CN113523835B - Compensation assistance type medium movable automobile seat pressure lifting platform - Google Patents

Abstract

The invention discloses a compensation assistance type medium moving type automobile seat pressure lifting platform which comprises a frame, a base, an intermediate intervention type magnetomotive moving mechanism, a compensation type seat rotating processing mechanism, an induction type medium heating, transmitting and drying mechanism, a self-unfolding type bidirectional stepping clamping and positioning mechanism, a pneumatic type pressure jacking lifting mechanism and a roller wheel auxiliary sliding mechanism. The invention belongs to the technical field of lifting platforms, and particularly relates to a compensation assistance type medium movable automobile seat pressure lifting platform; the invention provides a compensation assistance type medium moving type automobile seat pressure lifting platform which integrates processing, cleaning and drying, can quickly clamp and fix a seat, realizes positioning of a seat processing position under the condition of no fixed structure, and is convenient for collecting and storing scrap iron and cleaning agents.

Description

Compensation assistance type medium movable automobile seat pressure lifting platform

Technical Field

The invention belongs to the technical field of lifting platforms, and particularly relates to a compensation assistance type medium movable automobile seat pressure lifting platform.

Background

The lifting platform is a hoisting machine for vertically transporting people or objects. The device also refers to a device for vertical conveying in logistics systems such as factories and automatic warehouses, and various plane conveying devices are often arranged on a lifting platform, are used as connecting devices of conveying lines with different heights, and are widely applied to operations such as high-altitude installation and maintenance besides being used for conveying goods with different heights.

The invention discloses a lifting platform for processing an automobile seat, which is disclosed in the Chinese patent with the publication number of CN208895588U, and comprises a lifting platform body, wherein a lower mounting plate is arranged below the lifting platform body, a fixed seat is fixedly mounted at the top of the lower mounting plate, a sliding groove is formed in the top of the fixed seat, the inner walls of two sides of the sliding groove are fixedly provided with the same positioning rod, a base is slidably sleeved on the positioning rod, the top of the base is fixedly mounted with the bottom of the lifting platform body, a rectangular groove is formed in the base, a plurality of wheels are rotatably mounted in the rectangular groove, the bottoms of the wheels extend to the lower side of the base, the wheels are in contact with the inner wall of the bottom of the sliding groove, and a screw rod is fixedly mounted at the bottom of one side of the base. The invention avoids the deviation from the preset position when the automobile seat framework is drilled to a certain extent, saves time and labor, is beneficial to the use of workers, and has defects in the aspects of stability and safety.

At present the lift platform of using in car seat processing factory is mostly fluid pressure type lift platform, if the maintenance is improper or the condition that solid impurity will appear easily for the long time of the overhaul, air and water invasion hydraulic system, thereby influence the stability of lift platform when using, if car seat adds the sudden fastener of lift platform when processing such as drilling is polished, its processing effect must receive the influence, current car seat processing lift platform uses singlely, can not satisfy the processing demand to car seat, only confine to and process certain aspect to the seat, the seat after the processing can not wash, often will carry the seat that processes to the washing region, make the seat spill everywhere at handling iron fillings like this, very big reduction seat processing lift platform's availability factor.

Disclosure of Invention

Aiming at the situation and overcoming the defects of the prior art, the invention provides a compensation assistance type medium moving type automobile seat pressure lifting platform, wherein an intermediary intervention type magnetomotive force moving mechanism is arranged according to the characteristics of homopolar repulsion and heteropolar attraction of magnets, so that the seat can be processed in multiple stations without intervention of moving equipment, and the technical problem that the seat can not be moved without moving equipment is solved; the compensation type seat rotating processing mechanism arranged by adopting the compensation assistance idea realizes assistance to the seat in the overturning processing, greatly reduces the working load pressure of a motor and the rotating supporting pressure of a main shaft, and solves the technical problems that the seat is required to be overturned and the seat is not required to be overturned, which are difficult to solve in the prior art; the induction type medium heating, transmitting and drying mechanism arranged according to the electromagnetic induction heating principle realizes hot gas transmission to dry the processed seat, and solves the technical problem that the seat cannot be dried under the condition of no intervention of drying equipment; the utility model provides a collection processing, washing and dry integration more than combining, can press from both sides tight fixedly fast to the seat, realize the fixed to seat processing position under the condition of no fixed knot structure, and be convenient for collect the compensation helping hand formula medium removal type car seat pressure lift platform of storage to iron fillings and cleaner.

The technical scheme adopted by the invention is as follows: the invention relates to a compensation assisting type medium moving type automobile seat pressure lifting platform which comprises a frame, a base, an intermediary intervention type magnetomotive moving mechanism, a compensation type seat rotating processing mechanism, an induction type medium heating, transmitting and drying mechanism, a self-unfolding type bidirectional stepping clamping and positioning mechanism, a pneumatic type pressure jacking lifting mechanism and a roller wheel auxiliary sliding mechanism, wherein the base is arranged below the frame, the compensation type seat rotating processing mechanism is arranged on the inner wall of the frame, the intermediary intervention type magnetomotive moving mechanism is arranged on the compensation type seat rotating processing mechanism, the induction type medium heating, transmitting and drying mechanism is arranged on the side wall of one end of the frame, the self-unfolding type bidirectional stepping clamping and positioning mechanism is arranged on the compensation type seat rotating processing mechanism, the pneumatic type pressure jacking lifting mechanism is arranged on the base, and the roller wheel auxiliary sliding mechanism is arranged on the frame, the compensation type seat rotary processing mechanism comprises a sliding table, a processing table, a fixed rotating shaft, a connecting turntable, a movable sliding rail, a movable sliding block, an auxiliary guide rail, a compensation sliding block, a fixed south-pole magnet, a fixed north-pole magnet, a rotary south-pole magnet, a motor box, a rotary motor, a sliding support, a rotary main shaft, a rotary connecting plate and a sliding groove.

