LU500583B1 - A shock absorbing device for electromechanical devices - Google Patents

Abstract

A shock absorbing device for electromechanical equipment, comprising an electromechanical equipment body, the bottom of the electromechanical equipment body being fixed to a mounting plate, the guide posts being symmetrically arranged on both sides of the mounting plate, the guide post being laterally provided with a first sliding groove, the inner wall the first slide groove slidably connected to a first slide block, the two first slide blocks being fixed to the side of the mounting plate, the lower surface of the mounting plate being fixed to a first buffer assembly and a second buffer assembly, respectively. The device solves the problem that the existing shock absorbing device of electromechanical equipment has poor stability and shock absorbing effect, which reduces the lifespan of electromechanical equipment. The invention has the advantages of reasonable structural design, simple operation and convenient use, effectively reduces the shock force generated by the electromechanical equipment, greatly improves the stability of the electromechanical equipment, achieves good shock absorption effect.

Description

DESCRIPTION 0500583 A shock absorbing device for electromechanical devices Technical field The invention relates to the technical field of electromechanical devices, in particular a shock absorbing device for electromechanical devices. Background Art Electromechanical equipment generally refers to mechanical, electrical, and automated equipment. In the construction industry, it mostly refers to the common name of machinery and piping equipment other than geotechnical, carpentry, rebar, and muddy water. Unlike hardware, electromechanical devices are mostly finished products that can implement specific functions. With the continuous improvement of people's living standards, people have more and more needs for electromechanical devices in their daily lives. From vehicles to various household appliances, computers and printers, they have become indispensable electromechanical products in people's lives. Advanced electromechanical equipment not only can greatly improve labor productivity, reduce labor intensity, improve the production environment and complete tasks that cannot be done by manpower, but also, as one of the national industrial bases, have a direct and important impact on the development of the whole national economy and the improvement of science, technology and national defense strength, and they are also an important symbol to measure a country's scientific and technological level and overall national strength.

Electromechanical devices vibrate slightly when working. If not effectively dampened, it will significantly shorten the life of electromechanical devices and cause severe noise pollution. In most cases, electromechanical equipment is placed directly on the floor, and its underside is generally in direct contact with the floor, or a pad is simply placed under the equipment's foot frame to prevent the machine tool from crushing and crushing the floor. However, the existing shock absorbing device for mechanical equipment has poor stability and shock absorbing effect, which reduces the lifespan of electromechanical equipment.

SUMMARY OF THE INVENTION The invention aims to provide a shock absorbing device for electromechanical equipment, which aims to solve the problems of poor stability, poor shock absorbing effect and reduction in life of electromechanical equipment.

In order to achieve the above purpose, the invention provides the following technical solution: A shock absorbing device for electromechanical equipment comprises an electromechanical equipment body, the bottom of the electromechanical equipment body is fixedly connected to a mounting plate, guide columns are symmetrically arranged on both sides of the mounting plate, a first slide groove is arranged laterally of the guide post, a first slide block is slidably connected to the inner wall of the first slide groove, the two first slide blocks are fixed to the side of the mounting plate, the underside of the mounting plate is provided with a first buffer assembly or a second buffer arrangement is firmly connected, wherein the second buffer arrangement is firmly connected to a fixedly connected to the guide column mounting plate.

As a further solution of the invention, the electromechanical device body is fixedly connected to the mounting plate by screws, the bottom of the guide column being fixedly connected to a foot pad.

As a further solution of the invention, the first buffer assembly comprises first attachment seats symmetrically and rigidly connected to the underside of the mounting plate, the first attachment seat being articulated to a first connecting rod, the other end of the first connecting rod being articulated to a second attachment seat, which is fixedly connected to the tie rod, the first connecting rod is provided with a first through hole, the pin shaft is slidably connected to the inner wall of the first through hole, the pin shaft is fixedly connected to a movable rod, the bottom of the movable rod having a sliding sleeve, the sliding sleeve being slidably connected to a sliding rod, both ends of the sliding rod being fixed to the guide post, a first spring being arranged on both sides of the sliding rod, the first spring on the outside of the sliding rod is sheathed, with both ends firmly connected to the guide column and the sliding sleeve.

