阅读说明：本技术 —种水文地质勘察信息传输方法及传输系统 (Hydrogeological survey information transmission method and transmission system ) 是由 崔素 杨能上 王飞 孙鹏 范龙刚 王峰 于 2021-09-18 设计创作，主要内容包括：本发明公开了—种水文地质勘察信息传输系统,包括安装环,安装环的中部螺纹连接有安装壳,安装壳呈圆形且为中空结构,安装壳的中部通过安装机构连接有通信天线,通信天线的中部圆周外部上套设且固定连接有连接环,连接环上通过固定机构连接有四个支撑机构,本发明所达到的有益效果是：本发明的通信天线通过安装机构安装在安装环上,安装机构的安装套卡接在安装环上的安装壳内,而通信天线的下端通过螺纹支杆连接在安装套的内部,安装时通过将通信天线的插在安装套的内部,并将螺纹支杆螺纹连接在安装槽内部的螺孔中,进而将通信天线固定在安装环上,无需借助工具进行操作,较为方便。(The invention discloses a hydrogeological survey information transmission system, which comprises a mounting ring, wherein the middle part of the mounting ring is in threaded connection with a mounting shell, the mounting shell is circular and has a hollow structure, the middle part of the mounting shell is connected with a communication antenna through a mounting mechanism, the outer part of the middle circumference of the communication antenna is sleeved and fixedly connected with a connecting ring, and the connecting ring is connected with four supporting mechanisms through a fixing mechanism, so that the hydrogeological survey information transmission system has the following beneficial effects that: the communication antenna is arranged on the mounting ring through the mounting mechanism, the mounting sleeve of the mounting mechanism is clamped in the mounting shell on the mounting ring, the lower end of the communication antenna is connected to the inside of the mounting sleeve through the threaded support rod, the communication antenna is inserted into the mounting sleeve during mounting, the threaded support rod is connected to the screw hole in the mounting groove in a threaded mode, and therefore the communication antenna is fixed on the mounting ring, operation is conducted without the aid of tools, and the communication antenna is convenient to use.)

1. The hydrogeological survey information transmission system comprises a mounting ring (1) and is characterized in that the middle of the mounting ring (1) is in threaded connection with a mounting shell (8), the mounting shell (8) is circular and is of a hollow structure, the middle of the mounting shell (8) is connected with a communication antenna (3) through a mounting mechanism (2), the outer part of the middle circumference of the communication antenna (3) is sleeved with and fixedly connected with a connecting ring (4), the connecting ring (4) is connected with four supporting mechanisms (7) through fixing mechanisms (6), the four supporting mechanisms (7) are respectively positioned at the two sides and the front and the rear parts of the communication antenna (3) and are respectively connected onto the mounting ring (1), the lower end of the communication antenna (3) is fixedly connected with a threaded support rod (5), and the middle side walls of the upper end and the lower end of the mounting shell (8) are respectively provided with a through hole (11), the mounting structure is characterized in that notches (12) are formed in the inner walls of the front portion and the rear portion of a through hole (11) in the upper end of the mounting shell (8), positioning holes (13) are formed in the inner walls of the two sides of the upper end of the mounting shell (8), a sliding ring (14) is connected to the middle of the inner side of the mounting shell (8) in a sliding mode, a plurality of mounting grooves (15) are formed in the lower end of the sliding ring (14) at equal intervals, compression springs (16) are fixedly connected to the inner portions of the mounting grooves (15), and the lower ends of the compression springs (16) are fixedly connected to the inner wall of the lower end of the mounting shell (8).

2. The hydrogeological survey information transmission system of claim 1, wherein the mounting mechanism (2) comprises a mounting sleeve (21), the mounting sleeve (21) is sleeved and slidably connected to the lower end of the communication antenna (3), a screw hole (24) is formed in the inner wall of the lower end of the mounting sleeve (21), a threaded support rod (5) at the lower end of the communication antenna (3) is in threaded connection with the inside of the screw hole (24), the mounting sleeve (21) penetrates through and is slidably connected to the two through holes (11) in the mounting shell (8), pressing plates (22) are fixedly connected to the outer walls of the circumferences of two sides of the portion, located inside the mounting shell (8), of the mounting sleeve (21), positioning blocks (23) are fixedly connected to the upper ends of the pressing plates (22), and the positioning blocks (23) are clamped inside the positioning holes (13) on the same side.

