CN205312351U - Waste transportation station elevating gear - Google Patents

Abstract

The utility model provides a waste transportation station elevating gear, waste transportation station elevating gear includes a bracket component, two drive assembly and receive drive assembly, be in by drive assembly drive assembly's drive is in down go up and down in the bracket component. Waste transportation station elevating gear stable in structure, area is little. Rubbish transfer station elevating gear operational method makes rubbish transfer station elevating gear and refuse collecting vehicle and the high -efficient cooperation of rubbish van improve the refuse collection treatment effeciency.

Description

Refuse transfer station lowering or hoisting gear

Technical field

This utility model relates to refuse transfer station, more precisely, is for moving the hoistable platform of garbage container in refuse transfer station.

Background technology

Along with urbanization process, domestic waste problem is also more serious, how to process domestic waste effectively quickly and is increasingly becoming a great problem in city management. The one of modern city is characterized in that greatly the in short supply of land resource, and in domestic rubbish disposal process, it is necessary to take considerable land resource to collect rubbish. Existing urban garbage disposal process is as follows: first collected rubbish by the numerous small-sized rubbish collection facilities being placed in congregated district of population, the rubbish in small-sized rubbish collection facility is collected afterwards by refuse collector, refuse collector will be transported to refuse transfer station in the refuse collecting collected, it is transported to the refuse collection of refuse transfer station to garbage container, is finally transported garbage container by rubbish van and focus on to process place in refuse collecting. Said process processes the general addressing in place away from city in refuse collecting, and in order to facilitate the collection of rubbish, small-sized rubbish collection facility and the equal addressing of refuse transfer station are among city, wherein refuse transfer station is built according to the distribution addressing of small-sized rubbish collection facility, city typically requires many refuse transfer stations of construction, for instance build near the community that resident concentrates. In prior art, the capital equipment supporting with refuse transfer station includes refuse collector, rubbish van and vertical garbage container. Existing refuse collector mainly adopts the mode of lifting to carry out discharging, and refuse collector is provided with lifting device, and the compartment of dumper can be lifted to certain angle of inclination, and the rubbish in refuse collector compartment is toppled over away from discharge port under gravity. Vertical garbage container is vertically deposited in refuse transfer station, reception refuse collector is dumped rubbish, the axial both ends of the surface of vertical garbage container have charging aperture and discharge port, when vertical garbage container is vertically placed among rubbish point of shipment, the charging aperture of vertical garbage container is vertically upward, it is little that vertical garbage container has floor space, and capacity is big, the advantage that conevying efficiency is high. Rubbish van is used for transporting vertical garbage container, process place is transported to refuse collecting from refuse transfer station including by the vertical garbage container filling rubbish, and empty vertical garbage container is processed from refuse collecting place transport to refuse transfer station, and when rubbish van transports vertical garbage container, the discharge port of vertical garbage container is positioned at the afterbody of rubbish van. The refuse transfer station of existing employing vertical garbage container is in order to effectively operate vertical garbage container, adopt lifting device and the coefficient mode of turning device, operation vertical garbage container is transported to the process of refuse transfer station from rubbish van, and vertical refuse transfer box is transported to the process of rubbish van from refuse transfer station. When vertical garbage container is operated by lifting device and turning device in refuse transfer station, vertical garbage container needs to take additional space in switching process, thus waste transportation is accomplished by when standing in construction taking bigger area, and in order to ensure refuse transfer station Effec-tive Function, one refuse transfer station typically requires deposits more than one vertical garbage container, each garbage container all needs to utilize lifting device and turning device to operate, and further increases the floor space of refuse transfer station. Still have to be hoisted as it has been described above, adopt the waste transportation of prior art to stand in reduction floor space aspect.

Summary of the invention

A purpose of the present utility model is in that to provide refuse transfer station lowering or hoisting gear and an operational method thereof, described refuse transfer station lowering or hoisting gear vertical lift vertical garbage container, described refuse transfer station lowering or hoisting gear floor space is little, and refuse transfer station floor space is little.

