CN216071858U - Floor is equipment translation device for surface - Google Patents

Abstract

The utility model provides a floor surface equipment translation device, which comprises two sliding frames, a translation piece, a supporting seat and a synchronous translation structure, wherein the two sliding frames are arranged on the two sliding frames; the carriage includes two vertical portions and a horizontal portion. The translation piece is connected to one horizontal part in a sliding manner and is connected with a synchronous driving assembly; the supporting seat is arranged below the other horizontal part in a sliding manner through the vertical adjusting structure; the synchronous translation structure is arranged between the translation piece and the supporting seat. When the device is used, firstly, the lifting place of the device is determined by moving the positions of the two sliding frames; then, the structure of the supporting seat is adjusted through the vertical adjusting structure, and the equipment is loaded on the surface of the supporting seat; and finally, the linear driving assembly drives the translation piece to move, and the translation piece drives the supporting seat to move, so that the equipment is translated. The floor surface equipment translation device provided by the utility model can effectively translate equipment on the floor surface, and the equipment cannot contact with the protruding structure in the translation process, so that the manpower is saved, and the translation efficiency of the equipment is improved.

Description

Floor is equipment translation device for surface

Technical Field

The utility model belongs to the technical field of equipment displacement, and particularly relates to an equipment translation device for a floor surface.

Background

In the high-rise building construction process, partial large-scale equipment needs to be moved among each layer, and the process comprises the following steps: firstly, lifting equipment outside a high-rise to the surface of the floor by a crane; the apparatus is then translated to a preset position by the constructor on the floor surface.

The inventor finds that when a constructor manually translates equipment, the ground is provided with protruding structures such as doorsills and protruding beams, and in order to avoid damaging the protruding structures, the constructor needs to lift the equipment to pass through; in the process, the equipment translation efficiency is influenced, and constructors are easy to trip over, so that the safety of the constructors is limited.

SUMMERY OF THE UTILITY MODEL

The embodiment of the utility model provides a floor surface equipment translation device, and aims to solve the technical problems that safety of constructors is limited and equipment translation efficiency is low due to the fact that a raised structure is arranged on the ground.

In order to achieve the purpose, the utility model adopts the technical scheme that:

there is provided a floor surface equipment translation device comprising:

the two sliding frames are arranged on the surface of the floor in a sliding manner along the length direction of the protruding structure and are respectively positioned on two sides of the protruding structure; the sliding frame comprises two vertical parts which are arranged on two sides of the protruding structure in a sliding mode and a horizontal part of which two ends are connected with the two vertical parts respectively;

the translation piece is connected to one of the horizontal parts in a sliding mode along the length direction of the horizontal parts and is connected with a linear driving assembly for driving the translation piece to translate;

the supporting seat is used for supporting equipment, is arranged below the other horizontal part in a sliding mode through a vertical adjusting structure, and has the same sliding direction as that of the translation piece; and

the synchronous translation structure is arranged between the translation piece and the supporting seat; when the translation piece moves, the translation piece drives the supporting seat to move through the synchronous translation structure.

In one possible implementation, the vertical adjustment structure includes:

the guide plates are arranged below the horizontal part at intervals in the vertical direction, and two ends of each guide plate are respectively connected with the two vertical parts;

the inserting plate is suitable for being inserted between two adjacent guide plates, one end of the inserting plate is provided with a limiting plate which is connected with the supporting seat and is abutted against the side surface of the guide plate, and the other end of the inserting plate extends out of the guide plate and is provided with a positioning hole which penetrates through the inserting plate along the vertical direction; and

the positioning plate is suitable for being inserted into the positioning hole from top to bottom, and the top end of the positioning plate is provided with an abutting part used for being supported on the upper surface of the insertion plate;

the adjacent two guide plates, the positioning plate and the limiting plate clamp the guide plates to limit the insertion plate to move along the direction perpendicular to the sliding direction of the supporting seat.