As a further solution of the invention, the slide bar and the mounting plate are each alternately connected to the guide column.

As a further solution of the invention, the bottoms of the two sliding sleeves are each fixed to a second rotating shaft, with a box body disposed below the second rotating shaft, the inside of the box body being a hollow structure, with a second through hole slidably communicating with the second rotating shaft is arranged above the box body, the lower part of the second rotating shaft extends to the inside of the box body through the second through hole, and the outside is fixedly connected to the first gear, the first gear meshing with a second gear wherein the second gear is fixedly connected to a third rotating shaft, the top and bottom of the third rotating shaft being pivoted to a first limit rod and a second limit rod through bearings, respectively, the other end of the first limit rod being pivoted to the second rotating shaft through bearings is, where the between eite limit rod is articulated to a fourth rotary shaft via bearings, a third gear meshing with the second gear being rigidly connected to the outside of the fourth rotary shaft, the side of the fourth rotary shaft facing away from the third gear being rigidly connected to a bearing seat is fixedly connected to the bottom surface of the box body, with a thin rope wound around the surface of the fourth rotary shaft, the other end of the thin rope being fixedly connected to a moving block slidably connected to the box body, the Side of the moving block is fixed to a third spring which is fixed to the side wall of the box body.

As a further solution of the invention, the bottom surface of the box body is provided with a second slide groove, and a second slide block fixedly connected to the bottom surface of the movable block is slidably connected to the inner wall of the second slide groove.

As a further solution of the invention, the second buffer assembly comprises a third mounting seat fixedly connected to the underside of the mounting plate, the second connecting rods being symmetrically articulated to the third mounting seat, the other end of the second connecting rod being articulated to a first rotary shaft, wherein the first rotary shaft is articulated to a third connecting rod and a piston rod respectively, the other ends of the two third connecting rods being articulated to a fourth fixing seat integral with the fixing plate, the piston rod passing through the cylinder and extending inside the Cylinder extends, the end of the piston rod being fixed to a piston which is slidably connected to the inner wall of the cylinder, a second spring being fixed between the two pistons.

Compared to the prior art, the invention has the following advantageous effects: In this device, the electromechanical device body is attached to the mounting plate. The impact force generated during the operation of the electromechanical device body drives the mounting plate and the first slide block to slide down along the first slide groove in the guide post, using the first buffer assembly and the second buffer assembly to buffer them to achieve the effect of damping the electromechanical devices, and then effectively reducing the impact force generated by the electromechanical devices. Therefore, the stability of the electromechanical devices is greatly improved, a good shock absorption effect is achieved, the life of the electromechanical devices is prolonged, the device cost is reduced, and the economic benefit is improved.

Description of Drawings Fig. 1 is a structural diagram of a shock absorbing device for electromechanical equipment; Fig. 2 is an internal sectional view of the cylinder; Fig. 3 is an internal sectional view of the box body; Fig. 4 is an A-direction view in Fig. 3.

List of reference symbols: 1. Electromechanical device body; 2. mounting plate; 3. First Sliding Block; 4. First sliding groove; 5. guide pillar; 6. First mounting seat; 7. First

connecting rod; 8. First through hole; 9. Second mounting seat; 10. pin shaft; 11. Movable rod; 12. Sliding sleeve; 13. Sliding rod, 14. First spring, 15. Third mounting seat; 16. Second connecting rod; 17. First rotary shaft; 18. Third connecting rod; 19. Fourth fastening seat; 20. Fixing plate; 21. piston rod; 22. piston; 23rd cylinder; 24. Second spring; 25. Second rotary shaft; 26. box body;27. Second through hole; 28. First Perimeter Bar; 29. First Gear; 30. Second Gear; 31. Third rotary shaft; 32. Second Boundary Bar; 33. Third Gear; 34. Fourth rotary shaft;

35. Thin rope; 36. bearing seat; 37. Movable block; 38. Second Sliding Block; 39. Second sliding groove; 40. Third spring.

