阅读说明：本技术 一种机电设备的减震安装结构 (Shock attenuation mounting structure of electromechanical device ) 是由 彭加山 彭晓芳 于 2019-10-30 设计创作，主要内容包括：本发明涉及机电设备安装领域,具体公开一种机电设备的减震安装结构,包括安装座以及拆装式安装在所述安装座上的机电设备本体,所述安装座具有容纳机电设备本体的安装槽,所述安装槽的底部具有对机电设备本体起缓冲支撑作用的第一缓冲机构,所述安装槽的侧部具有对机电设备本体起缓冲支撑作用的第二缓冲机构。本发明实施例提供的减震安装结构方便对机电设备本体的快速拆装；且通过第一缓冲机构和第二缓冲机构的设置,能够对安装在安装槽内的机电设备本体起到良好的缓冲支撑效果。(The invention relates to the field of electromechanical equipment installation, and particularly discloses a shock absorption installation structure of electromechanical equipment, which comprises an installation seat and an electromechanical equipment body which is detachably installed on the installation seat, wherein the installation seat is provided with an installation groove for accommodating the electromechanical equipment body, the bottom of the installation groove is provided with a first buffer mechanism for buffering and supporting the electromechanical equipment body, and the side part of the installation groove is provided with a second buffer mechanism for buffering and supporting the electromechanical equipment body. The shock absorption mounting structure provided by the embodiment of the invention is convenient for quick assembly and disassembly of the electromechanical device body; and through the arrangement of the first buffer mechanism and the second buffer mechanism, the electromechanical device body arranged in the mounting groove can be well buffered and supported.)

1. The shock absorption mounting structure of the electromechanical equipment is characterized by comprising a mounting seat (2) and an electromechanical equipment body (1) which is detachably mounted on the mounting seat (2), wherein the mounting seat (2) is provided with a mounting groove (5) for accommodating the electromechanical equipment body (1), the bottom of the mounting groove (5) is provided with a first buffering mechanism for buffering and supporting the electromechanical equipment body (1), and the side part of the mounting groove (5) is provided with a second buffering mechanism for buffering and supporting the electromechanical equipment body (1);

the second buffer mechanism comprises a supporting vertical rod (9) fixedly installed in a side plate of the installation groove (5), a buffer supporting seat (12) which is sleeved on the supporting vertical rod (9) in an up-and-down sliding manner, and an upper vertical supporting spring (10) and a lower vertical supporting spring (11) which are sleeved on the supporting vertical rod (9) and are respectively positioned on the upper side and the lower side of the buffer supporting seat (12);

and a supporting and locking piece for locking and installing the electromechanical equipment body (1) arranged in the installation groove (5) is arranged on the buffering support seat (12).

2. The shock-absorbing mounting structure of an electromechanical device according to claim 1, wherein said first buffer mechanism includes a placing plate (6) for supporting a bottom of said electromechanical device body (1); the first buffer mechanism also comprises buffer components for supporting the bottoms of the two sides of the placing plate (6).

3. The shock-absorbing mounting structure of electromechanical equipment according to claim 2, wherein said buffer assembly comprises a transverse buffer cavity (16) provided on the bottom plate of said mounting groove (5), a transverse support cross bar (19) is provided in the inner fixing frame of the transverse buffer cavity (16), said buffer assembly further comprises two support sliding sleeves (17) slidably sleeved on said transverse support cross bar (19), said two support sliding sleeves (17) are supported and connected with the inner walls of the two ends of said transverse buffer cavity (16) through a transverse buffer spring (18), said buffer assembly further comprises two support connecting rods (15) connected with the bottom surface of said placing plate (6) through a hinge mode, and said two support connecting rods (15) are respectively hinged with said two support sliding sleeves (17).

4. The shock-absorbing mounting structure of electromechanical device according to any one of claims 1 to 3, wherein said support locking member comprises a receiving cavity (20) opened on said buffer support base (12), an elastic support member is rotatably disposed in said receiving cavity (20), and a position-limiting protrusion (25) for limiting the position of said elastic support member is further disposed on the inner wall of said receiving cavity (20).

5. The shock-absorbing mounting structure of the electromechanical device according to claim 4, wherein the elastic supporting member is provided with a locking block (14), the locking block (14) is a prism block structure with an inclined surface, and the outer wall of the electromechanical device body (1) is provided with a locking groove (13) matched with the locking block (14).

6. The shock-absorbing mounting structure of an electromechanical device according to claim 5, wherein said buffer support base (12) is further provided with an adjusting portion for adjusting the orientation of the inclined surface of said locking block (14).