As a further preference of the scheme, the movable slide rail is arranged on the inner wall of the frame, the movable slide block is slidably arranged on the movable slide rail, the fixed rotating shaft is arranged on one side of the movable slide block away from the movable slide rail, the connecting rotary table is rotatably arranged on the fixed rotating shaft, the sliding groove is arranged on one side of the frame away from the movable slide rail, the sliding groove is a through arrangement, the sliding table is arranged on one side of the connecting rotary table away from the movable slide block, the rotary connecting plate is arranged on one side of the sliding table away from the connecting rotary table, the auxiliary guide rail is arranged at one end of the frame away from the movable slide rail, the auxiliary guide rail is symmetrically arranged on the upper wall and the bottom wall of the frame, the compensation slide block is slidably arranged on the auxiliary guide rail, the sliding bracket is arranged on one side of the compensation slide block away from the auxiliary guide rail, the motor box is arranged on one side of the sliding bracket away from the compensation slide block, and the rotating motor is arranged in the motor box, the rotary main shaft penetrates through the motor box and is arranged at the power output end of the rotary motor, one side of the rotary main shaft, which is far away from the rotary motor, penetrates through the sliding groove and is arranged on the side wall of the rotary connecting plate, the fixed south-pole magnet is arranged on the side wall of the motor box, which is far away from the rotary motor, the fixed north-pole magnet is arranged on the side wall of the rotary main shaft, the fixed north-pole magnet is arranged on the side wall of the motor box, the fixed south-pole magnet is arranged on the side wall of the rotary main shaft, the fixed north-pole magnet is arranged on the side wall of the motor box, the rotary main shaft is arranged on the side wall of the rotary main shaft, which is far away from the fixed south-pole magnet, the rotary north-pole magnet and the rotary south-pole magnet are symmetrically arranged on the upper wall and the bottom wall of the rotary main shaft, the processing table is arranged on the upper wall of the sliding table, the rotary motor drives the rotary main shaft to rotate, the rotary main shaft drives the sliding table through the rotary connecting turntable to rotate around the fixed rotating shaft, the rotary north-pole magnet, the rotary main shaft rotates to one side of the fixed north-pole magnet, the rotary south-pole magnet rotates to one side of the fixed south-pole magnet, the fixed south-pole magnet is mutually attracted through the magnetic force of the fixed south-pole magnet, the fixed north-pole magnet and the rotary south-pole magnet attract each other through magnetic force, so that the rotary spindle is assisted in the rotating process.

Preferably, the induction type medium heating, transmitting and drying mechanism comprises a heating metal rod, a high-frequency coil, an air pump, an air exhaust pipeline, an exhaust pipeline, a shunt pipeline, a transmission pipeline, a conical spray head, a fixed support, a hot air generating box and an air inlet pipeline, wherein the hot air generating box is arranged on the side wall of one end of the frame, the heating metal rod is arranged on the inner wall of the hot air generating box, the high-frequency coil is arranged on the inner wall of the hot air generating box outside the heating metal rod, the air pump is arranged on the upper wall of the hot air generating box, the air exhaust pipeline is communicated and arranged between the power input end of the air pump and the hot air generating box, the fixed support is symmetrically arranged on the upper wall of the hot air generating box on two sides of the air pump, the shunt pipeline is arranged between one ends of the fixed support far away from the hot air generating box, the exhaust pipeline is communicated and arranged between the power output end of the air pump and the shunt pipeline, and a plurality of the transmission pipelines are communicated and arranged on one side of the shunt pipeline far away from the exhaust pipeline, the conical spray head is communicated with one side of the transmission pipeline far away from the shunt pipeline, the air inlet pipeline is communicated with one side of the hot air generation box far away from the frame, the high-frequency coil is electrified to heat the heating metal rod, strong magnetic beams with instantly changed polarity are generated in the high-frequency coil, the heating metal rod is placed in the high-frequency coil, the magnetic beams can penetrate through the whole heating metal rod, corresponding eddy current can be generated in the heating metal rod in the direction opposite to the heating current, the heating metal rod is heated, the temperature of the heating metal rod rises to enable the temperature of air in the hot air generation box to rise, the air pump extracts hot air in the hot air generation box through the air extraction pipeline, the hot air enters the transmission pipeline through the exhaust pipeline, and the transmission pipeline discharges the hot air through the conical spray head.

Further, the self-unfolding bidirectional stepping clamping and positioning mechanism comprises fixed rotating plates, bidirectional screws, sliding screw blocks, rotating plates, positioning slide rails, clamping sliders, bidirectional stepping clamping supports, guide plates and guide rods, wherein the fixed rotating plates are symmetrically arranged on two sides of the sliding table in pairs as a group, the bidirectional screws are rotatably arranged between the fixed rotating plates, two ends of the bidirectional screws respectively penetrate through the fixed rotating plates, the rotating plates are symmetrically arranged on two sides of the bidirectional screws, the sliding screw blocks are arranged on the bidirectional screws, the sliding screw blocks are in threaded connection with the bidirectional screws, the positioning slide rails are symmetrically arranged on the upper wall of the processing table, the clamping sliders are slidably arranged on the positioning slide rails, the bidirectional stepping clamping supports are arranged between the sliding screw blocks and the clamping sliders, the guide plates are symmetrically arranged on two sides of the sliding table, and the guide plates are arranged on the side walls of the sliding table between the fixed rotating plates, the guide rod penetrates through the bidirectional stepping clamping support and is arranged between the guide plate and the side wall of the fixed rotating plate at one end of the frame close to the motor box, the bidirectional stepping clamping support at one end of the frame close to the motor box is arranged on the guide rod in a sliding manner, the rotating plate drives the bidirectional screw rod to rotate, the bidirectional screw rod drives the sliding screw block to move oppositely or back to back, the bidirectional stepping clamping support at one end of the frame close to the motor box moves along the guide rod to drive the clamping slide block to slide along the positioning slide rail, the bidirectional stepping clamping support at one end of the frame far away from the motor box drives the clamping slide block to slide along the positioning slide rail, when a seat needs to be machined, the sliding screw block moves back to back, the sliding screw block drives the clamping slide block to leave the positioning slide rail through the bidirectional stepping clamping support, the bidirectional stepping clamping support at one end of the frame close to the motor box keeps horizontal movement along the guide rod, and the bidirectional stepping clamping support at one end of the frame far away from the motor box has no guide rod, the bidirectional stepping clamping support drives the clamping slide block to rotate towards the two sides of the sliding table to be opened, so that the seat can be conveniently installed on the clamping slide block to be processed.

Wherein, the medium intervenes formula magnetomotive force moving mechanism includes positive direction drive fixed electromagnet, negative direction drive fixed electromagnet, drying processing movable electromagnet, mechanized processing movable electromagnet and superconducting material shielding layer, the one end inner wall of frame is located to positive direction drive fixed electromagnet, the one end inner wall that positive direction drive fixed electromagnet was kept away from to the frame is located to the negative direction drive fixed electromagnet, drying processing movable electromagnet locates the slip spiral shell piece lateral wall that the sliding tray is close to negative direction drive fixed electromagnet one end, and negative direction drive fixed electromagnet sets up with drying processing movable electromagnet relatively, mechanized processing movable electromagnet locates the slip spiral shell piece lateral wall that the sliding tray is close to positive direction drive fixed electromagnet one end, and positive direction drive fixed electromagnet sets up with mechanized processing movable electromagnet relatively, the fixed electro-magnet of positive direction drive is located respectively to the superconducting material shielding layer, the fixed electro-magnet of reverse direction drive, the drying processing removes the electro-magnet and the mechanized processing removes the electro-magnet outside, the fixed electro-magnet of positive direction drive and the mechanized processing removes the electro-magnet and circular telegram respectively, positive direction drive fixed electro-magnet and the homopolar setting of mechanized processing removal electro-magnet, positive direction drive fixed electro-magnet passes through repulsion force promotion mechanized processing removal electro-magnet and drives the sliding table and remove to one side of the fixed electro-magnet of reverse direction drive, reverse direction drive fixed electro-magnet and drying processing removal electro-magnet circular telegram respectively, reverse direction drive fixed electro-magnet and drying processing removal electro-magnet homopolar setting, reverse direction drive fixed electro-magnet promotes the drying processing removal electro-magnet through the repulsion force and removes to one side of the fixed electro-magnet of positive direction drive.

