CN218449306U - Network monitoring wire tube protection structure for weak current engineering - Google Patents

Abstract

The utility model discloses a light current is network monitoring spool protective structure for engineering relates to engineering line protection technical field, including lag, connecting piece and external screw thread, the inboard of lag is provided with the insulator and fills, the inboard that the insulator was filled evenly is provided with the mounting hole, fixed cover is all installed to the inboard of mounting hole. The utility model discloses when receiving external impact, through the mutual striking extrusion of first semicircle elastic block and second semicircle elastic block, first semicircle elastic block absorbs the impact force with the elasticity realization of second semicircle elastic block, and inside elasticity through damping spring by extrusion deformation and elastic rubber piece cushions the vibrational force simultaneously, makes the engineering line not influenced by external impact force, and increase of service life has solved the problem of receiving the impact damage.

Description

Network monitoring wire tube protection structure for weak current engineering

Technical Field

The utility model relates to an engineering line protection technical field specifically is a network control spool protective structure for light current engineering.

Background

Weak current is network control spool for engineering is through protecting the engineering line, make the engineering line be difficult for receiving the striking, drag and damage, prolong the life of engineering line, present a lot of spool simple structure, and fragile, thereby can not have a fine guard action to the engineering line, and present spool does not have the effect of shock attenuation buffering, receive the impact, the engineering line will receive and drag, and can not adjust the installation according to engineering line diameter, the suitability is poor, when needs extension protective range, the structure of not connecting on the spool, thereby cause and use inconveniently.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a network control spool protective structure for weak current engineering to it does not have the problem of being convenient for splice, shock attenuation and being convenient for adjust to propose current network control spool protective structure for weak current engineering in solving above-mentioned background art.

In order to achieve the above purpose, the utility model provides a following technical scheme: a network monitoring line pipe protection structure for weak current engineering comprises a protection sleeve, a connecting piece and external threads, wherein an insulator is arranged on the inner side of the protection sleeve for filling, mounting holes are uniformly formed in the inner side of the insulator for filling, fixing sleeves are arranged on the inner sides of the mounting holes, and a damping mechanism is arranged in the protection sleeve;

a splicing groove is formed in one side of the protective sleeve, a splicing body matched with the splicing groove is arranged on the other side of the protective sleeve, and connecting mechanisms are uniformly arranged on the outer wall of one side of the protective sleeve;

the outer wall of fixed cover evenly is provided with adjusts the structure.

Preferably, the outer side of one side of the protective sleeve is provided with a threaded sleeve, and the outer wall of one side of the protective sleeve is provided with an external thread matched with the internal thread of the threaded sleeve.

By the technical scheme, the threaded sleeve is in threaded fit with the external thread, so that the threaded sleeve can move rightwards or leftwards, and the protective sleeves can be mounted and dismounted.

Preferably, the damping mechanism comprises a cavity, a first semicircular elastic block and a second semicircular elastic block, the cavity is arranged inside the protective sleeve, the first semicircular elastic block is uniformly arranged on the inner wall of one side of the cavity, and the second semicircular elastic block is uniformly arranged on the inner wall of the other side of the cavity.

With above-mentioned technical scheme, through the mutual striking extrusion of first semicircle elastic block and second semicircle elastic block, the elasticity realization of first semicircle elastic block and second semicircle elastic block absorbs the impact force, and the shock attenuation is effectual.

Preferably, the inner wall of mounting hole evenly is provided with the constant head tank, the quantity of constant head tank all is provided with threely.

With above-mentioned technical scheme, all be provided with threely through the quantity of constant head tank and threaded rod, be convenient for make the threaded rod block advance the constant head tank in fix a position the installation.

Preferably, adjust the structure and include the screw hole, the screw hole evenly sets up in the outer wall of fixed cover, the threaded rod is all installed to the inboard of screw hole, the bottom of threaded rod all is connected with the connecting piece through the bearing, the below of connecting piece all is connected with splint.

With above-mentioned technical scheme, through threaded rod and screw hole screw-thread fit, make the decline stable, and adjust the convenience.

Preferably, damping spring is evenly installed to the inner wall of connecting piece, and damping spring's below is connected with the elastic rubber piece, the top in splint is connected to the below of elastic rubber piece.

By the technical scheme, the vibration force is buffered and damped by the damping spring which is extruded and deformed and the elasticity of the elastic rubber block, so that the engineering line is not influenced by external impact force.

