CN214243725U - Electromechanical installation safety structure - Google Patents

Abstract

The utility model belongs to the technical field of the technique of electromechanical installation and specifically relates to a mechatronic installation safety structure is related to, it includes the lift platform that is used for lifting the operative employee, lift platform includes the base that is used for supporting the operative employee and the safety barrier who is used for protecting the operative employee, the spout has been seted up to the lateral wall of base, the sliding tray that link up with the spout is seted up to the top surface of base, sliding fit has the thing case in the spout, the top surface of the lateral wall that the thing case is located the spout has set firmly locking portion, locking portion and sliding tray sliding fit, this application has the in-process that carries out high altitude construction in lift platform at the operative employee, reduce the effect of falling object potential safety hazard.

Description

Electromechanical installation safety structure

Technical Field

The application relates to the technical field of electromechanical installation, in particular to an electromechanical installation safety structure.

Background

The quality of the electromechanical installation project, which is an important component in building construction projects, directly affects the safe operation and the energy-saving effect of the whole equipment of the building and the use function of the building after the building is put into use.

The safety of workers needs to be guaranteed in the electromechanical installation engineering, so that the electromechanical installation safety structure is produced at the right moment, the overhead operation usually needs the assistance of lifting equipment, a lifting platform used for supporting an operator is usually installed at the top end of the lifting equipment, and the lifting equipment lifts the operator to the operation height by using the lifting platform to perform the overhead operation.

With respect to the related art among the above, the inventors consider that the following drawbacks exist: in the process of an operator working in the lifting platform, the operator often breaks away from the operator due to carelessness of the operator, and the operator falls, so that the potential safety hazard of falling objects exists.

SUMMERY OF THE UTILITY MODEL

In order to reduce the potential safety hazard of falling objects in the process of carrying out high-altitude operation in a lifting platform by an operator, the application provides an electromechanical installation safety structure.

The electromechanical installation safety structure provided by the application adopts the following technical scheme: the utility model provides an electromechanical installation safety structure, includes the lift platform that is used for lifting the operative employee, lift platform includes the base that is used for supporting the operative employee and is used for protecting operative employee's safety barrier, and the spout has been seted up to the lateral wall of base, and the sliding tray that link up with the spout is seted up to the top surface of base, and sliding fit has the thing case in the spout, and the top surface of the lateral wall that the thing case is lieing in the spout has set firmly locking portion, locking portion and sliding tray sliding fit.

Through adopting above-mentioned technical scheme, lift platform lifts the operative employee to the high altitude after, the operative employee promotes locking portion and pushes out the spout with the thing case, the operative employee is when taking lift platform high altitude construction, if because after careless hand instrument that leads to takes off, the instrument can drop into in the thing case and can directly not drop subaerial, reduce the potential safety hazard of object falling from high altitude, after high altitude construction, push back the thing case to the spout with the help of locking portion, reduce the occupancy of lift platform to the space, at last, take out the instrument in the thing case through the sliding tray.

Optionally, be equipped with the locking subassembly in the locking portion, the locking subassembly includes hasp and lock spring, sliding groove has been seted up with one side of sliding groove slip butt in the locking portion, the groove of stirring that link up with sliding groove is seted up to the top surface of locking portion, hasp and sliding groove sliding fit, the hasp is located the one end of sliding inslot portion and has set firmly the portion of stirring that is located stirring inslot portion, at least two lock grooves of pegging graft complex with the hasp are seted up to the inner wall of sliding groove, the lock groove is close to the both ends of sliding groove respectively, the lock spring is located the sliding inslot and is used for applying elasticity to the hasp.

Through adopting above-mentioned technical scheme, before will carrying the thing case and push out the spout, slide the hasp into the sliding groove with the help of the stirring portion and make the hasp break away from the locked groove, unblock locking subassembly promotes the locking portion and will carry the thing case and push out the back from the spout, and the lock spring is automatic inserts the hasp into next locked groove and locks and carry the thing case, keeps carrying the relative stability of thing case and base, improves operative employee's high altitude construction security.

Optionally, the locking groove has a plurality of, and each locking groove is along the trend interval distribution of sliding tray.