Another purpose of the present utility model is in that to provide refuse transfer station lowering or hoisting gear and an operational method thereof, in described refuse transfer station lowering or hoisting gear vertical lift process, vertical garbage container is without upset, described refuse transfer station lifting device structure is stable, refuse transfer station Stability Analysis of Structures.

Another purpose of the present utility model is in that to provide refuse transfer station lowering or hoisting gear and an operational method thereof, and described refuse transfer station lowering or hoisting gear adopts multiple support composition guide rail, stabilized structure.

Another purpose of the present utility model is in that to provide refuse transfer station lowering or hoisting gear and an operational method thereof, and described refuse transfer station lowering or hoisting gear adopts multiple support composition guide rail, and described refuse transfer station lowering or hoisting gear runs smooth and easy.

Another purpose of the present utility model is in that to provide refuse transfer station lowering or hoisting gear and an operational method thereof, described refuse transfer station lowering or hoisting gear stress equalization, Stability Analysis of Structures, failure rate is low.

Another purpose of the present utility model is in that to provide refuse transfer station lowering or hoisting gear and an operational method thereof, described refuse transfer station lowering or hoisting gear can keep stress equalization when vertical garbage container Mass Distribution is uneven, it is possible to stably transport vertical garbage container.

Another purpose of the present utility model is in that to provide refuse transfer station lowering or hoisting gear and an operational method thereof, the operational method of described refuse transfer station lowering or hoisting gear makes described refuse transfer station lowering or hoisting gear efficiently coordinate with refuse collector, and refuse transfer station refuse collection efficiency is high.

Another purpose of the present utility model is in that to provide refuse transfer station lowering or hoisting gear and an operational method thereof, the operational method of described refuse transfer station lowering or hoisting gear makes described refuse transfer station lowering or hoisting gear efficiently coordinate with rubbish van, and refuse transfer station garbage transporting efficiency is high.

In order to achieve the above object, this utility model provides a refuse transfer station lowering or hoisting gear, and described refuse transfer station lowering or hoisting gear is arranged in a foundation ditch, it is characterised in that including:

One carriage assembly, described carriage assembly is vertically installed in bottom described foundation ditch;

Two drive assembly, and described driving assembly is set and is slidably connected to described carriage assembly, and two described driving assemblies are parallel to each other; And

One assembly driven, described assembly driven is subject to the driving of described driving assembly and moves with the direction identical with described driving assembly and speed.

Preferably, described carriage assembly includes a base and four guide rail support, and described base is arranged at bottom described foundation ditch, and four described guide rail support are vertically installed in described base, and four described guide rail support are parallel to each other.

Preferably, described base is square, and four described guide rail support are arranged at square four angles of described base.

Preferably, two described driving assemblies move along the direction being perpendicular to described base.

Preferably, described carriage assembly includes two crossbeams, and described crossbeam is set be connected vertical with two described guide rail support, and two described crossbeams are parallel to each other and identical with the distance of described base.

Preferably, described driving assembly includes a hydraulic stem, one cross bar, two the first guide wheel assemblies, described hydraulic stem is set and is perpendicular to the described base described base of connection and described cross bar, and described cross bar is slidably connected with the two described guide rail support being connected to described crossbeam by two described first guide wheel assemblies. .

Preferably, described assembly driven includes a platform, two dividing plates and four the second guide wheel assemblies, described dividing plate is set and is perpendicular to described platform and is connected with described platform, and described platform is slidably connected by four described second guide wheel assemblies and four described guide rail support.

Preferably, described carriage assembly includes eight crossbeam connection members, and four described crossbeam connection members are set on each described crossbeam, and described crossbeam connection member two group is arranged at the centre position at described crossbeam two ends respectively.

Preferably, described driving assembly includes two pulley assemblies, described pulley assembly includes two pulleys, and two described pulleys are set that corotation moving axis is adjacent rotationally to be fixed on described cross bar, and described pulley assembly is arranged at the centre position at described cross bar two ends respectively.

