CN217486528U - Foldable scanning support - Google Patents

Abstract

The utility model relates to a scanning field discloses a folding scanning support. Comprises a flat plate, and four separated petals are arranged on one side of the flat plate. The flat plates positioned outside the two first X-direction crease lines at the outermost ends of the flat plates are laminated to be connected into a closed shape in an end-to-end connection, when the flat plates positioned at the two sides of each first X-direction crease line are respectively folded to be vertical, the flat plates surround a three-dimensional square frame with a rectangular cross section, a light transmission part is arranged on one side surface of the three-dimensional square frame, and when the end surface formed by laminating the flaps is rectangular, the end surface is completely blocked in the port of the three-dimensional square frame to support the three-dimensional square frame; when each flap is positioned outside the port of the three-dimensional frame, the cross section of the three-dimensional frame is deformed into a parallelogram from a moment until the cross section is flattened to a flat shape that two layers of flat plates connected end to end are attached to each other. The application is convenient, and accomodate the convenience, and a thing is multi-purpose.

Description

Foldable scanning support

Technical Field

The utility model relates to a scanning field discloses a folding scanning support.

Background

At present, when written documents such as books, A4 paper documents and the like are scanned, the written documents are generally shot by a scanner or a mobile phone. If a scanner is used for scanning, scanning equipment is needed and the operation is complicated and inconvenient; if a mobile phone is used for shooting, the artificial influence of hand shake, deviation and the like exists.

Disclosure of Invention

An object of the embodiment of the utility model is to provide a folding scanning support, it is convenient to use, and accomodate the convenience.

An object of the embodiment of the utility model is to provide a folding scanning support, it is convenient to use, and accomodate the convenience.

The embodiment of the utility model provides a foldable scanning bracket, which comprises a flat plate, one side of the flat plate is provided with at least four mutually separated petals,

a continuous linear Y-direction crease line is arranged on the flat plate along the Y direction, the Y-direction crease line is a connecting line of each flap and the flat plate,

the distance between each two adjacent flaps on the side close to the Y-direction crease line is smaller than the distance between each two adjacent flaps on the distal end side of each flap,

at least four first X-direction crease lines extending in the X direction are arranged on the flat plate, one end of each first X-direction crease line is arranged between every two adjacent flaps, the other end of each first X-direction crease line is arranged on the other side edge of the flat plate opposite to each flap,

the flat plates positioned outside the two outermost X-direction crease lines are connected in a stacked mode, the flat plates form a closed shape in an end-to-end connection mode, when the flat plates positioned on the two sides of each first X-direction crease line are perpendicular to each other respectively, the flat plates form a three-dimensional square frame with a rectangular cross section, a light transmission part is arranged on one side face of the three-dimensional square frame, one end part of the square frame is a port communicated with the outside, the other end part of the square frame is each flap,

when the flaps are folded into the port along the Y-direction crease line respectively and the end surface formed by stacking the flaps is perpendicular to the side surface of the three-dimensional square frame, the end surface formed by stacking the flaps is rectangular, is completely blocked in the port of the three-dimensional square frame and supports the three-dimensional square frame;

when each flap is positioned outside the port of the three-dimensional square frame, two first X-direction crease lines at the opposite corners of the three-dimensional square frame are relatively far away, the other two first X-direction crease lines are relatively close to each other, the cross section of the three-dimensional square frame is deformed into a parallelogram from a moment until the two layers of flat plates connected end to end are flattened to be flat, the two first X-direction crease lines far away are positioned at the outermost end of the flat plate, and the two first X-direction crease lines close to each other are respectively positioned at the upper layer and the lower layer of the flat plate.

Optionally, when the stereoscopic square frame is flattened to a flat state that two layers of the flat plates connected end to end are attached to each other, two second X-direction crease lines extending along the X direction are arranged at the positions of the flat plates which are positioned on the upper layer and the lower layer of the flat plates and are opposite to one of the two first X-direction crease lines,

the central line between the two second X-direction crease lines is opposite to the first X-direction crease line on the flat plate opposite to the second X-direction crease line,

the distance between the two second X-direction crease lines is equal to or more than twice of the thickness of the flat plate, the two second X-direction crease lines extend to the tail ends of the flaps,

folding the flat stacked plates along the two second X-direction crease lines and the first X-direction crease line opposite thereto so that the four layers are attached to each other, wherein at the folded position, the two second X-direction crease lines are located on the outer side and the first X-direction crease line is located on the inner side.