7. The shock-absorbing mounting structure of electromechanical equipment according to claim 6, wherein said elastic supporting member comprises a rotating sleeve (21) rotatably disposed in said accommodating cavity (20), said rotating sleeve (21) is provided with a shaped slider (22) in a radial sliding manner, said shaped slider (22) is in supporting connection with an inner wall of one end of said rotating sleeve (21) through a first compression spring (23), said locking block (14) is fixedly mounted with a support column (24), and another end of said first compression spring (23) extends into said rotating sleeve (21) and is fixedly connected with said shaped slider (22); the adjustment part is connected with a rotating sleeve (21) of the elastic support.

8. The shock-absorbing mounting structure of electromechanical device according to claim 7, wherein said adjusting portion comprises an adjusting rod (27) rotatably connected to said buffer support base (12), an end portion of said adjusting rod (27) extending into said accommodating cavity (20) is fixedly connected to a shaft surface of said rotating sleeve (21) in said elastic support member, and said adjusting portion further comprises an adjusting disk (26) radially slidably sleeved on said adjusting rod (27).

9. The shock-absorbing mounting structure of electromechanical equipment according to claim 8, wherein an anti-drop block (29) is further fixedly mounted at an outer end of the adjusting rod (27), and the anti-drop block (29) is connected with the adjusting disk (26) through a second compression spring (28) sleeved on the adjusting rod (27); the coaxial fixed mounting in surface of adjustment disk (26) has annular dogtooth (33), coaxial fixed mounting have on the outer wall of buffering supporting seat (12) with fixed disk (31) that adjustment disk (26) are relative, coaxial seted up on fixed disk (31) with annular tooth's socket (32) of annular dogtooth (33) looks adaptation.

Technical Field

The invention relates to the field of electromechanical equipment installation, in particular to a damping installation structure of electromechanical equipment.

Background

Electromechanical device generally indicates machinery, electrical apparatus and electric automation equipment, in fields such as production, processing, often can adopt a large amount of electromechanical device to carry out various production, processing or monitoring operation, when placing electromechanical device, electromechanical device is direct placement subaerial mostly, subaerial electromechanical device does not utilize corresponding damping device, make electromechanical device receive the shock influence on ground, be unfavorable for electromechanical device's safe and stable operation, therefore, the market urgently need develop an electromechanical device's shock attenuation mounting structure and help people to solve current problem.

Disclosure of Invention

The present invention is directed to a shock-absorbing mounting structure of an electromechanical device to solve the above-mentioned problems of the background art.

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

a shock absorption mounting structure of electromechanical equipment comprises a mounting seat and an electromechanical equipment body which is detachably mounted on the mounting seat, wherein the mounting seat is provided with a mounting groove for accommodating the electromechanical equipment body, the bottom of the mounting groove is provided with a first buffer mechanism for buffering and supporting the electromechanical equipment body, and the side part of the mounting groove is provided with a second buffer mechanism for buffering and supporting the electromechanical equipment body;

the second buffer mechanism comprises a supporting vertical rod fixedly installed in the side plate of the installation groove, a buffer supporting seat which is sleeved on the supporting vertical rod in an up-and-down sliding manner, and an upper vertical supporting spring and a lower vertical supporting spring which are sleeved on the supporting vertical rod and are respectively positioned on the upper side and the lower side of the buffer supporting seat; the side plates of the mounting groove are respectively provided with an upper supporting groove and a lower supporting groove, wherein the top end of the supporting vertical rod is fixedly mounted in the upper supporting groove, and the bottom end of the supporting vertical rod is fixedly mounted in the lower supporting groove;

and the buffer supporting seat is provided with a supporting locking piece for locking and installing the electromechanical equipment body arranged in the installation groove.

As a further scheme of the invention: the first buffer mechanism comprises a placing plate which plays a role in supporting the bottom of the electromechanical device body; the first buffer mechanism further comprises a buffer assembly which is used for supporting the bottoms of the two sides of the placing plate, the buffer assembly comprises a transverse buffer cavity arranged on the bottom plate of the mounting groove, a transverse supporting transverse rod is arranged on a fixing frame in the transverse buffer cavity, the buffer assembly further comprises a sliding sleeve arranged on two supporting sliding sleeves on the transverse supporting transverse rod, the two supporting sliding sleeves are connected with the inner walls of the two ends of the transverse buffer cavity through supporting of transverse buffer springs, the buffer assembly further comprises two supporting connecting rods which are connected with the bottom surface of the placing plate in a hinged mode, and the two supporting connecting rods are respectively hinged with the two supporting sliding sleeves.