Preferably, described assembly driven includes four connection member groups driven, described connection member group driven includes two connection members driven, and two described connection members driven are adjacent to be arranged side by side, and described driving assembly and described pulley assembly vertical alignment.

Preferably, described assembly driven includes eight and connects rope, and described connection rope is perpendicular to described base, and the described rope that connects connects described connection member driven and described crossbeam connection member by described pulley.

Preferably, described guide rail support includes two root posts, and two described columns are set the described base that is perpendicular to parallel to each other, and have a guide rail between two described columns.

Preferably, described first guide wheel assembly includes one first wheel seat and two the first limiting components, one Middle face of described first wheel seat is set be connected vertical with described cross bar, two described first limiting components are set and are installed on the one side that the one side of the described first wheel seat described cross bar of connection opposes, and described first limiting component embeds described guide rail slidably.

Preferably, described first guide wheel assembly includes four the first rollers, the two sides that described first roller is two group in opposition to each other by being installed in rotation on described first wheel seat respectively, and described first roller of correspondence position is symmetrical.

Preferably, described second guide wheel assembly includes one second wheel seat and two the second limiting components, and described second wheel seat is set and is connected with described platform, and two described first limiting components are connected towards described guide rail support with described second wheel seat.

Preferably, described second guide wheel assembly includes four the second rollers, and two one group of described second roller is installed in rotation on described and wheel seat two sides in opposition to each other respectively, and described second roller of correspondence position is symmetrical.

A kind of refuse transfer station lowering or hoisting gear operational method, for a vertical garbage container is carried out descending operation, it is characterised in that including:

(B) extend described hydraulic stem, drive described cross bar to be perpendicular to described base and rise;

(C) the described cross bar that rises is parallel with described basal plane to described platform, drives described vertical garbage container to be put forward described foundation ditch with described platform.

Preferably, before described step (B), also include a step (A): sinking described platform to described foundation ditch, described vertical garbage container is lowered into described foundation ditch with described platform.

Preferably, described step (A) including:

(A1) shrink described hydraulic stem, drive described cross bar to be perpendicular to described base and decline;

(A2) the described cross bar that declines arrives described base to described platform.

Accompanying drawing explanation

Fig. 1 show the front schematic view of the refuse transfer station lowering or hoisting gear of a preferred embodiment of the present utility model.

It it is the top view of the refuse transfer station lowering or hoisting gear of a preferred embodiment of the present utility model described in Fig. 2.

Fig. 3 show the side schematic view of the refuse transfer station lowering or hoisting gear of a preferred embodiment of the present utility model, and under diagram state, described assembly driven is positioned at minimum point.

Fig. 4 show the side schematic view of the refuse transfer station lowering or hoisting gear of a preferred embodiment of the present utility model, and under diagram state, described assembly driven is positioned at peak.

Fig. 5 A show the operational method schematic diagram of the refuse transfer station lowering or hoisting gear of a preferred embodiment of the present utility model, and under diagram state, described vertical garbage container is in sinking watching.

Fig. 5 B show the operational method schematic diagram of the refuse transfer station lowering or hoisting gear of a preferred embodiment of the present utility model, and under diagram state, described vertical garbage container is in bottom described foundation ditch.

Fig. 5 C show the operational method schematic diagram of the refuse transfer station lowering or hoisting gear of of the present utility model preferred embodiment, and under diagram state, described vertical garbage container is in uphill process.

Detailed description of the invention

It is described below for disclosing this utility model so that those skilled in the art are capable of this utility model. Preferred embodiment in being described below is only used as citing, it may occur to persons skilled in the art that other apparent modification. The ultimate principle of the present utility model defined in the following description can apply to other embodiments, deformation program, improvement project, equivalent and the other technologies scheme without departing from spirit and scope of the present utility model.

