TWI321543B - Packing system - Google Patents

Description

1321543 » », Nine, invention description: [Technical field to which the invention pertains] The present invention relates to a buffer package "structure; in particular, the invention relates to the use of the package itself, structure as a buffer Buffer package ^ Ji structure. [Prior Art] The packaging of fragile items has always been an important issue in the delivery of products. Insufficient packaging • When properly, it often results in damage to the item during shipment, which in turn increases production costs. Especially for high-precision or fragile electronic shocks, such as liquid crystal display devices, display devices, organic light-emitting diode displays, home theater groups, lamps, etc., it is easy to damage the interior due to impact during transportation. The circuit construction or other fragile structure' causes a loss of product. Taking the display of the stacked package shown in FIG. 1 and FIG. 1b as an example, generally, the display device panel 70 is separated without any support during the product transportation process. First, the bottom of the 1 mesh body 1G is filled with the cushioning material (2), and then the holder 50 folded to the minimum compression position is placed in the cushioning material 22. A partition 30 is disposed above the support base 50 to isolate the display reading panel 7{) above the cut-out seat 5G without the plate 3G to prevent the support base 50 from striking the display device panel 7 during transport. Finally, the cushioning material 21 is filled above the display device panel 70 to complete the packing operation. In the above-mentioned packaging method, the protection and buffering of the external impact is completely dependent on the buffer material 2 and 22 and the partition 3G filled by the ^, so the thickness and material of the cushioning material 2 and 22 and the partition 30 are determined. All buffering effects. Relatively. The support seat is 5 mi of the factor causing the destruction of the display panel 7 ,, and the support base 5 (the structure of the 1 is mostly provided with a spring or other elastic material, and the buffer structure t of the body is used as the shock absorbing material, and It is a pity. Therefore, how to change the device from the Wei electronic device 1 to the device for increasing the buffering effect is a reflection of the present invention. [The invention] The punching structure has the advantages of saving buffering material setting. The purpose is to provide a buffer packaging structure, which is provided with the function of cushioning and shock absorbing by the structure of the package itself to achieve the function of shock absorber. The cushioning package of the present invention should include a button, a part, and a deformable packaged package. The first content and the second content. The box body is inclined::: The first buffer material is disposed inside the interior space of the box body, and forms a work space between the box and the first cushioning material. The deformable first-content system is in a state of being stretched between the stretched state and the compressed state, and is accommodated in the first space. Further, the deformable first content is preferably read by the portion so that it is mechanically disposed on box The first buffer village can be filled with a gap between the deformable first content and the box. The second is also disposed in the inner space and is located on both sides of the partition with the first cushioning material. The second space is accommodated in the second space, and the second buffer material can be used to fill the gap between the main body of the electronic device and the box. In addition to the portion in contact with the spacer, it is preferably implemented. In an example, the second cushioning material is deformable to substantially cover the electronic device (4); the first cushioning preferably also includes the first portion of the first content except the portion in contact with the spacer. In a preferred embodiment, the deformable portion A content is a standard seat containing the narration, cutting rod, and connecting ship components. The reading rod is connected to the base of the opposite base end and the new end, and the branch end is relatively bottom. The axis of the rod is located at the extension position, the compression position and the extension and the age of the joint. The miscellaneous components are respectively connected to the base and the branch. When the t-bar is stretched green, the deformation of the tree And the elastic force generated is the most - when the support is in the compression position When the relative displacement of the support bar and the base has reached the limit, the volume of the support base is minimized. At this time, the deformation amount of the elastic member and the elastic force generated are the largest. When the support seat is at the extension position and the compression position The amount of deformation of the elastic member and the generated elastic force are both in an increaseable section. When the support seat is received in the first space of the casing, the support base can be expanded