Specific embodiment The technical solution of the present patent will be described in further detail in combination with specific embodiments.

Embodiments of the present patent are described in detail below. An example of the embodiment is shown in the accompanying figures, in which the same or similar legends throughout represent the same or similar elements or elements with the same or similar functions. The exemplary embodiments described below with reference to the attached figures are for the purpose of illustration and are used only for the interpretation of the present patent and cannot be understood as limiting the present patent.

Embodiment 1 Referring to Figs. 1-4, a shock absorbing device for electromechanical equipment in the embodiment of the invention comprises an electromechanical equipment body 1, the bottom of the electromechanical equipment body 1 being fixedly connected to a mounting plate 2, with guide columns 5 symmetrically provided on both sides of the mounting plate 2, with a first sliding groove 4 being arranged laterally of the guide column 5, with the first sliding block 3 being slidably connected to the inner wall of the first sliding groove 4, with the two first sliding blocks 3 being fixed to the side of the mounting plate 2, thereby characterized in that the underside of the mounting plate 2 is firmly connected to a first buffer arrangement or a second buffer arrangement, the second buffer arrangement being firmly connected to a fastening plate 20 firmly connected to the guide column 5 .

In the exemplary embodiment of the invention, the electromechanical device body 1 is fixed on the mounting plate 2 . The impact force generated during the operation of the electromechanical equipment body 1 drives the mounting plate 2 and the first slide block 3 to slide down along the first slide groove 4 in the tie bar 5, using the first buffer assembly and the second buffer assembly to buffer them , to achieve the effect of cushioning the electromechanical devices, and then effectively reduce the impact force generated by the electromechanical devices. Therefore, the stability of the electromechanical devices is greatly improved, a good shock absorption effect is achieved, the life of the electromechanical devices is prolonged, the device cost is reduced, and the economic benefit is improved. A mounting plate 20 is arranged to mount and support the second bumper assembly.

Embodiment 2 Referring to Fig. 1 as a preferred embodiment of the present invention, the electromechanical apparatus body 1 is fixed to the mounting plate 2 by screws, and the bottom of the tie bar 5 is fixed to a foot pad.

In the embodiment of the present invention, it is convenient to fix the electromechanical device body 1 and the mounting plate 2 to each other by screws, and it is convenient for disassembling and assembling. A foot pad is arranged to increase the contact area with the ground and achieve the function of shock absorption.

Embodiment 3 See Fig. 1 as a preferred embodiment of the present invention, the first buffer assembly comprises first mounting seats 6 symmetrically and rigidly connected to the underside of the mounting plate 2, the first mounting seat 6 being articulated with a first connecting rod 7, the other end of the first connecting rod 7 is articulated to a second mounting seat 9 fixedly connected to the guide column 5, the first connecting rod 7 being provided with a first through hole 8, the pin shaft 10 being slidably connected to the inner wall of the first through hole 8 , wherein the pin shaft 10 is fixedly connected to a movable rod 11, the bottom of the movable rod 11 is fixedly connected to a sliding sleeve 12, the sliding sleeve 12 is slidably connected to a sliding rod 13, both ends of the sliding rod 13 are fixedly connected to the Guide column 5 are connected, with an e The first spring 14 is disposed on both sides of the slide bar 13, the first spring 14 being sheathed on the outside of the slide bar 13, both ends of which are fixedly connected to the tie bar and the slide sleeve 12.