Specifically, the pneumatic pressure jacking lifting mechanism comprises a gas pressure pump, a pressure gas conveying pipeline, a lifting cylinder, a lifting column and a limiting plate, the lifting cylinders are symmetrically arranged on the upper walls of the two ends of the base in pairs, the lifting cylinders are cavities with openings at the upper ends, the lifting column is arranged in the lifting cylinder in a sliding way, one side of the lifting column, which is far away from the lifting cylinder, is arranged on the bottom wall of the frame, the limiting plates are arranged on the inner wall of the lifting cylinder close to the bottom, the gas pressure pumps are symmetrically arranged on the upper walls of the two ends of the base, the pressure gas conveying pipelines are respectively communicated and arranged between the power output end of the gas pressure pump and the lifting cylinder, the limiting plate below is located to the one end of pressure gas pipeline intercommunication lift cylinder, and in gas pressure pump transmitted pressure gas to the lift post through pressure gas pipeline, pressure gas was with lift post jack-up, and the lift post drives the frame and goes up and down.

Further, the supplementary slide mechanism of running roller includes three hole direction connecting plates, supplementary pivot and supplementary removal wheel, on the rotating main shaft between sliding stand and the frame inner wall was located to three hole direction connecting plates symmetry, three hole direction connecting plates rotated and located rotating main shaft, supplementary removal wheel symmetry is located in the sliding tray, and supplementary removal wheel roll-action is located the sliding tray, supplementary pivot is located between supplementary removal wheel and the three hole direction connecting plates, and the sliding stand removes and drives three hole direction connecting plates through rotating main shaft and remove, and three hole direction connecting plates drive supplementary removal wheel through supplementary pivot and remove along the sliding tray.

Still further, the base is equipped with iron fillings collecting box, seat washing case, washing liquid collection box, support frame and recovery pipeline, the iron fillings collecting box is located the base and is kept away from one end upper wall that the steam takes place the case, the support frame symmetry is located the base and is close to the upper wall that the steam takes place case one end, the washing liquid collection box is located one side that the base was kept away from to the support frame, the seat washing case is located the base upper wall between iron fillings collecting box and the washing liquid collection box, the recovery pipeline intercommunication is located between washing liquid collection box and the seat washing case.

Furthermore, the frame is close to the one end lateral wall of positive direction drive fixed electro-magnet and is equipped with the controller, the controller respectively with positive direction drive fixed electro-magnet, the fixed electro-magnet of negative direction drive, drying processing removal electro-magnet, mechanized processing removal electro-magnet, rotating electrical machines, high frequency coil, aspiration pump and gas force pump electric connection.

The invention with the structure has the following beneficial effects: the scheme is that the compensation assistance type medium moving type automobile seat pressure lifting platform realizes the movement of a seat processing platform through an intermediary intervention type magnetomotive moving mechanism, the method can complete the multi-position movement of the seat without the intervention of transmission equipment, so that the seat processing device has multiple functions, the seat is driven to move under the action of a medium according to the principle that homopolar repulsion and heteropolar attraction mutually perform various processing treatments on the seat, a fixed electromagnet and a mechanical processing moving electromagnet are driven to be homopolar to be arranged in the positive direction, the fixed electromagnet is driven to be in the positive direction, the mechanical processing moving electromagnet is driven to drive the sliding table to move towards one side of the fixed electromagnet in the negative direction through repulsion, the fixed electromagnet is driven to be in the negative direction and the drying processing moving electromagnet are in the homopolar arrangement, and the drying processing moving electromagnet is driven to move towards one side of the fixed electromagnet in the positive direction through repulsion; the method has the advantages that the assistance in the overturning process of the sliding table is realized through the compensation type seat rotating processing mechanism, on one hand, the working load pressure of the rotating motor is reduced to a certain extent, on the other hand, the probability that the rotating main shaft deforms in long-time rotating operation is avoided, and the rotating motor is effectively protected; under the condition that no drying equipment is involved, the seat is dried after being cleaned through an induction type medium heating, transmitting and drying mechanism, the method effectively finishes the drying of the seat by using a few structures, a high-frequency coil is electrified to heat a heating metal rod, the temperature of the heating metal rod is increased to raise the temperature of air in a hot air generating box, a suction pump extracts hot air in the hot air generating box through an air extraction pipeline, the hot air enters a transmission pipeline through an exhaust pipeline, and the transmission pipeline exhausts the hot air through a conical nozzle to dry the seat; the seat is fixedly clamped by the self-unfolding type bidirectional stepping clamping and positioning mechanism, the seat is fixedly machined under the condition that no clamping device is involved by the method, the guide rod is arranged at one end of the sliding table, the bidirectional stepping clamping support without guide rod guiding is automatically unfolded to facilitate installation of the seat, clamping and installation are integrally arranged, complex steps in the using process of the device are effectively reduced, and one-step in-place in the true sense is realized.

Drawings

FIG. 1 is a schematic view of an internal structure of a pressure elevating platform of a compensation-assisted medium mobile car seat according to the present invention;

FIG. 2 is a perspective view of a pressure elevating platform of a compensation booster type medium mobile car seat according to the present invention;

FIG. 3 is a front view of a pressure elevating platform of a compensation boosting type medium mobile car seat according to the present invention;

FIG. 4 is a rear view of a pressure elevating platform of a compensation booster type medium mobile car seat according to the present invention;

FIG. 5 is a left side view of a pressure elevating platform of a compensation boosting type medium mobile car seat according to the present invention;

FIG. 6 is a right side view of a pressure elevating platform of a compensation boosting type medium mobile car seat according to the present invention;

FIG. 7 is a top view of a pressure elevating platform of a compensation-assisted type medium movable type car seat according to the present invention;

FIG. 8 is a sectional view taken along section A-A of FIG. 4;

FIG. 9 is a sectional view of portion B-B of FIG. 7;

fig. 10 is a partial cross-sectional view of C-C of fig. 7.

