RU44109U1 - LIFT - Google Patents

Abstract

The utility model relates to industrial vehicles in construction, industry and the social sphere. The lift contains a base, two parallel arranged, of the same length with hinged ends of the lever, a support lever pivotally connected to the base and serving as a support for parallel levers, a hydraulic cylinder pivotally connected to one of the parallel levers and with a supporting lever, an L-shaped bracket with an inclined ( upper) and vertical (lower) shoulders. The inclined shoulder rests on the upper hinges of the parallel levers, and with its lower end, by means of a hinge with a vertical axis of rotation, is connected with the upper end of the vertical shoulder of the bracket. The lift comprises a lifting platform consisting of two articulated parts with the possibility of folding. The lifting platform is hinged with a horizontal axis of rotation with the lower end of the vertical arm of the bracket and has the ability to turn its folded parts from horizontal to vertical position. The lift includes a spring pivotally connected to the vertical arm of the bracket and the lifting platform, which, due to the interference, compensates for the weight of the lifting platform. The lifting platform has a guard in the form of pivoting flaps pivotally mounted along its edges and having the ability to rotate 235 °, as well as fixing when turning 135 °. The support lever has a groove covering the edge of the doorway of the room or vehicle and providing maximum use of the width of the doorway. Foldable design of the lifting platform and certain size ratios provide minimum dimensions and a small area of bearing support in the folded state. It is possible to lower the load below the base, as well as lift the load from this level, turn the lifting platform around the vertical axis and, due to this, expand the area served by the lift. Thanks to the applied spring with an interference fit, it is possible to maintain the lift with minimal energy consumption. The swing guard is multifunctional. It can protect the load from shifting and falling during lifting, and also serve as a ramp, facilitating loading and unloading.

Description

The utility model relates to lifting vehicles and can find application in construction, industry, as well as in the social sphere when loading disabled people in wheelchairs into vehicles for subsequent transportation.

A known lift containing a base and a loading platform with a guard located between them by a hinged-lever mechanism, such as "Nuremberg scissors", the ends of one of the upper and lower levers of which are mounted with the possibility of movement in horizontal guides, respectively mounted on the base and the loading platform, with which the ends of the other upper and lower levers of the specified mechanism are connected through articulated supports, connected with the hydraulic system, which includes a hydraulic cylinder, a hydraulic station and a control unit a hydraulic system interconnected hydraulically, and the hydraulic station is located on the base under the loading platform inside the articulated lever mechanism, mounted with the possibility of rotation in the folded position around the articulated bearings of the base with the hydraulic system locked due to the horizontal guides of the base with openings for leading upward ends of the articulated lever arms mechanism, and the hydraulic control unit is located on the base (1).

Known lift has the disadvantage that the cargo platform cannot lower to the level of the base and below. This does not allow loading by pushing or rolling loads “from the ground”. In addition, the lift in the folded, transport state has significant dimensions. It requires a supporting surface of the base, equal in area to the loading platform. The disadvantage is that the fence of the loading platform has a narrow functional purpose - preventing the displacement of goods, and cannot be transformed into a ramp that facilitates the loading and unloading of goods by pushing or rolling them.

In addition, when servicing the lift, the rotation of the cargo platform is associated with high energy costs. Performing this operation manually is not possible. Additional lifting equipment required. This leads to significant energy and maintenance costs for the lift.

Closest to the claimed utility model is a lift containing a base on which, by means of three pairs of tilted levers, a lifting platform is pivotally mounted, consisting of two parts interconnected by hinges placed between the pair of levers extreme from the hydraulic cylinder and the middle pair of levers near the last . When applying pressure to the hydraulic cylinder and turning the drive pairs of levers, the lifting force of the sections of the lifting platform at the point of their connection with the hinges goes into the traction, excluding bending stresses (2).

The specified lift has several disadvantages. The lifting platform cannot fall below the level of the base. This does not allow without additional lifting means to supply loads to the lifting platform that are below the level of support of the base of the lift.

In addition, the hoist when folded, with the hoist platform lowered, has significant dimensions. It requires a supporting area greater than that of a lifting platform. Being installed at the entrance to the room or vehicle, the lift, even when folded, will block the doorway, making it difficult for the personnel or passengers to enter and exit the lift.

The disadvantage of this lift is that the lifting platform before loading and unloading, in the process of lifting and lowering is not able to move in the direction of the transverse longitudinal axis of the lift. Place of loading and unloading should be strictly in the direction of the above axis. This limits the service area and the applicability of the lift.

