CN113681526A

CN113681526A - Electromechanical engineering power equipment auxiliary device

Info

Publication number: CN113681526A
Application number: CN202110950090.0A
Authority: CN
Inventors: 林建国
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-08-18
Filing date: 2021-08-18
Publication date: 2021-11-23

Abstract

The invention discloses an auxiliary device for electromechanical engineering electric power equipment, belonging to the technical field of electromechanical engineering electric power equipment, and the auxiliary device for electromechanical engineering electric power equipment comprises: the linkage plate, the shock mount, the mounting bracket, clamping device, drive arrangement and rotating device are through placing electrical equipment on the horizontal plane of a pair of L shape splint, start a pair of push cylinder, push cylinder's output pulling U-shaped plate removes, because be connected with the connecting plate through the linking arm between a pair of U-shaped plate, when being close to each other between a pair of U-shaped plate, drive a pair of linking arm and promote the connecting plate and rotate, because a pair of round pin axle pivoted angle is the same on the connecting plate, thereby make a pair of U-shaped plate displacement is the same, make electrical equipment be located the center department of device all the time, and play the effect of quick fixation and dismantlement to electrical equipment through opening and shutting of a pair of L shape splint.

Description

Electromechanical engineering power equipment auxiliary device

Technical Field

The invention belongs to the technical field of electromechanical engineering, and particularly relates to an auxiliary device for electromechanical engineering electric equipment.

Background

The electromechanical devices generally refer to machines, electrical appliances and electrical automation devices, and in buildings, the electromechanical devices generally refer to machines and pipeline devices except for earthwork, woodwork, reinforcing steel bars and muddy water, and the classification methods are also various, wherein the mechanical devices comprise a plurality of large-scale devices with larger volume and weight.

However, most of the volumes of the electrical equipment are large, in the traditional installation process, the electrical equipment can only be carried through manual work, the time and the labor are wasted, the electrical equipment is generally fixed at a high position, the long-time operation is realized, the normal work of the electrical equipment is ensured, people need to overhaul the electrical equipment regularly, but the movable range of people is limited because most of the electrical equipment is fixedly arranged at one position, the flexibility is greatly reduced, the overhaul progress of people is influenced, and the inconvenience is brought to the work of people.

Disclosure of Invention

The invention aims to provide an auxiliary device for electromechanical engineering electric power equipment, which aims to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

an electromechanical engineering power equipment auxiliary device comprising: the device comprises a connecting plate, a shock absorption seat, a mounting frame, a clamping device, a driving device and a rotating device.

Wherein, the lower surface that is located the connection plate is installed the cushion socket, because electrical equipment when installing, in order to guarantee the stability of its installation in addition to the fastness and the accuracy of installation, through the cushion socket that sets up in connection plate below, can carry out omnidirectional shock attenuation buffering to electrical equipment, reduce the vibrations that the operation during operation in installation and later stage of electrical equipment produced and transmit for the inner assembly, avoid shaking altogether.

The mounting frame comprises a pair of horizontal rods and a connecting beam, the horizontal rods are arranged on two sides of the length direction of the connecting plate, the connecting beam is connected between the horizontal rods, the connecting beam is parallel to the connecting beam and perpendicular to the connecting beam, the clamping device and the driving device are lifted, and a heat dissipation space and a movement space of the driving device are reserved.

The clamping device comprises a sliding rail arranged on the pair of horizontal rods and a pair of sliding parts connected to the sliding rail in a sliding mode, and the pair of sliding parts are matched with the sliding rail to finish approaching or separating of the pair of sliding parts, so that clamping and fixing of the electrical equipment are achieved.

Wherein the driving device is formed on the connecting plate between the pair of sliding pieces, and the driving device is arranged to provide power output for controlling the movement of the pair of sliding pieces on the sliding rails.

Wherein, rotating device takes shape on a pair of slider, can drive the electrical equipment who has fixed through the rotating device who sets up and carry out the angle rotation to later stage maintenance for the workman provides convenient operation.

As a preferable scheme of the present invention, each of the sliding members includes a sliding block slidably connected to the sliding rail, a U-shaped plate is installed between upper surfaces of the sliding blocks, a vertical plate is vertically installed on an outer side of the U-shaped plate, and a pair of first connection plates are installed on a vertical common plane of the U-shaped plate and the vertical plate.