Alternatively, two second X-direction crease lines extending in the X direction may be provided on the flat plates located on the upper and lower layers of the flat stacked flat plates, respectively.

Optionally, the end of the first flap of one of the two opposite flaps is concave, the end of the second flap of the other one is convex, the width of the convex part is smaller than that of the concave part,

the other two opposite flaps are a third flap and a fourth flap which are opposite and opposite in shape,

when the end face formed by the four valve flaps is completely blocked in the end port of the three-dimensional square frame, the first valve flap is positioned at the innermost layer, the third valve flap and the fourth valve flap are attached outside the first valve flap, gaps are formed between the third valve flap and the fourth valve flap and the bottom edge of the concave position of the first valve flap,

the second petal is tightly attached to the outside of the third petal and the fourth petal, and the convex part at the tail end is inserted from the gap and tightly attached to the inner side of the first petal.

Optionally, the width of the first flap is the same as the width of the side face connected with the first flap and used as the stereoscopic box,

when the flat plate is encircled into the square frame and the first flap is folded at the port of the square frame, two opposite outer edges of the first flap abut against the inner wall of the square frame.

Optionally, the ends of the third flap and the fourth flap are respectively rectangular, and the widths of the end portions of the third flap and the fourth flap are narrower than the widths of the end portions of the third flap and the fourth flap connected to the Y-direction crease line end.

Optionally, the parts of the third flap and the fourth flap connected to the side of the Y-direction crease line are in a right trapezoid shape,

the right-angle sides of the right-angle trapezoids are positioned at the outer sides of the third and fourth petals, and the bevel sides are positioned at the inner sides of the third and fourth petals.

Optionally, two positioning blocks are further disposed on the outer surface of the side where the light-transmitting portion is located, one of the two positioning blocks is located on the top side of the light-transmitting portion, and the other positioning block is located outside the left side or the right side of the light-transmitting portion.

Optionally, the plates are laminated together end to end, adhesively bonded, or stapled.

Optionally, the contour line of the port side of the opening of the stereoscopic box is a curve

Therefore, by adopting the technical scheme of the embodiment, scanning of the intelligent terminal 6 is placed on the scanning support of the embodiment, so that the manual influences of hand trembling, deflection and the like can be avoided, and flexible scanning is facilitated. When the scanning is not needed, the end face formed by the flaps 3 of the three-dimensional frame faces downwards to be used as the bottom face of the three-dimensional frame, and the scanning support can be used as a storage box for storage, so that the multifunctional scanning rack is multipurpose.

When the folding type three-dimensional square frame is not needed to be used, the angle between the end face formed by the flap 3 and the side face of the square frame is adjusted to be in a non-vertical shape, the flap 3 does not support the positioning of the three-dimensional square frame, the three-dimensional square frame is further flattened, two first X-direction crease lines 2 opposite to the opposite corners of the three-dimensional square frame are far away from each other, the other two first X-direction crease lines 2 opposite to the opposite corners of the three-dimensional square frame are close to each other, the cross section of the three-dimensional square frame is changed from a rectangle to a parallelogram until two opposite sides of the parallelogram are tightly attached, the three-dimensional square frame is flattened into a flat shape with two layers of flat plates which are tightly attached up and down, the two first X-direction crease lines 2 opposite to the opposite corners of the three-dimensional square frame are positioned on two sides of the flat plate, the other two first X-direction crease lines 2 are respectively positioned on the upper layer of flat plate and the lower layer of flat plate, and the flat plates positioned on two sides of the two first X-direction crease lines 2 are in a plane shape. It is thus clear that the scanning support of this embodiment can flatten to the platykurtic and conveniently accomodate, also convenient transportation when not using, avoids occupation space.