In the embodiment of the present invention, the impact force generated during the operation of the electromechanical device body 1 drives the mounting plate 2 to move downward. The first mounting seat 6 and the second mounting seat 9 drive the first connecting rod 7 to rotate and then drive the pin shaft 10 to rotate

Sliding with the first through hole 8 and then driving the moving rod 11 and the sliding sleeve 12 to move rightward along the sliding rod 13 drives the first spring 14 to deform, and the generated elastic potential energy acts on the Counteracting the impact force to achieve the effect of shock absorption.

Embodiment 4 Referring to Fig. 1, as a preferred embodiment of the present invention, the slide bar 13 and the mounting plate 20 are alternately connected to the tie bar, respectively.

In the embodiment of the present invention, the slide bar 13 and the mounting plate 20 are alternately connected to the tie bar 5 to prevent interference during the operation of the first buffer assembly and the second buffer assembly.

Embodiment 5 Referring to Fig. 1, 3, 4, as a preferred embodiment of the present invention, the bottoms of the two sliding sleeves 12 are each fixedly connected to a second rotating shaft, with a box body 26 disposed below the second rotating shaft 25, with the inside of the Box body 26 is a hollow structure with a second through hole 27 slidably connected to the second rotating shaft 25 disposed above the box body 26, with the lower part of the second rotating shaft 25 extending through the second through hole 27 to the inside of the box body 26 , and the outside is fixedly connected to the first gear 29, the first gear 29 meshing with a second gear 30, the second gear 30 being fixedly connected to a third rotating shaft 31, the top and bottom of the third rotating shaft 31 each with a first limiting rod 28 and a second limiting rod 32 via L ager are hinged,

the other end of the first limit rod 28 being pivoted to the second rotary shaft 25 through bearings, the second limit rod 32 being pivoted to a fourth rotary shaft 34 through bearings, a third gear 33 meshing with the second gear 30 being fixed is connected to the outside of the fourth rotating shaft 34, the side of the fourth rotating shaft 34 opposite to the third gear 33 being fixedly connected to a bearing seat 36 fixedly connected to the bottom surface of the box body 26, with a thin rope 35 around the surface of the fourth rotating shaft 34, the other end of the thin rope 35 being fixedly connected to a moving block 37 which is slidably connected to the box body 26, the side of the moving block 37 being fixedly connected to a third spring 40 which is fixed is connected to the side wall of the box body 26.

In the embodiment of the present invention, when the slide sleeve 12 moves rightward along the slide rod 13, it drives the second rotating shaft 25 to slide along the second through hole 27 in the box body 26, and then drives the first gear 29, the second gear 30 and the third gear 33 to rotate together, drives the fourth rotary shaft 34 to rotate to wind up the thin rope 35 and drives the moving block 37 to move and drives the third spring 40 begins to deform, and the generated elastic potential energy counteracts the impact force to achieve the effect of shock absorption. The first limit rod 28, the third rotary shaft 31 and the second limit rod 32 are arranged to fix and support the second gear 30 and ensure the stability of the movement of the first gear 29, the second gear 30 and the third gear 33. The bearing seat 36 is arranged to fix and support the third gear 33 and ensure its movement stability.

Example 6

See Fig. 3 as a preferred embodiment of the present invention, the bottom surface of the box body 26 is provided with a second sliding groove 39, and a second sliding block 38 fixed to the bottom surface of the movable block 37 is slidable with the inner wall of the second sliding groove 39 is connected.

In the embodiment of the present invention, the movable block 37 and the second sliding block 38 move along the second sliding groove 39 when winding the thin rope 35.