The claimed utility model is aimed at providing the possibility of lowering the cargo below the base of the elevator and lifting the cargo from this level, expanding the area served by the elevator, reducing its size and occupied space when folded, making fuller use of the width of the cargo channel, for example, the doorway, through which is carried out loading and unloading, to reduce energy consumption during maintenance of the lift, the expansion of the functional purpose of the railing of the lifting platform.

This goal is achieved by the fact that the claimed utility model of the lift contains a base, a rectangular lifting platform, consisting of two parts connected by hinges, and having a guard, levers parallel in equal length with the hinged ends, having the ability to rotate around the hinge axes perpendicular to the plane of the arrangement of the levers, and a hydraulic cylinder pivotally coupled to one of the levers.

New in the claimed utility model is that the lift is equipped with two levers, an L-shaped bracket with an inclined (upper) and vertical (lower) shoulders, the lower end of the vertical shoulder by means of a hinge connected to the middle of the longer side of the lifting platform, and near the upper end inclined shoulder, leaning on the upper hinges of the levers. In addition, the lift is equipped with a compression spring with hinged ends, an upper hinge connected with a vertical arm of the bracket, and a lower one with a lifting platform, and is also equipped with a support arm pivotally connected to the base, with the possibility of rotation around a vertical axis and serving as a support for the lower hinges of the levers and hydraulic cylinders, and the dimensions of the lift have the following ratios:

e-m + [d + (c-b)] sin α> h; α = c cos (90-a); t = e + c * sin (90-α);

where d is the length of the levers;

C is the length of the upper arm of the bracket;

b is the distance between the upper hinges of the levers;

α is the angle of inclination of the line connecting the axis of the lower hinges of the levers to the horizon;

e is the length of the vertical arm of the bracket;

h is the height of the support surface of the lift;

a is the length of the base part of the lifting platform;

t is the width of the lifting platform;

m is the distance from the reference plane to the lowest located lower hinge of the elevator lever.

The novelty of the claimed utility model lies in the fact that the support arm near its articulated connection with the base has a groove with vertical walls, open in the opposite direction from the location of the lifting platform after lifting and covering the edge of the window or door openings through which loading is unloaded .

New in the claimed utility model is that the inclined arm of the bracket with its lower end is connected via a hinge to the upper end of the vertical arm of the bracket with the possibility of mutual rotation about the vertical axis of the above hinge.

The claimed utility model differs from the well-known lifts in that one part of the lifting platform, the swing platform, is rotatable 180 ° around the axis of the hinges connecting it to the other, the base part, and the rotary part has the ability to overlap with the base part, which remains in horizontal position. In addition, the hinge located on the lower end of the vertical arm of the bracket is connected to the base part of the lifting platform and has a horizontal axis of rotation parallel to the plane of arrangement of the levers and provides the ability to rotate the folded parts of the lifting platform from horizontal to vertical position and vice versa.

New in comparison with the known lifts is that the spring with the lower hinge is connected to the base part of the lifting platform eccentrically with respect to the horizontal axis of rotation of the base part, and is preloaded so that the moments relative to the above axis created by the force of preliminary deformation of the spring and the weight of the lifting platform in horizontal position, are equal in magnitude, but opposite in sign. In addition, the fence of the lifting platform is made in the form of rotary flaps pivotally connected to the edges of the lifting platform with the possibility of rotation 235 ° around the horizontal axis of the hinges lying at each flap on one straight line along the edge of the lifting platform, and when turning 135 ° from the position in which the flap is superimposed on the working surface of the lifting platform, it can be fixed from rotation. Moreover, each of the flaps has two hinges made in the form of cylindrical pairs of rotation so that due to the radial clearance they have the possibility of limited angular displacement of the axes, moreover, one of the hinges has a cylindrical axis with two parallel, symmetrical longitudinal flats, and a hole in which this axis is located, has a radial groove open in the hinge cavity, formed by two parallel planes, the distance between which is greater than between the flats of the axis.

The use in the elevator of the proposed ratios of the characteristic sizes of the components provides the possibility of lowering the elevating platform with the cargo below the base, as well as lifting the cargo from this level and reducing the dimensions of the elevator, the area it occupies when folded.

The inclusion of a L-shaped bracket with articulated shoulders in the hoist allows for the rotation of the hoisting platform around the vertical axis and, thus, the expansion of the area served by the hoist.

The implementation of the lifting platform from the base and rotary parts allows you to fold the lifting platform in a horizontal plane. The connection of the lower end of the vertical arm of the bracket by means of a hinge with the middle of the longer side of the lifting platform provides the ability to rotate its folded parts from horizontal to vertical position.

