifting body 2 having the load W is attached. And the forward component force FF is set.

When stopping the mounting bracket 100 from the upper limit position in the elevating direction to an arbitrary position below the elevating direction, or when stopping the mounting bracket 100 from the lower limit position in the elevating direction to an arbitrary position above the elevating direction, the operator attaches the mounting bracket. The operating force F0 or F4 is applied downward or upward in the elevating direction by putting a hand on the elevating body 2 attached to the 100.

When the operating force F0 or F4 acts in the locked state, the forward component force FF acting forward in the front-rear direction increases with respect to the second slider 60. As the front component force FF increases, the engaging convex portion 73 is disengaged from the first lock recess 19 or the second lock recess 20 and unlocked. Further, when the operating force F0 or F4 is continuously applied, the rear component FR is maintained on the second slider 60, and the first slider 40, the second slider 60, and the third slider 80 are attached to the mounting bracket 100. It moves upward or downward in the elevating direction together with the elevating body 2 via the above.

The engaging convex portion 73 of the second slider 60 is in pressure contact with the inner wall surface of the back wall 13 of the support column 12 by the rear component force FR, and a frictional force F3 is generated in the elevating direction. When the total load applied to the first slider 40 in the ascending / descending direction becomes equal to the frictional force F3 due to the action of the operating force F0 or F4, the elevating body 2 moves upward or in the elevating direction with respect to the support column 12. Move to.

When the operating force of the operating force F0 or F4 is released between the upper limit lock position positioned in the first lock recess 19 and the lower limit lock position positioned in the second lock recess 20, the frictional force F3 acts. , The second slider 60 is held at that position. As a result, the lifting body 2 attached to the mounting bracket 100 can be stopped and held at that position.

In the present embodiment, the number of parts can be significantly reduced by using both the friction mechanism and the lock mechanism. Therefore, the assembly man-hours and costs can be reduced.

Further, the inner wall surface of the back wall 13 of the support column 12 generates a frictional force F3 when it comes into contact with the tip surface 73a of the engaging convex portion 73 of the second slider 60, so that the surface can be surface-processed to an appropriate surface roughness. It is good to apply or attach a friction member.

Further, the spring portion 4 can save space by arranging the two springs of the first spring 35 and the second spring 36 coaxially, and can concentrate the spring forces of the plurality of springs. Can be given to a place. Further, by using two springs having different spring forces, the total spring force can be finely set.

The wedge effect of the second slider 60 and the third slider 80 generates a rear component FR, which is a force for locking the engaging convex portion 73 and a force for holding friction at an arbitrary position. However, the present invention is not limited to this. In short, any spring force acting upward in the elevating direction may generate a rear component force FR in the engaging convex portion 73. For example, a link mechanism having a panda graph structure can be exemplified.

Second Embodiment FIG. 9 shows a vertical cross-sectional view showing a second embodiment of the friction mechanism / locking mechanism.

In FIG. 9, in the first slider 400 slidably arranged in the support column 12 along the elevating direction, the inside 402 of the first main body portion 401 is formed in an empty space, the lower surface is opened, and the top surface is the top wall. It is closed by a portion 403, and four side surfaces are surrounded by a wall portion. An opening window 405 is formed in the back wall portion 404 of the first main body portion 401. The internal 402 of the first main body 401 constitutes a link mechanism 414 in which four link members 406 to 409 composed of plate members extending in the left-right direction are connected by the first to fourth connecting members 410 to 413. .. An engaging convex portion 73 of the second slider 60 shown in FIG. 3 is attached to the fourth connecting member 413, which is a moving member located on the rear end side in the front-rear direction. The engaging protrusion 73 is capable of penetrating the opening window 405.

A plate-shaped spring receiving seat 415 is movably arranged in the first main body 401 in the elevating direction in the bottom opening of the first main body 401. The third connecting member 412 comes into contact with the upper surface of the spring receiving seat 415. A first spring having a spring force F1 (not shown) and a second spring having a spring force F2 (not shown) are arranged on the lower surface of the spring receiving seat 415.

In the link mechanism 414, the first connecting member 410 abuts on the lower surface of the top wall portion 403, and the second connecting member 411 abuts on the inner surface of the front wall portion 416. The spring force (F1 + F2) acting upward in the elevating direction with respect to the spring receiving seat 415 is transmitted to the link mechanism 414 via the third connecting member 412.