Embodiment 7 See Fig. 1-2 as a preferred embodiment of the present invention, the second buffer assembly comprises a third mounting seat 15 fixedly connected to the underside of the mounting plate 2, wherein the second connecting rods 16 are symmetrically hinged to the third mounting seat 15, wherein the other end of the second connecting rod 16 is articulated to a first rotary shaft 17, the first rotary shaft 17 being articulated to a third connecting rod 18 and a piston rod 21 respectively, the other ends of the two third connecting rods 18 being articulated to a fourth attachment seat 19, fixed to the mounting plate 20, the piston rod 21 passing through the cylinder 23 and extending to the interior of the cylinder 23, the end of the piston rod 21 being fixed to a piston 22 slidably connected to the inner wall of the cylinder 23 is connected, with a second spring 24 between between the two pistons 22 is firmly connected.

In the embodiment of the present invention, the impact force generated during the operation of the electromechanical device body 1 drives the mounting plate 2 to move downward. The third mounting seat 15 and the fourth mounting seat 19 drive the second connecting rod 16 and the third connecting rod 18 to rotate and then drive the piston rod 21 and the piston 22 to move inward along the cylinder 23 to release the second spring 24'. The second spring 24 deforms, and the generated elastic potential energy opposes the impact force to achieve the effect of shock absorption. The first rotating shaft 17 is arranged to connect the second connecting rod 16, the third connecting rod 18 and the piston rod 21 to ensure the movement stability of the three.

The working principle of the invention is as follows: The electromechanical device body 1 is fixed on the mounting plate 2. The impact force generated during the operation of the electromechanical equipment body 1 drives the mounting plate 2 and the first slide block 3 to slide down along the first slide groove 4 in the tie bar 5 . The first fixing seat 6 and the second fixing seat 9 drive the first connecting rod 7 to rotate and then drive the pin shaft 10 to slide with the first through hole 8 and then drive the moving rod 11 and the sliding sleeve 12 to move rightward along the Moving the slide rod 13 drives the first spring 14 to deform, and the generated elastic potential energy counteracts the impact force to achieve the effect of shock absorption. When the slide sleeve 12 moves rightward along the slide rod 13, it drives the second rotating shaft 25 to slide along the second through hole 27 in the box body 26, and then drives the first gear 29, the second gear 30 and the third gear 33 to rotate together, drives the fourth rotary shaft 34 to rotate to wind up the thin rope 35, drives the moving block 37 to move, and drives the third spring 40 to deform . The generated elastic potential energy counteracts the impact force, so to achieve the effect of shock absorption. When the mounting plate 2 moves down, the third mounting seat and the fourth mounting seat 19 drive the second connecting rod 16 and the third

Connecting rod 18 to rotate and then drive the piston rod 21 and piston 22 to move inward along the cylinder 23 to compress the second spring 24. The second spring 24 is deformed, and the generated elastic potential energy counteracts the impact force to achieve the shock absorbing effect, and then effectively reduce the impact force generated by the electromechanical device. Therefore, the stability of the electromechanical devices is greatly improved, a good shock absorption effect is achieved, the life of the electromechanical devices is prolonged, the device cost is reduced, and the economic benefit is improved.

The above is only the preferred embodiment of the present invention. It should be noted that a number of modifications and improvements can be made for those skilled in the art without departing from the concept of the present invention, which should also be construed as the scope of the invention. None of this will affect the working effect of the present invention and the practicability of the patent.

Claims (7)

