RU62914U1 - DEVICE FOR SUSPENSION AND WEIGHT CONTROL OF THE LIFT WORK PLATFORM - Google Patents

Abstract

The utility model relates to material handling equipment and can be used in lifts with a working platform. A device for suspending and controlling the mass of the working platform of the elevator comprises a power-receiving element mounted on the head of the elevator boom with the possibility of plane-parallel movement, connected to the base of the operating platform through power transmitting units equipped with strain gauges that record shear strain. The power-receiving element of the head of the elevator boom and the base of the working platform are interconnected using two parallel and spaced relative to each other power-transmitting units made in the form of force-measuring sensors of the frame type, with end fastening to the power-receiving element of the elevator and the base of the working platform using threaded fasteners. Each of the indicated load-measuring sensors of the frame type includes two parallel force-absorbing beams, located one above the other and symmetrically spaced relative to the longitudinal axis of the sensor, each of which is made in the form of a bar with a rectangular cross section and has its own measuring section, on which the force-sensing side walls the beams are made in opposite directions through holes, separated by a thin vertical force-measuring partition, on which the proper the first strain gauge, which records the shear strain, and two vertical elements connecting the end parts of the power-receiving beams to form a load-measuring frame, in which the sockets for these threaded fasteners are made. Achievable technical result is expressed in increasing the reliability of the device and reducing the complexity of mounting the device on a lift. 6 c.p. f-ly, 7 ill.

Description

The utility model relates to material handling equipment and can be used on discontinuous lifting machines designed to move people with tools and materials and carry out work within the service area.

A device for suspending and controlling the mass of a working platform of a lift is known, comprising a horizontal support platform in the form of a frame and four supports for mounting the working platform on a support platform, each support being made in the form of a horizontally located power-receiving element, the ends of which are connected, respectively, with the support platform and a working platform, and each power-sensing element has its own measuring section equipped with a strain gauge transducer (see RF patent No. 2146060, G01G 19/02, 2 10.10.1999, Fig.6). This design has enhanced protection of strain gauges from external atmospheric influences due to the introduction of two bushings that cover the outside of the power-sensing element, however, this significantly complicates the design, complicates the assembly of supports and adjustment of this device.

A device is also known for suspending and controlling the mass of a working platform of a lift, comprising a support platform and four supports for mounting the platform on a support platform, each support being made in the form of a power-receiving beam, the ends of which are rigidly connected, respectively, to the support platform and the platform, and each the force-sensing beam has its own measuring section, equipped with strain gauges that measure the bending deformation of the beam (see US patent No. 4573542, MKI G01G 19/52, G01G 3/14, NKI 177/132, 03.03.1986). When using this design, it is necessary to fulfill two mutually exclusive requirements: to increase

Accuracy of mass measurement requires a sufficiently flexible force-sensing beam, and to increase reliability in operation and ensure a sufficient margin of safety, it is necessary to increase the thickness of the force-sensing beam to the detriment of the accuracy of the platform mass control. In addition, this design has insufficient protection of strain gauges from external influences, and it is difficult to provide increased protection for strain gauges, since any protection will require the introduction of additional elements in the platform support structure, or a radical change in the structure of the support.

Closest to the claimed utility model in terms of essential features is a device for suspending and controlling the mass of the working platform of the elevator, comprising a force-sensing element mounted on the head of the elevator boom with the possibility of plane-parallel movement, connected to the base of the operating platform via power transmitting nodes equipped with strain gauges that record shear deformation (see RF patent for utility model No. 58521, B66C 13/16, G01G 3/14, 11/27/2006). In this device, load cells are supports for mounting the work platform on a support platform. The number of supports with which the working platform is mounted on a horizontal support platform is determined by the designer, but it cannot be less than three, since the plane can be defined by at least three points. In this case, from the point of view of the convenience of design and calculations, it is advisable to have four supports, which complicates the design of this device and the adjustment of the mass control system of the working platform during operation.

The objective of this utility model is to develop an effective and easy-to-use device for suspending and controlling the mass of the working platform of the elevator, providing a sufficiently high accuracy of controlling the mass of the working platform at a reduced cost

manufacture that can be easily installed on existing lifts.

Thus, the achieved technical result is expressed in increasing the reliability of the device and reducing the complexity of mounting the device on a lift.

To achieve the objectives and other advantages, a device is proposed for suspending and controlling the mass of the working platform of the elevator, comprising a force-sensing element mounted on the head of the elevator boom with the possibility of plane-parallel movement, connected to the base of the operating platform via power transmitting units equipped with strain gauges that record shear strain, in which the power-receiving element of the head of the boom of the elevator and the base of the working platform are interconnected using two parallel and spaced relative to each other power transmitting units made in the form of load-measuring sensors of the frame type, with end fastening to the power-receiving element of the lift and the base of the working platform using threaded fasteners, while each of these load-measuring sensors of the frame type includes two parallel, one above the other and symmetrically spaced relative to the longitudinal axis of the sensor force-sensing beams, each of which is made and in the form of a bar with a rectangular cross-section and has its own measuring section, on which opposite side-through notches are made in the side walls of the force-sensing beam, separated by a thin vertical force-measuring partition, on which is mounted its own strain gauge that records shear deformation, and two vertical elements connecting the end parts of the power-receiving beams with each other with the formation of the load-measuring frame, in which the nests are made under the decree nnye threaded fasteners.

