CN208813735U - It is a kind of to seal fungi-proofing capsule endoscope packing device - Google Patents

Abstract

The utility model, which discloses, a kind of seals fungi-proofing capsule endoscope packing device, it include: upper shell, lower casing and receiving portion be made of soft materials, placement capsule endoscope, described accommodation section is set to the inside bottom of the lower casing, and the upper shell is connected with the lower casing removable seal.The present apparatus makes capsule endoscope in packaging, transport, storing process, can effectively separate with the external world, to ensure that capsule endoscope is not contaminated by bacterial；It can be compatible with various sizes of capsule in a certain range, be conducive to the versatility for packing the capsule endoscope of different model specification；During transportation can the light transmitting shell of damping and capsule endoscope there is scratch.

Description

Sealed antibacterial capsule endoscope packing plant

Technical Field

The utility model relates to the field of medical equipment packaging and protection, in particular to the packaging and protection of a capsule endoscope for examining the alimentary canal.

Background

The capsule endoscope is a medical instrument which is swallowed in the digestive tract of a human body and utilizes a miniature camera to shoot images of the digestive tract so as to achieve the purpose of examining digestive tract diseases. The anti-scratch measure of the lens for shooting images is reliable, and the protection measure of the whole capsule endoscope against impurity pollution and the reliability guarantee of the shockproof measure in the transportation process are also important.

In the packaging structure of a common capsule endoscope in the market at present, an upper hard shell and a lower hard shell are generally used as protective shells, and the upper hard shell and the lower hard shell are generally in a simple buckling mode and have no sealing effect. The capsule endoscope is placed in a housing part between upper and lower hard shells, the housing part and the upper shell fix the endoscope capsule, and the housing part is hard and soft. Some capsule endoscopes are directly contacted with the hard accommodating part, so that the risk of scratching a lens is inevitable in the transportation process, and the influence on the image shooting effect is great; scratches produce fines that affect the appearance and contaminate the capsules. Some capsule endoscopes' lens part direct contact thing is soft, but the in-process of capsule endoscope card income packing flexible glue, and capsule endoscope lens can rub with the flexible glue always, still can produce the risk of scratch. Moreover, even if the size of the capsules of different sizes varies little, different packages must be used whenever there are portions in rigid contact.

In summary, no sealing measure is adopted in the packaging structure of the existing capsule endoscope, the capsule is not an omnibearing soft package, and the lens area has no special protection. These packaging methods risk scratching the capsules both during production and during transport. Meanwhile, the capsule endoscope can not be damped in an all-round manner due to random rolling and vibration possibly existing in the transportation and transfer processes. The upper and lower shells do not have any sealing effect, and the antibacterial effect and the storage period are not prolonged. Even if the size difference of capsules of different models is small, different packaging materials are used, and the universality is poor.

SUMMERY OF THE UTILITY MODEL

The utility model provides a sealed antibiotic capsule endoscope packing plant, its aim at solve the capsule endoscope can't guarantee sealed antibiotic and shock attenuation and outward appearance in packing, transportation, storage process and appear the problem of mar, also solve the capsule endoscope problem that same packing plant can't satisfy the different size and specification of packing simultaneously.

The technical scheme of the utility model is like this:

a hermetically sealed, bacteria-proof capsule endoscope packaging device, comprising: the capsule endoscope comprises an upper shell, a lower shell and a containing part which is made of soft materials and used for containing the capsule endoscope, wherein the containing part is arranged at the bottom of the inner side of the lower shell, and the upper shell and the lower shell are detachably connected in a sealing mode.

Further, the sealing connection mode of the upper shell and the lower shell is at least one of threaded sealing connection, sealing element sealing connection or sealing glue sealing connection.

Furthermore, an inwards concave annular boss is arranged on the outer circumference of the lower end part of the upper shell, and an external thread is arranged on the outer circumference of the annular boss; the inner circumference of the lower shell is provided with an internal thread matched with the external thread; an annular groove is formed in the inner side of the bottom of the lower shell, the lower end face of the upper shell is in surface contact with the bottom end face of the annular groove, and threaded sealing connection between the upper shell and the lower shell is achieved; or,

and an annular sealing element is arranged in the annular groove, and the annular sealing element, the annular groove and the upper shell are in interference fit.