Wherein, 1, a frame, 2, a base, 3, an intermediate intervention type magnetic power moving mechanism, 4, a positive direction driving fixed electromagnet, 5, a negative direction driving fixed electromagnet, 6, a drying processing moving electromagnet, 7, a mechanical processing moving electromagnet, 8, a superconducting material shielding layer, 9, a compensation type seat rotating processing mechanism, 10, a sliding table, 11, a processing table, 12, a fixed rotating shaft, 13, a connecting turntable, 14, a moving slide rail, 15, a moving slide block, 16, an auxiliary guide rail, 17, a compensation slide block, 18, a fixed south pole magnet, 19, a fixed north pole magnet, 20, a rotating north pole magnet, 21, a rotating south pole magnet, 22, a motor box, 23, a rotating motor, 24, a sliding support, 25, a rotating main shaft, 26, a rotating connecting plate, 27, a sliding groove, 28, an induction type medium heating transmission drying mechanism, 29 and a heating metal rod, 30. 31, a suction pump, 32, a suction pipeline, 33, an exhaust pipeline, 34, a shunt pipeline, 35, a transmission pipeline, 36, a conical nozzle, 37, a fixed bracket, 38, a hot gas generation box, 39, an air inlet pipeline, 40, a self-unfolding type bidirectional stepping clamping and positioning mechanism, 41, a fixed rotating plate, 42, a bidirectional screw rod, 43, a sliding screw block, 44, a rotating plate, 45, a positioning slide rail, 46, a clamping slide block, 47, a bidirectional stepping clamping bracket, 48, a guide plate, 49, a guide rod, 50, a pneumatic pressure jacking lifting mechanism, 51, a gas pressure pump, 52, a pressure gas transmission pipeline, 53, a lifting cylinder, 54, a lifting column, 55, a roller auxiliary sliding mechanism, 56, a three-hole guide connecting plate, 57, an auxiliary rotating shaft, 58, an auxiliary moving wheel, 59, a limiting plate, 60, an iron scrap collecting box, 61, a seat cleaning box, 62, A cleaning liquid recovery box 63, a support frame 64, a recovery pipeline 65 and a controller.

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus should not be construed as limiting the present invention.

As shown in fig. 1-10, the invention relates to a compensation assisted medium moving type automobile seat pressure lifting platform, which comprises a frame 1, a base 2, an intermediary intervention type magnetomotive moving mechanism 3, a compensation type seat rotary processing mechanism 9, an induction type medium heating, transmitting and drying mechanism 28, a self-unfolding type bidirectional stepping clamping and positioning mechanism 40, a pneumatic type pressure lifting mechanism 50 and a roller auxiliary sliding mechanism 55, wherein the base 2 is arranged below the frame 1, the compensation type seat rotary processing mechanism 9 is arranged on the inner wall of the frame 1, the intermediary intervention type magnetomotive moving mechanism 3 is arranged on the compensation type seat rotary processing mechanism 9, the induction type medium heating, transmitting and drying mechanism 28 is arranged on the side wall of one end of the frame 1, the self-unfolding type bidirectional stepping clamping and positioning mechanism 40 is arranged on the compensation type seat rotary processing mechanism 9, the pneumatic type pressure lifting mechanism 50 is arranged on the base 2, the roller auxiliary sliding mechanism 55 is arranged on the frame 1, and the compensation type seat rotating processing mechanism 9 comprises a sliding table 10, a processing table 11, a fixed rotating shaft 12, a connecting turntable 13, a movable sliding rail 14, a movable sliding block 15, an auxiliary guide rail 16, a compensation sliding block 17, a fixed south-pole magnet 18, a fixed north-pole magnet 19, a rotating north-pole magnet 20, a rotating south-pole magnet 21, a motor box 22, a rotating motor 23, a sliding support 24, a rotating spindle 25, a rotating connecting plate 26 and a sliding groove 27.

As shown in fig. 6-8, the movable slide rail 14 is disposed on the inner wall of the frame 1, the movable slide block 15 is slidably disposed on the movable slide rail 14, the fixed rotating shaft 12 is disposed on a side of the movable slide block 15 away from the movable slide rail 14, the connecting rotary disc 13 is rotatably disposed on the fixed rotating shaft 12, the sliding groove 27 is disposed on a side of the frame 1 away from the movable slide rail 14, the sliding groove 27 is disposed in a through manner, the sliding table 10 is disposed on a side of the connecting rotary disc 13 away from the movable slide block 15, the rotating connecting plate 26 is disposed on a side of the sliding table 10 away from the connecting rotary disc 13, the auxiliary guide rail 16 is disposed on an end of the frame 1 away from the movable slide rail 14, the auxiliary guide rails 16 are symmetrically disposed on the upper wall and the bottom wall of the frame 1, the compensation slide block 17 is slidably disposed on the auxiliary guide rail 16, the sliding bracket 24 is disposed on a side of the sliding bracket 24 away from the compensation slide block 17, the rotary motor 23 is arranged in the motor box 22, the rotary spindle 25 penetrates through the motor box 22 and is arranged at the power output end of the rotary motor 23, one side of the rotary spindle 25, which is far away from the rotary motor 23, penetrates through the sliding groove 27 and is arranged on the side wall of the rotary connecting plate 26, the fixed south-pole magnet 18 is arranged on the side wall of the motor box 22, which is far away from one side of the rotary spindle 25, the fixed north-pole magnet 19 is arranged on the side wall of the motor box 22, which is far away from one side of the fixed south-pole magnet 18, the rotary north-pole magnet 20 and the rotary south-pole magnet 21 are symmetrically arranged on the upper wall and the bottom wall of the rotary spindle 25, the processing table 11 is arranged on the upper wall of the sliding table 10, the rotary motor 23 drives the rotary spindle 25 to rotate, the rotary spindle 25 drives the sliding table 10 through the rotary connecting plate 26, the sliding table 10 rotates around the fixed rotating shaft 12 through the connecting turntable 13, the rotary spindle 25 rotates to drive the rotary magnet 20 to rotate to one side of the fixed south-pole magnet 18, and the rotary south-pole magnet 21 rotates to one side of the fixed north-pole magnet 19, the fixed south magnet 18 and the rotary north magnet 20 are attracted to each other by magnetic force, and the fixed north magnet 19 and the rotary south magnet 21 are attracted to each other by magnetic force, whereby the rotary main shaft 25 is assisted in rotation.