In one possible implementation, the synchronous translation structure includes:

the strip-shaped hole penetrates through the supporting seat along the vertical direction and is arranged in an extending mode along the sliding direction of the sliding frame; and

the connecting arm is arranged on the bottom surface of the translation piece in a swinging mode, and the swinging shaft is arranged along the sliding direction of the translation piece in the swinging mode; the connecting arm is suitable for swinging until the lower end of the connecting arm is inserted into the strip-shaped hole;

when the translation piece slides, the connecting arm is abutted to the strip-shaped hole to drive the supporting seat to move.

In a possible implementation manner, an anti-drop bolt is connected to the swing end face of the connecting arm in a threaded manner, and the anti-drop bolt can be screwed in the axial direction of the connecting arm;

the periphery wall of anticreep bolt has the first ring flange that outwards extends the setting, first ring flange be suitable for with the bottom surface butt of supporting seat, in order to restrict the linking arm breaks away from the bar hole.

In a possible implementation manner, the bottom surface of the horizontal part connected with the translation piece is provided with a T-shaped groove extending along the length direction of the horizontal part, and the upper surface of the translation piece is provided with a sliding block matched and connected with the T-shaped groove.

In one possible implementation, the linear drive assembly includes:

the driving screw is in threaded connection with the translation piece, and the axial direction of the driving screw is parallel to the length direction of the horizontal part; one end of the driving screw is rotatably connected with one of the vertical parts, and the other end of the driving screw penetrates through the other vertical part and extends out of the other vertical part; and

and the rotating motor is fixedly arranged on the vertical part, and the power output end is coaxially connected with the extending end of the driving screw rod.

In a possible implementation manner, a handle is rotatably arranged on the vertical part, and the rotating axial direction is parallel to the axial direction of the driving screw rod;

the handle is coaxially connected with a first gear, the driving screw is coaxially connected with a second gear, and a transmission belt is arranged between the handle and the driving screw; the transmission belt is wound on the peripheries of the first gear and the second gear, and a plurality of convex teeth arranged at intervals along the length direction of the transmission belt are arranged on the inner wall of the transmission belt.

In a possible implementation manner, a sliding piece is arranged on the horizontal part connected with the supporting seat in a sliding manner along the length direction of the horizontal part, and the sliding piece is provided with a jack penetrating along the sliding direction of the sliding frame; the translation piece is provided with a balance arm which extends towards the support seat and is suitable for being inserted into the insertion hole, and the extending end of the balance arm is provided with a second flange plate used for being abutted against the sliding piece.

In a possible implementation manner, a distance adjusting structure is arranged between the two sliding frames, and the distance adjusting structure comprises:

the axial direction of the double-end screw is parallel to the sliding direction of the sliding frame; the double-end screw has two screw thread portions opposite in thread direction, two the screw thread portion respectively with two carriage threaded connection is used for driving two the carriage removes or removes dorsad in opposite directions.

In one possible implementation, the floor surface device translation apparatus further includes:

the two rails are fixedly arranged on the surface of the floor and are respectively positioned on two sides of the convex structure; the extending direction of the rails is parallel to the arrangement direction of the two sliding frames, and the two rails are respectively connected with the two vertical portions to limit the sliding direction of the vertical portions.

In the embodiment of the application, two sliding frames are arranged on the surface of a floor, and the installation of the device is completed.

When the equipment is moved, firstly, determining the lifting position of the equipment by moving the positions of the two sliding frames;

subsequently, when the equipment is lifted to a floor, the structure of the supporting seat is adjusted through the vertical adjusting structure, and the equipment is manually loaded on the surface of the supporting seat;

and finally, the linear driving assembly drives the translation piece to move, and the translation piece drives the supporting seat to move, so that the equipment is translated.

The floor is equipment translation device for surface that this embodiment provided can be in the effective translation equipment in floor surface, and can not contact protruding structure at the translation in-process, has practiced thrift the manpower and has improved the translation efficiency of equipment.