Further, the contact surface between the inner circumference of the upper shell and the annular groove is in line-surface contact or line-line contact.

Furthermore, the contact surfaces of the inner side wall of the upper shell and the annular groove are respectively surface contact of the upper shell made of hard materials and the annular groove made of soft materials; or the upper shell is made of hard material, and the annular groove is also made of hard material.

Further: the section of the annular sealing element is rectangular or circular.

Further: the internal thread and the external thread are both common threads or are both sealing threads.

Further: the internal thread and the external thread are both single threads or multi-thread threads.

Further: the accommodating portion includes: a bottom cushion pad internally disposed at the bottom of the lower casing, and,

two first bumps which are integrally formed with the bottom cushion pad and protrude upwards and are approximately in a C shape; the C-shaped openings of the two first bumps are relatively and horizontally arranged on the bottom cushion, the bottom cushion between the two first bumps and the two first bumps forms a first accommodating groove, and the capsule endoscope is placed in the first accommodating groove; or two second bumps which are integrally formed with the bottom cushion pad and protrude upwards and are approximately U-shaped; the U-shaped openings of the two second convex blocks are relatively and horizontally arranged on the bottom cushion pad, the bottom cushion pad between the two second convex blocks and the two second convex blocks forms a second accommodating groove, and the capsule endoscope is placed in the second accommodating groove.

Further: an annular gradual change bulge is arranged on the bottom buffer pad of the first accommodating groove along the axial direction of the capsule endoscope; the bottom buffer pad of the second accommodating groove is also provided with the annular gradual change bulge along the axial direction of the capsule endoscope.

Further: the tops of the inner sides of the two first lugs are in interference fit with the tops of the two ends of the capsule endoscope; the inner sides of two ends of each first bump are in interference fit with two halves of circumferences of the capsule endoscope along the axial lead direction; when the capsule endoscope is placed into the accommodating groove, the capsule endoscope is fixed in the accommodating groove under the action of the radial clamping force and the axial clamping force of the two first convex blocks.

Further: the longest distance between the inner sides of the two first lugs in the axial placement direction of the capsule endoscope is greater than the length of the capsule endoscope, the capsule endoscope is placed behind the first accommodating groove, the first clearance area reserved by the first accommodating groove enables the lens area of the capsule endoscope to be in a suspended state, and the lens area is prevented from being touched by the first lugs.

Further, the height of the two first bumps is larger than the height of the cylindrical surface of the placed capsule endoscope.

Furthermore, two first gaps are formed between the two first lugs; two second gaps are formed between the two second convex blocks.

Furthermore, a pressing block protruding downwards is arranged in the middle of the inner side of the upper shell; the pressing block is made of soft materials; the pressing block is in line-surface contact with the upper end part of the circumferential side surface of the capsule endoscope.

Furthermore, a protruding rib extends downwards from the middle of the inner side of the upper shell, a strip-shaped block made of soft materials is arranged below the rib, and the strip-shaped block is in line-surface contact with the upper end part of the circumferential side surface of the capsule endoscope.

Furthermore, a mounting groove is arranged at the middle position of the lower end part of the buffer pad.

Furthermore, the soft material is silica gel.

Further, the accommodating part and the lower housing are integrally injection-molded; or, the accommodating part is connected with the lower shell in a snap-fit manner.

Further, the upper shell and the lower shell are both injection molded by hard materials.

Further, the upper shell is formed by injection molding of organic glass.

The utility model has the advantages of: by adding the sealing device between the upper shell and the lower shell, the capsule endoscope can be effectively isolated from the outside in the processes of packaging, transporting and storing, thereby ensuring that the capsule endoscope is not polluted by bacteria; meanwhile, due to the flexibility of the buffer cushion, the buffer cushion can be compatible with capsules with different sizes in a certain range, and is favorable for the universality of packaging capsule endoscopes with different models and specifications; because of the flexibility of the buffer cushion, the capsule package can effectively absorb shock in the transportation process, so that the capsule is better protected, and scratches of the light-transmitting shell of the capsule endoscope are also avoided.