Providing the lift with a support arm pivotally connected to the base with the possibility of rotation around the vertical axis allows the elevator to be rotated around the above axis and placed in the folded state in the room or inside the vehicle.

The possibility of folding parts of the lifting platform in a horizontal plane and their subsequent rotation to a vertical position, as well as the rotation of the lift around the vertical axis of the hinge of the support arm and base, provide the lift with minimal dimensions when folded. Moreover, it occupies the area of the supporting surface.

smaller than the working surface of the lifting platform. Moreover, in the folded state, the lift does not block the doorway of the room or vehicle and does not interfere with the entry and exit of service personnel or passengers.

The use of a support lever with a groove covering the edge of the doorway of a room or vehicle provides maximum use of the width of the doorway (channel of movement of the load) when the lift is in operation. The inclusion of a spring in the lift, which compensates for the weight of the lifting platform due to its preload, allows you to manually rotate the lifting platform into a vertical position with minimal energy consumption before putting the lift into a folded state. No additional lifting equipment required. This reduces the cost of energy and money when servicing the lift.

Fencing the lifting platform in the form of flaps pivotally connected to the edges of the lifting platform with the possibility of rotation around the horizontal axis of the hinges by 235 ° and fixing at an angle of rotation of 135 °, allows to expand their functional purpose. When the flaps are fixed in the upper position, they can be used as a fence preventing the load from moving and falling when it is raised or lowered, and when the flaps are turned to a larger angle, until the free edge touches the ground or the cargo deck, as a ramp facilitating loading and unloading of goods .

Figure 1 shows a General view of the lift mounted on a vehicle with a lowered lifting platform before loading; figure 2 is a top view of figure 1 with two options for the position and loading of the lifting platform; figure 3 is a General view of the lift with a raised lifting platform before unloading it in the passenger compartment; figure 4 - after unloading in the folding process (the rotary part of the lifting platform is closed with its base part); figure 5 - in the folded position outside the vehicle; figure 6 - in the transport state (folded and deployed inward into the passenger compartment); Fig.7 is a top view of Fig.6; in Fig.8 is a view along arrow A in Fig.1; figure 9 is a section along BB in figure 1; figure 10 is a view along arrow B in figure 2; figure 11 is a view along arrow G in figure 5; on Fig presents a diagram of the lift with its characteristic dimensional parameters; Fig.13 is a view along arrow A in Fig.12.

The elevator consists of a base 1, two parallelly spaced equal lengths with hinged ends of the levers 2 and 3, which can be rotated around the hinge axes perpendicular to the plane of the arrangement of the levers, a supporting arm 4, pivotally connected to the base 1 with the possibility of rotation of the vertical axis and serving as a support for the lower hinges of levers 2 and 3.

The elevator includes a hydraulic cylinder 5, pivotally connected to a lever 2 and a supporting lever 4, an L-shaped bracket with an inclined (upper) 6 and a vertical (lower) 7 shoulders. Tilt shoulder

6 of the bracket near the upper end rests on the upper hinges of the levers 2 and 3, and with its lower end, by means of the hinge 8, is connected to the upper end of the vertical shoulder 7 of the bracket with the possibility of mutual rotation of the shoulders around the vertical axis of the above hinge. The elevator comprises a lifting platform consisting of a base 9 and a rotary 10 parts connected by hinges 11 with axes located on one straight, perpendicular plane of the arrangement of levers 2 and 3 with the possibility of reverse movement of the rotary part 10 around the axis of the above hinges from its working horizontal position to overlay to the base part 9 of the lifting platform and back. The hinge 12 of the vertical arm shoulder 7 is connected to the base part 9 of the lifting platform. Moreover, the hinge 12 has a horizontal axis of rotation parallel to the plane of arrangement of the levers 2 and 3 and provides the ability to reverse rotation of the folded parts 9 and 10 of the lifting platform from horizontal to vertical position and vice versa.

The lift includes a compression spring 13 (gas), the upper end pivotally connected to the horizontal axis 14 mounted on the vertical arm 7 of the bracket, and the lower end to the horizontal axis 15 of the lever 16 of the base part 9 of the lifting platform, the axis 15 being mounted on the lever 16 eccentrically relative to the axis the hinge 12 of the vertical arm 7 of the bracket so that with the horizontal working position of the lifting platform, the distance between the axles 14 and 15 is less than between the axes 12 and 14. The spring 13 is pre-compressed so that the moments are relatively B 12, a force generated by compression spring 13 pre-weighing and lifting platform in a horizontal position are equal in magnitude but opposite in direction.