3. The hydrogeological survey information transmission system of claim 1, wherein the fixing mechanisms (6) each comprise a carrier ring (61), the carrier ring (61) is sleeved and slidably connected to the communication antenna (3), a support ring (62) is fixedly connected to the upper end edge of the carrier ring (61), an inner ring (63) is fixedly connected to the inside of the support ring (62) through a bearing, the inner ring (63) is sleeved and slidably connected to the communication antenna (3), a threaded sleeve (65) is fixedly connected to the upper end of the inner ring (63), the threaded sleeve (65) is sleeved and slidably connected to the communication antenna (3), and the upper end of the threaded sleeve (65) is threadedly connected to the inside of the connection ring (4).

4. A hydrogeological survey information transmission system according to claim 3, wherein a plurality of first rotary plates (64) are fixedly connected to the outer circumferential wall of the upper end of said inner ring (63), and the distances between two adjacent first rotary plates (64) are the same.

5. The hydrogeological survey information transmission system according to claim 1, wherein the supporting mechanisms (7) each comprise a mounting base (71), the mounting bases (71) are each fixedly connected to the upper end of the mounting ring (1), the upper ends of the mounting bases (71) are each rotatably connected to a first rotating plate (73) through a first rotating shaft (72), the upper ends of the first rotating plates (73) are each fixedly connected to an expansion link (74), the upper ends of the expansion links (74) are each fixedly connected to a second rotating plate (75), and the second rotating plates (75) are each rotatably connected to the lower end of the carrier ring (61) of the fixing mechanism (6) through a second rotating shaft (76).

6. A hydrogeological survey information transmission system as claimed in claim 1, wherein said slip ring (14) has an inner diameter equal to the diameter of said through hole (11), and wherein the circumferential outer wall of said slip ring (14) is in contact with the inner wall of said mounting housing (8).

7. A hydrogeological survey information transmission system according to claim 1, wherein a fixed ring (9) is fixedly connected to the upper end of said mounting housing (8), and a second rotating plate (10) is fixedly connected to the circumferential outer wall of said fixed ring (9) at equal intervals.

8. The hydrogeological survey information transmission method of any of claims 1-7, comprising the steps of:

the method comprises the following steps that firstly, the mounting ring (1) is mounted on a tripod at the moment, the mounting shell (8) is mounted inside the mounting ring (1), the tripod is supported on the ground, then the mounting sleeve (21) is inserted into a through hole (11) formed in the upper end of the mounting shell (8), two pressing plates (22) on the mounting sleeve (21) are aligned with two notches (12), the mounting sleeve (21) is pressed downwards, the pressing plates (22) are pressed into the mounting shell (8), the sliding ring (14) is pressed downwards through the pressing plates (22), the mounting sleeve (21) is rotated when positioning blocks (23) on the two pressing plates (22) also enter the mounting shell (8), the two pressing plates (22) deviate from the lower part of the notches (12) on the same side, the mounting sleeve (21) is loosened, the mounting sleeve (21) moves upwards under the extrusion of a compression spring (16), and the upper ends of the two positioning blocks (23) are all abutted against the inner wall of the upper end of the mounting shell (8), continuing to rotate the mounting sleeve (21), when the two positioning blocks (23) are aligned with the two positioning holes (13), the two positioning blocks (23) are respectively clamped into the positioning holes (13) on the same side, and the mounting sleeve (21) is fixed on the mounting shell (8);