Drawings

Fig. 1 is a schematic perspective view of a foldable scanning support according to an embodiment of the present invention;

fig. 2 is a schematic view of an expanded structure of a foldable scanning support according to an embodiment of the present invention;

fig. 3-7 are schematic views of a flap folding structure of a foldable scanning support according to an embodiment of the present invention;

fig. 8 is a schematic view of an application structure of a foldable scanning bracket according to an embodiment of the present invention.

Fig. 9 is a schematic view of another application structure of a foldable scanning stand according to an embodiment of the present invention.

Reference numerals:

1: a Y-direction crease line; 2: a first X-direction crease line; 3: a flap;

31: a first flap; 32: a second flap; 33: a third flap; 34: a fourth lobe;

4: a light-transmitting portion; 5: a second X-direction crease line; 6: an intelligent terminal;

7: a gap; 8: and (5) positioning the blocks.

Detailed Description

The invention will be described in detail with reference to the specific drawings and examples, which are illustrative of the invention and are not intended to limit the invention.

See fig. 1-9.

The embodiment provides a foldable scanning support, which mainly includes a flat plate (as shown in fig. 2) with a certain rigidity, a Y-direction crease line 1 is arranged on one side edge of the flat plate, the extending direction of the Y-direction crease line 1 is the Y direction, four mutually separated flaps 3 extend outside the Y-direction crease line 1 along the X direction perpendicular to the Y direction, and the flaps 3 are located on the same side of the flat plate. The thickness of the Y-direction folding line 1 may be designed to be thinner than that of a flat plate, but not limited thereto, so that each flap 3 can be folded along the Y-direction folding line 1.

The distance between any two adjacent flaps 3 on the side close to the Y-direction folding line 1 is narrower than the distance between the two flaps 3 on the distal ends of the two flaps 3, and the two adjacent flaps 3 intersect each other on the Y-direction folding line 1, are gradually separated in the distal direction of the flaps 3, and have a gap 7.

Four X-direction crease lines (referred to as first X-direction crease lines 2) parallel to each other are provided in the flat plate laid flat along the X direction, one end point of each first X-direction crease line 2 is located between each two adjacent flaps 3, the other end point is located on the other side edge opposite to the side where the flap 3 is located, each first X-direction crease line 2 divides the flat plate (not including the flap 3) into a plurality of portions, but not limited to, the thickness of each first X-direction crease line 2 is designed to be thinner than the thickness of the film, so that each portion of the flat plate divided by each first X-direction crease line 2 can be folded along each first X-direction crease line 2.

The flat plates outside the first X-direction crease lines 2 at the two ends of the flat plates are stacked and connected together into a closed shape, such as but not limited to an adhesive fixed connection, and a binding fixed connection. When the folding type folding device is applied, the flat plates of the closed flat plates connected end to end and respectively spaced at two sides of each first X-direction crease line 2 are respectively folded along each first X-direction crease line 2, so that the flat plates spaced at two sides of each first X-direction crease line 2 are perpendicular to each other, the flat plates connected end to end enclose a three-dimensional frame, the cross section of the three-dimensional frame is rectangular, and the flat plates spaced at two sides of each first X-direction crease line 2 form four side faces of the three-dimensional frame. Each flap 3 is located outside one port of the three-dimensional frame, at the end part, each flap 3 is respectively folded towards one port of the three-dimensional frame along the Y-direction crease line 1, so that each flap 3 forms an integral end surface, when the end surface formed by the flaps 3 is perpendicular to the side surface of the three-dimensional frame, the end surface is matched with the rectangle of the port of the three-dimensional frame, the end surface is blocked on the port, and the three-dimensional frame is kept to keep the rectangle (shown in figure 1). The other end of the three-dimensional frame is an open port communicated with the outside.

The flat plate of this embodiment is further provided with a light-transmitting portion 4, and the light-transmitting portion 4 may be a through hole or may be formed by adding a light-transmitting sheet into the through hole.