As a further scheme of the invention: the supporting locking piece comprises a containing cavity arranged on the buffering supporting seat, an elastic supporting piece is arranged in the containing cavity in a rotating mode, and a limiting protrusion limiting the position of the elastic supporting piece is further arranged on the inner wall of the containing cavity.

As a further scheme of the invention: the elastic support piece is provided with a locking block on an upper frame, the locking block is of a prism block structure with an inclined plane, and the outer wall of the electromechanical device body is provided with a locking groove matched with the locking block.

As a further scheme of the invention: the buffer support seat is also provided with an adjusting part for adjusting the orientation of the upper inclined surface of the locking block.

As a further scheme of the invention: the elastic supporting piece comprises a rotating sleeve rotatably arranged in the accommodating cavity, a special-shaped sliding block is arranged in the rotating sleeve in a sliding mode, the special-shaped sliding block is connected with the inner wall of one end of the rotating sleeve in a supporting mode through a first compression spring, a supporting column is fixedly arranged on the locking block, and the other end of the first compression spring extends into the rotating sleeve and then is fixedly connected with the special-shaped sliding block; the adjusting portion is connected with the rotating sleeve of the elastic supporting member.

As a further scheme of the invention: the adjusting part comprises an adjusting rod which is rotatably connected to the buffering supporting seat and extends to the end part of the adjusting rod in the accommodating cavity and is fixedly connected with the middle shaft surface of the rotating sleeve in the elastic supporting piece, the adjusting part further comprises an adjusting disc which is sleeved with a radial sliding sleeve and is arranged on the adjusting rod, the adjusting disc is driven to rotate by operating the adjusting disc, and the orientation of the inclined surface of the locking block can be adjusted.

As a further scheme of the invention: the outer end of the adjusting rod is also fixedly provided with an anti-falling block, and the anti-falling block is connected with the adjusting disc through a second compression spring sleeved on the adjusting rod; the coaxial fixed mounting in surface of adjustment disk has annular dogtooth, coaxial fixed mounting on the outer wall of buffering supporting seat have with the fixed disk that the adjustment disk is relative, coaxial seted up on the fixed disk with the annular tooth's socket of annular dogtooth looks adaptation under second compression spring's elastic support effect, can promote in annular dogtooth embedding annular tooth's socket to reach the rotatory effect of restriction regulation pole.

Compared with the prior art, in the damping mounting structure provided by the embodiment of the invention, the inclined surface of the locking block is adjusted to face upwards by operating the adjusting part, when the electromechanical device body is pushed into the mounting groove, the bottom end edge of the electromechanical device body slides along the inclined surface of the locking block, when the electromechanical device body continues to move downwards, the locking block can be pushed to retract into the accommodating cavity until the locking block is aligned with the locking groove, the locking block can be pushed to be embedded into the locking groove under the action of the elastic force of the elastic supporting part, and at the moment, because the bottom surface of the locking block is a plane, the electromechanical device body cannot be pulled out of the mounting groove, namely the electromechanical device body is mounted; and through the arrangement of the first buffer mechanism and the second buffer mechanism, the electromechanical device body arranged in the mounting groove can be well buffered and supported.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention.

Fig. 1 is a schematic structural diagram of a shock-absorbing mounting structure of an electromechanical device according to an embodiment of the present invention.

Fig. 2 is an enlarged schematic view of a portion a in fig. 1.

Fig. 3 is a schematic structural diagram of a support lock in a shock-absorbing mounting structure of an electromechanical device according to an embodiment of the present invention.

Fig. 4 is an enlarged structural view of a portion B in fig. 3.

In the figure: 1-electromechanical device body, 2-mounting seat, 3-supporting baseplate, 4-reinforcing block, 5-mounting groove, 6-placing plate, 7-upper supporting groove, 8-lower supporting groove, 9-supporting vertical rod, 10-upper vertical supporting spring, 11-lower vertical supporting spring, 12-buffering supporting seat, 13-locking groove, 14-locking block, 15-supporting connecting rod, 16-transverse buffering cavity, 17-supporting sliding sleeve, 18-transverse buffering spring, 19-transverse supporting cross rod, 20-containing cavity, 21-rotating sleeve, 22-special-shaped slider, 23-first compression spring, 24-pillar, 25-limiting projection, 26-adjusting disk, 27-adjusting rod, 28-second compression spring, 29-anti-drop block, 30-limiting convex strip, 31-fixing disc, 32-annular tooth groove and 33-annular convex tooth.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present invention more clearly apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.