It is the structural representation of a refuse transfer station lowering or hoisting gear 3 of a preferred embodiment of the present utility model as shown in Figure 1, Figure 2, Figure 3 and Figure 4. Described refuse transfer station lowering or hoisting gear 3 is arranged in a foundation ditch 2, and described foundation ditch 2 is formed to mine working relative to a basal plane 1, and the bottom surface of described foundation ditch 2 is parallel with described basal plane 1. Described refuse transfer station lowering or hoisting gear 3 is mainly used in a vertical garbage container 400 is carried out descending operation. Described vertical garbage container 400 is sunk to described foundation ditch 2 under the effect of described refuse transfer station lowering or hoisting gear 3 or is put forward described foundation ditch 2 under the effect of described rubbish point of shipment lowering or hoisting gear 3.

Described refuse transfer station lowering or hoisting gear 3 includes a carriage assembly 31, two groups and drives assembly 32 and an assembly 33 driven. Described carriage assembly 31 includes a base 311, four guide rail support 312 and two crossbeams 313. As it is shown in figure 1, described base 311 is set the bottom being fixed on described foundation ditch 2, the bottom of described foundation ditch 2 is parallel with described basal plane 1, thus described base 311 is parallel with described basal plane 1. Described base 311 is square, and described base 311 plane is identical with the shape of described foundation ditch 2 bottom surface and ratio consistent, and the edge of described base 311 is identical with the distance of described foundation ditch 2 bottom margin. Four described guide rail support 312 are vertically installed in four angles of described base 311 respectively, described base 311 is parallel with described basal plane 1 again, described guide rail support 312 is vertical with described basal plane 1, and the height of four described guide rail support 312 is higher than the degree of depth of described foundation ditch 2, namely described guide rail support 312 exceeds described basal plane 1. As shown in Figure 2, described guide rail support 312 is made up of two root posts 3121, and two described columns 3121 are set setting parallel to each other, forms a guide rail 3122 between two described columns 3121 of described guide rail support 312, described guide rail 3122 is wide, and the direction of described guide rail 3122 is consistent. As in figure 2 it is shown, described crossbeam 313 is set be connected vertical with described guide rail support 312, and owing to described guide rail support 312 is vertical with described basal plane 1, described crossbeam 313 is namely parallel with described basal plane 1.Two described crossbeams 313 are parallel to each other, and two described crossbeams 313 are identical apart from the distance of described base 311. Every described crossbeam 313 is set be connected vertical with two described guide rail support 312, and two described guide rails 3122 that two piece described guide rail support 312 with described crossbeam 313 being connected are set are coplanar. Described crossbeam 313 is connected with described guide rail support 312 and described crossbeam 313 is positioned at the described guide rail support 312 side close to described foundation ditch 2 sidewall, and described crossbeam 313 does not stop the described guide rail 3122 of connected two described guide rail support 312 simultaneously. The half that distance is described foundation ditch 2 degree of depth of described crossbeam 313 and described base 311. As shown in Figure 3, described crossbeam 313 is provided with four crossbeam connection members 3131, described crossbeam connection member 3,131 two one group is arranged at the centre position at described crossbeam 313 two ends respectively, and described crossbeam connection member 3131 is respectively positioned on the described crossbeam 313 side towards described foundation ditch 2 opening part.