As a preferable scheme of the present invention, the driving device includes a shaft seat installed at a center of the connecting plate, and a pair of pushing cylinders located at both sides of the shaft seat, a rotating shaft is vertically and rotatably connected in the shaft seat, a connecting plate is connected to an upper end of the rotating shaft, a pair of connecting arms are rotatably connected to both sides of an upper surface of the connecting plate through a pin shaft, and the other ends of the pair of connecting arms are respectively connected to upper surfaces of a pair of U-shaped plates.

In a preferred embodiment of the present invention, a pair of the pushing cylinders are fixedly mounted on the connecting beam at a side thereof away from the axle seat through cylinder seats, and a movable end of each of the pushing cylinders is connected to a lower surface of the U-shaped plate.

As a preferable scheme of the present invention, the rotating device includes a rotating motor installed on the vertical plate on one side and an auxiliary shaft located on the vertical plate on the other side, an output end of the rotating motor and one end of the auxiliary shaft both penetrate through the vertical plate, and the penetrating ends are both connected with an L-shaped clamp plate, and a pair of second fixing plates is fixedly installed on a common vertical surface of the L-shaped clamp plate.

As a preferable scheme of the present invention, a pair of first telescopic rods are mounted on a horizontal plane and a vertical plane of each L-shaped splint, a moving plate is connected between the pair of first telescopic rods, and a first spring is sleeved on each first telescopic rod.

As a preferable scheme of the invention, the shock absorption seat comprises a bottom plate located below the connecting plate, a pair of first limiting grooves are formed in the upper surface of the bottom plate, two pairs of second limiting grooves are formed in the bottom plate located on two sides of the pair of first limiting grooves, guide rods are connected to the pair of first limiting grooves along the length direction, a second spring is coaxially sleeved on each pair of guide rods, second telescopic rods are vertically installed in the two pairs of second limiting grooves, a third spring is coaxially sleeved on each second telescopic rod, and the upper end face of each second telescopic rod and the connecting plate are installed together.

As a preferable scheme of the present invention, a pair of moving blocks are slidably connected to the guide rods located at both sides of the second spring, a first connecting lug is mounted on each of the pair of moving blocks, a pair of second connecting lugs is mounted on the lower surface of the connecting plate, and a support arm is rotatably connected between the first connecting lug and the second connecting lug through a pin.

The invention has the beneficial effects that:

1. according to the invention, the rotating motor is started, and the output end of the rotating motor and the auxiliary shaft drive the L-shaped clamping plate to rotate in an angle, so that convenient operation is provided for later maintenance of workers.

2. According to the invention, the electrical equipment is placed on the horizontal planes of the pair of L-shaped clamping plates, the pair of pushing cylinders is started, the output ends of the pushing cylinders pull the U-shaped plates to move, the pair of U-shaped plates are connected with the connecting plate through the connecting arms, when the pair of U-shaped plates approach each other, the pair of connecting arms are driven to push the connecting plate to rotate, and the rotating angles of the pair of pin shafts on the connecting plate are the same, so that the pair of U-shaped plates move at the same distance, the electrical equipment is always positioned at the center of the device, and the electrical equipment is rapidly fixed and detached through the opening and closing of the pair of L-shaped clamping plates.

3. The first telescopic rod, the moving plate and the first spring on the L-shaped clamping plate are matched to play a role in damping and heat dissipation on the electrical equipment, when the electrical equipment vibrates longitudinally, the connecting plate pushes the pair of moving blocks on the guide rod to mutually approach through the supporting arm to compress the second spring, the second spring absorbs vibration in the vertical direction when being compressed, and meanwhile, when the second spring vibrates vertically, the connecting plate compresses the third spring through the second telescopic rod to absorb and buffer the vibration, so that the vibration generated when the electrical equipment is installed and operates in the later period is reduced and transmitted to the internal components, and the common vibration is avoided.

Drawings

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

FIG. 2 is a schematic view of the shock mount of the present invention;

FIG. 3 is an enlarged view of the structure at A in FIG. 2 according to the present invention;

FIG. 4 is a schematic diagram of a portion of FIG. 1 according to the present invention;

FIG. 5 is an enlarged view of the structure at B in FIG. 1 according to the present invention;

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

In the figure: 1. a connector tile; 2. a shock absorbing seat; 201. a base plate; 202. a first limit groove; 203. a second limit groove; 204. a guide bar; 205. a second spring; 206. a second telescopic rod; 207. a third spring; 208. a motion block; 209. a first connecting lug; 210. a second engaging lug; 211. a support arm; 3. a mounting frame; 301. a horizontal bar; 302. a connecting beam; 4. a clamping device; 401. a slide rail; 402. a slider; 4021. a slider; 4022. a U-shaped plate; 4023. a vertical plate; 4024. a first connecting plate; 5. a drive device; 501. a shaft seat; 502. a push cylinder; 503. a rotating shaft; 504. a connecting plate; 505. a connecting arm; 6. a rotating device; 601. rotating the motor; 602. an auxiliary shaft; 603. an L-shaped splint; 604. a second fixing plate; 605. a first telescopic rod; 606. a motion plate; 607. a first spring.