and contracted in the first direction. To provide a floor force in the partition and to absorb the vibration and displacement of the partition during the handling of the box. When the external force of the second inner grain is vibrated, the partition is compressed in the first direction. The external force is transmitted to the support seat in the first direction, so that the support seat is compressed from the more extended position to the more compressed position to absorb the shock and the displacement generated. At this time, the elastic element accumulates an elastic force, so that the support seat can be restored after being compressed. To the original position, that is, the extension position, the compression of the support seat and the elastic force of the elastic member can buffer the vibration of the second content caused by the shock of the external force. In a preferred embodiment, the first predetermined gap 1321543' between the spacer and the first cushioning material is provided with an elastic material. Compared with the partition portion and the first cushioning material, the rigidity coefficient of the miscellaneous material is the smallest; in other words, when the external force is received by an equal amount, the resistance of the elastic material to the external force is less. When the relevant force lang-direction is pressed downwards, the elastic material will have a compressive deformation prior to the spacer and the first cushioning material to provide a sufficient amount of the branch portion. [Embodiment] The present invention provides a buffer packaging structure. In a preferred embodiment, the buffer package structure is an electronic device package structure. In the present invention, the electronic device J is exemplified by the display of money as shown in Fig. 2; however, the present invention can also be applied to other devices or devices such as fans, lamps, and the like. In the embodiment shown in Figures 3a and 3b, the cushioning package structure preferably includes a case 100, a first cushioning material 220, and a spacer 3. The cabinet ι00 has an internal space 110. In this embodiment, the case 1 is preferably a square case, and the internal space 110 is also a square space. However, in various embodiments, the shape of the housing 100 and its interior 110 may be other different shapes to accommodate different shapes of the package. Further, the case 1 is preferably a carton made of cardboard; however, in various embodiments, the case 1 may be made of plastic or of other materials. As shown in Figures 3a and 3b, the first cushioning material 220 is disposed within the interior space 110. The first cushioning material 220 is preferably made of styrofoam. However, in different embodiments, the first cushioning material 220 may also be made of foam or other organic foaming material. 8 If it is a cushioning material such as an air cushion. The _ section 300 is movably disposed in the inner compartment 110 of the box, and its two ends are respectively connected to the inner wall flute 1 of the cabinet 100 to maintain the stability of the partition_horizontal direction. The spacer system and the stamping material 220 maintain the first predetermined gap super, so as to be separated from the first cushioning material 22 as shown in FIG. 3b, the spacing portion is thinned to divide the internal space 11〇, and the working chamber 112 is The second space 111. The first space 112 is formed between the interval i and the first cushioning material 22G and has a first height. Further, in the case of the yoke, the rigidity coefficient of the spacer portion is larger than the rigidity coefficient of the first cushioning member 220. In a preferred embodiment, the spacer 3GG is movably disposed on the sloping surface by friction with the housing 1; however, in various embodiments, the spacer is accommodated in the The contents of the space 112+ are supported to be movably disposed within the casing 1〇〇. When the field box body 1 is subjected to a collision or other external force, the first cushioning material 22 is relatively moved with the partition portion 300. (1) When the first cushioning material 220 and the spacer portion 300 are opposed to each other due to compression. As shown in FIG. 3c, the box body 1〇〇 is deformed to reduce the original first preset gap 221 between the first buffer material 220 and the spacer 300 to the second preset gap 222, and the second preset gap 222 is smaller than the first preset gap 222. A preset gap 221. At this time, the original first height of the first space 112 is also compressed to a smaller first south degree. Further, in the preferred embodiment, when an external force is generated, the casing 100 is initially deformed toward the first predetermined gap 222 to match the change in the gap between the first cushioning material 220 and the spacer 300. Another embodiment of the spacer 300 and the first cushioning material 220 is shown in Figure 3d. In this embodiment, both ends of the spacer 300 extend toward the first cushioning material 22, respectively. The first cushioning material 220 has a plate shape. The first cushioning material 220 is in contact with and supported by the extending portions of both