By transmitting the spring force (F1 + F2), the engaging convex portion 73 attached to the fourth connecting member 413 is inserted into and engaged with the first lock recess 19 or the second lock recess 20, or the back wall 13 of the support column 12 It abuts on the inner wall surface of. In this case, a reaction force (-FR) directed forward in the front-rear direction acts on the front wall portion 416 that abuts on the second connecting member 411, and the fourth connecting member 413 is rearward toward the rear in the front-rear direction. Component FR is generated. As a result, the engaging convex portion 73 is inserted into the first lock recess 19 or the second lock recess 20 to engage, or frictionally contacts the inner wall surface of the back wall 13 of the support column 12 to generate a frictional force F4. Let me.

Further, when the pushing down force F0 acts on the mounting bracket 100 via the lifting body (not shown) in the locked state, the slope of the engaging convex portion 73 and the first locking concave portion are as described in the first embodiment. The front component force FF is generated by the wedge effect generated by the contact with the slope of the hole portion of 19 (second lock recess 20), and the lock is released.

In the link mechanism, since the second connecting member 411 is restricted from moving backward in the front-rear direction due to contact with the front wall portion 416, the first connecting member 411 can tolerate deformation of the link mechanism. And the third connecting member 412 have a roller structure, for example, so as to be movable along the front-rear direction. Further, the second connecting member 411 has a roller structure, for example, so as to be movable in the elevating direction.

According to this embodiment, the holding mechanism and the locking mechanism can be configured with a simple configuration.

In each of the above-described embodiments, the engaging convex portion 73 performs each lock and stop operation by moving toward the rear in the front-rear direction, but is limited to the rearward movement in the front-rear direction. It's not something. For example, the moving direction of the engaging convex portion 73 may be forward in the front-rear direction, left or right in the left-right direction, and the first and second lock recesses 19, 20 and the wall portion of the support column 12 may be provided.

Since the present invention is configured as described above, it is possible to provide an elevating device for a display device such as a liquid crystal monitor which has a simple structure and can be provided at low cost, and a display device using the elevating device.

1 Lifting device 2 Lifting body 3 Stop / lock component force generating part 4 Spring part 12 Support 13 Back wall (support wall part)
19 1st lock recess (click fitting part)
20 Second lock recess (click fitting part)
35 1st spring (spring force F1)
36 Second spring (spring force F2)
40 1st slider 54 Engagement recess 60 2nd slider (moving member)
73 Engagement convex part 80 Third slider 100 Mounting bracket (mounting member for lifting body)
400 1st slider 406-409 Link member 414 Link mechanism

Claims (4)

An elevating device that can stop and hold the elevating body at any position in the elevating direction.
A strut extending in the elevating direction and having a plurality of click fitting portions formed at one or a plurality of click fitting portions separated vertically in the elevating direction on the strut wall portion along the elevating direction.
Stop / lock that is arranged so as to be able to move up and down with respect to the support column, moves the moving member in a direction orthogonal to the elevating direction by a spring force upward in the elevating direction, and generates an outward component force from the inside to the outside of the support column. With the component force generator
The outward component force is provided at the tip of the moving member, and the click fitting portion is click-fitted at the position of the click fitting portion by the outward component force, and the outward component force is click-fitted at an arbitrary position within the elevating range. With the engaging convex portion that comes into pressure contact with the inner wall surface of the support column wall portion,
An elevating body mounting member provided in the stop / lock component force generating portion and attaching the elevating body,
Have a, a spring portion that applies the spring force to lift upward with respect to the stop-lock component force generating unit,
The stop / lock component force generating portion can move up and down in the support column along the elevating direction, and has a first slider to which the elevating body mounting member is fixed and a moving member arranged in the first slider. It has a second slider to be formed and a third slider that abuts on the lower surface of the second slider and applies the spring force of the spring portion, and the contact surfaces of the second slider and the third slider are inclined parallel to each other. An elevating device characterized by being formed on a surface . In the elevating device according to claim 1,
The stop / lock component force generating portion can move up and down in the support column along the elevating direction, and is arranged in the first slider to which the elevating body mounting member is fixed and in the first slider in the elevating direction. An elevating device having a link mechanism in which link members are connected along the link member, and the spring force of the spring portion is applied to the link member below in the elevating direction. In the elevating device according to any one of claims 1 and 2 .
The spring portion is an elevating device characterized in that a plurality of springs having different spring forces are arranged with their axes along the elevating direction as the same axis. In the lifting device according to any one of claims 1 to 3 ,
An elevating device characterized in that the tip surface of the engaging convex portion is partially formed with a concave portion or a convex portion.

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