Preferably, each strain gauge transducer comprises two strain gauges located at right angles to each other and at an angle of 45 ° to the force-sensing beam, the strain gauges of the upper and lower force-sensing beams of the force-measuring frame forming one measuring bridge with four active resistances. Preferably, in each load-measuring frame, the force-sensing beams and vertical elements are made in one piece in the form of a parallelepiped with a cavity in the vertical side wall.

Preferably, the load-measuring frame is made with protrusions on the end surfaces in which these sockets for threaded fasteners are made.

Preferably, each load cell is equipped with a signal processing unit from strain gauges installed in the cavity of the load cell.

Preferably, the load-measuring frame is equipped with covers that isolate the cavity of the frame and through holes from the external environment, while the signal processing unit from the strain gauges is mounted on one of these covers.

The utility model is based on the connection of the power-receiving element of the head of the elevator boom with the base of the working platform using two parallel and spaced relative to each other power-transmitting nodes made in the form of force-measuring sensors of the frame type, with end fastening to the power-receiving element of the elevator and the base of the working platform using threaded fasteners elements, which simplifies the overall design of the device for suspension of the working platform of the elevator and greatly simplifies the adjustment The control system mass of the working platform during operation. At the same time, the supporting capabilities of the working platform and the performance of the suspension with the control of the mass of the working platform during any movements of the lift and any

operator movements on a working platform without using a parallelogram mechanism.

The load cell in which each strain gauge transducer contains two strain gages located at right angles to each other and at an angle of 45 ° to the force-sensing beam, the strain gages of the upper and lower force-sensing beams of the force-measuring frame form one measuring bridge with four active resistances, provides a constant output signal of the power measuring system regardless of the position of the load on the working platform and the movements of the operator.

The implementation in each load-measuring frame of power-sensing beams and vertical elements in one piece in the form of a parallelepiped with a cavity in the vertical side wall, simplifies the design of the load-measuring sensor and the technology of its manufacture.

The implementation of the load-measuring frame with protrusions on the end surfaces, in which the sockets for threaded fasteners are made, ensure a tight fit of the load-measuring sensor to the power-receiving element of the head of the boom of the elevator and the base of the working platform and the absence of spurious deformations of the load-measuring frame during its installation.

Providing each load sensor with a signal processing unit from strain gauges installed in the cavity of the load measuring frame makes it possible to produce a single-block force sensor with a minimum distance between strain gauges and the signal processing unit, thereby reducing the influence of external noise on the signal recorded from strain gauges. At the same time, the load cell itself is an autonomous cell in which strain gauge transducers and a signal processing unit are located, which makes it possible to simultaneously protect them from the influence of the external environment.

Equipping the load-measuring frame with covers provides reliable protection from external conditions of strain gauge transducers, signal processing unit and connecting wires.

The fastening of the signal processing unit from strain gauge transducers on one of these covers simplifies the manufacturing technology of the frame type load cell sensor.

Figure 1 shows the proposed device for suspension of the working platform on the boom of the elevator, side view; figure 2 - a view of figure 1 (without a working platform); figure 3 - load cell on an enlarged scale; figure 4 and 5 - section bb and bb in figure 3; figure 6 - placement of the signal processing unit with strain gauge converters; 7 is a connection diagram of strain gauges in the measuring bridge.

The device for suspending the working platform on the boom of the elevator comprises a power-receiving element 2 mounted on the head 1 of the elevator boom, connected to the base 3 of the operating platform 4 with two parallel and spaced apart power transmitting units made in the form of force-measuring sensors 5 of a frame type with end fastening to the power-sensing element of the elevator and the base of the working platform using threaded fasteners.

The tip 1 of the boom lift is made with elements 6 and 7 for articulating with the end of the boom and with the hydraulic actuator rod (not shown) of the leveling system of the base of the working platform. Such a connection provides a plane-parallel movement of the power-sensing element 2 and, accordingly, the base 3 of the working platform during the operation of the elevator.

The base 3 of the working platform is made in the form of a bracket 8, equipped with a power transmitting element 9 and two beams 10, on which the working platform 4 is fixed using four supports 11. As a rule, a connection unit with electrically insulating bushings is used to fasten the working platform to the supporting platform.

Each load sensor 5 includes two force-sensing beams parallel to each other located in the same vertical plane - the upper 12 and lower 13 in the form of square-shaped beams, each of which has its own measuring section 14, on which the sides of the power-receiving beam are counter-made directional through holes 15 separated by a thin vertical force-measuring partition 16, on which strain gauge transducers are mounted on one side Ateliers 17, recording shear deformation, and two vertical elements 18 connecting the end parts of the power-receiving beams to form a force-measuring frame.

