CN109604031B - Vibration screening device for power ultrasonic soil remediation device - Google Patents

Abstract

The invention relates to a screening device, in particular to a vibration screening device for a power ultrasonic soil remediation promoting device. The soil breaking device comprises a breaking mechanism I, a breaking mechanism II, a screening mechanism, a multidirectional damping mechanism, a base and a drying mechanism, soil blocks in soil can be firstly crushed into sandy soil through a breaking plate, the soil can be intermittently conveyed onto the screening plate through intermittent up-and-down movement of a soil carrying plate, the soil is screened by the screening plate, sundries such as stones are screened out, finally, the soil is dried through a drying cylinder and a heating pipe, the moisture content of the soil is reduced, and the rotation of the drying cylinder is beneficial to uniform and sufficient drying of the soil.

Description

Vibration screening device for power ultrasonic soil remediation device

Technical Field

The invention relates to a screening device, in particular to a vibration screening device for a power ultrasonic soil remediation promoting device.

Background

Soil remediation refers to the physical, chemical and biological processes used to transfer, absorb, degrade and transform pollutants in soil to reduce their concentration to acceptable levels, or to transform toxic and harmful pollutants into harmless materials. The ultrasonic treatment method is an advanced oxidation technology, and can effectively degrade and mineralize refractory organic pollutants. For example, polycyclic aromatic hydrocarbons, which are important environmental and food pollutants and widely distributed in the environment, can have a great impact on human health through the food chain in soil, and may be produced wherever organic matter is processed, discarded, burned or used. And the polycyclic aromatic hydrocarbons in the soil can be desorbed into the solution by mechanical, thermal and chemical effects caused by cavitation of the ultrasonic waves, and further degradation can occur. But the water content in the soil can increase the scattering probability of the ultrasonic waves, reduce the effective sound energy density of the ultrasonic waves, and be not beneficial to the ultrasonic degradation of organic pollutants in the solution, and impurities such as stones in the soil are also not beneficial to the ultrasonic desorption of the organic pollutants adsorbed on soil particles. Therefore, the design of the vibration screening device for the power ultrasonic soil remediation device is particularly important.

Disclosure of Invention

The invention aims to provide a vibration screening device for a power ultrasonic soil remediation promotion device, which can reduce the water content in soil, remove impurities such as stones in the soil and is beneficial to ultrasonic soil remediation.

The purpose of the invention is realized by the following technical scheme:

power supersound promotes soil prosthetic devices and uses vibration screening device, including breaking mechanism I, breaking mechanism II, screening mechanism, multidirectional damper, base and stoving mechanism, breaking mechanism II and connecting on breaking mechanism I, screening mechanism fixed connection is on multidirectional damper, breaks I fixed connection in multidirectional damper's upper end in the mechanism, multidirectional damper fixed connection is in the upper end of base, fixedly connected with stoving mechanism on the base.

The breaking mechanism I comprises a first shell, a soil inlet, a first funnel, a soil outlet, an upper cover, an opening, a first bearing with a seat, a support, a second shell, a second funnel, a soil carrying plate, a mounting plate, a first sliding column and a first spring, wherein the soil inlet is arranged on the front side of the upper end of the first shell, the first funnel is fixedly connected with the left side and the right side of the lower end of the first shell, the soil outlet is arranged on the left side and the right side of the lower end of the first shell, the upper cover is fixedly connected with the upper end of the first shell, the opening is arranged on the upper end of the upper cover, the first bearing with a seat is fixedly connected with the upper end of the upper cover, the support is fixedly connected with the front side and the rear side of the lower end of the first shell, the second shell is fixedly connected with the lower end of the second shell, the soil carrying plate is slidably connected with the inner end of, the first sliding column is connected to the lower end of the first shell in a sliding mode, a first spring is sleeved on the first sliding column, and the lower end of the first spring is in contact with the lower end of the first shell.

The breaking mechanism II comprises a first motor, a first belt wheel, a second belt wheel, a shaft, a first connecting rod, a second connecting rod, a hinged seat, a breaking plate and breaking grooves, wherein the output shaft of the first motor is fixedly connected with the first belt wheel, the first belt wheel is in transmission connection with the second belt wheel through a transmission belt, the second belt wheel is fixedly connected to the front end of the shaft, the rear end of the shaft is rotatably connected with one end of the first connecting rod, the other end of the first connecting rod is hinged with one end of the second connecting rod, the other end of the second connecting rod is hinged with the hinged seat, the hinged seat is fixedly connected to the breaking plate, and the breaking plate is provided with a plurality of breaking grooves; the first motor is fixedly connected to the front end of the first shell, the middle end of the shaft is rotatably connected to the first bearing with a seat, and the breaking plate is slidably connected to the inner end of the first shell.