Through adopting above-mentioned technical scheme, peg graft the cooperation with hasp and all locked slots and can make a plurality of different positions that carry the thing case and be located the spout, realize carrying the thing case and follow different length of the interior slip-out of spout to adapt to different high altitude construction spaces.

Optionally, a spring for automatically ejecting the carrying box from the sliding groove is arranged in the sliding groove.

Through adopting above-mentioned technical scheme, behind the unblock locking Assembly, the spring makes automatically that to carry the thing case to pop out from the spout, improves the operating efficiency and the convenience of carrying the thing case.

Optionally, a spongy cushion is fixedly arranged at the bottom of the carrying box.

Through adopting above-mentioned technical scheme, when the instrument drops into the thing incasement that carries, the foam-rubber cushion can reduce the impact force between instrument and the thing case of carrying, protection instrument and the thing case of carrying.

Optionally, the end of the latch is inclined away from the slide slot and away from the spring.

Through adopting above-mentioned technical scheme, when will carry the thing case to push back to the spout inside, the opening edge of locked groove can make the hasp automatic sliding advance the inslot that slides by the terminal surface of butt hasp slope, makes the process that carries the thing case and slide to the spout in more swift convenient.

Optionally, the middle part of the inner part of the bottom plate of the carrying box is sunk to form a shape with a middle bottom and a high periphery.

Through adopting above-mentioned technical scheme, the instrument that drops in carrying the thing incasement can roll to the middle lowest department that carries the thing case, conveniently takes out the instrument from carrying the thing incasement through the sliding tray.

Optionally, the carrying box is made of magnetic raw materials.

Through adopting above-mentioned technical scheme, carry the thing case and can adsorb the instrument that drops at carrying the thing incasement, alleviate the instrument and drop the spring degree at carrying thing bottom of the case portion in-process, and make the instrument place in carrying the thing incasement steadily statically.

In summary, the present application includes at least one of the following beneficial technical effects:

1. by arranging the carrying box in the base, if the tool on the hand falls off due to carelessness, the tool can fall into the carrying box and cannot directly fall on the ground, so that the potential safety hazard of falling objects from high altitude is reduced;

2. by arranging the locking assembly, the locking assembly can lock the carrying box at a plurality of different positions in the sliding groove, so that the carrying box can slide out of the sliding groove by different lengths to adapt to different high-altitude operation spaces;

3. through making the inside middle part of bottom plate that carries the thing case sink and form the high shape all around at the bottom of the middle part, can make the instrument that drops in carrying the thing incasement roll to the middle lowest of carrying the thing case, conveniently take out the instrument from carrying the thing incasement through the sliding tray.

Drawings

FIG. 1 is a schematic structural view of an electro-mechanical mounting security feature of an embodiment of the present application;

fig. 2 is an exploded view of a lock spring.

Description of reference numerals: 1. a lifting platform; 11. a base; 111. a chute; 112. a sliding groove; 113. locking the groove; 12. a safety barrier; 2. a carrying box; 21. a lock section; 211. a sliding groove; 212. a poking groove; 3. a locking assembly; 31. a latch; 311. a toggle part; 32. a locking spring; 4. a spring; 5. a spongy cushion.

Detailed Description

The present application is described in further detail below with reference to figures 1-2.

The embodiment of the application discloses an electromechanical installation safety structure, refer to fig. 1, the electromechanical installation safety structure comprises a lifting platform 1 for lifting an operator, the lifting platform 1 comprises a base 11 for supporting the operator and a safety guardrail 12 for protecting the operator, the safety guardrail 12 and the top surface of the base 11 are integrally formed and form a ring shape for surrounding the operator, the side wall of the base 11 is provided with a sliding groove 111, the top surface of the base 11 is provided with a sliding groove 112 communicated with the sliding groove 111, a carrying box 2 is in sliding fit in the sliding groove 111, the opening of the carrying box 2 faces the top of the base 11, the carrying box 2 is integrally formed with a locking part 21 on the top surface of the side wall in the sliding groove 111, and the locking part 21 is in sliding fit with the sliding groove 112; a locking assembly 3 for locking the carrying box 2 at a plurality of positions of the sliding chute 111 is arranged in the locking part 21; the sliding groove 111 is internally and fixedly provided with a spring 4 for ejecting the carrying box 2 out of the sliding groove 111, one end of the spring 4 is welded and fixed with the groove bottom of the sliding groove 111, and the other end of the spring 4 is welded and fixed with the outer side wall of the carrying box 2 inside the sliding groove 111.