secondly, sequentially penetrating the communication antenna (3) through a threaded sleeve (65), an inner ring (63) and a carrying ring (61), inserting the lower end of the communication antenna (3) into the mounting sleeve (21), rotating the communication antenna (3), connecting a threaded support rod (5) at the lower end of the communication antenna (3) into a screw hole (24) in the inner wall of the lower end of the mounting sleeve (21), and fixing the lower end of the communication antenna (3) in the mounting sleeve (21), namely on a tripod;

thirdly, sliding the bearing ring (61) upwards, when the upper end of the threaded sleeve (65) abuts against the lower end of the connecting ring (4), rotating the inner ring (63) through the first rotating support plate (64), wherein the inner ring (63) drives the threaded sleeve (65) to rotate, connecting the upper end of the threaded sleeve (65) to the inside of the connecting ring (4), and stretching the four telescopic rods (74) to the limit length, so that the four telescopic rods (74) respectively support the two sides and the front and back parts of the communication antenna (3), and the communication antenna (3) cannot shake on a tripod;

and fourthly, connecting the communication antenna (3) with other communication equipment together, starting information transmission work, and after the work is finished, detaching the communication antenna (3) from the mounting sleeve (21) according to the method, and folding the tripod.

Technical Field

The invention relates to an information transmission method and a transmission system, in particular to a hydrogeological exploration information transmission method and a transmission system, and belongs to the technical field of hydrogeological exploration equipment.

Background

Hydrogeological survey also called hydrogeological survey refers to hydrogeological survey research work carried out for finding out hydrogeological conditions in a region, aims at mastering the cause, distribution and motion law of underground water and surface water, utilizes water resources for reasonable exploitation, correctly carries out foundation and pile driving engineering design and construction and provides basis, usually utilizes a communication device to transmit the surveyed information to other workers during hydrogeological survey, facilitates subsequent surveying work, and an antenna is one of information transmission devices used during hydrogeological survey and is used for receiving signals.

The antenna that uses when present hydrogeological survey is used is installed on a tripod mostly, need fix it on the tripod with the help of the fastener of bolt class during the installation for the fastener is all needed to be twisted with the help of the instrument in installation at every turn, and is comparatively troublesome, and the whole of antenna is longer, only fixes the lower extreme of antenna on the tripod during the installation, if peripheral wind-force is great, during the use, the antenna rocks on the tripod easily, causes the damage to the coupling part of antenna and tripod.

Disclosure of Invention

The invention provides a hydrogeological survey information transmission system, which effectively solves the problems in the prior art.

In order to solve the technical problems, the invention provides the following technical scheme:

the invention relates to a hydrogeological survey information transmission system, which comprises a mounting ring, wherein the middle part of the mounting ring is in threaded connection with a mounting shell, the mounting shell is in a circular and hollow structure, the middle part of the mounting shell is connected with a communication antenna through a mounting mechanism, the outer part of the middle circumference of the communication antenna is sleeved and fixedly connected with a connecting ring, the connecting ring is connected with four supporting mechanisms through fixing mechanisms, the four supporting mechanisms are respectively positioned at the two sides and the front and back parts of the communication antenna and are all connected on the mounting ring, the lower end of the communication antenna is fixedly connected with a threaded support rod, the side walls of the middle part of the upper end and the lower end of the mounting shell are all provided with through holes, the inner walls of the front and back parts of the through hole at the upper end of the mounting shell are all provided with notches, the inner walls at the two sides of the upper end of the mounting shell are all provided with positioning holes, and the middle part of the inner side of the mounting shell is connected with a sliding ring in a sliding manner, a plurality of mounting grooves are formed in the lower end of the sliding ring at equal intervals, compression springs are fixedly connected to the inner portions of the mounting grooves, and the lower ends of the compression springs are fixedly connected to the inner wall of the lower end of the mounting shell.