Drawings

Fig. 1 is a schematic perspective view of a floor surface device translation device according to an embodiment of the present invention;

fig. 2 is a second schematic perspective view (for convenience of illustration, the track therein is hidden) of the floor surface equipment translation device according to the embodiment of the present invention;

FIG. 3 is an exploded view of a vertical adjustment structure used in an embodiment of the present invention;

FIG. 4 is a schematic view of an exploded structure of a translation member and a sliding member employed in an embodiment of the present invention;

FIG. 5 is a schematic view of a linear drive assembly and handle configuration used in an embodiment of the present invention;

description of reference numerals:

1. a carriage; 11. a vertical portion; 12. a horizontal portion; 121. a T-shaped groove; 2. a translation member; 21. a slider; 22. a balance arm; 221. a second flange plate; 3. a supporting seat; 4. a synchronous translation structure; 41. a strip-shaped hole; 42. a connecting arm; 421. an anti-drop bolt; 422. a first flange plate; 5. a linear drive assembly; 51. a drive screw; 511. a second gear; 52. rotating the motor; 53. a handle; 531. a first gear; 54. a transmission belt; 541. a convex tooth; 6. a vertical adjustment structure; 61. a guide plate; 62. a plugboard; 621. a limiting plate; 622. positioning holes; 63. positioning a plate; 631. an abutting member; 7. a slider; 71. a jack; 8. a double-ended screw; 9. a track; 100. a floor surface; 200. and (4) a convex structure.

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 utility model and are not intended to limit the utility model.

Referring to fig. 1 to 5 together, the floor surface equipment translation device according to the present invention will now be described. The floor surface equipment translation device is used for loading the equipment to the floor surface 100, and the floor surface 100 refers to a plane where equipment needing translation is lifted; moreover, the device is partially located above the protruding structure 200, that is, the protruding structure 200 on the ground does not affect the assembly of the device. The floor surface equipment translation device comprises two sliding frames 1, a translation piece 2, a supporting seat 3 and a synchronous translation structure 4.

The two sliding frames 1 are arranged on the floor surface 100 in a sliding manner along the length direction of the convex structure 200 and are respectively arranged on two sides of the convex structure 200; specifically, the carriage 1 includes two vertical portions 11 and a horizontal portion 12.

Wherein, the two vertical parts 11 are arranged on the floor surface 100 in a sliding way along the length direction of the convex structure 200 and are respectively arranged at two sides of the convex structure 200 on the ground; the horizontal portion 12 is provided in a length direction thereof along a horizontal direction, and both ends of the horizontal portion 12 are connected to the top ends of the two vertical portions 11, respectively.

The translation piece 2 is connected to one horizontal part 12 in a sliding mode along the length direction of the horizontal part 12, and a linear driving assembly 5 for driving the translation piece to translate is connected to the translation piece; the linear driving assembly 5 can drive the horizontal moving part 2 to move along the length direction of the horizontal portion 12, that is, to move horizontally above the protrusion 200 along the direction perpendicular to the length direction of the protrusion 200.

The support base 3 is for supporting the equipment to be moved and has an upper surface for supporting the equipment.

The supporting seat 3 is arranged below the other horizontal part 12 in a sliding manner through the vertical adjusting structure 6, and the sliding direction of the supporting seat is the same as that of the translation piece 2.

Synchronous translation structure 4 sets up between translation piece 2 and supporting seat 3, can connect translation piece 2 and supporting seat 3, gains following beneficial effect: when the translation piece 2 moves, the translation piece 2 drives the supporting seat 3 to move through the synchronous translation structure 4.

In the embodiment of the present application, two sliding frames 1 are provided on the floor surface 100, and the installation of the present apparatus is completed.