Drawings

Fig. 1 is an exploded view of the disclosed device;

FIG. 2 is a full sectional view of the present device along a cross section of a capsule endoscope;

FIG. 3 is a schematic view of the capsule endoscope installation;

FIG. 4 shows the capsule endoscope mounted in the housing;

FIG. 5 is an enlarged view of FIG. 2 at A; the cross section of the sealing device is rectangular;

FIG. 6 is an enlarged view of FIG. 2 at A; the cross section of the sealing device is circular;

FIG. 7 is a top view of FIG. 4;

FIG. 8 is a schematic structural diagram of a second embodiment;

FIG. 9 is a schematic structural diagram of a third embodiment;

FIG. 10 is a view showing the structure of the packaging apparatus with the seal ring removed;

fig. 11 is a schematic view of the structure of the sealing device 2 shown in fig. 2 with the parts removed.

Detailed Description

In order to make the technical problem, technical solution and advantageous effects to be solved by the present invention more clearly understood, the following description is given in conjunction with the accompanying drawings and embodiments to illustrate the present invention in further detail. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

The utility model discloses a sealed fungi-proofing capsule endoscope packing plant, include: the capsule endoscope comprises an upper shell, a lower shell and a containing part which is made of soft materials and used for containing the capsule endoscope, wherein the containing part is arranged on the end surface of the inner side of the lower shell, and the upper shell and the lower shell are detachably connected in a sealing mode. Because the accommodating part is made of soft materials, when the capsule endoscope is placed in the accommodating part, the shell of the capsule endoscope cannot be scratched even though the shell of the capsule endoscope is made of hard plastic because of the elastic characteristic of the soft materials. In addition, the upper shell and the lower shell are connected in a detachable sealing way, so that when the capsule endoscope is arranged in a closed space formed by the upper shell and the lower shell, the capsule endoscope cannot be infected by bacteria, and the health of a human body when the capsule endoscope is taken out and swallowed is ensured.

The connection mode of the upper shell and the lower shell can be common threaded connection, snap connection, loose-leaf connection or hinged connection. Referring to fig. 2, as one of the common connection means, an outer circumference of the upper housing 5 is provided with an external thread 51, and an inner circumference 11 of the lower housing 1 is provided with an internal thread 12. The purpose of covering the upper and lower housings 5 and 1 together is achieved by the threaded connection of the external and internal threads 51 and 12.

Specifically, in fig. 2, the lower end portion of the outer circumference of the upper case 5 is provided with a recessed annular boss 52, and the outer circumference of the annular boss 52 is provided with the aforementioned external thread 51.

The external thread 53 and the internal thread 12 can be both common threads or both sealing threads; either as single or multiple thread connections are common mechanical thread connections.

Referring to fig. 3, an annular groove 13 is further designed at the bottom end of the inner side of the lower housing 1, and an annular sealing member 2 is placed at the bottom end of the annular groove 13. Referring to fig. 2, when the upper casing 5 and the lower casing 1 are screwed, the lower end portion of the annular boss 52 of the upper casing 5 presses the annular sealing member 2, and the annular sealing member 2 is deformed after being pressed, and the left and right ends thereof press the both side walls of the annular groove 13, respectively. In the upper shell 5 and the lower shell 1, the upper end of the annular sealing element 2 is extruded by the lower end part of the annular boss 52, the lower end of the annular sealing element is extruded by the bottom end of the annular groove 13, and the inner side and the outer side of the annular sealing element are extruded by the side wall of the annular groove 13, so that the space 6 formed after the upper shell 5 and the lower shell 1 are covered by the annular sealing element 2 can be effectively separated from the outside to form a closed space. It will be appreciated that the distance between the inner and outer sides of the cross-section of the annular seal 2 when uncompressed is greater than the width of the annular groove 13 (see figure 6), so that the annular seal 2 forms an interference fit with the annular groove 13 and the lower housing 1; similarly, when the annular sealing member 2 is not pressed, the distance between the upper end and the lower end of the cross section is larger than the distance between the lower end of the upper shell 5 and the groove bottom of the annular groove 13 after the upper shell 5 and the lower shell 1 are screwed.

In particular, the annular seal 2 may be an o-ring seal, which when uncompressed has a circular cross-section as shown in figures 2 and 3; it may be an annular rubber ring with a rectangular cross section (see fig. 5), or it may be a sealing elastic member with a cross section having other shapes and structures. Note that, if the annular seal member 2 is an o-ring, its shape after being pressed is an oval (see fig. 6).