The screening mechanism comprises a screening frame, wedge-shaped grooves, screening plates, screening holes, vibration exciters, a stop gate, a first handle, wedge-shaped sliding blocks and a third hopper, the wedge-shaped grooves are formed in the front side and the rear side of the left end of the screening frame, the screening plates are fixedly connected to the lower sides of the inner ends of the screening frame, a plurality of screening holes are formed in the screening plates, the vibration exciters are fixedly connected to the front end and the rear end of the screening frame, the wedge-shaped sliding blocks are fixedly connected to the front end and the rear end of the stop gate, the two wedge-shaped sliding blocks are respectively connected into the two wedge-shaped grooves in a sliding mode, the first handle is fixedly connected to the upper end of the stop; the right end of the screening plate is located right below the second hopper.

The multidirectional damping mechanism comprises a first damping mechanism, a second damping mechanism and a second connecting beam, the first damping mechanism comprises a second sliding column, a first connecting block, a first cross beam, a second spring, a third sliding column, a second connecting block, a fourth spring and a fifth spring, the middle end of the second sliding column is fixedly connected with the first connecting block, the upper end and the lower end of the second sliding column are respectively and slidably connected with the left end of the first cross beam and the left end of the second cross beam, the second sliding column is sleeved with the second spring and the third spring, the second spring is positioned between the first connecting block and the first cross beam, the third spring is positioned between the first connecting block and the second cross beam, the middle end of the third sliding column is fixedly connected with the second connecting block, the upper end and the lower end of the third sliding column are respectively and slidably connected with the right end of the first cross beam and the right end of the second cross beam, the third sliding column is sleeved with the fourth spring and the fifth spring, the fourth spring is positioned between the first beam and the second connecting block, the fifth spring is positioned between the second beam and the second connecting block, the number of the first damping mechanisms is two, the second damping mechanism comprises a third cross beam, a fourth sliding column, a first connecting beam and a sixth spring, the left end of the third cross beam is fixedly connected with the fourth sliding column, the left end of the fourth sliding column is slidably connected with the first connecting beam, the middle end of the fourth sliding column is sleeved with the sixth spring, the number of the second damping mechanisms is two, one third cross beam is fixedly connected with the left ends of the two first cross beams and the two second cross beams, the other third cross beam is fixedly connected with the right ends of the two first cross beams and the two second cross beams, the number of the second connecting beams is two, the front end and the rear end of one first connecting beam are fixedly connected to the left ends of the two second connecting beams, and the front end and the rear end of the other first connecting beam are fixedly connected to the right ends of the two second connecting beams; the left and right sides at both ends are equallyd divide respectively fixedly connected with first connecting block and second connecting block around the screening frame, and two supports are fixed connection respectively in the upper end of two second tie-beams.

The base comprises a base main body, a second motor, a third belt wheel, a second belt bearing and a third belt bearing, the second motor is fixedly connected to the upper end of the base main body, the third belt wheel is fixedly connected to an output shaft of the second motor, and the second belt bearing and the third belt bearing are fixedly connected to the left end and the right end of the base main body respectively; the front side and the rear side of the upper end of the base main body are fixedly connected with second connecting beams.

The drying mechanism comprises a drying cylinder, an inner frame, a heating pipe, a fourth belt wheel, a baffle ring, a back cover, a main shaft, a door platform, a door, a second handle and a permanent magnet, wherein the inner end of the drying cylinder is fixedly connected with the inner frame, the heating pipe is fixedly connected in the inner frame, the fourth belt wheel is fixedly connected on the drying cylinder, the baffle ring and the back cover are respectively and fixedly connected at the left end and the right end of the drying cylinder, the main shaft is fixedly connected at the right end of the back cover, the door platform is fixedly connected at the right side of the lower end of the drying cylinder, the drying cylinder is communicated with the door platform, the door is inserted in the door platform, the second handle is fixedly connected at the rear end of the; the left end and the right end of the drying cylinder are respectively connected in the second belt seat bearing and the third belt seat bearing in a rotating mode, the third belt wheel and the fourth belt wheel are connected through a transmission belt, and the right side of the lower end of the third hopper is located in the retaining ring.