During scanning, the side face, provided with the light transmission portion 4, of the three-dimensional frame faces upwards, a scanned object (such as a photo, a flat plate or a book and the like) to be scanned is placed into the end portion of the opening of the self-standing frame, the intelligent terminal 6 (such as a mobile phone or a flat plate) is placed on the top face of the three-dimensional frame, a camera of the intelligent terminal 6 is located in the light transmission portion 4, shooting images on the intelligent terminal 6 are observed, the position of the scanned object in the three-dimensional frame is adjusted, appropriate images are obtained, and the scanned object is scanned by the intelligent terminal 6.

By applying the technical scheme of the embodiment, the intelligent terminal 6 is arranged on the scanning support of the embodiment in a scanning mode, so that the manual influences of hand trembling, deflection and the like can be avoided, and the scanning is convenient and flexible. When the scanning is not needed, the end face formed by the flaps 3 of the three-dimensional frame faces downwards to be used as the bottom face of the three-dimensional frame, and the scanning support can be used as a storage box for storage, so that the multifunctional scanning rack is multipurpose.

When the three-dimensional square frame is not needed to be used, the angle between the end face formed by the flap 3 and the side face of the square frame is adjusted to be in a non-vertical shape, so that the flap 3 does not play a role in supporting the positioning of the three-dimensional square frame, the three-dimensional square frame is further flattened, two first X-direction crease lines 2 opposite to the opposite corners of the three-dimensional square frame are far away from each other, the other two first X-direction crease lines 2 opposite to the opposite corners of the three-dimensional square frame are close to each other, the cross section of the three-dimensional square frame is changed from a rectangle to a parallelogram until the two opposite sides of the parallelogram are tightly attached, the three-dimensional square frame is flattened into a flat shape that two layers of flat plates are tightly attached together up and down, the two first X-direction crease lines 2 opposite to the opposite corners of the three-dimensional square frame are positioned on the two sides of the flat plate, the other two first X-direction crease lines 2 are respectively positioned on the upper layer of the flat plate and the lower layer of the flat plate, and the flat plates positioned on the two sides of the two first X-direction crease lines 2 are in a plane shape. It is thus clear that the scanning support of this embodiment can flatten to the platykurtic and conveniently accomodate when not, and occupation space is avoided in also convenient transportation.

As an illustration of the present embodiment, two second X-direction crease lines 5 extending in the X direction are further provided on one side surface of the three-dimensional frame having a large area. One end of the two second X-direction crease lines 5 extends to the end of the flap 3, and the other end extends to the edge of the side opposite to the flap 3. The distance between the two second X-direction crease lines 5 is greater than or equal to twice the thickness of the flat plate. Thus, when the three-dimensional frame is flattened into a flat shape with two flat plates attached to each other, the center lines (non-solid lines) of the two second X-direction crease lines 5 on the flat plate of the upper layer or the lower layer are opposite to the first X-direction crease line 2 in the flat plate. The two layers of flat plates outside the two second X crease lines can be further folded along the two second X crease lines 5 and the first X crease line 2 opposite to the two second X crease lines, so that the folded two layers of flat plates are further turned to form a flat shape with four layers of flat plates attached. At this turning position, the two second X-direction folding lines 5 are located on the outer side, and the first X-direction folding line 2 opposite to the two second X-direction folding lines 5 is located on the inner side. This may further reduce the size of the collapsed scanning support, further facilitating storage or carrying or transport by the user.

As an illustration of the embodiment, but not limited to, two second X-direction crease lines 5 may be respectively disposed on two opposite side surfaces of the three-dimensional frame with a larger area, so that the two opposite side surfaces can be respectively folded from two sides of the flat plate that has been flattened into two layers of flat plates, so that two sides of the flat plate respectively form a structure that four layers of flat plates are adhered to each other, thereby further reducing the size of the flattened bracket, and further facilitating the storage or carrying by a user.

As an illustration of the present embodiment, the present embodiment further provides a structural illustration of the flap 3:

one of the two flaps 3 connected to the two opposite side surfaces of the three-dimensional frame is a first flap 31, the end of the first flap 31 is concave, the other is a second flap 32, the end of the second flap 32 is convex, and the width of the convex part is smaller than that of the concave part.