Referring to fig. 4, 7 and 9, the induction type medium heating, transferring and drying mechanism 28 includes a heating metal rod 29, a high frequency coil 30, a suction pump 31, a suction pipe 32, an exhaust pipe 33, a shunt pipe 34, a transfer pipe 35, a conical nozzle 36, a fixing bracket 37, a hot gas generating box 38 and an air inlet pipe 39, the hot gas generating box 38 is disposed on one end side wall of the frame 1, the heating metal rod 29 is disposed on the inner wall of the hot gas generating box 38, the high frequency coil 30 is disposed on the inner wall of the hot gas generating box 38 outside the heating metal rod 29, the suction pump 31 is disposed on the upper wall of the hot gas generating box 38, the suction pipe 32 is connected between the power input end of the suction pump 31 and the hot gas generating box 38, the fixing bracket 37 is symmetrically disposed on the upper wall of the hot gas generating box 38 on both sides of the suction pump 31, the shunt pipe 34 is disposed between the fixing bracket 37 and the end far from the hot gas generating box 38, the exhaust pipe 33 is connected between the power output end of the suction pump 31 and the shunt pipe 34, a plurality of groups of transmission pipelines 35 are communicated with one side of the diversion pipeline 34 far away from the exhaust pipeline 33, a conical nozzle 36 is communicated with one side of the transmission pipeline 35 far away from the diversion pipeline 34, an air inlet pipeline 39 is communicated with one side of the hot air generation box 38 far away from the frame 1, the high-frequency coil 30 is electrified to heat the heating metal bar 29, a strong magnetic beam with instantly changed polarity is generated in the high-frequency coil 30, the heating metal bar 29 is placed in the high-frequency coil 30, the magnetic beam penetrates through the whole heating metal bar 29, corresponding eddy current is generated in the heating metal bar 29 in the direction opposite to the heating current, so as to heat the heating metal bar 29, the temperature of the heating metal bar 29 is increased to increase the air temperature in the hot air generation box 38, the air pump 31 extracts the hot air in the hot air generation box 38 through the air extraction pipeline 32, and the hot air enters the transmission pipeline 35 through the exhaust pipeline 33, the transfer duct 35 discharges the hot gas through a conical spray head 36.

As shown in fig. 1, 2 and 7, the self-unfolding bidirectional stepping clamping and positioning mechanism 40 includes two fixed rotating plates 41, two bidirectional screws 42, sliding screws 43, rotating plates 44, positioning slide rails 45, clamping sliders 46, bidirectional stepping clamping brackets 47, guide plates 48 and guide rods 49, the two fixed rotating plates 41 are symmetrically disposed on two sides of the sliding table 10 in pairs, the two bidirectional screws 42 are rotatably disposed between the fixed rotating plates 41, two ends of the two bidirectional screws 42 respectively penetrate through the fixed rotating plates 41, the rotating plates 44 are symmetrically disposed on two sides of the two bidirectional screws 42, the sliding screws 43 are disposed on the two bidirectional screws 42, the sliding screws 43 are in threaded connection with the two bidirectional screws 42, the positioning slide rails 45 are symmetrically disposed on the upper wall of the machining table 11, the clamping sliders 46 are slidably disposed on the positioning slide rails 45, the bidirectional stepping clamping brackets 47 are disposed between the sliding screws 43 and the clamping sliders 46, the guide plates 48 are symmetrically disposed on two sides of the sliding table 10, the guide plate 48 is arranged on the side wall of the sliding table 10 between the fixed rotating plates 41, the guide rod 49 penetrates through the bidirectional stepping clamping support 47 and is arranged between the guide plate 48 and the side wall of the fixed rotating plate 41 at the end, close to the motor box 22, of the frame 1, the bidirectional stepping clamping support 47 at the end, close to the motor box 22, of the frame 1 is arranged on the guide rod 49 in a sliding manner, the rotating plate 44 drives the bidirectional screw rod 42 to rotate, the bidirectional screw rod 42 rotates to drive the sliding screw block 43 to move relatively or oppositely, the bidirectional stepping clamping support 47 at the end, close to the motor box 22, of the frame 1 moves along the guide rod 49 to drive the clamping slide block 46 to slide along the positioning slide rail 45, the bidirectional stepping clamping support 47 at the end, far from the motor box 22, of the frame 1 drives the clamping slide block 46 to slide along the positioning slide rail 45, when the seat needs to be machined, the sliding screw block 43 moves oppositely, the clamping slide block 43 drives the clamping slide block 46 to leave the positioning slide rail 45 through the bidirectional stepping clamping support 47, the bidirectional stepping clamping bracket 47 at one end of the frame 1 close to the motor box 22 keeps moving horizontally along the guide rod 49, and the bidirectional stepping clamping bracket 47 at one end of the frame 1 far away from the motor box 22 drives the clamping slide block 46 to rotate and open towards the two sides of the sliding table 10 due to the fact that the guide rod 49 does not guide the bidirectional stepping clamping bracket 47, so that the seat can be conveniently installed on the clamping slide block 46 for processing.

As shown in fig. 9, the intermediary intervention type magnetomotive force moving mechanism 3 comprises a forward direction driving fixed electromagnet 4, a reverse direction driving fixed electromagnet 5, a drying processing moving electromagnet 6, a mechanical processing moving electromagnet 7 and a superconducting material shielding layer 8, wherein the forward direction driving fixed electromagnet 4 is arranged on the inner wall of one end of the frame 1, the reverse direction driving fixed electromagnet 5 is arranged on the inner wall of one end of the frame 1 far away from the forward direction driving fixed electromagnet 4, the drying processing moving electromagnet 6 is arranged on the side wall of a sliding screw block 43 at one end of the sliding table 10 close to the reverse direction driving fixed electromagnet 5, the reverse direction driving fixed electromagnet 5 is arranged opposite to the drying processing moving electromagnet 6, the mechanical processing moving electromagnet 7 is arranged on the side wall of the sliding screw block 43 at one end of the sliding table 10 close to the forward direction driving fixed electromagnet 4, the forward direction driving fixed electromagnet 4 is arranged opposite to the mechanical processing moving electromagnet 7, the superconducting material shielding layers 8 are respectively arranged on the outer sides of the positive direction driving fixed electromagnet 4, the negative direction driving fixed electromagnet 5, the drying processing movable electromagnet 6 and the mechanical processing movable electromagnet 7, the positive direction driving fixed electromagnet 4 and the mechanical processing movable electromagnet 7 are respectively electrified, the positive direction driving fixed electromagnet 4 and the mechanical processing movable electromagnet 7 are arranged in the same pole, the positive direction driving fixed electromagnet 4 pushes the mechanical processing movable electromagnet 7 to drive the sliding table 10 to move to one side of the negative direction driving fixed electromagnet 5 through repulsion force, the negative direction driving fixed electromagnet 5 and the drying processing movable electromagnet 6 are respectively electrified, the negative direction driving fixed electromagnet 5 and the drying processing movable electromagnet 6 are arranged in the same pole, and the negative direction driving fixed electromagnet 5 pushes the drying processing movable electromagnet 6 to move to one side of the positive direction driving fixed electromagnet 4 through repulsion force.

As shown in fig. 1, 2 and 10, the pneumatic pressure jacking lifting mechanism 50 includes a gas pressure pump 51, a pressure gas delivery pipe 52, a lifting cylinder 53, lifting columns 54 and a limit plate 59, wherein two lifting cylinders 53 are symmetrically arranged on the upper walls of two ends of the base 2, the lifting cylinder 53 is a cavity with an open upper end, the lifting columns 54 are slidably arranged in the lifting cylinders 53, one side of the lifting columns 54 far away from the lifting cylinders 53 is arranged on the bottom wall of the frame 1, the limit plate 59 is arranged on the inner wall of the lifting cylinders 53 close to the bottom, the gas pressure pump 51 is symmetrically arranged on the upper walls of two ends of the base 2, the pressure gas delivery pipes 52 are respectively communicated between the power output end of the gas pressure pump 51 and the lifting cylinders 53, one end of the pressure gas delivery pipe 52 communicated with the lifting cylinders 53 is arranged below the limit plate 59, the gas pressure pump 51 delivers pressure gas into the lifting columns 54 through the pressure gas delivery pipe 52, the lifting columns 54 are jacked up by the pressure gas, the lifting column 54 drives the frame 1 to lift.