As shown in Figure 2, Figure 3 and Figure 4, described driving assembly 32 includes a hydraulic stem 321, a cross bar 322, two the first guide wheel assemblies 323 and two pulley assemblies 324. Described driving assembly 32 is combined with two that are connected to described crossbeam 313 described guide rail support 312. Described cross bar 322 is set vertical with described guide rail support 312, two described first guide wheel assemblies 323 are installed in two terminations of described cross bar 322 respectively, and described cross bar 322 is slidably connected by two described first guide wheel assemblies 323 and two described guide rail support 312. Described first guide wheel assembly 323 can move along the described guide rail 3122 of described guide rail support 312, thus the described cross bar 322 that first guide wheel assembly 323 described with two is connected also is able to move along the described guide rail 3122 of described guide rail support 312, and owing to described guide rail support 312 is perpendicular to described base 311, described cross bar 322 moves up and down along the direction being perpendicular to described base 311, and due to spacing to described cross bar 322 of two described guide rail support 312, described cross bar 322 cannot move to other directions. Described hydraulic stem 321 is perpendicular to described base 311 and connects described base 311 and described cross bar 322, described hydraulic stem 321 is connected towards the side of described base 311 with described cross bar 322, and the midpoint that link position is described cross bar 322 of described hydraulic stem 321 and described cross bar 322. Described hydraulic stem 321 has the function stretched along its axis direction, and described hydraulic stem 321 is vertical with described base 311, thus described hydraulic stem 321 stretches along being perpendicular to described base 311 direction. The point midway of described cross bar 322 is connected with described hydraulic stem 321, thus when described hydraulic stem 321 along be perpendicular to described base 311 direction flexible time, described cross bar 322 moves up and down along the direction being perpendicular to described base 311 with the direction identical with described hydraulic stem 321 and speed. Described cross bar 322 is provided power by described hydraulic stem 321, described cross bar 322 is subject to the spacing of described guide rail support 312 by described first guide wheel assembly 323 simultaneously, thus the kinestate of described cross bar 322 accurately can control by controlling described the flexible of hydraulic stem 321. Described hydraulic stem 321 has an initial length, and the shortest length that described initial length is described hydraulic stem 321, when described cross bar 322 arrives the height concordant with described basal plane 1, described hydraulic stem 321 stops elongation, and described hydraulic stem 321 reaches its extreme length.Described hydraulic stem 321 is at the uniform velocity flexible, drives described cross bar 322 at the uniform velocity to move up and down along described guide rail support 312. Described pulley assembly 324 includes two identical pulleys 3241, and two described pulleys 3241 are adjacent is arranged side by side. Described pulley assembly 324 is arranged at the centre position at described cross bar 322 two ends respectively, and two described pulley assemblies 324 are respectively positioned on described cross bar 322 and described base 311 opposite direction. Four described pulley 3241 corotation moving axis and the rotation axle of four described pulleys 3241 in two described pulley assemblies 324 are parallel with described cross bar 322. As in figure 2 it is shown, described first guide wheel assembly 323 includes one first wheel seat 3231, four the first rollers 3232 and two the first limiting components 3233. One Middle face of described first wheel seat 3231 is set and is connected with described cross bar 322, and the axis of described cross bar 322 is perpendicular to the plane being connected with described first wheel seat 3231. The one side that described first wheel seat 3231 opposes with the one side being connected described cross bar 322, namely described first wheel seat 3231 is towards mounted two described first limiting components 3233 of one side of described guide rail support 312, and two described first limiting components 3233 embed described guide rail 3122 all slidably. Described first limiting component 3233 is cylindrical, bottom cylindrical face is connected with described first wheel seat 3231, the diameter of described first limiting component 3233 cylindrical cross-section is close with the width of described guide rail 3122, and the diameter of described first limiting component 3233 cylindrical cross-section is less than the width of described guide rail 3122, thus described first limiting component 3233 can move along described guide rail 3122 swimmingly. The moving direction of described first wheel seat 3231 is produced restriction by described first limiting component 3233 so that described first wheel seat 3231 is only capable of moving along described guide rail 3122, and namely described first wheel seat 3231 is only capable of moving along described guide rail support 312. The two sides that 3,232 two one group of described first roller is in opposition to each other by being installed in rotation on described first wheel seat 3231 respectively, and described first roller 3232 of correspondence position is symmetrical. Owing to the motion of described first wheel seat 3231 has been limited by described first limiting component 3233, described first roller 3232 rolls along described column 3121, described first roller 3232 avoids described first wheel seat 3231 and contacts with the direct of described guide rail support 312, reduce the frictional force between described first guide wheel assembly 323 and described guide rail support 312, it is ensured that described first guide wheel assembly 323 can move along described guide rail support 312 swimmingly. Assembly 32 is driven to be installed symmetrically in described carriage assembly 31 described in two groups, and when driving assembly 32 to operate described in two groups, drive assembly 32 to move in a similar direction with identical speed described in two groups, be maintained with described in two groups and drive the described cross bar 322 in assembly 32 to be in identical height all the time.