The third and fourth flaps 33, 34 are provided on the other opposite side surfaces connected to the solid frame, and when the stand is opened in the solid frame shape, the third and fourth flaps 33, 34 are opposed to each other in shape and position.

When the stent is opened into a solid square frame shape, the first flap 31 is folded with the innermost layer of the end face, the third flap 33, the fourth flap 33, 343 and 34 are respectively folded outside the first flap 31, a gap 7 is formed between the concave bottom edges of the third flap 33, the fourth flap 34 and the first flap 31, the second flap 32 is folded outside the third flap 33 and the fourth flap 34, and the convex part at the tail end of the second flap 32 is inserted into the gap 7 between the third flap 33, the fourth flap 3 and the first flap 31 to be tightly attached to the inner side of the first flap 31, so that an end face structure which is nested and not easy to release is formed. When the end face is perpendicular to the side face of the three-dimensional frame, the end face is rectangular, and the end face maintains the three-dimensional frame in a structure with a rectangular cross section so as to avoid deformation.

As an illustration of the present embodiment, but not limited to, the width of the first flap 31 may be designed to be the same as the width of the side surface to which the first flap 31 is connected. When the end face is perpendicular to the side face, the two opposite edges of the first flap 31 abut against the inner wall of the side face of the three-dimensional frame, so that the three-dimensional frame is supported and positioned.

In addition, as a schematic illustration of the present embodiment, the ends of the third flap 33 and the fourth flap 34 are rectangular, and the widths of the ends of the third flap 33 and the fourth flap 34 are narrower than the width connected to the end of the Y-direction crease line 1. For example, but not limited to, the shapes of the third and fourth flaps 33, 34 connected to the side of the Y-direction crease line 1 may be designed to be right trapezoids, the right-angle side of each right trapezium is located on the outer side of the third and fourth flaps 33, 34, and the oblique side of each right trapezium is located on the inner side of the two third and fourth flaps 33, 34.

As an indication of this embodiment, two positioning blocks 8 may be further disposed on the outer surface of the side where the light-transmitting portion 7 is located, one of the two positioning blocks 8 is located on the top side of the light-transmitting portion 7, and the other is located outside the left side or the right side of the light-transmitting portion 7, when the intelligent terminal 66 is placed on the side, the edge of the intelligent terminal 66 may be positioned through the two positioning blocks 8, so that the camera can conveniently shoot right, and right scanning is achieved.

As an illustration of the present embodiment, but not limited to, the contour line of the flat plate on the other side of the flat plate opposite to the flap 3 is a curve, so that when the scanning support is opened into a solid block, the contour line of the port of the solid block is a three-dimensional contour line which is not in the same plane. When the support is used as a file storage box, a user can conveniently take and place files. The convenience of use is improved.

As an illustration of the present embodiment, the foldable scanning support of the present embodiment can be supported by but not limited to reinforced cardboard.

The above-described embodiments do not limit the scope of the present invention. Any modification, equivalent replacement, and improvement made within the spirit and principle of the above-described embodiments should be included in the protection scope of the technical solution.

Claims (10)

1. A foldable scanning bracket is characterized by comprising a flat plate, wherein one side of the flat plate is provided with at least four mutually separated petals,

a continuous linear Y-direction crease line is arranged on the flat plate along the Y direction, the Y-direction crease line is a connecting line of each flap and the flat plate,

the distance between each two adjacent flaps on the side close to the Y-direction crease line is smaller than the distance between each two adjacent flaps on the distal end side of each flap,

at least four first X-direction crease lines extending in the X direction are arranged on the flat plate, one end of each first X-direction crease line is arranged between every two adjacent flaps, the other end of each first X-direction crease line is respectively arranged on the other side edge of the flat plate opposite to each flap,

the flat plates positioned outside the two first X-direction crease lines at the outermost ends are connected in a stacking way, the flat plates form a closed shape in an end-to-end connection, when the flat plates positioned at the two sides of each first X-direction crease line are respectively vertical, the flat plates surround a three-dimensional frame with a rectangular cross section, a light transmission part is arranged on one side surface of the three-dimensional frame, one end part of the frame is a port communicated with the outside, and the other end part of the frame is each flap,