The lifting platform has a guard made in the form of rotary safety flaps 17, through two hinges 18 and 19 connected to the edges of the lifting platform, with the possibility of rotation around the horizontal axes of the above hinges. Both hinges are made in the form of cylindrical plain bearings so that due to the radial clearance they have the possibility of limited rotation of the axes, moreover, at the hinge 19, the cylindrical axis has two parallel, symmetrical longitudinal flats, and the hole in which it is located has a radial groove open in the hinge cavity , the width of which is greater than the distance between the flats of the axis.

The elevator, for example, fixed by a base on the cargo floor of the car, in the transport state has folded base 9 and rotary 10 parts, in this form rotated in a vertical position, and is inside the passenger compartment. The lift works as follows. If it is necessary to load cargo “from the ground,” for example, a wheelchair with a disabled person sitting in it, the support arm 4 is deployed around the vertical axis of the hinge connecting

it with the base 1, and the elevator is led out through the doorway outside the vehicle interior, while the groove of the support arm 4 covers the edge of the doorway. Next, lay out the lifting platform. Initially, its folded base 9 and rotary 10 parts are rotated around the horizontal axis of the hinge 12 of the vertical shoulder to a horizontal position. Then the rotary part is rotated 180 ° around the horizontal axes of the hinges 11. The lifting platform assumes a working position. If the loading object, for example, a disabled person in a wheelchair, expects loading on the side of the road, then the lifting platform is deployed around the vertical axis of the hinge 8, bringing the lifting platform closer to the side of the road. Then, pressure is supplied to the hydraulic cylinder 5 so that due to the force developed by the hydraulic cylinder, levers 2 and 3 are turned away from the car. The lifting platform is lowered. When it touches the ground, the pressure supply to the hydraulic cylinder is stopped. After that, the flaps 17, touching the free edges of the working surface of the lifting platform, are deployed around their hinges 18 and 19. Moreover, the flap 17, closest to the car, is fixed after turning 135 °. For this, the axis of the hinge 19, cut off by two flats, is lowered into the radial groove of the hinge. The flap located in front of the loading object is turned until it is supported by the free edge on the ground. In this position, the flap makes it easier to place the load on a lifting platform, such as rolling a wheelchair. After placing the load on the lifting platform, the flap 17, which acts as a ramp, is deployed and fixed in the upper inclined position similarly to the flap closest to the car. After that, both flaps are ready to perform a safety function - to prevent spontaneous displacement of the load from the lifting platform when it is raised. If the lifting platform before loading was deployed around the vertical axis of the hinge 8, then briefly apply pressure to the hydraulic cylinder and lift the lifting platform from the ground. After this, by rotation, it is returned to its original position, symmetrical with respect to the doorway. Then turn on the pressure supply to the hydraulic cylinder and complete the lifting of the cargo to the level of the flooring of the passenger compartment. Next, the flap located in front of the doorway is removed from a fixed position. To do this, it is lifted from the side of the fixing hinge 19. In this case, the axis having two flats is shifted up and out of the radial groove of the hinge 19 and, being in a cylindrical hole, gets the opportunity to rotate with the flap. The flap is turned towards the car until it rests on the edge of the cargo deck of the passenger compartment. In this position, the flap acts as a ramp, facilitating the subsequent movement of cargo from the lifting platform to the passenger compartment, for example, rolling a wheelchair with a disabled person. In this position, the lifting platform and the flaps also carry out the reverse operation — moving the cargo from the car to the lift.

After performing the necessary loading and unloading, the lift is folded. To do this, deploy the flaps in the touch position of the working surface of the lifting platform. Rotate the rotary part 10 around the hinges 11 until it is applied to the base part 9 of the lifting platform. Both parts of the platform when folded rotate around the axis of the hinge 12 of the bracket to a vertical position. After that, the support arm 4 is rotated around the vertical axis of the hinge of the base 1 and the lift is led through the doorway into the passenger compartment so that it does not overlap the doorway and occupies the minimum area of the passenger compartment. In this condition, the lift is ready for transport.

The manufacture of the lift, taking into account the ratio of characteristic sizes, proposed in the form of the inequality e-m + [d + (c-b)] sin α> h, makes it possible to lower the platform below the base of the elevator, as well as to lift the load from this level. The indicated ratio is obtained based on the analysis of the lift circuit. The figure (Fig. 12) shows the position of the links of the elevator mechanism with the maximally lowered lifting platform. Levers 2 are closed and inclined to the horizon at an angle a. Based on this, the expression of the left side of the above ratio is obtained. This expression defines the maximum permissible amount of lowering of the lifting platform. The claimed technical result “providing the possibility of lowering the load below the base of the lift and lifting the load from this level” will be ensured in all cases when the maximum achievable lowering of the lifting platform will be greater than the height of the supporting surface of the lift h.