ends of the partition portion 300. The first space 112 is formed between the extended ends of the spacers 300. In the embodiment shown in Figures 4a and 4b, the cushioning package structure further comprises a packaged deformable first content 500 and a second content 700; the deformable first content 500 is received in the first space The second content 700 is housed in the second space 111. The deformable first content 5 is preferably a support having a deformability and a restoring force; but in other embodiments, it may be other devices having a deformability and a strain restoring force. The second content 700 is exemplified by a display main body. However, in different embodiments, the second content 700 may also be an electronic device such as a fan body or a lamp body. Further, in the present invention, the second content 7〇〇 also includes other packaged non-electronic products, such as mirrors, glasses, and the like. In this embodiment, the thickness of the spacer 300 can be adjusted according to the size of the inner space no of the case 1 to adjust the size of the second space iu and the first space ι 2 in the preferred embodiment, the spacer The coffee is made from styrofoam. In order to match the impact resistance of the content 700 and the deformable first content 500, the hardness of the P 3GG may be adjusted. For example, the styrofoam material having a higher bribe degree is used as the spacer 300. In addition, the spacer 3 can also adopt a multi-layer structure, and increase its buffering capacity to meet other needs. In the setting of the hard partition paste as shown in Fig. g, it is possible to reduce the damage of the spacer _ and the possibility of being penetrated. In the embodiment shown in Figures 4a and 4b, a second cushioning material 210 disposed within the interior 110 of the body 100 is further included. The second cushioning material 210 = forms a second space (1) with the partition portion 300 for accommodating the second content paste. The second cushioning material 210 is in contact with the partition portion 3A to fill the gap between the second contents 7〇〇 and the casing 100. When the casing 1 is subjected to an external force, the second cushioning material 210 does not move relative to the partition portion 3; in other words, the relative positional relationship between the second cushioning material 21'' and the partition portion 3GG is substantially constant. As shown in FIG. 4b, in addition to the portion in contact with the spacer 300, the second buffer material 210 is preferably substantially covered with the second content 7GG; however, in various embodiments, the second buffer material 21 can also be Only the spacer 300 is placed above and below the second content 7〇0. Further, the second buffer 210 is preferably made of styrofoam. However, in various embodiments, the second cushioning material 210 may also use foam, other organic foaming materials, or cushioning materials such as air cushions. In the embodiment shown in Figures 4a and 4b, the deformable first content 5 is a support base 501 for detachably combining with the second content 7〇〇 to support the second content 700. . As shown in Figures 4b and 6a, the support base 501 preferably includes a base 510, a support rod 530, a connector block 550, and a resilient member 570. The two ends of the support rod 530 are opposite the base end 531 and the support end 533, respectively. The base end 531 is rotatably coupled to the base 510, and the support end 530 is rotatably coupled to the docking station 550. The support end 533 is rotatable relative to the base end 531 if the base 51 is used as a reference point. The elastic members 570 are connected to the base 510 and the support rod 530, respectively. In the preferred embodiment, the elastic member 57 is a torsion spring disposed on the base 531 of the support rod 530; however, in the embodiment shown in FIG. gb, the elastic member 132353 may also be a straight line extending along the cutting rod 530. spring. ® IT" 510 6a ^ 550 can be connected to the backing plate of the second content of 7 ° ° f. The base 51G is placed in a flat to provide the second content. In addition, in this state, the deformation of the elastic element 57G The amount and the resulting I:: is t. As shown in the figure, when the support bar is at a compression position of 51° with respect to the base, the support bar 53G is opposite to the base 51 ()

The limit makes the volume of the branch 收缩 shrink to a minimum. At this time, the elastic element 5 = = = the elastic force of the life is the largest. As shown in Figure 7. As shown, when the support bar 53〇 = is in the extended position and the face position or the compression position, the volume of the support seat 501 is also in the volume of the above two states. At this time, the amount of elastic shape and the elastic force generated are in the section where the amount of elasticity can be increased. The change of the external force of the rod_β is rotated relative to the base 51, and the elastic member 570 is further stretched to generate an elastic force corresponding to the external force, so that the branch base 5〇1 integrally forms a shock absorbing device having an absorbing mechanism.