As shown in fig. 4 and 7, the roller auxiliary sliding mechanism 55 includes a three-hole guide connecting plate 56, an auxiliary rotating shaft 57 and an auxiliary moving wheel 58, the three-hole guide connecting plate 56 is symmetrically disposed on the rotating main shaft 25 between the sliding table 10 and the inner wall of the frame 1, the three-hole guide connecting plate 56 is rotatably disposed on the rotating main shaft 25, the auxiliary moving wheel 58 is symmetrically disposed in the sliding groove 27, the auxiliary moving wheel 58 is rotatably disposed in the sliding groove 27, the auxiliary rotating shaft 57 is disposed between the auxiliary moving wheel 58 and the three-hole guide connecting plate 56, the sliding table 10 moves to drive the three-hole guide connecting plate 56 to move through the rotating main shaft 25, and the three-hole guide connecting plate 56 drives the auxiliary moving wheel 58 to move along the sliding groove 27 through the auxiliary rotating shaft 57.

As shown in fig. 1-4, the base 2 is provided with an iron scrap collecting box 60, a seat cleaning box 61, a cleaning solution recycling box 62, a supporting frame 63 and a recycling pipeline 64, the iron scrap collecting box 60 is arranged on the upper wall of one end of the base 2 far away from the hot air generating box 38, the supporting frame 63 is symmetrically arranged on the upper wall of one end of the base 2 close to the hot air generating box 38, the cleaning solution recycling box 62 is arranged on one side of the supporting frame 63 far away from the base 2, the seat cleaning box 61 is arranged on the upper wall of the base 2 between the iron scrap collecting box 60 and the cleaning solution recycling box 62, and the recycling pipeline 64 is communicated between the cleaning solution recycling box 62 and the seat cleaning box 61.

As shown in fig. 1 and 3, a controller 65 is disposed on a side wall of the frame 1 near the forward driving fixed electromagnet 4, and the controller 65 is electrically connected to the forward driving fixed electromagnet 4, the reverse driving fixed electromagnet 5, the drying processing moving electromagnet 6, the machining processing moving electromagnet 7, the rotating motor 23, the high-frequency coil 30, the air pump 31, and the air pressure pump 51, respectively.

When the device is used specifically, in the first embodiment, in an initial state, the mechanically-processed moving electromagnet 7 is attached to the forward-direction driving fixed electromagnet 4, the sliding table 10 is located above the scrap iron collecting box 60, the controller 65 controls the gas pressure pump 51 to start, the gas pressure pump 51 conveys pressure gas into the lifting cylinder 53 through the pressure gas conveying pipeline 52, the pressure gas pushes the lifting column 54 to slide along the inner wall of the lifting cylinder 53, the lifting column 54 is lifted to drive the frame 1 to ascend, the rotating plate 44 is rotated forward, the rotating plate 44 drives the bidirectional screw 42 to rotate, the bidirectional screw 42 drives the sliding screw block 43 to move along the bidirectional screw 42, the bidirectional screw 42 drives the clamping slide block 46 to slide along the positioning slide rail 45 through the bidirectional stepping clamping support 47 to leave the positioning slide rail 45, the bidirectional stepping clamping support 47 at one end of the frame 1, which is close to the motor box 22, moves along the guide rod 49 to drive the clamping slide block 46 to slide along the positioning slide rail 45, the bidirectional stepping clamping bracket 47 at one end of the frame 1, which is far away from the motor box 22, drives the clamping slider 46 to slide along the positioning slide rail 45, the bidirectional screw 42 rotates to drive the bidirectional stepping clamping bracket 47 at one end of the frame 1, which is far away from the motor box 22, to rotate towards two sides of the sliding table 10, the seat is installed on the positioning slide rail 45, the rotating plate 44 is rotated reversely, the rotating plate 44 drives the bidirectional screw 42 to rotate, the bidirectional screw 42 drives the bidirectional stepping clamping bracket 47 to return through the sliding screw 43, the bidirectional stepping clamping bracket 47 at one end of the frame 1, which is far away from the motor box 22, drives the clamping slider 46 to rotate to be horizontal to the positioning slide rail 45, the operator holds the bidirectional stepping clamping bracket 47 with a hand column to continue rotating the rotating plate 44, the bidirectional stepping clamping bracket 47 at one end of the frame 1, which is far away from the motor box 22, slides onto the positioning slide rail 45, the bidirectional stepping clamping bracket 47 at one end of the frame 1, which is near the motor box 22, drives the clamping slider 46 to slide along the guide rod 49 and enter the positioning slide rail 45, the clamping slide block 46 relatively moves to be close to a slide rail of the seat to fixedly clamp the seat, the controller 65 respectively controls the positive direction to drive the fixed electromagnet 4 and the mechanized processing movable electromagnet 7 to be electrified, the positive direction drives the fixed electromagnet 4 and the mechanized processing movable electromagnet 7 to be arranged in different poles, the positive direction drives the fixed electromagnet 4 and the mechanized processing movable electromagnet 7 to mutually adsorb through magnetic force to fix the processing position of the sliding table 10, the seat is mechanically processed after the sliding table 10 is fixed, and scrap iron generated in the mechanical processing process of the seat is cleaned and enters the scrap iron collecting box 60 to be stored; in the second embodiment, the seat after processing is cleaned to remove the excessive iron chips on the seat, the controller 65 controls the magnetic pole of the fixed electromagnet 4 driven in the