Preferably, the connecting mechanism comprises a pressing plate, a reset spring, a connecting rod, a locking block and a locking groove, the connecting rod is uniformly installed on the outer wall of one side of the protective sleeve, the bottom end of the connecting rod extends to the inner side of the splicing groove, the reset spring is installed on the outer wall above the connecting rod, the top end of the connecting rod is connected with the pressing plate, the locking block is connected to the lower portion of the connecting rod, and the outer wall of the splicing body is provided with the locking groove matched with the locking block.

With above-mentioned technical scheme, through rotatory thread bush, realize that the locking piece descends to the locked groove internal fixation, realize the locking of inner structure through external force, it is convenient to use.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) The utility model provides a have clamp plate, connecting rod and locked groove, utilize the concatenation body card of lag one end into the concatenation groove of another lag, then rotate the thread bush, the thread bush internal thread cooperates with the external screw thread, make the thread bush move to one side of clamp plate, then make the clamp plate press and fix in the thread bush inboard, through the clamp plate by extrusion downwards, reset spring is extruded and warp, the connecting rod drives the locking piece and moves to the concatenation inslot inboard simultaneously, then the card is gone into the locked groove and is fixed, realize the concatenation between the lag, solved the inconvenient problem of concatenation;

(2) The utility model provides a have fixed cover, threaded rod and splint, utilize and install the engineering line in the fixed cover, through rotatory threaded rod, the screw-thread fit of threaded rod and screw hole makes the threaded rod rotate and descend, drives the splint and moves to the inboard simultaneously, presss from both sides tight installation to the engineering line through a plurality of splint, is convenient for adjust in a flexible way according to the diameter of engineering line, and the suitability is strong, has solved the poor problem of suitability;

(3) The utility model provides a have first semicircle elastic block, damping spring and second semicircle elastic block, when receiving external impact, through the mutual striking extrusion of first semicircle elastic block and second semicircle elastic block, first semicircle elastic block is realized absorbing the impact with the elasticity of second semicircle elastic block, inside elasticity through damping spring by extrusion deformation and elastic rubber piece cushions the vibrational force simultaneously, make the engineering line not influenced by external impact force, and prolonged service life has solved the problem of receiving the impact damage.

Drawings

Fig. 1 is a schematic sectional view of the protective cover of the present invention;

fig. 2 is a schematic view of the sectional structure of the fixing sleeve of the present invention;

fig. 3 is a schematic view of the three-dimensional structure of the protective cover of the present invention;

FIG. 4 is a schematic view of the sectional structure of the splicing mechanism of the present invention;

fig. 5 is an enlarged schematic view of a portion a of fig. 2 according to the present invention;

fig. 6 is an enlarged schematic view of the structure at B in fig. 4 according to the present invention.

In the figure: 1. a protective sleeve; 2. a damping mechanism; 201. a cavity; 202. a first semi-circular elastomeric block; 203. a second semicircular elastic block; 3. positioning a groove; 4. mounting holes; 5. filling an insulator; 6. fixing a sleeve; 7. a splint; 8. a threaded rod; 9. splicing grooves; 10. a threaded sleeve; 11. a threaded hole; 12. a damping spring; 13. a connecting member; 14. an elastic rubber block; 15. a splice body; 16. an external thread; 17. a connecting mechanism; 1701. pressing a plate; 1702. a return spring; 1703. a connecting rod; 1704. a locking block; 1705. and (4) locking the groove.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example 1: referring to fig. 1-6, a network monitoring line pipe protection structure for weak current engineering comprises a protection sleeve 1, a connecting piece 13 and external threads 16, wherein an insulator filling 5 is arranged on the inner side of the protection sleeve 1, mounting holes 4 are uniformly formed on the inner side of the insulator filling 5, fixing sleeves 6 are respectively arranged on the inner sides of the mounting holes 4, and a damping mechanism 2 is arranged in the protection sleeve 1;

one side of the protective sleeve 1 is provided with a splicing groove 9, the other side of the protective sleeve 1 is provided with a splicing body 15 matched with the splicing groove 9, and the outer wall of one side of the protective sleeve 1 is uniformly provided with a connecting mechanism 17;

the outer wall of the fixed sleeve 6 is uniformly provided with an adjusting structure;

referring to fig. 1-6, the network monitoring line tube protection structure for the weak current engineering further comprises an adjusting structure, the adjusting structure comprises threaded holes 11, the threaded holes 11 are uniformly arranged on the outer wall of the fixing sleeve 6, threaded rods 8 are respectively arranged on the inner sides of the threaded holes 11, the bottom ends of the threaded rods 8 are respectively connected with a connecting piece 13 through bearings, and clamping plates 7 are respectively connected below the connecting pieces 13;

the inner walls of the mounting holes 4 are uniformly provided with three positioning grooves 3;

specifically, as shown in fig. 1, 2 and 5, when using this structure, through installing the engineering line in fixed cover 6, through rotatory threaded rod 8, threaded rod 8 and the screw-thread fit of screw hole 11 make threaded rod 8 rotatory descending, drive splint 7 simultaneously and move to the inboard, press from both sides tight installation to the engineering line through a plurality of splint 7, be convenient for carry out nimble regulation according to the diameter of engineering line, the suitability is strong.