In addition, in order to maintain the support rod 53 (standing in the extended position without rebounding to the extended position, the support base 5) preferably includes a surrounding component. The bundle element is used to surround the base 510 and the reading rod 53Q, the closing of the support rod 53 () to the extension position as shown in Figure 7c 'the bundle element 59 〇 preferably limits the branch to the extension position (4) inspection; however, in different embodiments, The fence member 590 restricts the support base 501 from being in the most compressed position to avoid unintended stretching of the support base 501. In the preferred embodiment, the envelope element 590 is preferably a plastic drawstring. In an embodiment, the bundle element 12 590 can also be a strap of a rope or other material. In addition, the bundle element 59 can also be replaced by a component such as a positioning device or a cassette built into the support base 501. In different embodiments The bundling element 590 is also used on other types of deformable first contents 5〇〇 other than the support base 5Q1. In the embodiment shown in Figures 8a and 8b, the support base 5〇1 is in tension. Positioned at a more extended position between the compression positions and accommodated in the cabinet 1 In a space 112, the support base 501 is expandable and contractible in the first direction 41〇; in other words, by the arrangement of the support bar 530 and the elastic member 570, the connecting seat 550 is slidable relative to the base 51 in the first direction 410. In the preferred embodiment, the first direction 410 is perpendicular to the direction in which the spacer 300 is disposed. The support seat 5〇1 is in contact with the spacer 300' to provide a spacer 3 and absorb The vibration and displacement of the spacer 300. In the preferred embodiment, the connector 550 of the support base 〇1 is in contact with the spacer 300; however, in different embodiments, the base 510 of the support 501 may also be in contact with the spacer. In addition, as shown in FIG. 8b, the support base 501 is maintained in a more extended position by providing the surrounding element 590. However, in different embodiments, the support base 501 can also receive the spacer 300 and the The weight of the two contents is 7〇〇 to maintain the stretched position, and is not fully stretched. Further, in the preferred embodiment, the second content 7〇〇, the support seat 5〇1 stretch position, Both the extension position and the compression position are in the first place Arranged toward 41. As shown in Fig. 8c, when the first inner grain 700 is shaken by an external force, the spacer 300 is compressed in the first direction 410. The spacer 300 is then transmitted to the support in the first direction 410. 501 'Brings the support 501 toward the compressed position to generate a compression enthalpy to 1543 and move to a more compressed position to absorb the shock and the resulting displacement. Since the spacer 3 is moved relative to the first cushioning material 220, the height of the first space 112 is The original first height is lowered to the second height. At this time, the elastic member 57 蓄 accumulates an elastic force due to the compression, so that the support base 501 is then returned to the original position (i.e., the stretched position) toward the extended position. By the compression of the socket 501 and the elastic force of the elastic member 570, the shock generated by the shock of the external force 7 is buffered to reduce the damage of the second content 700. In the embodiment shown in Figures 8a and 8b, the package structure further comprises an elastomeric material 600. The elastic material 600 is disposed in the first predetermined gap 221 between the partition portion 300 and the first cushioning material 220. Compared with the spacer 300 and the first cushioning material 22, the elastic modulus of the elastic material 600 is the smallest; in other words, when an external force is received, the elastic material 600 is less resistant to external forces than the spacer 300 and the first cushioning material 22〇. Less. Further, when an external force is received, the amount of deformation of the elastic material 6 is larger than that of the spacer 300 and the first cushioning material 220. In the preferred embodiment, the elastomeric material 6 is over an air cushion, although in various embodiments, the elastomeric material 6〇〇 may also comprise other materials such as foam. As shown in Fig. 8c, when the spacer 300 is pressed downward in the first direction, the first predetermined gap 221 is reduced to the second preset gap 222. ^ The coefficient of elasticity of the elastic material is small, because the conversion material_ will be compressed before the spacer 300 and the first cushioning material 220 to match the compression amount of the support seat 5〇1, and absorb part of the impact. Figure 9a shows another embodiment of the invention. In this embodiment, the support bar 530 of the support base 501 and the base 510 are sleeved in the axial direction of the support bar 530. In other words, the support rod 53 〇 and the base 51 () of the pedestal 501 constitute a so-called telescopic mirror-type support structure. In this embodiment, the elastic member 570 preferably includes a coil spring or a force spring, and the two ends are respectively