When the equipment is moved, firstly, the lifting position of the equipment is determined by moving the positions of the two sliding frames 1;

subsequently, when the equipment is lifted to the floor, the structure of the supporting seat 3 is adjusted through the vertical adjusting structure 6, and the equipment is manually loaded on the surface of the supporting seat 3;

finally, the linear driving assembly 5 drives the translation piece 2 to move, and the translation piece 2 drives the supporting seat 3 to move, so that the equipment can be translated.

The floor surface equipment translation device provided by the embodiment can effectively translate equipment on the floor surface 100, and cannot contact with the protruding structures 200 in the translation process, so that manpower is saved, and the translation efficiency of the equipment is improved.

In some embodiments, the above-described characteristic vertical adjustment structure 6 may adopt a structure as shown in fig. 3. Referring to fig. 3, the vertical adjustment structure 6 includes a plurality of guide plates 61, a socket plate 62, and a positioning plate 63.

A plurality of guide plates 61 are provided at intervals in the up-down direction below the corresponding horizontal portion 12 (the horizontal portion 12 referred to herein means the horizontal portion 12 that is not in direct contact with the translation member 2), and both ends of each guide plate 61 are connected to the two vertical portions 11, respectively.

The inserting plate 62 is adapted to be inserted between any two adjacent guide plates 61, and one end of the inserting plate 62 has a limit plate 621 connected to the support base 3 and abutting against the side surface of the guide plate 61, and the other end extends out of the guide plate 61 and has a positioning hole 622 penetrating in the vertical direction.

The positioning plate 63 is adapted to be inserted into the positioning hole 622 from top to bottom, and the top end has an abutting part 631 supported on the upper surface of the insertion plate 62, the abutting part 631 extends along the horizontal direction and the extending end is deflected downward to hang on the side of the insertion plate 62 close to the positioning hole 622.

Wherein, two adjacent guide plates 61, positioning plates 63 and limiting plates 621 clamp the guide plates 61 to limit the movement of the inserting plate 62 in the direction perpendicular to the sliding direction of the supporting base 3.

During adjustment, the support base 3 is moved back to the guide plates 61 to draw the insertion plate 62 away from between two adjacent guide plates 61, so that the sliding frame 1 and the support base 3 are separated; when the connector board 62 is installed again, the connector board 62 is aligned to the gap between two adjacent connector boards 62 corresponding to the required height, and the supporting seat 3 is moved towards the guide board 61, so that the connector boards 62 are inserted between two adjacent connector boards 62, and meanwhile, the limiting board 621 is abutted to one side of the guide board 61; finally, the positioning plate 63 is inserted into the positioning hole 622, so that the guide plate 61 is clamped by the positioning plate 63 and the limiting plate 621.

Through adopting above-mentioned technical scheme, locating plate 63 and the tight both sides of deflector 61 of limiting plate 621 clamp to can make the support that the supporting seat 3 that links to each other with limiting plate 621 can be steady support in protruding structure 200 top, play the effect of support equipment, can also avoid supporting seat 3 to break away from carriage 1 simultaneously, improve the reliability of this device when in-service use.

In some embodiments, the above-described feature synchronous translation structure 4 may adopt a structure as shown in fig. 1 and 2. Referring to fig. 1 and 2, the simultaneous translation structure 4 comprises a strip-shaped hole 41 and a connecting arm 42.

The strip-shaped hole 41 penetrates the support base 3 in the up-down direction and is provided to extend in the sliding direction of the carriage 1.

The connecting arm 42 is arranged on the bottom surface of the translation member 2 in a swinging manner, and the swinging axis is arranged along the sliding direction of the translation member 2; when the two sliding frames 1 are at the farthest distance, the swinging end of the connecting arm 42 is suitable for swinging from top to bottom to be inserted into the strip-shaped hole 41.