In fig. 5 and 6, the contact surface 13A between the annular groove 13 and the lower end portion of the upper case 5 may be a surface-to-surface contact or a line-to-surface contact. If the annular groove 13 is in surface-to-surface contact, one side wall of the annular groove 13 and the contact surface 13A of the annular boss 52 are designed to be in interference fit, so that the contact surface 13A of the annular groove 13 and the annular boss 52 forms good sealing, and the sealing effect is further improved.

In fig. 5 and 6, the contact surface 13A of the annular groove 13 and the annular boss 52 may be a contact of a hard material and a soft material, or a contact of a hard material and a hard material. If the contact surface 13A is in line-surface contact with the contact surface of the annular groove 13 and the annular projection 52, the portion of the annular groove 13 in contact with the annular projection 52 may be configured to have a saw-tooth shape (not shown), or the portion of the annular projection 52 in contact with the annular groove 13 may be configured to have a saw-tooth shape (not shown).

Example 1

Referring to fig. 1, the aforementioned accommodating portion includes two embodiments. The first embodiment: the accommodating portion 3 is provided at the bottom of the inner side of the lower case 1, and includes: a bottom cushion 31 made of a soft material; two first projections 32, which are substantially "C" shaped, extend upwardly from the bottom cushion 31. Referring to fig. 4, the "C" shaped openings of the two first projections 32 are horizontally opposed, the two first projections 32 and the bottom cushion 31 between the two first projections 32 constitute a first receiving groove in which the capsule endoscope 4 is placed. As can be seen from fig. 1 and 2, the first protrusions 32 and the bottom cushion 31 are integrally formed by injection molding. Referring to fig. 2, fig. 2 is a radial longitudinal sectional view of the capsule endoscope of fig. 4, the inner side wall 320 of the first projection 32 is in interference fit with the hemispherical end 41 of the capsule endoscope 4, and after the capsule endoscope 4 is loaded from the upper end of the first accommodating groove, the capsule endoscope 4 is pressed by the radial force from the first projection 32 due to the interference fit of the first projection 32 and the capsule endoscope 4, and is firmly clamped in the first accommodating groove, so that the capsule endoscope cannot move upwards and turn over during transportation and packaging. In addition, because the bottom buffer pad 31 and the two first bumps 32 are made of soft materials, when the capsule endoscope is placed in the first accommodating groove, the capsule shell does not leave scratches due to the contact with the inner wall of the first accommodating groove.

In fig. 2, the upper end 321 of the first protrusion 32 is higher than the top 42 of the cylindrical surface of the installed capsule endoscope 4, and this structure design can effectively prevent the external object from touching the lens area 43 (see fig. 3) of the capsule endoscope, and ensure that the lens area 42 of the capsule endoscope is not scratched.

Referring to fig. 3 and 4, the inner bottom of the first projection 32 is provided with an annular tapered protrusion 322 in the axial direction in which the capsule endoscope is placed. The distance between the inner side walls 323 of the first protrusions 32 along the axial line direction of the capsule endoscope is greater than the length of the capsule endoscope 4, and after the capsule endoscope 4 is placed into the first accommodating groove, the first accommodating groove is provided with a clearance area 324 for suspending the lens area 42 at one end of the capsule endoscope without colliding with the first accommodating groove. The other end of the capsule endoscope abuts against the inner side wall 323 of the other first lug 32 along the axial direction of the capsule endoscope, and the interference fit structure of the annular gradual change bulge 322, the first lug 32 and the capsule endoscope prevents the capsule endoscope from moving along the axial direction. In addition, the advantage of setting the distance between the inner side walls 323 of the two first protrusions 32 in the direction of the axis of the capsule endoscope to be greater than the axial length of the capsule endoscope is also beneficial to the fact that the accommodating groove can accommodate capsule endoscopes with different length specifications.

To sum up, radial clamping force and axial clamping force provided by the interference fit structural design of the annular gradual change protrusion 322 and the inner side wall 320 of the two first bumps and the two hemispherical end portions 41 of the capsule endoscope 4 prevent the capsule endoscope from axially and radially moving in the transportation process, so that scratches cannot occur to the shell of the capsule endoscope, and the optical lens shell of the capsule endoscope is effectively protected. Meanwhile, the two first bumps 32 and the bottom buffer pad 31 are made of soft materials, and the soft materials have certain ductility, so that the first accommodating groove can accommodate capsule endoscopes with different circumferential diameters in a certain range. Therefore, the device can meet the requirements of capsule endoscope packages with different specifications.