connected to the bottom of the support rod 53 and the base 510. The support end 53 is rotatably coupled to the base 55A. As shown in Fig. 9b, the support base 5〇1 is housed in the first space 112 of the casing 1〇〇. In this embodiment, a bundle element 590 is preferably included to surround the connector 550 and the base 510 of the support base 501 to maintain the support base 501 in a relatively compressed position. The pedestal 501 can be telescoped in the first direction 410; in other words, by the struts 530 and the resilient member 570, the yoke 55 can be displaced relative to the base 510 in the first direction 41 。. The support base 501 is in contact with the spacer 300 to provide a spacer 3 to absorb the ground force and absorb the shock and displacement of the spacer. In the preferred embodiment, the base 550 of the support base 501 abuts the spacer 300; however, in various embodiments, the base 510 of the support base may also interfere with the spacer 300. In addition, in the preferred embodiment, the second content 7〇〇, the extended position of the support base 5〇1, the compressed position and the compressed position are all arranged in the first direction 41〇. When the second content paste is shaken by an external force, the spacer 300 is compressed in the first direction 410. The spacer 300 is then transmitted to the support base 501 in the first direction 41〇, causing the support seat 5〇1 to compress toward the compressed position to absorb shock and displacement. At the same time, the elastic force of the elastic member 570 causes the support base 5〇1 to return to the original position toward the extended position, i.e., the compression position. By the compression of the support seat 〇1 and the elastic force of the elastic member 570, the shock generated by the shock of the external force is damped to reduce the damage of the second content. Figures 10a and 10b show another embodiment of the present invention. As shown in Fig. 1A, 15 1321543, the support base 501 is compressed to the compressed position by the weight of the spacer 300 and the second content 7〇〇 thereon. The bunching element 590 is wrapped around the base 51 and the support rod 53 and restricts the extension of the support 501 from exceeding the stretched position between the extended position and the compressed position. In other words, as shown in Fig. 10a, when the support base 5〇1 is compressed to the compressed position, the surrounding element 590 is in a state of being held. However, when the cabinet 100 is opened and the partition portion 3〇〇 on the support base 5〇1 and the second content are taken out, as shown in FIG. 10B, the support seat 5〇1 is moved toward the extended position. Rebound. By the arrangement of the bundling member 590, it is possible to restrict the extension of the support base 5G1 from staying at the above-mentioned stretched position to avoid accidents caused by the direct rebound to the extended position. The present invention has been made by the above-mentioned _real_, and the above embodiment is merely a system for implementing the present invention. It must be pointed out that the example of Wei has not limited the scope of the invention. Modifications and equal arrangements of the spirit and scope of the present invention are included in the scope of the present invention. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1a is a schematic diagram of a disassembly of a packaging structure in a prior art; FIG. 1b is a schematic cross-sectional view of a conventional technical packaging structure; FIG. 2 is a schematic view of an embodiment of an electronic device; Figure 3b is a schematic cross-sectional view of the embodiment of Figure 3a; Figure 3c is a schematic view of the embodiment of Figure 3b; Figure 3d is an alternative embodiment of the spacer and the first cushioning material. Figure 4a is an exploded view of another embodiment of the cushioning package structure; 1321543 Figure 4b is a cross-sectional view of the embodiment shown in Figure 4a; Figure 5 is a cross-sectional view of an embodiment in which a hard spacer is added; Figure 6a is an implementation of the support base Figure 6b is a schematic view of another embodiment of the support base; Figure 7a is a schematic view of the embodiment when the support base is in the extended position; Figure 7b is a schematic view of the embodiment when the support base is in the compressed position; Figure 7c is a schematic view of the support seat Figure 8a is an exploded view of the embodiment of the embodiment comprising the elastic material; Figure 8b is a cross-sectional view of the embodiment when the support seat is in the extended position; Figure 8c is an embodiment of the support seat in a more compressed position Fig. 9a is a schematic view of another embodiment of the first content and the second content of the present invention, and Fig. 9b is a cross-sectional view showing an embodiment of the package structure of the embodiment shown in Fig. 9a. 10a and 10b are schematic views of another embodiment of the present invention. [Main component symbol description] 10 box 21 cushioning material 22 cushioning material 30 spacer 50 support seat 59 bundle element 70 electronic device body 17 1321543 100 cabinet 110 internal space 111 second space 112 first space 210 second cushioning material 220 first cushioning material 221 first preset gap 222 second preset gap 300 partition portion 310 hard partition 410 first direction 500 deformable first content 501 support seat 510 base 530 support rod 531 base end 533 support end 550 Connection seat 570 elastic element 590 bundle element 600 elastic material 700 second content