Before use, the connecting arm 42 is swung into the strip-shaped hole 41 to complete the connection relationship between the translation piece 2 and the supporting seat 3; this connection relationship can ensure the following process: when the translation member 2 slides, the connecting arm 42 abuts against the strip-shaped hole 41 to drive the supporting seat 3 to move.

Through adopting above-mentioned technical scheme, connect translation piece 2 and supporting seat 3, and this relation of connection is convenient for artifical adjustment, has effectively improved the efficiency when transporting different width equipment, ensures the efficiency of this device when in-service use.

In some embodiments, the swinging end of the above-described feature connecting arm 42 may be configured as shown in FIG. 4. Referring to fig. 4, the swing end surface of the connecting arm 42 is threadedly connected with a retaining bolt 421, and the retaining bolt 421 can be screwed in the axial direction of the connecting arm 42.

The peripheral wall of the anti-slip bolt 421 has a first flange 422 extending outwards, and the first flange 422 is adapted to abut against the bottom surface of the support base 3 to limit the connecting arm 42 from disengaging from the strip-shaped hole 41.

Through adopting above-mentioned technical scheme, on the swing terminal surface with anticreep bolt 421 threaded connection to linking arm 42, make first ring flange 422 play the effect of restriction supporting seat 3 and the separation of linking arm 42, improved the structural stability of this device to and the reliability in the in-service use process.

In some embodiments, the above-described features may be employed between horizontal portion 12 and translator 2, as shown in figures 2 and 4. Referring to fig. 2 and 4, the horizontal portion 12 connected to the translator 2 has a T-shaped groove 121 extending along its length on its bottom surface, and the translator 2 has a slider 21 on its upper surface which is in mating connection with the T-shaped groove 121.

By adopting the technical scheme, the combined structure of the T-shaped groove 121 and the sliding block 21 can enhance the connection relation between the translation piece 2 and the horizontal part 12, and the structural stability and the reliability in practical use of the device are improved.

In some embodiments, the above-described features of linear drive assembly 5 may be configured as shown in fig. 2 and 5. Referring to fig. 2 and 5, the linear drive assembly 5 includes a drive screw 51 and a rotary motor 52.

The driving screw 51 is in threaded connection with the translation part 2 and is parallel to the axial direction of the horizontal part 12; one end of the drive screw 51 is rotatably connected to one of the upright portions 11, and the other end thereof penetrates the other upright portion 11 and protrudes.

The rotation motor 52 is fixedly arranged on the vertical portion 11 (the vertical portion 11 mentioned here refers to the vertical portion 11 corresponding to the sliding frame 1 connected to the translation member 2), and the power output end thereof is parallel to the axial direction of the drive screw 51 and is coaxially connected with the extending end of the drive screw 51.

Through adopting above-mentioned technical scheme, rotate motor 52 and can drive screw 51 automatically and rotate to drive translation piece 2 horizontal migration, avoid manual drive, ensure translation efficiency, improved the efficiency and the reliability of this device when in-service use.

In some embodiments, the vertical portion 11 and the drive screw 51 may be configured as shown in fig. 2 and 5. Referring to fig. 2 and 5, the vertical portion 11 is rotatably provided with a handle 53, and the rotational axial direction is parallel to the axial direction of the drive screw 51.

A first gear 531 is coaxially connected to the handle 53, a second gear 511 is coaxially connected to the drive screw 51, and a transmission belt 54 is provided between the handle 53 and the drive screw 51; the belt 54 is wrapped around the outer circumference of the first gear 531 and the second gear 511, and a plurality of teeth 541 are provided on the inner wall of the belt 54 at intervals along the length direction of the belt 54.

Through adopting above-mentioned technical scheme, during the in-service use, can manual twist grip 53 to drive screw 51 and rotate, thereby can drive translation piece 2 and take place horizontal migration, ensure the reliability of this device when in-service use, and reduce the energy loss, ensure that this device can stable start.