Detailed Description

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Examples

Referring to fig. 1-2, an auxiliary device for electromechanical engineering electric power equipment includes: the connection plate 1, the shock absorption seat 2, the mounting frame 3, the clamping device 4, the driving device 5 and the rotating device 6.

Wherein, be located the lower surface mounting who links up fishplate bar 1 and have cushion socket 2, because electrical equipment when installing, still will ensure the stability of its installation in order to guarantee in addition to the fastness and the accuracy of installation, through cushion socket 2 that sets up in linking up fishplate bar 1 below, can carry out omnidirectional shock attenuation buffering to electrical equipment, reduce the vibrations that the operation during operation production in installation and later stage of electrical equipment produced and transmit for the inner assembly, avoid shaking altogether.

The mounting frame 3 comprises a pair of horizontal rods 301 arranged along two sides of the length direction of the connecting plate 1 and a connecting beam 302 connected between the pair of horizontal rods 301, the pair of connecting beams 302 are parallel to each other and perpendicular to the pair of horizontal rods 301, the clamping device 4 and the driving device 5 are lifted, and a heat dissipation space and a movement space of the driving device 5 are reserved.

The clamping device 4 comprises a slide rail 401 mounted on the pair of horizontal rods 301, and a pair of sliding members 402 slidably connected to the slide rail 401, and the pair of sliding members 402 are matched with the slide rail 401 to move closer to or away from each other, so as to clamp and fix the electrical equipment.

Wherein a driving device 5 is formed on the connector tile 1 between the pair of sliding members 402, and the driving device 5 is arranged to provide power output for controlling the movement of the pair of sliding members 402 on the sliding rail 401.

Wherein, rotating device 6 is formed on a pair of slider 402, can drive the electrical equipment that has fixed through the rotating device 6 that sets up and carry out the angle rotation to later stage maintenance for the workman provides convenient operation.

Specifically, referring to fig. 4, each sliding member 402 includes a sliding block 4021 slidably connected to the sliding rail 401, a U-shaped plate 4022 is installed between the upper surfaces of the sliding blocks 4021, preferably, four sliding blocks 4021 are provided, and two sliding blocks are slidably connected to a pair of sliding rails 401, so that the U-shaped plates 4022 are uniformly stressed during sliding, the pair of U-shaped plates 4022 are oppositely disposed at an opening, a vertical plate 4023 is vertically installed at the outer side of the U-shaped plate 4022, a ventilation notch for heat dissipation is formed in the vertical plate 4023, and a pair of first connection plates 4024 is installed on the vertical common plane between the U-shaped plate 4022 and the vertical plate 4023 to increase the strength of the joint surface.

Specifically, please refer to fig. 4, the driving device 5 includes a shaft seat 501 installed at the center of the connecting plate 1 and a pair of pushing cylinders 502 located at two sides of the shaft seat 501, the pair of pushing cylinders 502 are arranged in mirror symmetry, a rotating shaft 503 is vertically and rotatably connected in the shaft seat 501, a ball bearing is coaxially sleeved at one end of the rotating shaft 503 located in the shaft seat 501 to reduce friction and improve transmission efficiency, the upper end of the rotating shaft 503 is connected with a connecting plate 504, two sides of the upper surface of the connecting plate 504 are respectively and rotatably connected with a pair of connecting arms 505 through pin shafts, and the other ends of the pair of connecting arms 505 are respectively connected with the upper surfaces of the pair of U-shaped plates 4022.

Specifically, referring to fig. 5, a pair of pushing cylinders 502 are fixedly mounted on the connecting plate 1 on the side of the connecting beam 302 away from the shaft seat 501 through a cylinder seat, a movable end of each pushing cylinder 502 is connected with the lower surface of the U-shaped plate 4022, the pair of pushing cylinders 502 is provided as power output of the driving device 5, by starting the pair of pushing cylinders 502, the output end of the pushing cylinder 502 pulls the U-shaped plate 4022 to move, since the pair of U-shaped plates 4022 are connected with the connecting plate 504 through the connecting arm 505, when the pair of U-shaped plates 4022 approach each other, the pair of connecting arms 505 are driven to push the connecting plate 504 to rotate, and since the rotating angles of the pair of pins on the connecting plate 504 are the same, the pair of U-shaped plates 4022 move at the same distance, and the electrical device is always located at the center of the device.