Claims (1)

X. Applying for a patent garden: 1. A cushioning packaging structure, comprising: a first content can be stored, the buffer packaging structure has a box body having an internal space; the first empty cushioning material is disposed in the inner space Inside; and the punching material is placed in the space of the Leshi, and the system_and the first---------------------------------------------------------------------- - a content; a opposite force force action 'when the first cushioning material and the spacer portion = transport =, the shaft reading ship first - the cushioning material and the coffee portion are contracted between the first cushioning material The rigidity coefficient of the spacer is compared with the door. The cushioning structure according to the item i of claim 1, wherein the punching material comprises a styrofoam. 〃 ox 4· The buffer package structure, wherein the buffer package I structure further comprises a miscellaneous material, wherein the elastic material is provided with the first-predetermined gap, wherein the elastic material is more easily deformed than the box. 5. If the patent application is the fourth item The support cushion packaging structure, wherein the elastic material is an air cushion, when the box When the external force is applied, the air cushion is deformed. The occupant cushioning structure according to claim 4, wherein the elastic material, the spacer, and the first cushioning material are The elastic material has a rigidity J 厶丄 J leaf J number is the smallest. 7. The cushion packaging structure according to the item i, wherein the cushioning structure is more & 3 second cushioning material, the first The second cushioning material is disposed in the inner space 1 with respect to the first cushioning material side, and the second cushioning material is abutting against the phase port of the phase body X to an external force, the second cushioning material does not Moves relative to the spacer. Contains 〇. One mile buffer packaging structure a phase body having an internal space; a first cushioning material disposed in the shaft space; a partition portion disposed in the inner space, and the partition portion maintaining a first-predetermined gap with the first material The spacer and the first buffer material are separated from each other to form a first space between the first buffer material and the spacer; and a deformable first content is accommodated in the first (four), the first content can be maintained In - more stretched _ - more compressed one of the two; Wherein, when the box is not subjected to the oblique force (4), the first space sharpness 'the first content can be maintained in the stretched shape_accepted in the first return box is subjected to an external force' to make the first cushioning material And :: When moving, the box will start to deform from the adjacent - the preset gap = the first space is reduced to - the second height, the second height is less than the first high yield, = the first content is changed The buffer package structure described in the eighth aspect of the present invention is incorporated in the present invention. The ςθ° punching material comprises a styrofoam. 10. The cushioning structure according to item 8 of the patent application, wherein the spacer 20 has a large rigidity coefficient in the interval 20 1321543, the portion, and the first cushioning material. 11. The cushioning package structure of claim 8, further comprising an elastic material disposed in the first predetermined gap, wherein the elastic material is more easily deformed than the housing. 12. The cushioning package structure of claim n, wherein the elastic material, the spacer, and the first cushioning material have a minimum coefficient of rigidity. The cushioning package structure of claim 1, wherein the elastic material comprises an air cushion. The cushioning package structure of claim 8, wherein the first inner dance comprises a support base that can be telescoped in the first direction and interferes with the spacer, the support base comprising: a base ; a branch, the rod has a base end and a continuation end, the base end is connected to the base, the support end is movable relative to the base end; the 豢 joint is connected to the support end of the support rod The connecting seat is connected to an object; and, the elastic member is connected to the base and the support rod, and the support rod is located at a compression position between the extended position and the compressed position relative to the base. The elastic element system & provides an elastic force for the branch lever to drive to the extended position, and one of the base and the connecting seat resists the spacing portion. 