Example 2: the damping mechanism 2 comprises a cavity 201, a first semicircular elastic block 202 and a second semicircular elastic block 203, the cavity 201 is arranged inside the protective sleeve 1, the first semicircular elastic block 202 is uniformly arranged on the inner wall of one side of the cavity 201, and the second semicircular elastic block 203 is uniformly arranged on the inner wall of the other side of the cavity 201;

damping springs 12 are uniformly arranged on the inner wall of the connecting piece 13, an elastic rubber block 14 is connected below the damping springs 12, and the lower part of the elastic rubber block 14 is connected to the top end of the clamping plate 7;

specifically, as shown in fig. 1, fig. 2 and fig. 5, when the structure is used, when an external impact force is applied, the first semicircular elastic block 202 and the second semicircular elastic block 203 impact and extrude with each other, the impact force is absorbed by the elasticity of the first semicircular elastic block 202 and the second semicircular elastic block 203, and meanwhile, the interior of the structure is extruded and deformed by the damping spring 12 and the vibration force is buffered by the elasticity of the elastic rubber block 14, so that the engineering line is not affected by the external impact force, and the service life of the structure is prolonged.

Example 3: the connecting mechanism 17 comprises a pressing plate 1701, a return spring 1702, a connecting rod 1703, a locking block 1704 and a locking groove 1705, the connecting rod 1703 is uniformly arranged on the outer wall of one side of the protective sleeve 1, the bottom end of the connecting rod 1703 extends to the inner side of the splicing groove 9, the return spring 1702 is arranged on the outer wall above the connecting rod 1703, the pressing plate 1701 is connected to the top end of the connecting rod 1703, the locking block 1704 is connected to the lower part of the connecting rod 1703, and the locking groove 1705 matched with the locking block 1704 is arranged on the outer wall of the splicing body 15;

the outer side of one side of the protective sleeve 1 is provided with a threaded sleeve 10, and the outer wall of one side of the protective sleeve 1 is provided with an external thread 16 matched with the internal thread of the threaded sleeve 10;

specifically, as shown in fig. 4 and 6, when the structure is used, the splicing body 15 at one end of the protecting sleeve 1 is clamped into the splicing groove 9 of another protecting sleeve 1, then the threaded sleeve 10 is rotated, the internal thread of the threaded sleeve 10 is matched with the external thread 16, the threaded sleeve 10 moves towards one side of the pressing plate 1701, then the pressing plate 1701 is pressed on the inner side of the threaded sleeve 10 to be fixed, the pressing plate 1701 is downwards extruded, the reset spring 1702 is extruded and deformed, meanwhile, the connecting rod 1703 drives the lock block 1704 to move towards the inner side of the splicing groove 9, and then the lock block 1704 is clamped into the lock groove 1705 to be fixed, so that the splicing between the protecting sleeves 1 is realized.

The working principle is as follows: when the device is used, the engineering wire is firstly clamped into the inner side of the fixing sleeve 6 through the notch of the fixing sleeve 6, then the fixing sleeves 6 are penetrated into the mounting holes 4 for mounting, and are clamped into the positioning grooves 3 for positioning through the threaded rods 8, and the engineering wire has an insulating function through the insulator filling 5, so that good service performance is ensured;

the first innovation point implementation step:

the first step is as follows: the engineering line is installed in the fixed sleeve 6, and the threaded rod 8 is matched with the thread of the threaded hole 11 by rotating the threaded rod 8, so that the threaded rod 8 rotates and descends;

the second step: meanwhile, the clamping plates 7 are driven to move towards the inner side of the fixing sleeve 6 and are in bearing connection with the connecting piece 13 through the threaded rod 8, so that the threaded rod 8 rotates and descends, the clamping plates 7 only descend and do not rotate, and the engineering lines are clamped and installed through the clamping plates 7.