Referring to fig. 4 and 7, the space between the first protrusions 30 forms a first gap 34, which is used to facilitate the forefinger and thumb to pinch the two cylindrical sides of the capsule endoscope when placing or removing the capsule endoscope.

Example 2

Referring to fig. 8, unlike embodiment 1, in this embodiment, two second bumps 32A having a substantially "U" shape are used instead of the first bump 32 in embodiment 1. The two second bumps 32A, the bottom cushion 31 between the two second bumps 32A form a second receiving groove, and the capsule endoscope is placed in the second receiving groove. The U-shaped openings of the two second protrusions 32A are oppositely arranged, and the two end parts of the capsule endoscope are respectively placed in the U-shaped openings of the two second protrusions 32A. In addition, the bottom of the inner side of the two second lugs 32A is also provided with an annular gradual change bulge 322 along the axial direction of the capsule endoscope, and the distance of the inner side of the two U-shaped second lugs 32A along the axial lead of the capsule endoscope is also larger than the length of the capsule endoscope. Therefore, when the capsule endoscope is placed in the second receiving groove, one end of the second receiving groove still abuts against the inner side wall of one of the second protrusions 32A, and the optical lens area at the other end remains suspended as in embodiment 1.

It will be appreciated that the second protrusions 32A define a second gap (not shown, but refer to the first gap 34 in FIG. 7) therebetween, which, like the first gap, is also used for holding the circumferential sidewall of the capsule endoscope when the capsule endoscope is inserted or removed, by the index finger and the thumb.

Since the two U-shaped second protrusions 32A are no longer in interference fit with the circumferential side wall of the capsule endoscope, a pressing block 54 is required to be disposed directly above the capsule endoscope placed in the second accommodating groove, and the pressing block 54 is an independent component and is made of a soft material. The press block 54 and the upper housing 5 are detachably connected, and may be a bolt connection or a snap connection, for example. After the pressing block 54 is coupled to the upper casing 5, the upper casing 5 and the lower casing 1 are rotated so that the pressing block 54 is finally pressed against the upper end portion of the circumferential surface of the capsule endoscope, preventing the capsule endoscope from moving upward during transportation. It will be appreciated that the contact of the compact 54 and the capsule endoscope is a line-surface contact.

It should be noted that, in this document, the upper housing 5 and the lower housing 1 are both made of hard material by injection molding, so that the press block 54 needs to be made of soft material in order to prevent the capsule endoscope from being cut during transportation.

Example 3

Referring to fig. 9, unlike embodiment 2, the upper case 5 is provided with a downwardly extending rib 55 at the middle inside thereof, and the rib 55 and the upper case 5 are integrally injection-molded from a hard material. A bar-shaped block 56 made of soft material is arranged under the rib 55, the bar-shaped block 56 is in line-surface contact with the upper end part of the circumferential surface of the capsule endoscope 4

In addition, the housing portion 3 and the lower case 1 in fig. 2 may be two separate parts or may be integrated into one part by a two-shot molding method. In the case of two parts, the receiving portion 3 and the lower housing 1 are preferably snap-connected.

Example 4

Referring to fig. 10 and 11, in addition to the upper housing 5 and the lower housing 1 being sealed by the annular sealing member 2, the annular sealing member 2 may be omitted, and the upper housing 5 and the lower housing 1 are sealed directly by the lower end surface of the upper housing 5 and the bottom end surface of the annular groove 13 through the contact between the end surfaces, and at this time, it is required to satisfy that the external thread of the upper housing 5 is the sealing external thread 51A, and the internal thread of the lower housing 1 is the sealing internal thread 12A. The structure of the bump in the bottom cushion 31 therein may be the aforementioned C-shaped first bump, or may be a U-shaped second bump. The other structure of the bottom cushion 31 is the same as that described in embodiments 1 to 3.

Example 5

In fig. 10, the screw connection between the upper case 5 and the lower case 1 may be sealed by applying a sealant. At the time of use, the upper case 5 and the lower case 1 are separated by heating the sealant to soften the sealant which has hardened. The sealant is as follows: any one of a paste sealant, a liquid elastomer sealant, a hot melt sealant and a liquid sealant.