The vibration screening device for the power ultrasonic soil remediation device has the beneficial effects that:

the invention can crush soil blocks in soil into sandy soil through the breaking plate, the soil can be intermittently conveyed to the screening plate by the intermittent up-and-down movement of the soil carrying plate, the soil is screened by the screening plate, impurities such as stones and the like are screened out, and finally the soil is dried through the drying cylinder and the heating pipe, so that the moisture content of the soil is reduced, and the rotation of the drying cylinder is beneficial to uniform and sufficient drying of the soil.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic diagram I of the overall structure of a vibratory screening device for a power ultrasonic soil remediation device according to the present invention;

FIG. 2 is a second overall structural schematic of the present invention;

FIG. 3 is an overall cross-sectional schematic view of the present invention;

FIG. 4 is a schematic view of the breaking mechanism I of the present invention;

FIG. 5 is a schematic view of the internal structure of the breaking mechanism I of the present invention;

FIG. 6 is a schematic structural view of a breaking mechanism II of the present invention;

FIG. 7 is a schematic structural view of the sifting mechanism of the present invention;

FIG. 8 is a partial schematic view of the sifting mechanism of the present invention;

FIG. 9 is a schematic structural view of the multi-directional damping mechanism of the present invention;

FIG. 10 is a schematic view of a first shock absorbing mechanism of the present invention;

FIG. 11 is a schematic structural view of a second damping mechanism of the present invention;

FIG. 12 is a schematic view of the base structure of the present invention;

FIG. 13 is a first schematic structural diagram of a drying mechanism according to the present invention;

fig. 14 is a second structural schematic diagram of the drying mechanism of the present invention.

In the figure: a breaking mechanism I1; a first housing 1-1; 1-2 of a soil inlet; a first hopper 1-3; 1-4 of a soil outlet; 1-5 of an upper cover; 1-6 of an opening; a first pedestal bearing 1-7; 1-8 of a bracket; a second housing 1-9; a second funnel 1-10; 1-11 of a soil carrying plate; mounting plates 1-12; first spools 1-13; first springs 1-14; a breaking mechanism II 2; a first electric machine 2-1; a first pulley 2-2; a second pulley 2-3; 2-4 of a shaft; a first link 2-5; a second link 2-6; hinge seats 2-7; 2-8 parts of a breaking plate; 2-9 parts of a breaking groove; a screening mechanism 3; 3-1 of a screening frame; 3-2 of wedge-shaped groove; 3-3 parts of a screening plate; 3-4 of screening holes; 3-5 of a vibration exciter; 3-6 of a stop gate; a first handle 3-7; 3-8 of a wedge-shaped sliding block; 3-9 of a third funnel; a multidirectional damping mechanism 4; a first damper mechanism 4-1; a second traveler 4-1-1; a first connecting block 4-1-2; a first cross member 4-1-3; a second cross member 4-1-4; a second spring 4-1-5; a third spring 4-1-6; a third traveler 4-1-7; 4-1-8 parts of a second connecting block; a fourth spring 4-1-9; a fifth spring 4-1-10; a second damper mechanism 4-2; a third beam 4-2-1; a fourth traveler 4-2-2; a first connecting beam 4-2-3; a sixth spring 4-2-4; a second connecting beam 4-3; a base 5; a base body 5-1; a second motor 5-2; a third belt pulley 5-3; a second rolling bearing 5-4; a third rolling bearing 5-5; a drying mechanism 6; 6-1 of a drying cylinder; 6-2 of an inner frame; 6-3 of a heating pipe; a fourth pulley 6-4; 6-5 of a baffle ring; 6-6 of a back cover; 6-7 of a main shaft; 6-8 of a platform for the door; doors 6-9; a second handle 6-10; 6-11 of permanent magnet.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The first embodiment is as follows:

as shown in fig. 1-14, the vibration screening device for the power ultrasonic soil remediation device comprises a breaking mechanism i 1, a breaking mechanism ii 2, a screening mechanism 3, a multidirectional damping mechanism 4, a base 5 and a drying mechanism 6, wherein the breaking mechanism ii 2 is connected to the breaking mechanism i 1, the screening mechanism 3 is fixedly connected to the multidirectional damping mechanism 4, the breaking mechanism i 1 is fixedly connected to the upper end of the multidirectional damping mechanism 4, the multidirectional damping mechanism 4 is fixedly connected to the upper end of the base 5, and the drying mechanism 6 is fixedly connected to the base 5.