As a preferred technical scheme, the mounting mechanism comprises a mounting sleeve, the mounting sleeve is sleeved and slidably connected to the lower end of the communication antenna, a screw hole is formed in the inner wall of the lower end of the mounting sleeve, a threaded support rod at the lower end of the communication antenna is in threaded connection with the inside of the screw hole, the mounting sleeve penetrates through and is slidably connected to two through holes in the mounting shell, pressing plates are fixedly connected to the outer walls of the circumferences of two sides of the part, located inside the mounting shell, of the mounting sleeve, positioning blocks are fixedly connected to the upper ends of the pressing plates, and the positioning blocks are clamped inside positioning holes in the same side.

As a preferred technical scheme of the present invention, the fixing mechanisms each include a carrier ring, the carrier ring is sleeved and slidably connected to the communication antenna, a support ring is fixedly connected to an upper end edge of the carrier ring, an inner ring is fixedly connected to an inside of the support ring through a bearing, the inner ring is sleeved and slidably connected to the communication antenna, a threaded sleeve is fixedly connected to an upper end of the inner ring, the threaded sleeve is sleeved and slidably connected to the communication antenna, and an upper end of the threaded sleeve is threadedly connected to an inside of the connection ring.

As a preferable technical scheme of the invention, a plurality of first rotating support plates are fixedly connected to the outer wall of the circumference of the upper end of the inner ring, and the distances between every two adjacent first rotating support plates are the same.

As a preferred technical scheme of the present invention, the supporting mechanisms each include an installation seat, the installation seats are fixedly connected to the upper end of the installation ring, the upper ends of the installation seats are rotatably connected to a first rotating plate through a first rotating shaft, the upper ends of the first rotating plates are fixedly connected to a telescopic rod, the upper ends of the telescopic rods are fixedly connected to a second rotating plate, and the second rotating plates are rotatably connected to the lower end of the carrier ring of the fixing mechanism through a second rotating shaft.

In a preferred embodiment of the present invention, the inner diameter of the slip ring is the same as the diameter of the through hole, and the circumferential outer wall of the slip ring is in contact with the inner wall of the mounting case.

As a preferable technical scheme of the invention, the upper end of the mounting shell is fixedly connected with a fixing ring, and the circumferential outer wall of the fixing ring is fixedly connected with a second rotating support plate at equal intervals.

A hydrogeological survey information transmission method comprises the following steps:

the method comprises the following steps that firstly, a mounting ring is mounted on a tripod, a mounting shell is mounted inside the mounting ring, the tripod is supported on the ground, a mounting sleeve is inserted into a through hole formed in the upper end of the mounting shell, two pressing plates on the mounting sleeve are aligned with two notches, the mounting sleeve is pressed downwards and pressed into the mounting shell, a sliding ring is pressed downwards through the pressing plates, the mounting sleeve is rotated when positioning blocks on the two pressing plates also enter the mounting shell, the two pressing plates deviate from the lower side of the notches on the same side, the mounting sleeve is loosened and moves upwards under the extrusion of a compression spring, the upper ends of the two positioning blocks are abutted against the inner wall of the upper end of the mounting shell, the mounting sleeve continues to rotate, and when the two positioning blocks are aligned with the two positioning holes, the two positioning blocks are respectively clamped into the positioning holes on the same side, and the mounting sleeve is fixed on the mounting shell;

secondly, sequentially penetrating the communication antenna through the threaded sleeve, the inner ring and the carrying ring, inserting the lower end of the communication antenna into the mounting sleeve, rotating the communication antenna, connecting the threaded support rod at the lower end of the communication antenna into the screw hole in the inner wall of the lower end of the mounting sleeve, and fixing the lower end of the communication antenna in the mounting sleeve, namely on a tripod;

thirdly, sliding the carrier ring upwards, when the upper end of the threaded sleeve abuts against the lower end of the connecting ring, rotating the inner ring through the first rotating support plate, driving the threaded sleeve to rotate by the inner ring, connecting the upper end of the threaded sleeve inside the connecting ring, and stretching the four telescopic rods to the limit length, so that the four telescopic rods respectively support the two sides and the front and the rear parts of the communication antenna, and the communication antenna cannot shake on the tripod;

and fourthly, connecting the communication antenna with other communication equipment together, starting information transmission work, and after the work is finished, detaching the communication antenna from the mounting sleeve according to the method, and folding the tripod.