In some embodiments, the above-described features may be employed between horizontal portion 12 and translator 2, as shown in figures 2 and 4. Referring to fig. 2 and 4, a sliding member 7 is slidably disposed on the horizontal portion 12 connected to the support base 3 (i.e., the horizontal portion 12 not directly connected to the translation member 2) along the longitudinal direction thereof, and the sliding member 7 has a through hole 71 penetrating in the sliding direction of the sliding frame 1.

The translation member 2 has a balance arm 22 extending towards the support base 3 and adapted to be inserted into the insertion hole 71, and an extending end of the balance arm 22 has a second flange 221 for abutting against the sliding member 7.

By adopting the technical scheme, the translation piece 2 can be connected with the two sliding frames 1 through the balance arm 22 and the sliding piece 7, so that the stability of the horizontal movement of the translation piece 2 is ensured, and the reliability of the device in actual use is improved; meanwhile, the second flange 221 can prevent the balance arm 22 from separating from the jack 71, and the structural stability of the device is improved.

In some embodiments, the above-described characteristic slider 7 may adopt a structure as shown in fig. 1 and 2. Referring to fig. 1 and 2, the two carriages 1 have a distance adjustment structure between them, which comprises a single double-headed screw 8.

The axial direction of the double-headed screw 8 is parallel to the sliding direction of the sliding frame 1, the double-headed screw 8 is provided with two thread parts with opposite thread directions, and the two thread parts are respectively in threaded connection with the two sliding frames 1; since the sliding direction of the sliding frames 1 is limited, the two sliding frames 1 can move towards each other or away from each other when the double-headed screw 8 rotates.

Through adopting above-mentioned technical scheme, can drive two carriage 1 and remove in opposite directions or remove dorsad through double threaded screw 8 after adjusting two carriage 1's position, can realize the adjustment of two carriage 1 intervals to the equipment of the different width of adaptation has improved the reliability of this device when in-service use.

In some embodiments, the above-described feature may be applied to the underside of the carriage 1 as shown in fig. 1. Referring to fig. 1, the above-mentioned floor surface equipment translation device further comprises two straight rails 9.

The two rails 9 are fixedly disposed on the floor surface 100 and are respectively disposed on both sides of the protrusion structure 200.

The extending direction of each rail 9 is parallel to the arrangement direction of the two sliding frames 1, and the two rails 9 are respectively connected with the two vertical portions 11 to limit the sliding direction of the vertical portions 11.

Through adopting above-mentioned technical scheme, two tracks 9 mutually support, realize the injecing to carriage 1 slip direction, have improved the stability of this device when in actual use.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. Floor surface equipment translation device for loading to a floor surface and above a raised structure of the floor surface, characterized in that the floor surface equipment translation device comprises:

the two sliding frames are arranged on the surface of the floor in a sliding manner along the length direction of the protruding structure and are respectively positioned on two sides of the protruding structure; the sliding frame comprises two vertical parts which are arranged on two sides of the protruding structure in a sliding mode and a horizontal part of which two ends are connected with the two vertical parts respectively;

the translation piece is connected to one of the horizontal parts in a sliding mode along the length direction of the horizontal parts and is connected with a linear driving assembly for driving the translation piece to translate;

the supporting seat is used for supporting equipment, is arranged below the other horizontal part in a sliding mode through a vertical adjusting structure, and has the same sliding direction as that of the translation piece; and

the synchronous translation structure is arranged between the translation piece and the supporting seat; when the translation piece moves, the translation piece drives the supporting seat to move through the synchronous translation structure.