Referring to fig. 1, after the lifting platform 1 lifts the operator to the high altitude, the unlocking locking assembly 3, the spring 4 automatically ejects the carrying box 2 to the outside of the sliding groove 111, subsequently, the locking assembly 3 automatically locks the carrying box 2 again, when the operator takes the lifting platform 1 for high altitude operation, if the operator drops the hand tool due to carelessness, the tool can fall into the carrying box 2 and can not directly fall on the ground, the potential safety hazard of objects falling from the high altitude is reduced, after the high altitude operation is finished, the unlocking locking assembly 3 pushes the carrying box 2 back to the sliding groove 111 by means of the locking part 21, the locking assembly 3 locks the carrying box 2 again, the occupancy rate of the lifting platform 1 to the space is reduced, and finally, the tool in the carrying box 2 is taken out through the sliding groove 112.

Referring to fig. 1 and 2, the locking assembly 3 includes a lock bar 31 and a lock spring 32, a sliding groove 211 is formed in one side of the lock bar 21, which is in sliding contact with the sliding groove 112, a toggle groove 212 is formed in the top surface of the lock bar 21, which is communicated with the sliding groove 211, the lock bar 31 is in sliding fit with the sliding groove 211, a toggle portion 311 is integrally formed at one end of the lock bar 31, which is located inside the toggle groove 212, a plurality of lock grooves 113 are formed in the inner wall of the sliding groove 112, which are in plugging fit with the lock bar 31, the lock grooves 113 are equidistantly distributed along the sliding groove 112, the lock spring 32 is located inside the sliding groove 211 to apply an elastic force to the lock bar 31, one end of the lock spring 32 is welded and fixed to the bottom of the sliding groove 211, and the other end of the lock spring 32 is welded and fixed to the lock bar 31; the end of the latch 31 is inclined in a direction away from the slide groove 211 toward a direction away from the spring 4.

Referring to fig. 1 and 2, before the carrier box 2 is pushed out of the sliding slot 111, the latch 31 is slid into the sliding slot 211 by means of the toggle part 311 to disengage the latch 31 from the locking slot 113, the locking assembly 3 is unlocked, the carrier box 2 is automatically pushed out of the sliding slot 111 by the spring 4, when the carrier box 2 moves to a desired position, the latch 31 is opposite to one of the locking slots 113, the latch 31 is automatically inserted into the locking slot 113 by the locking spring 32 to lock the carrier box 2, the carrier box 2 and the base 11 are kept relatively stable, and the safety of high-altitude operation of an operator is improved; when the carrying box 2 is pushed back to the inside of the sliding groove 111, the locking assembly 3 is unlocked in the same way, the opening edge of the locking groove 113 can abut against the inclined end face of the latch 31 to enable the latch 31 to slide into the sliding groove 211 temporarily and automatically, so that the process that the carrying box 2 slides into the sliding groove 111 is faster and more convenient, and when the carrying box 2 slides into the sliding groove 111 completely, the latch 31 is automatically ejected into the locking groove 113 by the lock spring 32 to lock the carrying box 2.

Referring to fig. 1 and 2, the carrying box 2 is made of magnetic raw materials, and the middle part of the inner part of the bottom plate of the carrying box 2 sinks to form a shape with a middle bottom and a high periphery; the bottom of the carrying box 2 is fixedly bonded with a spongy cushion 5. When a tool falls into the carrying box 2, the spongy cushion 5 can reduce the impact force between the tool and the carrying box 2 and protect the tool and the carrying box 2; the tools falling in the carrying box 2 can roll to the lowest position in the middle of the carrying box 2, so that the tools can be conveniently taken out from the carrying box 2 through the sliding groove 112; carry thing case 2 and can adsorb the instrument that drops in carrying thing case 2, alleviate the instrument and drop the spring degree at the bottom in-process of carrying thing case 2, and make the instrument place in carrying thing case 2 steadily statically.