As shown in Figure 2, Figure 3 and Figure 4, described assembly 33 driven includes a platform 331,332, four groups of connection member groups 333 driven of two dividing plates, and four group of second guide wheel assembly 334 and eight connect ropes 335. Described assembly driven 33 is subject to the driving of described driving assembly 32 and moves along described guide rail support 312, and described assembly driven 33 moves in a similar direction with identical speed with described driving assembly 32. Described platform 331 plane is parallel with described base 311, and described platform 331 moves along the direction being perpendicular to described base 311, and described platform 331 does not contact with described guide rail support 312 in motor process.Two described dividing plates 332 are perpendicular to described platform 331 and are arranged on described platform 331, and two described dividing plates 332 are parallel to each other. Described dividing plate 332 is parallel with two that are connected to described driving assembly 32 described guide rail support 312, and described dividing plate 332 does not contact with described guide rail support 312 in the process moved with described platform 331. Described connection member group 333 driven is perpendicular to described platform 331 and is connected with described platform 331, and four described connection member groups driven 333 two group lay respectively at described platform 331 and are perpendicular to the position of described pulley assembly 324. Each described connection member group 333 driven para-position one pulley assembly 324, and the arrangement mode of described connection member group 333 driven is identical with the arrangement mode of described pulley assembly 324. Described connection member group 333 driven includes two connection members 3331 driven, and two described connection members 3331 driven are adjacent to be arranged side by side. The described rope 335 that connects is connected with described connection member 3331 driven, described connection rope 335 is perpendicular to described base 311 and extends through described pulley 3241 simultaneously, and the described rope 335 that connects is extending to and be connected with described crossbeam connection member 3131 through continuing to be perpendicular to described base 311 after described pulley 3241, namely described connect to restrict 335 connected described connection member driven 3331 and described crossbeam connection member 3131 by described pulley 3241. Described second guide wheel assembly 334 includes one second wheel seat 3341, four the second rollers 3342 and two the second limiting components 3343. Described second wheel seat 3341 is connected with described platform 331. Two described second limiting components 3343 embed described guide rail 3122 all slidably. Described second limiting component 3343 is cylindrical, bottom cylindrical face is connected with described second wheel seat 3341, the diameter of described second limiting component 3343 cylindrical cross-section is close with the width of described guide rail 3122, and the diameter of described second limiting component 3343 cylindrical cross-section is less than the width of described guide rail 3122, thus described second limiting component 3343 can move along described guide rail 3122 swimmingly. The moving direction of described second wheel seat 3341 is produced restriction by described second limiting component 3343 so that described second wheel seat 3341 is only capable of moving along described guide rail 3122, and namely described second wheel seat 3341 is only capable of moving along described guide rail support 312. The two sides that 3,342 two one group of described second roller is in opposition to each other by being installed in rotation on described second wheel seat 3341 respectively, and described second roller 3342 of correspondence position is symmetrical. Owing to the motion of described second wheel seat 3341 has been limited by described second limiting component 3343, described second roller 3342 rolls along described column 3121, described second roller 3342 avoids described second wheel seat 3341 and contacts with the direct of described guide rail support 312, reduce the frictional force between described second guide wheel assembly 334 and described guide rail support 312, it is ensured that described second guide wheel assembly 334 can move along described guide rail support 312 swimmingly.