2. The floor surface equipment translation device of claim 1, wherein the vertical adjustment structure comprises:

the guide plates are arranged below the horizontal part at intervals in the vertical direction, and two ends of each guide plate are respectively connected with the two vertical parts;

the inserting plate is suitable for being inserted between two adjacent guide plates, one end of the inserting plate is provided with a limiting plate which is connected with the supporting seat and is abutted against the side surface of the guide plate, and the other end of the inserting plate extends out of the guide plate and is provided with a positioning hole which penetrates through the inserting plate along the vertical direction; and

the positioning plate is suitable for being inserted into the positioning hole from top to bottom, and the top end of the positioning plate is provided with an abutting part used for being supported on the upper surface of the insertion plate;

the adjacent two guide plates, the positioning plate and the limiting plate clamp the guide plates to limit the insertion plate to move along the direction perpendicular to the sliding direction of the supporting seat.

3. The floor surface equipment translation device of claim 1, wherein the synchronous translation structure comprises:

the strip-shaped hole penetrates through the supporting seat along the vertical direction and is arranged in an extending mode along the sliding direction of the sliding frame; and

the connecting arm is arranged on the bottom surface of the translation piece in a swinging mode, and the swinging shaft is arranged along the sliding direction of the translation piece in the swinging mode; the connecting arm is suitable for swinging until the lower end of the connecting arm is inserted into the strip-shaped hole;

when the translation piece slides, the connecting arm is abutted to the strip-shaped hole to drive the supporting seat to move.

4. The floor surface equipment translation device according to claim 3, wherein an anti-drop bolt is threadedly connected to the swing end surface of the connecting arm, and the anti-drop bolt can be screwed in the axial direction of the connecting arm;

the periphery wall of anticreep bolt has the first ring flange that outwards extends the setting, first ring flange be suitable for with the bottom surface butt of supporting seat, in order to restrict the linking arm breaks away from the bar hole.

5. The floor surface appliance translator of claim 1 wherein the bottom surface of the horizontal portion to which the translator is attached has a T-shaped slot extending along its length, and the upper surface of the translator has a slide block matingly attached to the T-shaped slot.

6. The floor surface equipment translation device of claim 1, wherein the linear drive assembly comprises:

the driving screw is in threaded connection with the translation piece, and the axial direction of the driving screw is parallel to the length direction of the horizontal part; one end of the driving screw is rotatably connected with one of the vertical parts, and the other end of the driving screw penetrates through the other vertical part and extends out of the other vertical part; and

and the rotating motor is fixedly arranged on the vertical part, and the power output end is coaxially connected with the extending end of the driving screw rod.

7. The floor surface equipment translation device according to claim 6, wherein said vertical portion is rotatably provided with a handle, and the rotation axis direction is parallel to the axis direction of said drive screw;

the handle is coaxially connected with a first gear, the driving screw is coaxially connected with a second gear, and a transmission belt is arranged between the handle and the driving screw; the transmission belt is wound on the peripheries of the first gear and the second gear, and a plurality of convex teeth arranged at intervals along the length direction of the transmission belt are arranged on the inner wall of the transmission belt.

8. The floor surface equipment translator according to claim 1 wherein a slider is slidably disposed on the horizontal portion connected to the support base along a longitudinal direction thereof, the slider having a hole therethrough along a sliding direction of the sliding frame; the translation piece is provided with a balance arm which extends towards the support seat and is suitable for being inserted into the insertion hole, and the extending end of the balance arm is provided with a second flange plate used for being abutted against the sliding piece.

9. The floor surface equipment translator of claim 1 wherein there is a distance adjustment structure between two of said carriages, said distance adjustment structure comprising:

the axial direction of the double-end screw is parallel to the sliding direction of the sliding frame; the double-end screw has two screw thread portions opposite in thread direction, two the screw thread portion respectively with two carriage threaded connection is used for driving two the carriage removes or removes dorsad in opposite directions.

10. The floor surface equipment translation device of any of claims 1-9, wherein the floor surface equipment translation device further comprises:

the two rails are fixedly arranged on the surface of the floor and are respectively positioned on two sides of the convex structure; the extending direction of the rails is parallel to the arrangement direction of the two sliding frames, and the two rails are respectively connected with the two vertical portions to limit the sliding direction of the vertical portions.

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