The second embodiment is as follows:

as shown in figures 1-14, the breaking mechanism I1 comprises a first shell 1-1, a soil inlet 1-2, a first funnel 1-3, a soil outlet 1-4, an upper cover 1-5, an opening 1-6, a first seated bearing 1-7, a support 1-8, a second shell 1-9, a second funnel 1-10, a soil carrying plate 1-11, a mounting plate 1-12, a first sliding column 1-13 and a first spring 1-14, wherein the soil inlet 1-2 is arranged on the front side of the upper end of the first shell 1-1 and fixedly connected with the first funnel 1-3, the soil outlet 1-4 is arranged on the left side and the right side of the lower end of the first shell 1-1, the upper cover 1-5 is fixedly connected with the upper end of the first shell 1-1, the opening 1-6 is arranged on the upper end of the upper cover 1-5 and fixedly connected with the first seated bearing 1-7, the front side and the rear side of the lower end of the first shell 1-1 are fixedly connected with supports 1-8, the second shell 1-9 is fixedly connected with the lower end of the first shell 1-1, the second funnel 1-10 is fixedly connected with the lower end of the second shell 1-9, the soil carrying plate 1-11 is slidably connected with the inner end of the first shell 1-1, the lower end of the soil carrying plate 1-11 is fixedly connected with a mounting plate 1-12, the lower end of the mounting plate 1-12 is fixedly connected with a first sliding column 1-13, the first sliding column 1-13 is slidably connected with the lower end of the first shell 1-1 and sleeved with a first spring 1-14, and the lower end of the first spring 1-14 is in contact with the lower end of the first shell 1-1. When the soil to be restored is poured through the first hopper 1-3, the breaking plate 2-8 is ensured to be positioned at the upper end of the first hopper 1-3, which is to ensure that the soil can be poured onto the soil carrying plate 1-11 smoothly, the position of the soil carrying plate 1-11 is as shown in fig. 3, the breaking plate is positioned in the soil outlet 1-4 and is always positioned at the upper end of the soil outlet 1-4 through the first spring 1-14, if the soil is on the soil carrying plate 1-11, the soil carrying plate 1-11 cannot be caused to descend, namely the soil carrying plate 1-11 seals the soil outlet 1-4, and the soil cannot be separated from the soil carrying plate 1-11 through the soil outlet 1-4.

The third concrete implementation mode:

as shown in fig. 1-14, the breaking mechanism ii 2 includes a first motor 2-1, a first belt wheel 2-2, a second belt wheel 2-3, a shaft 2-4, a first connecting rod 2-5, a second connecting rod 2-6, a hinged seat 2-7, a breaking plate 2-8 and a breaking groove 2-9, the first belt wheel 2-2 is fixedly connected to an output shaft of the first motor 2-1, the first belt wheel 2-2 is in transmission connection with the second belt wheel 2-3 through a transmission belt, the second belt wheel 2-3 is fixedly connected to a front end of the shaft 2-4, a rear end of the shaft 2-4 is rotatably connected to one end of the first connecting rod 2-5, the other end of the first connecting rod 2-5 is hinged to one end of the second connecting rod 2-6, the other end of the second connecting rod 2-6 is hinged to the hinged seat 2-7, the hinged seat 2-7 is fixedly connected to the breaking plate 2-8, and a plurality of breaking grooves 2-9 are formed in the breaking plate 2-8; the first motor 2-1 is fixedly connected to the front end of the first shell 1-1, the middle end of the shaft 2-4 is rotatably connected into the first bearing with a seat 1-7, and the breaking plate 2-8 is slidably connected to the inner end of the first shell 1-1. The invention can also be used by matching with an intermittent feeding device, the breaking plate 2-8 can move up and down, the feeding device can start feeding when the breaking plate 2-8 moves to the highest position, the feeding device stops feeding when the breaking plate 2-8 starts to descend and approaches the first hopper 1-3, certainly, soil can be added to the height of the first hopper 1-3 at one time, and the breaking groove 2-9 is beneficial to breaking soil blocks.