when the flaps are respectively folded towards the inside of the port along the Y-direction crease line and the end surface formed by stacking the flaps is perpendicular to the side surface of the three-dimensional frame, the end surface formed by stacking the flaps is rectangular, is completely blocked in the port of the three-dimensional frame and supports the three-dimensional frame;

when each flap is positioned outside the port of the three-dimensional square frame, two first X-direction crease lines at the opposite corners of the three-dimensional square frame are relatively far away, the other two first X-direction crease lines are relatively close to each other, the cross section of the three-dimensional square frame is deformed into a parallelogram from moment to be flattened to be flat, the two flat layers of the flat plates connected end to end are attached to each other, the two first X-direction crease lines far away are positioned at the outermost ends of the flat plates, and the two first X-direction crease lines close to each other are respectively positioned at the upper layer and the lower layer of the flat plates.

2. The collapsible scanning stand of claim 1,

when the three-dimensional square frame is flattened to be flat when two layers of flat plates connected end to end are attached to each other, two second X-direction crease lines extending along the X direction are arranged at the position of the flat plate opposite to one of the two first X-direction crease lines on the upper layer and the lower layer of the flat plate,

the central line between the two second X-direction crease lines is opposite to the first X-direction crease line on the flat plate opposite to the second X-direction crease line,

the distance between the two second X-direction crease lines is equal to or more than twice of the thickness of the flat plate, the two second X-direction crease lines extend to the tail ends of the flaps,

folding the flat stacked plates along the two second X-direction crease lines and the first X-direction crease line opposite thereto so that the four layers are attached to each other, wherein at the folded position, the two second X-direction crease lines are located on the outer side and the first X-direction crease line is located on the inner side.

3. The collapsible scanning stand of claim 2,

the flat plates located at the upper and lower layers of the flat stacked flat plates are provided with two second X-direction crease lines extending in the X direction, respectively.

4. A collapsible scanning stand according to any one of claims 1 to 3,

the tail end of the first flap of one of the two opposite flaps is concave, the tail end of the second flap of the other opposite flap is convex, the width of the convex part is smaller than that of the concave part,

the other two opposite petals are a third petal and a fourth petal which are opposite and opposite in shape,

when the end face formed by the four valve flaps is completely blocked in the end port of the three-dimensional square frame, the first valve flap is positioned at the innermost layer, the third valve flap and the fourth valve flap are attached outside the first valve flap, gaps are formed between the third valve flap and the fourth valve flap and the bottom edge of the concave position of the first valve flap,

the second petal is clung to the outside of the third petal and the fourth petal, and the convex part at the tail end is inserted from the gap and clung to the inner side of the first petal.

5. The collapsible scanning stand of claim 4,

the width of the first flap is the same as that of the side face connected with the first flap and serving as the three-dimensional square frame,

when the flat plate encloses the square frame and the first flap is folded at the port of the square frame, two opposite outer edges of the first flap abut against the inner wall of the square frame.

6. The collapsible scanning stand of claim 4,

the end of the third flap and the end of the fourth flap are respectively rectangular, and the width of the end part of the third flap and the end part of the fourth flap is narrower than the width of the end part of the Y-direction crease line.

7. The collapsible scanning stand of claim 6,

the parts of the third flap and the fourth flap which are connected with the Y-direction crease line side are in a right-angled trapezoid shape,

the right-angle sides of the right-angle trapezoids are positioned at the outer sides of the third and fourth petals, and the bevel sides are positioned at the inner sides of the third and fourth petals.

8. A collapsible scanning stand according to any one of claims 1 to 3,

the outer surface of the side surface where the light transmission part is located is also provided with two positioning blocks, one of the two positioning blocks is located on the top side of the light transmission part, and the other positioning block is located outside the left side or the right side of the light transmission part.

9. A collapsible scanning stand according to any one of claims 1 to 3,

and the flat plates are laminated and bonded end to end or bound.

10. The collapsible scanning stand of any one of claims 1 to 3,

the contour line of the port side of the opening of the three-dimensional square frame is a curve.

Images