forward direction to change, the fixed electromagnet 4 driven in the forward direction and the movable electromagnet 7 for mechanical processing are arranged in the same pole, the sliding table 10 is pushed to move by the repulsion between the fixed electromagnet 4 driven in the forward direction and the movable electromagnet 7 for mechanical processing, the controller 65 respectively controls the fixed electromagnet 5 driven in the reverse direction and the movable electromagnet 6 for drying processing to be electrified, the fixed electromagnet 5 driven in the reverse direction and the movable electromagnet 6 for drying processing are arranged in different poles, the fixed electromagnet 5 driven in the reverse direction adsorbs the movable electromagnet 6 for drying processing by magnetic force, the movable electromagnet 6 for drying processing drives the sliding table 10 to move to one side of the hot air generating box 38, one side of the sliding table 10 slides along the movable sliding rail 14 by the movable sliding block 15 via the connecting rotary table 13, the side of the slide 10 remote from the connecting disk 13 is connected to a three-hole guide connecting plate 56, which three-hole guide connecting plate 56 is rolled in the slide groove 27 by means of an auxiliary rotating shaft 57 via an auxiliary moving wheel 58, thereby make the sliding table 10 move to the frame 1 intermediate position, the controller 65 controls the rotating electrical machines 23 to start, the rotating electrical machines 23 drives the rotating main shaft 25 to rotate, the rotating main shaft 25 drives the sliding table 10 to overturn through the rotating connecting plate 26, the sliding table 10 rotates around the fixed rotating shaft 12 through the connecting turntable 13 to drive the sliding table 10 to complete the overturn, the seat is made to rotate to one side close to the seat cleaning box 61, the controller 65 controls the gas pressure pump 51 to reduce the gas pressure, the lifting cylinder 53 slides down along the inner wall of the lifting column 54 to drive the seat to descend into the seat cleaning box 61, the seat is immersed in the cleaning agent in the seat cleaning box 61, and the iron filings on the seat slide down into the seat cleaning box 61 under the action of the cleaning agent; in the third embodiment, the seat after cleaning is dried, the controller 65 controls the gas pressure pump 51 to increase the gas pressure, the lifting column 54 slides up along the inner wall of the lifting cylinder 53, the lifting column 54 drives the frame 1 to ascend, the frame 1 drives the seat to leave the seat cleaning box 61, and stands still for a period of time, so that the redundant cleaning agent falls into the seat cleaning box 61, the controller 65 controls the rotating motor 23 to start, the rotating motor 23 drives the rotating main shaft 25 to rotate, the rotating main shaft 25 drives the sliding table 10 to turn over towards one side of the hot gas generating box 38 through the rotating connecting plate 26, the sliding table 10 is pushed to position the seat below the conical nozzle 36, the controller 65 controls the high-frequency coil 30 to be powered on, the high-frequency coil 30 heats the heating metal rod 29, the temperature of the heating metal rod 29 rises to raise the temperature inside the hot gas generating box 38, the controller 65 controls the gas pump 31 to start, the air pump 31 sucks hot air in the hot air generating box 38 into the shunt pipeline 34 through the air exhaust pipeline 33 through the air exhaust pipeline 32, and the shunt pipeline 34 sprays the hot air to the seat through the conical spray head 36 so as to dry the seat; in the fourth embodiment, the seat after drying is disassembled, the controller 65 controls the rotary motor 23 to start, the rotary motor 23 drives the rotary spindle 25 to rotate, the rotary spindle 25 drives the sliding table 10 to turn to the initial state through the rotary connecting plate 26, the controller 65 controls the reverse direction driving fixed electromagnet 5 and the drying processing moving electromagnet 6 to be electrified respectively, the controller 65 controls the reverse direction driving fixed electromagnet 5 and the drying processing moving electromagnet 6 to be arranged in the same pole, the reverse direction driving fixed electromagnet 5 pushes the drying processing moving electromagnet 6 through the repulsive force, the controller 65 controls the driving fixed electromagnet 4 and the mechanical processing moving electromagnet 7 to be electrified respectively, the controller 65 controls the forward direction driving fixed electromagnet 4 and the mechanical processing moving electromagnet 7 to be arranged in different poles, the forward direction driving fixed electromagnet 4 adsorbs the mechanical processing moving electromagnet 7 through the magnetic force, therefore, the sliding table 10 drives one side of the fixed electromagnet 4 to move towards the positive direction, the fixed electromagnet 4 and the mechanical processing movable electromagnet 7 are attached through magnetic force in the positive direction, the rotating plate 44 rotates forwards, the rotating plate 44 drives the bidirectional screw 42 to rotate, the bidirectional screw 42 drives the sliding screw block 43 to move back to back along the bidirectional screw 42, the sliding screw block 43 drives the clamping slide block 46 to slide out along the positioning slide rail 45 through the bidirectional stepping clamping support 47, the bidirectional stepping clamping support 47 at one end, far away from the motor box 22, of the frame 1 leaves the clamping slide block 46 under the condition of no guide rod 49 for guiding and then opens towards two sides, the processed seat is taken down from the positioning slide rail 45 in a sliding mode, the seat to be processed is installed, and the operation is repeated to complete the processing of the seat.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