Owing to described crossbeam connection member 3131 is fixedly connected on described crossbeam 313, and described crossbeam 313 is fixed with two described guide rail support 312 and is connected, and therefore described 335 one end being connected with described crossbeam connection member 3131 of restricting that connect constitute fixing end. The described cross bar 322 being provided with described pulley 3241 moves up and down along described guide rail support 312 acting on of described hydraulic stem 321, described connection rope 335 and described connection member 3331 driven is forced in by the described effect connecting rope 335, eight described connection members 3331 driven are subject to the effect of power by the described rope 335 that connects simultaneously, simultaneously because described connection member driven 3331 is symmetrically dispersed on described platform 331, described platform 331 is subject to being perpendicular to the effect of the power of described base 311, described platform 331 uniform force.Two described hydraulic stems 321 force in described platform 331 by the described rope 335 that connects respectively in the process promoting described cross bar 322, two described hydraulic stems 321 divide equally the power needed for mobile described platform 331, and described hydraulic stem 321 uniform force, and the direction being subject to making a concerted effort is perpendicular to described platform 331. The overall uniform force of described refuse transfer station lowering or hoisting gear 3 in the present embodiment, Stability Analysis of Structures, it is possible to expeditiously described vertical garbage container 400 is carried out vertical lift.

As Fig. 5 A, Fig. 5 B and Fig. 5 C show the operational method schematic flow sheet of refuse transfer station lowering or hoisting gear 3 described in the utility model, described refuse transfer station lowering or hoisting gear 3 is for carrying out descending operation to described vertical garbage container 400. Specifically including and utilize described refuse transfer station lowering or hoisting gear 3 described vertical garbage container 400 sinks to described foundation ditch 2 and utilizes described refuse transfer station lowering or hoisting gear 3 that described vertical garbage container 400 is put forward described foundation ditch 2, two processes constitute the operational method of a complete described refuse transfer station lowering or hoisting gear 3. It should be noted that in an initial condition, described platform 331 is parallel with described basal plane 1, and the operational method of described refuse transfer station lowering or hoisting gear 3 includes step:

(A) sinking described platform 331 to described foundation ditch 2, described vertical garbage container 400 is lowered into described foundation ditch 2 with described platform 331;

(B) rising described platform 331 to parallel with described basal plane 1, described vertical garbage container 400 is put forward described foundation ditch 2 with described platform 331.

The sinking of platform 331 described in wherein said step (A) is driven by described driving assembly 32, and described step (A) including:

(A1) shrink described hydraulic stem 321, drive described cross bar 322 to be perpendicular to described basal plane 1 and decline;

(A2) the described cross bar 322 that declines arrives bottom described foundation ditch 2 to described platform 331.

The rising of platform 331 described in wherein said step (B) is driven by described driving assembly 32, and described step (B) including:

(B1) extend described hydraulic stem 321, drive described cross bar 322 to be perpendicular to described basal plane 1 and rise;

(B2) the described cross bar 322 that rises is parallel with described basal plane 1 to described platform 331.

It should be understood by those skilled in the art that the embodiment of the present utility model shown in foregoing description and accompanying drawing is only used as citing and is not limiting as this utility model. The purpose of this utility model is completely and be effectively realized. Function of the present utility model and structural principle are shown in an embodiment and illustrate, without departing under described principle, embodiment of the present utility model can have any deformation or amendment.

Claims (16)

1. refuse transfer station lowering or hoisting gear, described refuse transfer station lowering or hoisting gear is arranged in a foundation ditch, it is characterised in that including:

One carriage assembly, described carriage assembly is vertically installed in bottom described foundation ditch;

Two drive assembly, and described driving assembly is set and is slidably connected to described carriage assembly, and two described driving assemblies are parallel to each other; And

One assembly driven, described assembly driven is subject to the driving of described driving assembly and moves with the direction identical with described driving assembly and speed.

2. refuse transfer station lowering or hoisting gear as claimed in claim 1, it is characterized in that, described carriage assembly includes a base and four guide rail support, described base is arranged at bottom described foundation ditch, four described guide rail support are vertically installed in described base, and four described guide rail support are parallel to each other.