The invention has the following beneficial effects:

1. the communication antenna is arranged on the mounting ring through the mounting mechanism, the mounting sleeve of the mounting mechanism is clamped in the mounting shell on the mounting ring, the lower end of the communication antenna is connected to the inside of the mounting sleeve through the threaded support rod, the communication antenna is inserted into the mounting sleeve during mounting, the threaded support rod is connected to the screw hole in the mounting groove in a threaded mode, and therefore the communication antenna is fixed on the mounting ring, operation is conducted without the aid of tools, and the communication antenna is convenient to use.

2. The fixing mechanism is arranged on the communication antenna and connected to the mounting ring through the supporting mechanism, when the fixing mechanism is used, the telescopic rod of the supporting mechanism can be connected to the communication antenna through the fixing mechanism, and the communication antenna is pulled by the telescopic rod, so that the situation that the communication antenna is damaged when sliding on the mounting ring is avoided.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic view of a cutaway structure of the present invention;

FIG. 2 is an enlarged view of the area A in FIG. 1;

FIG. 3 is an enlarged view of the area B in FIG. 1;

FIG. 4 is a schematic view of the upper end of the mounting housing of the present invention;

FIG. 5 is a schematic view of the internal structure of the mounting housing of the present invention;

FIG. 6 is a schematic view of the mounting sleeve construction of the present invention;

fig. 7 is an external structural view of the present invention.

In the figure: 1. a mounting ring; 2. an installation mechanism; 21. installing a sleeve; 22. pressing a plate; 23. positioning blocks; 24. a screw hole; 3. a communication antenna; 4. a connecting ring; 5. a threaded strut; 6. a fixing mechanism; 61. a carrier ring; 62. a support ring; 63. an inner ring; 64. a first rotating support plate; 65. a threaded sleeve; 7. a support mechanism; 71. a mounting seat; 72. a first rotating shaft; 73. a first rotating plate; 74. a telescopic rod; 75. a second rotating plate; 76. a second rotating shaft; 8. mounting a shell; 9. a fixing ring; 10. a second rotating support plate; 11. a through hole; 12. a notch; 13. positioning holes; 14. a slip ring; 15. mounting grooves; 16. compressing the spring.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example (b): as shown in fig. 1-7, the hydrogeological survey information transmission system of the present invention comprises a mounting ring 1, wherein the middle part of the mounting ring 1 is connected with a mounting shell 8 by screw threads, the mounting shell 8 is a circular and hollow structure, the middle part of the mounting shell 8 is connected with a communication antenna 3 by a mounting mechanism 2, the outer part of the middle circumference of the communication antenna 3 is sleeved and fixedly connected with a connecting ring 4, the connecting ring 4 is connected with four supporting mechanisms 7 by fixing mechanisms 6, the four supporting mechanisms 7 are respectively located at the two sides and the front and back parts of the communication antenna 3 and are both connected to the mounting ring 1, the lower end of the communication antenna 3 is fixedly connected with a threaded support rod 5, the side wall of the middle part of the upper and lower ends of the mounting shell 8 is both provided with through holes 11, the inner walls of the front and back parts of the through holes 11 of the mounting shell 8 are both provided with notches 12, the inner walls of the two sides of the upper end of the mounting shell 8 are both provided with positioning holes 13, the mounting structure is characterized in that a sliding ring 14 is slidably connected to the middle of the inner side of the mounting shell 8, a plurality of mounting grooves 15 are formed in the lower end of the sliding ring 14 at equal intervals, compression springs 16 are fixedly connected to the inner portions of the mounting grooves 15, the lower ends of the compression springs 16 are fixedly connected to the inner wall of the lower end of the mounting shell 8, the sliding ring 14 can be extruded during use, the mounting mechanism 2 can be jacked up conveniently, and the mounting mechanism 2 is clamped inside the mounting shell 8.