The fourth concrete implementation mode:

as shown in fig. 1-14, the screening mechanism 3 comprises a screening frame 3-1, wedge-shaped grooves 3-2, screening plates 3-3, screening holes 3-4, vibration exciters 3-5, shutters 3-6, a first handle 3-7, wedge-shaped sliders 3-8 and a third funnel 3-9, the wedge-shaped grooves 3-2 are respectively arranged on the front and rear sides of the left end of the screening frame 3-1, the screening plates 3-3 are fixedly connected to the lower side of the inner end of the screening frame 3-1, a plurality of screening holes 3-4 are arranged on the screening plates 3-3, the vibration exciters 3-5 are fixedly connected to the front and rear ends of the screening frame 3-1, the wedge-shaped sliders 3-8 are fixedly connected to the front and rear ends of the shutters 3-6, the two wedge-shaped sliders 3-8 are respectively slidably connected in the two wedge-shaped grooves 3-2, the upper end of the stop door 3-6 is fixedly connected with a first handle 3-7, and a third funnel 3-9 is fixedly connected with the lower end of the screening frame 3-1; the right end of the screening plate 3-3 is positioned right below the second hopper 1-10. The shutter 3-6 is used for preventing the situation of insufficient screening, for example, a large amount of soil exists on the screening plate 3-3, a part of the soil is vibrated to the left end of the screening plate 3-3 for screening in time, the shutter 3-6 can block the soil which is not screened to enable the soil to be screened continuously, after the screening is sufficient, a large amount of impurities such as stones still exist at the right end of the shutter 3-6, at the moment, the shutter 3-6 can be moved upwards by pulling the first handle 3-7 upwards, the impurities such as stones can slide down from the left end of the screening plate 3-3, and a vessel can be arranged at the sliding position so as to receive the impurities and facilitate transferring the impurities or recycling.

The fifth concrete implementation mode:

as shown in fig. 1-14, the multi-directional damping mechanism 4 includes a first damping mechanism 4-1, a second damping mechanism 4-2 and a second connecting beam 4-3, the first damping mechanism 4-1 includes a second strut 4-1-1, a first connecting block 4-1-2, a first beam 4-1-3, a second beam 4-1-4, a second spring 4-1-5, a third spring 4-1-6, a third strut 4-1-7, a second connecting block 4-1-8, a fourth spring 4-1-9 and a fifth spring 4-1-10, the middle end of the second strut 4-1-1 is fixedly connected with the first connecting block 4-1-2, and the upper and lower ends of the second strut 4-1-1 are respectively slidably connected with the left end and the left end of the first beam 4-1-3, and the upper and lower ends of the second strut 4-1-1 The left end of the second cross beam 4-1-4, the second sliding column 4-1-1 is sleeved with a second spring 4-1-5 and a third spring 4-1-6, the second spring 4-1-5 is positioned between the first connecting block 4-1-2 and the first cross beam 4-1-3, the third spring 4-1-6 is positioned between the first connecting block 4-1-2 and the second cross beam 4-1-4, the middle end of the third sliding column 4-1-7 is fixedly connected with a second connecting block 4-1-8, the upper end and the lower end of the third sliding column 4-1-7 are respectively connected with the right end of the first cross beam 4-1-3 and the right end of the second cross beam 4-1-4 in a sliding manner, the third sliding column 4-1-7 is sleeved with a fourth spring 4-1-9 and a fifth spring 4-1-10, a fourth spring 4-1-9 is positioned between a first cross beam 4-1-3 and a second connecting block 4-1-8, a fifth spring 4-1-10 is positioned between the second cross beam 4-1-4 and a second connecting block 4-1-8, two first damping mechanisms 4-1 are arranged, each second damping mechanism 4-2 comprises a third cross beam 4-2-1, a fourth sliding column 4-2-2, a first connecting beam 4-2-3 and a sixth spring 4-2-4, the left end of the third cross beam 4-2-1 is fixedly connected with the fourth sliding column 4-2-2, the left end of the fourth sliding column 4-2-2 is slidably connected with the first connecting beam 4-2-3, the middle end of the fourth sliding column 4-2-2 is sleeved with a sixth spring 4-2-4, two second damping mechanisms 4-2 are arranged, wherein one third beam 4-2-1 is fixedly connected with the left ends of the two first beams 4-1-3 and the two second beams 4-1-4, the other third beam 4-2-1 is fixedly connected with the right ends of the two first beams 4-1-3 and the two second beams 4-1-4, two second connecting beams 4-3 are arranged, the front end and the rear end of one first connecting beam 4-2-3 are fixedly connected to the left ends of the two second connecting beams 4-3, and the front end and the rear end of the other first connecting beam 4-2-3 are fixedly connected to the right ends of the two second connecting beams 4-3; the left side and the right side of the front end and the rear end of the screening frame 3-1 are respectively and fixedly connected with a first connecting block 4-1-2 and a second connecting block 4-1-8, and the two supports 1-8 are respectively and fixedly connected to the upper ends of the two second connecting beams 4-3. As can be seen from FIG. 7, the sieving plate 3-3 is obliquely arranged, which is beneficial to moving impurities such as stones leftwards and facilitating separation from the sieving plate 3-3, but soil can also move leftwards due to the oblique arrangement, and besides soil is enabled to continue sieving by blocking soil, due to the fact that the multidirectional damping mechanism 4 can enable the sieving plate 3-3 to move leftwards and rightwards, when the sieving plate 3-3 moves upwards and rightwards, soil on the sieving plate 3-3 can be thrown to the right end of the sieving plate 3-3, and the soil is beaten on the sieving plate 3-3, and the sieving effect is better.