3. refuse transfer station lowering or hoisting gear as claimed in claim 2, it is characterised in that described base is square, and four described guide rail support are arranged at square four angles of described base.

4. refuse transfer station lowering or hoisting gear as claimed in claim 3, it is characterised in that two described driving assemblies move along the direction being perpendicular to described base.

5. refuse transfer station lowering or hoisting gear as claimed in claim 4, it is characterised in that described carriage assembly includes two crossbeams, described crossbeam is set be connected vertical with two described guide rail support, and two described crossbeams are parallel to each other and identical with the distance of described base.

6. refuse transfer station lowering or hoisting gear as claimed in claim 5, it is characterized in that, described driving assembly includes a hydraulic stem, one cross bar, two the first guide wheel assemblies, described hydraulic stem is set and is perpendicular to the described base described base of connection and described cross bar, and described cross bar is slidably connected with the two described guide rail support being connected to described crossbeam by two described first guide wheel assemblies.

7. refuse transfer station lowering or hoisting gear as claimed in claim 6, it is characterized in that, described assembly driven includes a platform, two dividing plates and four the second guide wheel assemblies, described dividing plate is set and is perpendicular to described platform and is connected with described platform, and described platform is slidably connected by four described second guide wheel assemblies and four described guide rail support.

8. refuse transfer station lowering or hoisting gear as claimed in claim 7, it is characterized in that, described carriage assembly includes eight crossbeam connection members, four described crossbeam connection members are set on each described crossbeam, and described crossbeam connection member two group is arranged at the centre position at described crossbeam two ends respectively.

9. refuse transfer station lowering or hoisting gear as claimed in claim 8, it is characterized in that, described driving assembly includes two pulley assemblies, described pulley assembly includes two pulleys, two described pulleys are set that corotation moving axis is adjacent rotationally to be fixed on described cross bar, and described pulley assembly is arranged at the centre position at described cross bar two ends respectively.

10. refuse transfer station lowering or hoisting gear as claimed in claim 9, it is characterized in that, described assembly driven includes four connection member groups driven, described connection member group driven includes two connection members driven, two described connection members driven are adjacent to be arranged side by side, and described driving assembly and described pulley assembly vertical alignment.

11. refuse transfer station lowering or hoisting gear as claimed in claim 10, it is characterized in that, described assembly driven includes eight and connects rope, and described connection rope is perpendicular to described base, and the described rope that connects connects described connection member driven and described crossbeam connection member by described pulley.

12. refuse transfer station lowering or hoisting gear as claimed in claim 7, it is characterised in that described guide rail support includes two root posts, and two described columns are set the described base that is perpendicular to parallel to each other, and have a guide rail between two described columns.

13. refuse transfer station lowering or hoisting gear as claimed in claim 12, it is characterized in that, described first guide wheel assembly includes one first wheel seat and two the first limiting components, one Middle face of described first wheel seat is set be connected vertical with described cross bar, two described first limiting components are set and are installed on the one side that the one side of the described first wheel seat described cross bar of connection opposes, and described first limiting component embeds described guide rail slidably.

14. refuse transfer station lowering or hoisting gear as claimed in claim 13, it is characterized in that, described first guide wheel assembly includes four the first rollers, the two sides that described first roller is two one group in opposition to each other by being installed in rotation on described first wheel seat respectively, and described first roller of correspondence position is symmetrical.

15. refuse transfer station lowering or hoisting gear as claimed in claim 14, it is characterized in that, described second guide wheel assembly includes one second wheel seat and two the second limiting components, described second wheel seat is set and is connected with described platform, and two described first limiting components are connected towards described guide rail support with described second wheel seat.

16. refuse transfer station lowering or hoisting gear as claimed in claim 15, it is characterized in that, described second guide wheel assembly includes four the second rollers, the two sides that described second roller is two one group in opposition to each other by being installed in rotation on described second wheel seat respectively, and described second roller of correspondence position is symmetrical.