The inner diameter of the slip ring 14 is the same as the diameter of the through hole 11, the circumferential outer wall of the slip ring 14 is in contact with the inner wall of the mounting shell 8, the slip ring 14 can conveniently slide in the mounting shell 8, and the situation that the slip ring 14 inclines when sliding is avoided.

Wherein, the solid fixed ring 9 of upper end fixedly connected with of installation shell 8, equidistant fixedly connected with second rotation extension board 10 on the circumference outer wall of solid fixed ring 9 can be used to rotate installation shell 8 during the use, installs installation shell 8 in the inside of collar 1.

Wherein, installation mechanism 2 is including installation cover 21, installation cover 21 cover is established and sliding connection is at the lower extreme of communication antenna 3, screw 24 has been seted up on the lower extreme inner wall of installation cover 21, 5 threaded connection of screw branch of 3 lower extremes of communication antenna are in the inside of screw 24, installation cover 21 runs through and two through-holes 11 of sliding connection on installation shell 8, installation cover 21 is located equal fixedly connected with clamp plate 22 on the inside part both sides circumference outer wall of installation shell 8, the equal fixedly connected with locating piece 23 in upper end of clamp plate 22, the equal joint of locating piece 23 is in the inside of homonymy locating hole 13, can be used to peg graft communication antenna 3 during the use, fixes communication antenna 3's lower extreme on collar 1.

Wherein, the fixing mechanisms 6 all include a carrying ring 61, the carrying ring 61 is sleeved and slidably connected on the communication antenna 3, the upper end edge of the carrying ring 61 is fixedly connected with a support ring 62, the inside of the support ring 62 is fixedly connected with an inner ring 63 through a bearing, the inner ring 63 is sleeved and slidably connected on the communication antenna 3, a plurality of first rotating support plates 64 are fixedly connected on the outer wall of the circumference of the upper end of the inner ring 63, the distance between two adjacent first rotating support plates 64 is the same, the upper end of the inner ring 63 is fixedly connected with a threaded sleeve 65, the threaded sleeve 65 is sleeved and slidably connected on the communication antenna 3, the upper end of the threaded sleeve 65 is in threaded connection with the inside of the connecting ring 4, the supporting mechanisms 7 all include mounting seats 71, the mounting seats 71 are all fixedly connected on the upper end of the mounting ring 1, the upper ends of the mounting seats 71 are all rotatably connected with first rotating plates 73 through first rotating shafts 72, the equal fixedly connected with telescopic link 74 in upper end of first commentaries on classics board 73, the equal fixedly connected with second commentaries on classics board 75 in upper end of telescopic link 74, second commentaries on classics board 75 all rotates through second pivot 76 and connects the ring 61 lower extreme that carries at fixed establishment 6, can hold the both sides and the front and back portion in communication antenna 3 middle part during the use, fixes communication antenna 3's middle part, and communication antenna 3 rocks on collar 1 when avoiding using.

A hydrogeological survey information transmission method comprises the following steps:

firstly, at the moment, the mounting ring 1 is mounted on a tripod, the mounting shell 8 is mounted in the mounting ring 1, the tripod is supported on the ground, then the mounting sleeve 21 is inserted into the through hole 11 formed in the upper end of the mounting shell 8, the two pressing plates 22 on the mounting sleeve 21 are aligned with the two gaps 12, the mounting sleeve 21 is pressed downwards, the pressing plates 22 are pressed into the mounting shell 8, the sliding ring 14 is pressed downwards through the pressing plates 22, the mounting sleeve 21 is rotated when the positioning blocks 23 on the two pressing plates 22 also enter the mounting shell 8, the two pressing plates 22 are deviated from the lower part of the gaps 12 on the same side, the mounting sleeve 21 is loosened, the mounting sleeve 21 moves upwards under the extrusion of the compression spring 16, the upper ends of the two positioning blocks 23 are abutted against the inner wall on the upper end of the mounting shell 8, the mounting sleeve 21 is continuously rotated, when the two positioning blocks 23 are aligned with the two positioning holes 13, the two positioning blocks 23 are respectively clamped in the positioning holes 13 on the same side, fixing the mounting sleeve 21 on the mounting shell 8;