In the above 5 embodiments, the receiving portion 3 may be a separate component, and may be snapped into the lower case 1, or may be integrated with the lower case 1 by a two-shot molding method.

Referring to fig. 2, 8, 9 and 11, at the lower end of the bottom buffer pad 31, there is further provided a seating chamber 35, and the seating chamber 35 is used to seat a photoelectric switch which activates the capsule endoscope by means of a photoelectric control and a magnetic control power source.

The soft material in the present invention includes, but is not limited to, one of TPU (thermoplastic polyurethane elastomer rubber), TPE (thermoplastic elastomer rubber), TPR (thermoplastic elastomer), silica gel and rubber. The utility model discloses preferred silica gel is as the equal preferred silica gel of first lug, second lug, bottom blotter, briquetting, bar piece. The upper shell is preferably made of organic glass.

The utility model provides an go up shell and lower shell, the difference in the name of only doing for the convenience is distinguished, and this is not to say that the shell must be above, and lower shell must be below. In practice, the upper housing may also be below and the lower housing may also be above. That is, the upper housing may also be called a lower housing, and the lower housing may also be called an upper housing.

The utility model discloses a packaging device, which has the following advantages that 1, a sealing device is added between an upper shell and a lower shell or the lower end part of the upper shell and the bottom end surface of an annular groove of the lower shell are sealed with the end surface, so that a capsule endoscope can be effectively isolated from the outside in the packaging, transportation and storage processes, thereby ensuring that the capsule endoscope is not polluted by bacteria; 2. the two C-shaped first lugs are in interference fit with the capsule endoscope, so that axial stress and radial stress are generated on the capsule endoscope, and the capsule endoscope is prevented from moving and turning over in the transportation process; 3. the clearance design of the C-shaped first bump ensures that the optical lens of the capsule endoscope is suspended and cannot collide with any object; 4. the structural design of the U-shaped second bump pressing block can also realize the effect realized by the C-shaped first bump; 5. because of the softness of the buffer cushion, the buffer cushion not only has the function of shock absorption, but also can be compatible with capsules with different sizes in a certain range, and is beneficial to packaging capsule endoscopes with different models and specifications.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (21)

1. A hermetically sealed, bacteria-proof capsule endoscope packaging apparatus, comprising: the capsule endoscope comprises an upper shell, a lower shell and a containing part which is made of soft materials and used for containing the capsule endoscope, wherein the containing part is arranged at the bottom of the inner side of the lower shell, and the upper shell and the lower shell are detachably connected in a sealing mode.

2. The sealed, bacteria-proof, capsule endoscopic packaging apparatus of claim 1, wherein said upper housing and said lower housing are sealingly connected by at least one of a threaded seal, a sealing member seal, or a sealant seal.

3. The sealed and bacteria-proof capsule endoscope packaging device according to claim 2, characterized in that the outer circumference of the lower end part of the upper shell is provided with an inward-concave annular boss, and the outer circumference of the annular boss is provided with an external thread; the inner circumference of the lower shell is provided with an internal thread matched with the external thread; an annular groove is formed in the inner side of the bottom of the lower shell, the lower end face of the upper shell is in surface contact with the bottom end face of the annular groove, and threaded sealing connection between the upper shell and the lower shell is achieved; or,

and an annular sealing element is arranged in the annular groove, and the annular sealing element, the annular groove and the upper shell are in interference fit.

4. A sealed, bacteria-proof capsule endoscopic packaging apparatus as claimed in claim 3, wherein the contact surface of said inner circumference of said upper housing and said annular groove is either line-surface contact or line-line contact.

5. A sealed and antibacterial capsule endoscope packaging device according to claim 3, characterized in that the contact surfaces of the inner side wall of said upper shell and said annular groove are respectively the surface contact of the upper shell which is made of hard material and the annular groove which is made of soft material; or the upper shell is made of hard material, and the annular groove is also made of hard material.

6. A hermetically sealed, bacteria resistant capsule endoscopic packaging apparatus as claimed in any one of claims 3 to 5, wherein: the section of the annular sealing element is rectangular or circular.