N LU500583 PATENT CLAIMS 1. A shock absorbing device for electromechanical devices comprises an electromechanical device body (1), the underside of the electromechanical device body (1) being fixedly connected to a mounting plate (2), guide columns (5) being symmetrically arranged on both sides of the mounting plate (2). wherein a first sliding groove (4) is arranged laterally of the guide post (5), the first sliding block (3) being slidably connected to the inner wall of the first sliding groove (4), the two first sliding blocks (3) being connected to the side of the mounting plate (2) are firmly connected, characterized in that the underside of the mounting plate (2) is firmly connected to a first buffer arrangement or a second buffer arrangement, the second buffer arrangement being firmly connected to a fastening plate (20) firmly connected to the guide column (5). connected is. 2. A shock absorbing device for electromechanical equipment according to claim 1, characterized in that the electromechanical equipment body (1) is fixed to the mounting plate (2) by screws, the bottom of the guide post (5) being fixed to a foot pad. 3. A shock absorbing device for electromechanical equipment according to claim 1, characterized in that the first buffering arrangement comprises first mounting seats (6) symmetrically and rigidly connected to the underside of the mounting plate (2), the first mounting seat (6) having a first connecting rod (7) is articulated, the other end of the first connecting rod (7) being articulated to a second fixing seat (9) integral with the guide column (5), the first connecting rod (7) being provided with a first through hole ( 8), the pin shaft (10) being slidably connected to the inner wall of the first through hole (8), the pin shaft (10) being fixed to a movable rod (11), the bottom of the movable rod (11) with a sliding sleeve (12) is firmly connected, wherein the sliding sleeve (12) is slidably connected to a slide rod (13), both ends of the slide rod (13) fixed to the Fü guide column (5), with a first spring (14) being arranged on both sides of the slide bar (13), the first spring (14) being sheathed on the outside of the slide bar (13), with both ends fixed to the guide column (5) and the sliding sleeve (12) are connected. 4. A shock absorbing device for electromechanical equipment according to claim 3, characterized in that the slide rod (13) and the mounting plate (20) are connected to the guide post (5) alternately, respectively. 5. A shock absorbing device for electromechanical equipment according to claim 3, characterized in that the bottoms of the two sliding sleeves (12) are fixed to a second rotating shaft (25) respectively, and a box body (26) is arranged below the second rotating shaft (25). , wherein the inside of the box body (26) is a hollow structure, wherein a second through hole (27) slidably connected to the second rotary shaft (25) is arranged above the box body (26), the lower part of the second rotating shaft (25) extends through the second through hole (27) to the inside of the box body (26), and the outside is fixedly connected to the first gear (29), the first gear (29) meshing with a second gear (30). stands, wherein the second gear (30) is fixed to a third rotary shaft (31) the upper and lower sides of the third rotating shaft (31) being pivoted to a first limiting rod (28) and a second limiting rod (32) via bearings, respectively, the other end of the first limiting rod (28) being connected to the second rotating shaft ( 25) is bearing-pivoted, the second limit rod (32) being bearing-pivoted to a fourth rotary shaft (34), a third gear (33) meshing with the second gear (30) being fixed to the outside of the fourth rotary shaft (34), the third gear wheel (33) side of the fourth rotary shaft (34) being fixedly connected to a bearing seat (36) fixedly connected to the bottom surface of the box body (26), wherein a thin rope (35) is wound around the surface of the fourth rotary shaft (34), the other end of the thin rope (35) being fixedly connected to a movable block (37) slidably connected to the box body (26), wherein the page of the moving block (37) is integral with a third spring (40) integral with the side wall of the box body (26). 6. A shock absorbing device for electromechanical equipment according to claim 5, characterized in that the bottom surface of the box body (26) is provided with a second slide groove (39), and a second slide block (38) fixed to the bottom surface of the movable block (37 ) is slidably connected to the inner wall of the second sliding groove (39). A shock absorbing device for electromechanical equipment according to claim 1, characterized in that the second buffering arrangement comprises a third mounting seat (15) fixedly connected to the underside of the mounting plate (2), the second connecting rods (16) being symmetrically connected to the third mounting seat (15), the other end of the second connecting rod (16) being pivoted to a first pivot shaft (17), the first pivot shaft (17) being pivoted to a third connecting rod (18) or piston rod (21), the other ends of the two third connecting rods (18) being articulated to a fourth fixing seat (19) integral with the fixing plate (20), the piston rod (21) passing through the cylinder (23) and extending towards the inside of the cylinder (23), the end of the piston rod (21) being fixedly connected to a piston (22) which is slidably connected to the inner wall of the cylinder (23). unden, a second spring (24) being firmly connected between the two pistons (22).