15. The cushioning package structure of claim 14, wherein the support end is rotatable about the base end. The blister package structure of claim 15, wherein the elastic element comprises a linear spring extending along the support rod. 17. The cushioning package structure of claim 15, wherein the elastic element comprises a torsion spring disposed at the base end of the support rod. 18. The cushioning package structure of claim 14, wherein the support rod and the base are sleeved in an axial direction of the support rod. 19. The cushioning package structure of claim 14, wherein the elastic element comprises a coil spring disposed along the support rod. 20. The buffer packaging structure according to claim 14 of the patent scope, further comprising: a bundle of reading 'closed bundles to the base and the branch pole in the compressed position', and the contents are self-sustaining _ — stretched out completely. The buffer packaging structure of claim 8 further comprising a buffer material, the spacer being disposed between the second buffer material and the first buffer. Formed - the second space. 22. A buffer packaging structure comprising: a housing having an interior space; a first cushioning material disposed in the interior space; a spacer portion disposed in the interior space to define a first space therebetween; a deformable first content, the spacer and the first cushioning material Abutting the spacer; and a surrounding element that surrounds the first 'the first content-content to limit the first 22 content from a stretched state to a fully extended state In the middle of the _ (four) - the content of the mirror force, the t, and forced the first - internal record self-difficulty stretched to persuade the body to complain 0. 23. The cushioning packaging structure section of claim 22 It is tightly bonded to the first cushioning material. 24. The cushioning package structure of claim 22, The interval state is the lowest height state of the first content.乂 25. The cushioning packaging structure according to claim 22, wherein the first cushioning material is separated from the compartment, and the female 帛 缓 与 与 简 简 简 简 简 简 简 简 简 简 简 简 简 简 简 简The first cushioning material is separated from each other: a first space is formed between the first cushioning material and the spacing portion, and the first internal storage system is accommodated in the first space; the valley* wherein the housing is not When subjected to an external force, the first space maintains a first degree of the same degree. The first object can be transferred to the bribe state and (4) within the first office; when the auxiliary body is subjected to an external force, the first cushioning material is caused. Without the interval ς in the opposite movement, the button will be deformed from the adjacent first-predetermined bribe, so that the mth is reduced to the second height, and the second height is smaller than the first height, forcing the first content The damper is formed in the cushioning structure according to claim 22, wherein the first cushioning material and the spacer comprise styrofoam. The cushioning package structure of claim 22, wherein the spacing portion has a large rigidity coefficient of the spacer portion and the first cushioning material. 28. The cushioning package structure of claim 22, further comprising an elastic material disposed between the spacer and the first cushioning material, wherein the elastic material is more easily deformed than the casing . 29. The cushioning package structure of claim 28, wherein the elastic material, the spacer, and the first cushioning material have a minimum coefficient of rigidity. The cushioning package structure of claim 28, wherein the elastic material comprises an air cushion. The cushioning package structure of claim 22, wherein the first content comprises a support seat that can be telescoped in the H direction and interferes with the spacer, the support base comprising: a base; a support rod having a base end and a support end, the base end connected to the base, the support end being movable relative to the base end; a connecting base connecting the support end of the support rod, the support rod a connecting base for connecting to the main body of the electronic device; and an elastic member connecting the base and the support rod, the support rod being located at a compression position between the extended position and a compressed position relative to the base, the elastic element Providing an elastic force of the rod to the extended position, one of the base and the connecting portion resisting the spacing; wherein the surrounding element surrounds the base and the support 24 in the more compressed position 1321. The cushioning package structure of claim 31, wherein the support end is rotatable about the base end. 33. The cushioning package structure of claim 32, wherein the elastic element comprises a linear spring β-34 extending along the support rod. The cushioning package structure of claim 32, wherein the elastic The component includes a spring disposed at the base end of the support bar. 35. The cushioning package structure of claim 32, wherein the base and the connecting seat thereof are in contact with the surface of the spacer/, &36; as described in claim 31 The buffer packaging structure, wherein the support rod and the base are sleeved along an axial direction of the support rod. A cushioning package structure according to claim 36, wherein the elastic member comprises a coil spring disposed along the support rod. 38. The cushioning package structure of claim 22, further comprising: the spacer is disposed between the second cushioning material and the first cushioning material. = ; into a second space. 25