The present invention and its embodiments have been described above, and the description is not intended to be limiting, and the drawings are only one embodiment of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (4)

1. The utility model provides a compensation helping hand formula medium removal type car seat pressure lift platform, includes frame (1) and base (2), its characterized in that: comprises an intermediary intervention type magnetic power moving mechanism (3), a compensation type seat rotary processing mechanism (9), an induction type medium heating transmission drying mechanism (28), a self-unfolding type bidirectional stepping clamping and positioning mechanism (40), a pneumatic pressure jacking lifting mechanism (50) and a roller auxiliary sliding mechanism (55), wherein the base (2) is arranged below the frame (1), the compensation type seat rotary processing mechanism (9) is arranged on the inner wall of the frame (1), the intermediary intervention type magnetic power moving mechanism (3) is arranged on the compensation type seat rotary processing mechanism (9), the induction type medium heating transmission drying mechanism (28) is arranged on the side wall of one end of the frame (1), the self-unfolding type bidirectional stepping clamping and positioning mechanism (40) is arranged on the compensation type seat rotary processing mechanism (9), and the pneumatic pressure jacking lifting mechanism (50) is arranged on the base (2), the roller auxiliary sliding mechanism (55) is arranged on the frame (1); the induction type medium heating, conveying and drying mechanism (28) comprises a heating metal rod (29), a high-frequency coil (30), an air extracting pump (31), an air extracting pipeline (32), an exhaust pipeline (33), a shunt pipeline (34), a transmission pipeline (35), a conical spray head (36), a fixed support (37), a hot air generating box (38) and an air inlet pipeline (39), wherein the hot air generating box (38) is arranged on one end side wall of the frame (1), the heating metal rod (29) is arranged on the inner wall of the hot air generating box (38), the high-frequency coil (30) is arranged on the inner wall of the hot air generating box (38) outside the heating metal rod (29), the air extracting pump (31) is arranged on the upper wall of the hot air generating box (38), the air extracting pipeline (32) is communicated between the power input end of the air extracting pump (31) and the hot air generating box (38), and the fixed support (37) is symmetrically arranged on the upper walls of the hot air generating boxes (38) on two sides of the air extracting pump (31), the diversion pipeline (34) is arranged between one ends, far away from the hot gas generation box (38), of the fixed support (37), the exhaust pipeline (33) is communicated between the power output end of the air suction pump (31) and the diversion pipeline (34), a plurality of groups of transmission pipelines (35) are communicated and arranged on one side, far away from the exhaust pipeline (33), of the diversion pipeline (34), the conical spray head (36) is communicated and arranged on one side, far away from the diversion pipeline (34), of the transmission pipeline (35), and the air inlet pipeline (39) is communicated and arranged on one side, far away from the frame (1), of the hot gas generation box (38); the compensation type seat rotary processing mechanism (9) comprises a sliding table (10), a processing table (11), a fixed rotating shaft (12), a connecting turntable (13), a movable sliding rail (14), a movable sliding block (15), an auxiliary guide rail (16), a compensation sliding block (17), a fixed south-pole magnet (18), a fixed north-pole magnet (19), a rotary north-pole magnet (20), a rotary south-pole magnet (21), a motor box (22), a rotary motor (23), a sliding support (24), a rotary main shaft (25), a rotary connecting plate (26) and a sliding groove (27), wherein the movable sliding rail (14) is arranged on the inner wall of a frame (1), the movable sliding block (15) is arranged on the movable sliding rail (14) in a sliding manner, the fixed rotating shaft (12) is arranged on one side, away from the movable sliding rail (14), of the movable sliding block (15), and the connecting turntable (13) is arranged on the fixed rotating shaft (12) in a rotating manner, the sliding groove (27) is arranged on one side, away from the movable sliding rail (14), of the frame (1), the sliding groove (27) is arranged in a penetrating mode, the sliding table (10) is arranged on one side, away from the movable sliding block (15), of the connecting rotary table (13), and the rotating connecting plate (26) is arranged on one side, away from the connecting rotary table (13), of the sliding table (10); the auxiliary guide rail (16) is arranged at one end, far away from the movable slide rail (14), of the frame (1), the auxiliary guide rail (16) is symmetrically arranged on the upper wall and the bottom wall of the frame (1), the compensation sliding block (17) is arranged on the auxiliary guide rail (16) in a sliding manner, the sliding support (24) is arranged on one side, far away from the auxiliary guide rail (16), of the compensation sliding block (17), the motor box (22) is arranged on one side, far away from the compensation sliding block (17), of the sliding support (24), the rotating motor (23) is arranged in the motor box (22), the rotating main shaft (25) penetrates through the motor box (22) and is arranged at the power output end of the rotating motor (23), one side, far away from the rotating motor (23), of the rotating main shaft (25) penetrates through the sliding groove (27) and is arranged on the side wall of the rotating connecting plate (26), and the fixed south-pole magnet (18) is arranged on the side wall of the motor box (22) on one side of the rotating main shaft (25), the fixed north-pole magnet (19) is arranged on the side wall of the motor box (22) on one side, far away from the fixed south-pole magnet (18), of the rotating spindle (25), the rotating north-pole magnet (20) and the rotating south-pole magnet (21) are symmetrically arranged on the upper wall and the bottom wall of the rotating spindle (25), and the machining table (11) is arranged on the upper wall of the sliding table (10); the self-unfolding bidirectional stepping clamping and positioning mechanism (40) comprises a fixed rotating plate (41), bidirectional screws (42), sliding screw blocks (43), rotating plates (44), positioning slide rails (45), clamping sliders (46), bidirectional stepping clamping supports (47), guide plates (48) and guide rods (49), wherein every two of the fixed rotating plates (41) are symmetrically arranged on two sides of the sliding table (10) in a group, the bidirectional screws (42) are rotatably arranged between the fixed rotating plates (41), two ends of each bidirectional screw (42) respectively penetrate through the fixed rotating plates (41), the rotating plates (44) are symmetrically arranged on two sides of each bidirectional screw (42), the sliding screw blocks (43) are arranged on the bidirectional screws (42), and the sliding screw blocks (43) are in threaded connection with the bidirectional screws (42); intermediary's intervention formula magnetomotive force moving mechanism (3) is including positive direction drive fixed electromagnet (4), negative direction drive fixed electromagnet (5), drying processing movable electromagnet (6), mechanized processing movable electromagnet (7) and superconducting material shielding layer (8), the one end inner wall of frame (1) is located in positive direction drive fixed electromagnet (4), the one end inner wall of positive direction drive fixed electromagnet (4) is kept away from in frame (1) is located in negative direction drive fixed electromagnet (5), drying processing movable electromagnet (6) are located slide block (43) lateral wall that slide bench (10) are close to negative direction drive fixed electromagnet (5) one end, and negative direction drive fixed electromagnet (5) set up with drying processing movable electromagnet (6) relatively, mechanized processing movable electromagnet (7) are located slide bench (10) and are close to slip spiral shell piece (43) side of positive direction drive fixed electromagnet (4) one end The positive direction driving fixed electromagnet (4) and the mechanical processing movable electromagnet (7) are arranged oppositely, and the superconducting material shielding layer (8) is respectively arranged on the outer sides of the positive direction driving fixed electromagnet (4), the negative direction driving fixed electromagnet (5), the drying processing movable electromagnet (6) and the mechanical processing movable electromagnet (7); processing platform (11) upper wall is located to location slide rail (45) symmetry, press from both sides tight slider (46) and slide and locate on location slide rail (45), slip spiral shell piece (43) and press from both sides between tight slider (46) are located in two-way step-by-step clamping support (47), sliding stand (10) both sides are located to deflector (48) symmetry, and sliding stand (10) lateral wall between fixed rotor plate (41) is located in deflector (48), between fixed rotor plate (41) lateral wall that deflector (48) and frame (1) are close to motor case (22) one end is located in deflector (49) run through two-way step-by-step clamping support (47), and two-way step-by-step clamping support (47) that frame (1) is close to motor case (22) one end slide and locate deflector (49).

2. The pressure lifting platform for the compensation assistance type medium moving type automobile seat as claimed in claim 1, wherein: supplementary slide mechanism of running roller (55) is including three hole direction connecting plates (56), supplementary pivot (57) and supplementary removal wheel (58), on swivel spindle (25) between sliding stand (10) and frame (1) inner wall were located to three hole direction connecting plates (56) symmetry, swivel spindle (25) were located in rotation of three hole direction connecting plates (56), supplementary removal wheel (58) symmetry is located in sliding tray (27), and supplementary removal wheel (58) roll-motion is located sliding tray (27), supplementary pivot (57) are located between supplementary removal wheel (58) and three hole direction connecting plates (56).

3. The pressure lifting platform for the compensation assistance type medium moving type automobile seat as claimed in claim 2, wherein: pneumatic type pressure jack-up elevating system (50) include gas force pump (51), pressure gas pipeline (52), lift jar (53), lift post (54) and limiting plate (59), two liang of base (2) both ends upper walls are located for a set of symmetry in lift jar (53), and lift jar (53) are upper end open-ended cavity, lift post (54) slide and locate in lift jar (53), frame (1) diapire is located to one side that lift jar (53) were kept away from in lift post (54).

4. The pressure lifting platform of claim 3, wherein the pressure lifting platform comprises: limiting plate (59) are located lift cylinder (53) and are close to the inner wall of bottom, gas force pump (51) symmetry is located base (2) both ends upper wall, gaseous delivery duct (52) of pressure communicate respectively and locate between gaseous force pump (51) power take off end and lift cylinder (53), limiting plate (59) below is located to gaseous delivery duct (52) of pressure one end of intercommunication lift cylinder (53).

Images