The implementation of the lift, taking into account the ratio a = c · cos (90-α); t = е + с · sin (90-α) will ensure complete coincidence of the dimensions of the lever system and the arm with the lifting platform when folded (see Fig. 12, the left extreme position of the links of the elevator mechanism). At the same time, the overall dimensions and the supporting area occupied by the lift are minimized. The fulfillment of these relations, as well as the presence of the base and rotary parts of the lifting platform, connecting the lower end of the vertical arm of the bracket by means of a hinge to the middle of the longer side of the lifting platform, providing the lift with a support arm pivotally connected to the base with the possibility of rotation around the vertical axis, provide the claimed technical the result, expressed by a decrease in size and occupied by the supporting area of the elevator when folded.

SOURCES OF INFORMATION.

1. RF patent No. 2081054, MKI B 66 F 3/22

2. RF patent No. 2035389, MKI B 60 F 3/22, 7/08

Claims (8)

1. A hoist comprising a base, a rectangular lifting platform, consisting of two parts connected by hinges and having a guard parallel to the same length with articulated ends, levers that can be rotated around articulated axes perpendicular to the plane of arrangement of the levers, and a hydraulic cylinder pivotally connected to one of the levers, characterized in that it is equipped with two levers, an L-shaped bracket with an inclined (upper) and vertical (lower) shoulders, the lower end of the vertical shoulder p by means of a hinge connected to the middle of the longer side of the lifting platform, and near the upper end of the inclined shoulder, resting on the upper hinges of the levers, in addition, the lift is equipped with a compression spring with hinged ends, an upper hinge connected to the vertical arm of the bracket, and the lower one - with the lifting platform , and is also equipped with a support lever pivotally connected to the base with the possibility of rotation around a vertical axis and serving as a support for the lower hinges of the levers and hydraulic cylinder, and the dimensions of the lift have the following relationships: e-m + [d + (c-b)] sin α> h; α = c cos (90-α); t = e + c * sin (90-α); where d is the length of the levers; C is the length of the upper arm of the bracket; b is the distance between the upper hinges of the levers; α is the angle of inclination of the line connecting the axis of the lower hinges of the levers to the horizon; e is the length of the vertical arm of the bracket; h is the height of the support surface of the lift; a is the length of the base part of the lifting platform; t is the width of the lifting platform; m is the distance from the reference plane to the lowest located lower hinge of the elevator lever. 2. The lift according to claim 1, characterized in that the support arm near its connection with the base has a groove with vertical walls, open to the side opposite from the location of the lifting platform after lifting, and covering the edge of the window or door openings through which loading and unloading. 3. The lift according to claim 1, characterized in that the inclined arm of the bracket with its lower end is pivotally connected to the upper end of the vertical arm of the bracket with the possibility of mutual rotation around the vertical axis of the hinge. 4. The lift according to claim 1, characterized in that one part of the lifting platform is swivel, capable of 180 ° reversible rotation around the hinge axes connecting it to the other, the base part of the lifting platform, and the rotary part has the ability to overlap the base part remaining in this horizontal position. 5. The lift according to claim 1, characterized in that the hinge located on the lower end of the vertical arm of the bracket is connected to the base part of the lifting platform and has a horizontal axis of rotation parallel to the plane of arrangement of the levers, and allows the folded parts of the lifting platform to be rotated from horizontal to vertical position and back. 6. The lift according to claim 1, characterized in that the compression spring with a lower hinge is connected to the base part of the lifting platform eccentrically relative to the horizontal axis of rotation of the base part, and is preloaded so that the moments relative to the above axis created by the pre-deformation of the spring and weight lifting platform in a horizontal position, are equal in magnitude, but opposite in direction. 7. The lift according to claim 1, characterized in that the fence of the lifting platform is made in the form of rotary flaps pivotally connected to the edges of the lifting platform, with the possibility of their rotation 235 ° around the horizontal axis of the hinges lying at each flap on one straight line along the edge of the lifting platform, and when turning 135 ° from the position in which the flap is superimposed on the working surface of the lifting platform, it can be fixed from turning. 8. The lift according to claim 1, characterized in that each of the flaps has two hinges made in the form of cylindrical pairs of rotation so that due to the radial clearance they have the possibility of limited angular displacement of the axes, moreover, one of the hinges has a cylindrical axis with two parallel symmetrical longitudinal flats, and the hole in which this axis is located has a radial groove open in the hinge cavity, formed by two parallel planes, the distance between which is greater than between the flats of the axis.