The implementation principle of an electromechanical installation safety structure of the embodiment of the application is as follows: after the lifting platform 1 lifts the operator to high altitude, the latch 31 slides into the sliding groove 211 by means of the toggle part 311 to separate the latch 31 from the lock groove 113, the locking assembly 3 is unlocked, the carrier box 2 is automatically ejected out of the sliding groove 111 by the spring 4, when the carrier box 2 moves to a required position, the latch 31 is opposite to one of the lock grooves 113, the lock spring 32 automatically inserts the latch 31 into the lock groove 113 to lock the carrier box 2, the relative stability of the carrier box 2 and the base 11 is kept, then, the operator starts high altitude operation, if the hand tool is accidentally dropped, the tool drops into the carrier box 2, after the high altitude operation is finished, the locking assembly 3 is unlocked in the same way, the carrier box 2 is pushed back into the sliding groove 111 by means of the locking part 21, the opening edge of the lock groove 113 can abut against the inclined end face of the latch 31 to make the latch 31 temporarily slide into the sliding groove 211 automatically, so that the process of sliding the carrier box 2 into the sliding groove 111 is more rapid and convenient, when the carrier box 2 is completely slid into the slide groove 111, the lock spring 32 automatically springs the lock bar 31 into the lock groove 113 to lock the carrier box 2, and finally, the tool in the carrier box 2 is taken out through the slide groove 112.

The embodiments of the present invention are preferred embodiments of the present application, and the scope of protection of the present application is not limited by the embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. An electromechanical installation safety structure, comprising a lifting platform (1) for lifting an operator, characterized in that: lifting platform (1) is including base (11) that are used for supporting the operative employee and safety barrier (12) that are used for protecting the operative employee, spout (111) have been seted up to the lateral wall of base (11), sliding tray (112) that link up with spout (111) have been seted up to the top surface of base (11), sliding tray (111) sliding fit has thing case (2), thing case (2) have set firmly locking portion (21) at the top surface of the lateral wall that is located spout (111), locking portion (21) and sliding tray (112) sliding fit.

2. An electro-mechanical installation safety structure as claimed in claim 1, wherein: be equipped with locking Assembly (3) in locking portion (21), locking Assembly (3) are including hasp (31) and lock spring (32), sliding groove (211) have been seted up in one side that sliding groove (112) slided the butt in locking portion (21), toggle groove (212) that link up with sliding groove (211) are seted up to the top surface of locking portion (21), hasp (31) and sliding groove (211) sliding fit, hasp (31) are located the inside one end of sliding groove (211) and have set firmly toggle portion (311) that are located toggle groove (212) inside, at least two lock grooves (113) with hasp (31) grafting complex are seted up to the inner wall of sliding groove (112), both ends that slide groove (112) are close to respectively in lock groove (113), lock spring (32) are located sliding groove (211) and are used for exerting elasticity to hasp (31).

3. An electro-mechanical installation safety structure as claimed in claim 2, wherein: the number of the locking grooves (113) is multiple, and the locking grooves (113) are distributed at intervals along the trend of the sliding groove (112).

4. An electro-mechanical installation safety structure as claimed in claim 3, wherein: a spring (4) which can make the loading box (2) automatically pop out from the sliding groove (111) is arranged in the sliding groove (112).

5. An electro-mechanical installation safety structure as claimed in claim 1, wherein: the bottom of the carrying box (2) is fixedly provided with a spongy cushion (5).

6. An electro-mechanical installation safety structure as claimed in claim 3, wherein: the end of the latch (31) is inclined in a direction away from the slide groove (211) and away from the spring (4).

7. An electro-mechanical installation safety structure as claimed in claim 5, wherein: the middle part of the inner part of the bottom plate of the carrying box (2) sinks to form a shape with a middle bottom and a high periphery.

8. An electro-mechanical installation safety structure as claimed in claim 7, wherein: the carrying box (2) is a carrying box (2) made of magnetic raw materials.

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