Specifically, referring to fig. 1, the rotating device 6 includes a rotating motor 601 mounted on one side vertical plate 4023 and an auxiliary shaft 602 located on the other side vertical plate 4023, an output end of the rotating motor 601 and one end of the auxiliary shaft 602 both penetrate through the vertical plate 4023, and the penetrating end is connected to the L-shaped clamping plate 603, by starting the rotating motor 601, the output end of the rotating motor 601 and the auxiliary shaft 602 drive the L-shaped clamping plate 603 to rotate angularly, and a pair of second fixing plates 604 is fixedly mounted on a common vertical surface of the L-shaped clamping plate 603, so as to increase the strength of the joint surface.

Specifically, referring to fig. 6, a pair of first telescopic rods 605 is installed on a horizontal plane and a vertical plane of each L-shaped clamping plate 603, a moving plate 606 is connected between the pair of first telescopic rods 605, the electrical equipment is placed on the horizontal plane of the pair of L-shaped clamping plates 603, a first spring 607 is sleeved on each first telescopic rod 605, so as to play a role in damping the electrical equipment, and meanwhile, a space is provided for heat dissipation of the electrical equipment by using a height difference between the moving plate 606 and the L-shaped clamping plates 603.

Specifically, referring to fig. 2, the cushion socket 2 includes a bottom plate 201 located below the joint plate 1, a pair of first limiting grooves 202 are formed in the upper surface of the bottom plate 201, two pairs of second limiting grooves 203 are formed in the bottom plate 201 located on two sides of the pair of first limiting grooves 202, the two pairs of second limiting grooves 203 are respectively located on two sides of the lower surface of the joint plate 1, guide rods 204 are respectively connected to the pair of first limiting grooves 202 along the length direction, a second spring 205 is coaxially sleeved on each of the pair of guide rods 204 and used for absorbing shock transversely, second telescopic rods 206 are vertically installed in the two pairs of second limiting grooves 203, a third spring 207 is coaxially sleeved on each of the second telescopic rods 206 and used for absorbing shock vertically, and the upper end surface of each of the second telescopic rod 206 is installed together with the joint plate 1.

Specifically, referring to fig. 2-3, a pair of moving blocks 208 are slidably connected to the guide rods 204 located at two sides of the second spring 205, a first connecting lug 209 is installed on each moving block 208, a pair of second connecting lugs 210 are installed on the lower surface of the connecting plate 1, a supporting arm 211 is rotatably connected between each first connecting lug 209 and each second connecting lug 210 through a pin, when the electrical device vibrates longitudinally, the connecting plate 1 pushes the pair of moving blocks 208 on the guide rods 204 to approach each other through the supporting arm 211 to compress the second spring 205, when the second spring 205 is compressed, the vertical vibration is absorbed, and when the electrical device vibrates vertically, the connecting plate 1 compresses the third spring 207 through the second telescopic rod 206, and the second telescopic rod 206 is arranged to guide the third spring 207.

The working principle is as follows:

when the device is installed, the electrical equipment is placed on the horizontal plane of the pair of L-shaped clamping plates 603, the pair of pushing cylinders 502 is started, the output ends of the pushing cylinders 502 pull the U-shaped plates 4022 to move, as the pair of U-shaped plates 4022 are connected with the connecting plate 504 through the connecting arm 505, when the pair of U-shaped plates 4022 are close to each other, the pair of connecting arms 505 are driven to push the connecting plate 504 to rotate, as the rotating angles of the pair of pin shafts on the connecting plate 504 are the same, the moving distances of the pair of U-shaped plates 4022 are the same, the electrical equipment is always positioned at the center of the device, after the electrical equipment is fixed, the first telescopic rods 605, the moving plates 606 and the first springs 607 on the L-shaped clamping plates 603 are matched to play a role in damping and heat dissipation for the electrical equipment, when the electrical equipment generates longitudinal vibration, the connecting plate 1 pushes the pair of moving blocks 208 on the guide rod 204 to close to each other through the supporting arms 211 to compress the second springs 205, when the second spring 205 is compressed, the vibration in the up-and-down direction is absorbed, and when the second spring is vibrated up and down, the connecting plate 1 compresses the third spring 207 through the second telescopic rod 206 to absorb and buffer, so that the resonance is avoided;

during the maintenance, start rotating motor 601, the output that rotates motor 601 drives L shape splint 603 with auxiliary shaft 602 and carries out the angle rotation to later stage maintenance for the workman provides convenient operation.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims

1. An electromechanical engineering electrical equipment auxiliary device, characterized by comprising:

the connecting plate (1) is of a rectangular plate-shaped structure, and a damping seat (2) is mounted on the lower surface of the connecting plate (1);

the mounting rack (3) is arranged above the connecting plate (1), and the mounting rack (3) comprises a pair of horizontal rods (301) arranged along two sides of the length direction of the connecting plate (1) and a connecting beam (302) connected between the pair of horizontal rods (301);

the clamping device (4) is arranged on the mounting rack (3) in a sliding mode, the clamping device (4) comprises a sliding rail (401) arranged on a pair of horizontal rods (301) and a pair of sliding pieces (402) connected to the sliding rail (401) in a sliding mode, each sliding piece (402) comprises a sliding block (4021) connected to the sliding rail (401) in a sliding mode, a U-shaped plate (4022) is installed between the upper surfaces of the sliding blocks (4021), a vertical plate (4023) is vertically installed on the outer side of the U-shaped plate (4022), and a pair of first connecting plates (4024) are installed on the vertical common plane of the U-shaped plate (4022) and the vertical plate (4023);

a driving means (5), said driving means (5) being formed on the splice plate (1) between the pair of slides (402) for driving the gripping movement of the gripping means (4);

and the rotating device (6) is formed on the first connecting plate (4024) and is used for rotatably disassembling the clamped power equipment.

2. An electromechanical engineering power equipment auxiliary device according to claim 2, characterized in that: drive arrangement (5) are including installing axle bed (501) of linking up fishplate bar (1) center department and a pair of push cylinder (502) that are located axle bed (501) both sides, perpendicular rotation is connected with pivot (503) in axle bed (501), pivot (503) upper end is rotated and is connected with connecting plate (504), the both sides of connecting plate (504) upper surface all are connected with a pair of linking arm (505) through the round pin hub rotation, and is a pair of the other end of linking arm (505) is in the same place with a pair of U-shaped board (4022) upper surface connection respectively.

3. An electromechanical engineering power equipment auxiliary device according to claim 3, characterized in that: the pair of pushing cylinders (502) are fixedly arranged on the connecting beam (302) far away from the connecting plate (1) on one side of the shaft seat (501) through cylinder seats, and the movable end of each pushing cylinder (502) is connected with the lower surface of the U-shaped plate (4022).

4. An electromechanical engineering power equipment auxiliary device according to claim 2, characterized in that: the rotating device (6) comprises a rotating motor (601) arranged on a side vertical plate (4023) and an auxiliary shaft (602) positioned on the other side vertical plate (4023), the output end of the rotating motor (601) and one end of the auxiliary shaft (602) penetrate through the side vertical plate (4023), an L-shaped clamping plate (603) is connected to one end of the penetrating end, and a pair of second fixing plates (604) are fixedly arranged on a common vertical surface of the L-shaped clamping plate (603).

5. An auxiliary device of electromechanical engineering electric equipment according to claim 5, characterized in that: a pair of first telescopic rods (605) is mounted on the horizontal plane and the vertical plane of each L-shaped clamping plate (603), a moving plate (606) is connected between the pair of first telescopic rods (605), and a first spring (607) is sleeved on each first telescopic rod (605).

6. The auxiliary device of electromechanical engineering electric equipment according to claim 1, characterized in that: shock attenuation seat (2) are including bottom plate (201) that is located linkage plate (1) below, bottom plate (201) upper surface is opened there is a pair of first spacing groove (202), is located to open on bottom plate (201) of a pair of first spacing groove (202) both sides has two pairs of second spacing grooves (203), and is a pair of all be connected with guide arm (204), a pair of along length direction in first spacing groove (202) all coaxial cover is equipped with second spring (205) on guide arm (204), two pairs all install second telescopic link (206), each perpendicularly in second spacing groove (203) all coaxial cover is equipped with third spring (207) on second telescopic link (206), and the up end of second telescopic link (206) is installed together with linkage plate (1).

7. The auxiliary device of electromechanical engineering electric equipment according to claim 6, characterized in that: be located sliding connection has a pair of motion piece (208) on guide arm (204) of second spring (205) both sides, and is a pair of install first engaging lug (209) on motion piece (208), be located the lower surface mounting who links up fishplate bar (1) and have second engaging lug (210), be connected with support arm (211) through the round pin axle rotation between first engaging lug (209) and second engaging lug (210).