Preferably, in each load-measuring frame, the force-sensing beams and vertical elements are made in one piece in the form of a parallelepiped with a cavity 19 in the vertical side wall, while the force-measuring frame itself is made with protrusions 20 on the end surfaces adjacent to the force-sensing element 2 and to the force-transmitting element 9, and in the vertical elements 18 at the locations of the protrusions 20, threaded sockets 21 are made for bolts 22 for the end connection of the load sensor 5 on one side with a power the receiving element 2, and on the other hand, with the power-transmitting element 9. Preferably, the through holes 15 are made in the form of cylindrical nests of the same diameter and depth and cavity of the holes filled with a sealing polymer material 23 that covers the strain gauges 17. In each power-receiving beam, they are made into cylindrical sockets channels 24 for electrical wiring from sensors to pressure output 25.

In the second embodiment shown in FIG. 6, a signal processing unit 26 from strain gauge transducers is installed in the cavity of the load-measuring frame, while the load-measuring frame is equipped with covers 27 that isolate the cavity 19 and through cavities 15 from the external environment, and the signal processing unit 26 itself from

strain gauge transducers mounted on one of these covers.

Each load sensor 5 contains two strain gauge transducers 17, one of which is located on the upper 12 load beam and the other on the lower 13 load beam. Strain gauge consists of two series-connected resistors. The resistors are located on the vertical partition 16 at an angle of 45 ° relative to the longitudinal axis of the power-receiving beam and at an angle of 90 ° relative to each other. Resistors 30 and 31 are located on the top 12 of the load beam, and resistors 32 and 33 are located on the bottom. Resistors 30, 32 are subjected to tensile stresses, and resistors 31, 33 are subjected to compressive stresses. The resistors of the upper and lower power receiving beams form one measuring bridge with four active resistances 30-33 connected to the signal processing unit 26 from strain gauges, the signals from which enter the microprocessor of the lift safety device (not shown in the drawing), in which the output algebraic addition signals of load sensors.

The inventive device operates as follows. If there is an operator or any load on the working platform, regardless of where they are located, the total mass of the working platform and operator is transmitted to the force sensors, while the total force acting on them is equal to the total mass of the working platform and operator. The force acting on any of the force sensors is perceived by its force-sensing beams 12 and 13, which are deformed. An increase in the effective force leads to a change in the deformation of the force-sensing beams. At the same time, the deformation of the vertical partition 16 changes and, accordingly, the resistors of the strain gauges 17 change their resistance. When changing the resistance of the resistors of strain gauges

the output signals from the measuring bridges change, and the change in the output signal corresponds to the total change in the resistance of all strain gauges, and, therefore, the sum of the output signals corresponds to the total mass of the load and the operator.

The proposed device can be manufactured industrially in factories producing equipment for hoisting machines. The device can be used strain gauge type KF5R firm TOV "VEDA" (Ukraine) or other strain gauge converters of this type. To process the measurement results, you can use the safety devices of lifting machines with the summation of the signals of the load sensors, for example, the OPG-1 load limiter, manufactured by the Arzamas Instrument-Making Plant.

Claims (7)

1. A device for suspending and controlling the mass of the working platform of the elevator, comprising a force-sensing element mounted on the head of the elevator boom with the possibility of plane-parallel movement, connected to the base of the operating platform via force transmitting nodes equipped with strain gauges that record shear strain, characterized in that it has a force-sensing element of the head the boom of the lift and the base of the working platform are interconnected using two parallel and spaced apart relative to the other of the power transmitting units made in the form of force-measuring sensors of the frame type, with end fastening to the power-sensing element of the elevator and the base of the working platform using threaded fasteners, while each of these force-measuring sensors of the frame type includes two parallel, located one above the other and force-sensing beams symmetrically spaced relative to the longitudinal axis of the sensor, each of which is made in the form of a bar with a rectangular cross section has its own measuring section, on which opposite lateral notches are made in the side walls of the force-sensing beam, separated by a thin vertical force-measuring partition, on which is mounted its own strain-gauge transducer, which records the shear strain, and two vertical elements connecting the end parts of the force-sensing beams with the formation of force the framework in which the sockets for the specified threaded fasteners are made. 2. The device according to claim 1, characterized in that each strain gauge transducer contains two strain gauges located at right angles to each other and at an angle of 45 ° to the force-sensing beam, and the strain gauges of the upper and lower force-sensing beams of the force-measuring frame form one measuring bridge with four active resistances. 3. The device according to claim 1, characterized in that in each load-measuring frame, the power-sensing beams and vertical elements are made in one piece in the form of a parallelepiped with a cavity in the vertical side wall. 4. The device according to claim 3, characterized in that the load-measuring frame is made with protrusions on the end surfaces in which these nests are made for threaded fasteners. 5. The device according to claim 3, characterized in that each load cell is equipped with a signal processing unit from strain gauges installed in the cavity of the load cell. 6. The device according to claim 5, characterized in that the load-measuring frame is equipped with covers that isolate the cavity of the frame and through openings from the influence of the external environment. 7. The device according to claim 6, characterized in that the signal processing unit from the strain gauges is mounted on one of these covers.