7. A hermetically sealed, bacteria resistant capsule endoscopic packaging apparatus as claimed in any one of claims 3 to 5, wherein: the internal thread and the external thread are both common threads or are both sealing threads.

8. A hermetically sealed, bacteria resistant capsule endoscopic packaging apparatus as claimed in any one of claims 3 to 5, wherein: the internal thread and the external thread are both single threads or multi-thread threads.

9. The sealed, bacteria-proof capsule endoscopic packaging apparatus of any of claims 1-5, wherein said containment portion comprises: a bottom cushion pad internally disposed at the bottom of the lower casing, and,

two first bumps which are integrally formed with the bottom cushion pad and protrude upwards and are approximately in a C shape; the C-shaped openings of the two first bumps are relatively and horizontally arranged on the bottom cushion, the bottom cushion between the two first bumps and the two first bumps forms a first accommodating groove, and the capsule endoscope is placed in the first accommodating groove; or two second bumps which are integrally formed with the bottom cushion pad and protrude upwards and are approximately U-shaped; the U-shaped openings of the two second convex blocks are relatively and horizontally arranged on the bottom cushion pad, the bottom cushion pad between the two second convex blocks and the two second convex blocks forms a second accommodating groove, and the capsule endoscope is placed in the second accommodating groove.

10. A sealed, bacteria-proof capsule endoscopic packaging apparatus as defined in claim 9, wherein: an annular gradual change bulge is arranged on the bottom buffer pad of the first accommodating groove along the axial direction of the capsule endoscope; the bottom buffer pad of the second accommodating groove is also provided with the annular gradual change bulge along the axial direction of the capsule endoscope.

11. A sealed, bacteria-proof capsule endoscopic packaging apparatus as defined in claim 10, wherein:

the tops of the inner sides of the two first lugs are in interference fit with the tops of the two ends of the capsule endoscope; the inner sides of two ends of each first bump are in interference fit with two halves of circumferences of the capsule endoscope along the axial lead direction; when the capsule endoscope is placed into the accommodating groove, the capsule endoscope is fixed in the accommodating groove under the action of the radial clamping force and the axial clamping force of the two first convex blocks.

12. The device as claimed in claim 11, wherein the longest distance between the inner sides of the two first protrusions along the axial direction of the capsule endoscope is greater than the length of the capsule endoscope, and after the capsule endoscope is placed in the first receiving groove, the first clearance area left by the first receiving groove enables the lens area of the capsule endoscope to be in a suspended state, so as to avoid the lens area from touching the first protrusions.

13. The sealed, bacteria-proof capsule endoscope packaging device of claim 9, characterized in that the height of said two first projections is larger than the height of the cylindrical surface of the placed capsule endoscope.

14. The sealed, bacteria-proof, capsule endoscopic packaging of claim 10, wherein two first indentations are formed between said two first protrusions; two second gaps are formed between the two second convex blocks.

15. The sealed, bacteria-proof capsule endoscopic packaging apparatus of claim 10, wherein a downwardly projecting press block is provided in the middle of the inside of said upper housing; the pressing block is made of soft materials; the pressing block is in line-surface contact with the upper end part of the circumferential side surface of the capsule endoscope.

16. The sealed and antibacterial capsule endoscope packaging device according to claim 10, characterized in that a protruding rib extends downwards from the middle part of the inner side of the upper shell, a bar-shaped block made of soft material is arranged under the rib, and the bar-shaped block is in line-surface contact with the upper end part of the circumferential side surface of the capsule endoscope.

17. The sealed, bacteria-proof capsule endoscope packaging apparatus of claim 10, characterized in that a seating groove is provided at a middle position of a lower end portion of said cushion pad.

18. The sealed, bacteria-proof, capsule endoscopic packaging of any of claims 1-5, wherein said flexible material is silicone.

19. The sealed, bacteria-proof capsule endoscopic packaging of any of claims 1-5, wherein said receptacle and said lower housing are integrally injection molded; or, the accommodating part is connected with the lower shell in a snap-fit manner.

20. The sealed, bacteria-proof capsule endoscopic packaging of any of claims 1-5, wherein said upper housing and said lower housing are each injection molded from a hard material.

21. A sealed, bacteria-proof capsule endoscopic packaging apparatus as recited in claim 20, wherein said upper housing is injection molded from plexiglas.