secondly, the communication antenna 3 sequentially penetrates through the threaded sleeve 65, the inner ring 63 and the carrying ring 61, the lower end of the communication antenna 3 is inserted into the mounting sleeve 21, the communication antenna 3 is rotated, the threaded support rod 5 at the lower end of the communication antenna 3 is connected into the screw hole 24 on the inner wall of the lower end of the mounting sleeve 21, and the lower end of the communication antenna 3 is fixed in the mounting sleeve 21, namely fixed on a tripod;

thirdly, sliding the carrier ring 61 upwards, when the upper end of the threaded sleeve 65 abuts against the lower end of the connecting ring 4, rotating the inner ring 63 through the first rotating support plate 64, driving the threaded sleeve 65 to rotate by the inner ring 63, connecting the upper end of the threaded sleeve 65 to the inside of the connecting ring 4, and stretching the four telescopic rods 74 to the limit length, so that the four telescopic rods 74 respectively support the two sides and the front and rear parts of the communication antenna 3, and the communication antenna 3 cannot swing on a tripod;

and fourthly, connecting the communication antenna 3 with other communication equipment together, starting information transmission work, and after the work is finished, detaching the communication antenna 3 from the mounting sleeve 21 according to the method, and folding the tripod.

Specifically, when the tripod mounting device is used, the mounting ring 1 is mounted on a tripod, the mounting shell 8 is mounted inside the mounting ring 1, the tripod is supported on the ground, the mounting sleeve 21 is inserted into the through hole 11 formed in the upper end of the mounting shell 8, the two pressing plates 22 on the mounting sleeve 21 are aligned with the two notches 12, the mounting sleeve 21 is pressed downwards, the pressing plates 22 are pressed into the mounting shell 8, the sliding ring 14 is pressed downwards through the pressing plates 22, the sliding ring 14 continuously presses the compression spring 16, when the positioning blocks 23 on the two pressing plates 22 also enter the mounting shell 8, the mounting sleeve 21 is rotated to enable the two pressing plates 22 to deviate from the lower part of the notches 12 on the same side, then the mounting sleeve 21 is loosened, the mounting sleeve 21 moves upwards under the extrusion of the compression spring 16, the upper ends of the two positioning blocks 23 are abutted against the inner wall of the upper end of the mounting shell 8, the mounting sleeve 21 is continuously rotated, when the two positioning blocks 23 are aligned with the two positioning holes 13, the two positioning blocks 23 are respectively clamped in the positioning holes 13 on the same side, the mounting sleeve 21 is fixed on the mounting shell 8, the communication antenna 3 sequentially passes through the threaded sleeve 65, the inner ring 63 and the carrying ring 61, the lower end of the communication antenna 3 is inserted into the mounting sleeve 21, the communication antenna 3 is rotated, the threaded support 5 at the lower end of the communication antenna 3 is connected in the threaded hole 24 on the inner wall of the lower end of the mounting sleeve 21, the lower end of the communication antenna 3 is fixed in the mounting sleeve 21, namely fixed on a tripod, then the carrying ring 61 is slid upwards, when the upper end of the threaded sleeve 65 is abutted against the lower end of the connecting ring 4, the inner ring 63 is rotated through the first rotating support plate 64, the inner ring 63 drives the threaded sleeve 65 to rotate, the upper end of the threaded sleeve 65 is connected in the connecting ring 4, and the four telescopic rods 74 are stretched to the limit length, so that the four telescopic rods 74 respectively support the two sides and the front and rear parts of the communication antenna 3, the communication antenna 3 cannot shake on the tripod, the communication antenna 3 is connected with other communication equipment, information transmission work is started, and after the work is finished, the communication antenna 3 is detached from the mounting sleeve 21 according to the method, and the tripod is folded.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.