The implementation step of the second innovation point:

the first step is as follows: when external impact force is applied, the first semicircular elastic block 202 and the second semicircular elastic block 203 are impacted and extruded mutually, and the elasticity of the first semicircular elastic block 202 and the second semicircular elastic block 203 absorbs the impact force, so that the damping effect is realized;

the second step is that: meanwhile, the vibration force is buffered by the internal part of the damping spring 12 being extruded and deformed and the elasticity of the elastic rubber block 14, so that the engineering line is not influenced by the external impact force, the service life is prolonged, and the service performance is ensured.

The third innovation point implementation step:

the first step is as follows: the splicing body 15 at one end of the protective sleeve 1 is clamped into the splicing groove 9 of the other protective sleeve 1, then the threaded sleeve 10 is rotated, and the internal thread of the threaded sleeve 10 is matched with the external thread 16, so that the threaded sleeve 10 moves towards one side of the pressing plate 1701;

the second step: then make clamp plate 1701 press and fix at the thread bush 10 inboard, by the extrusion downwards through clamp plate 1701, reset spring 1702 is by extrusion deformation, and connecting rod 1703 drives locking piece 1704 and moves to the splice groove 9 inboard simultaneously, then fixes in the card goes into the lock groove 1705, realizes the concatenation between the lag 1, is convenient for prolong the protection scope as required.

It should be noted that, in this document, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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.

Claims (7)

1. The utility model provides a weak current is network monitoring spool protective structure for engineering, includes lag (1), connecting piece (13) and external screw thread (16), its characterized in that: an insulator filling device (5) is arranged on the inner side of the protecting sleeve (1), mounting holes (4) are uniformly formed in the inner side of the insulator filling device (5), fixing sleeves (6) are mounted on the inner sides of the mounting holes (4), and a damping mechanism (2) is arranged in the protecting sleeve (1);

a splicing groove (9) is formed in one side of the protective sleeve (1), a splicing body (15) matched with the splicing groove (9) is arranged on the other side of the protective sleeve (1), and connecting mechanisms (17) are uniformly arranged on the outer wall of one side of the protective sleeve (1);

the outer wall of the fixed sleeve (6) is uniformly provided with an adjusting structure.

2. The network monitoring line pipe protection structure for the weak current engineering according to claim 1, characterized in that: the thread sleeve (10) is installed in the outside of lag (1) one side, the outer wall of lag (1) one side is provided with thread sleeve (10) internal thread assorted external screw thread (16).

3. The network monitoring line pipe protection structure for the weak current engineering according to claim 1, characterized in that: damper (2) include cavity (201), first semicircle elastic block (202) and second semicircle elastic block (203), cavity (201) set up in the inside of lag (1), first semicircle elastic block (202) are evenly installed to one side inner wall of cavity (201), second semicircle elastic block (203) are evenly installed to the opposite side inner wall of cavity (201).

4. The network monitoring line pipe protection structure for the weak current engineering of claim 1, characterized in that: the inner wall of mounting hole (4) evenly is provided with constant head tank (3), the quantity of constant head tank (3) all is provided with threely.

5. The network monitoring line pipe protection structure for the weak current engineering of claim 1, characterized in that: the adjusting structure comprises a threaded hole (11), the threaded hole (11) is uniformly formed in the outer wall of the fixed sleeve (6), a threaded rod (8) is installed on the inner side of the threaded hole (11), the bottom end of the threaded rod (8) is connected with a connecting piece (13) through a bearing, and a clamping plate (7) is connected to the lower portion of the connecting piece (13).

6. The network monitoring line pipe protection structure for the weak current engineering according to claim 5, characterized in that: damping spring (12) are evenly installed to the inner wall of connecting piece (13), and damping spring (12)'s below is connected with elastic rubber block (14), the top in splint (7) is connected to the below of elastic rubber block (14).

7. The network monitoring line pipe protection structure for the weak current engineering of claim 1, characterized in that: the connecting mechanism (17) comprises a pressing plate (1701), a reset spring (1702), a connecting rod (1703), a locking piece (1704) and a locking groove (1705), the connecting rod (1703) is uniformly installed on the outer wall of one side of the protective sleeve (1), the bottom end of the connecting rod (1703) extends to the inner side of the splicing groove (9), the reset spring (1702) is installed on the outer wall above the connecting rod (1703), the pressing plate (1701) is connected to the top end of the connecting rod (1703), the locking piece (1704) is connected to the lower portion of the connecting rod (1703), and the locking groove (1705) matched with the locking piece (1704) is formed in the outer wall of the splicing body (15).

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