The sixth specific implementation mode:

as shown in fig. 1-14, the base 5 includes a base main body 5-1, a second motor 5-2, a third belt pulley 5-3, a second belt bearing 5-4 and a third belt bearing 5-5, the upper end of the base main body 5-1 is fixedly connected with the second motor 5-2, an output shaft of the second motor 5-2 is fixedly connected with the third belt pulley 5-3, and the left and right ends of the base main body 5-1 are respectively fixedly connected with the second belt bearing 5-4 and the third belt bearing 5-5; the front side and the rear side of the upper end of the base main body 5-1 are fixedly connected with second connecting beams 4-3. The base 5 mainly has the function of enabling other parts to be installed on the base, and the second bearing with a seat 5-4 and the third bearing with a seat 5-5 are convenient for the drying drum 6-1 to rotate.

The seventh embodiment:

as shown in fig. 1-14, the drying mechanism 6 comprises a drying cylinder 6-1, an inner frame 6-2, a heating pipe 6-3, a fourth belt wheel 6-4, a baffle ring 6-5, a back cover 6-6, a main shaft 6-7, a door platform 6-8, a door 6-9, a second handle 6-10 and a permanent magnet 6-11, the inner end of the drying cylinder 6-1 is fixedly connected with the inner frame 6-2, the inner frame 6-2 is fixedly connected with the heating pipe 6-3, the drying cylinder 6-1 is fixedly connected with the fourth belt wheel 6-4, the left end and the right end of the drying cylinder 6-1 are respectively fixedly connected with the baffle ring 6-5 and the back cover 6-6, the right end of the back cover 6-6 is fixedly connected with the main shaft 6-7, the right side of the lower end of the drying cylinder 6-1 is fixedly connected with the door platform 6-8, the drying cylinder 6-1 is communicated with a door platform 6-8, a door 6-9 is inserted into the door platform 6-8, the rear end of the door 6-9 is fixedly connected with a second handle 6-10, and the front end of the door platform 6-8 is fixedly connected with a permanent magnet 6-11; the left end and the right end of the drying cylinder 6-1 are respectively and rotatably connected into a second belt bearing 5-4 and a third belt bearing 5-5, a third belt wheel 5-3 and a fourth belt wheel 6-4 are in transmission connection through a transmission belt, and the right side of the lower end of a third funnel 3-9 is positioned in a retaining ring 6-5. When the soil drying device is used, the permanent magnet 6-11 needs to be electrified firstly, the door 6-9 is attracted by magnetic force when the permanent magnet is used, soil cannot be separated from the right end of the drying cylinder 6-1 through the door 6-9, soil cannot be separated from the left end of the drying cylinder 6-1 through the baffle ring 6-5, and the heating pipe 6-3 needs to be preheated before the soil drying device is used, so that sufficient heat is available in the drying cylinder 6-1 to dry the soil in the drying cylinder 6-1 in time.

The invention discloses a vibration screening device for a power ultrasonic soil remediation promotion device, which has the working principle that:

the soil to be restored needs to be subjected to the primary treatment of the invention before restoration, soil blocks in the soil are crushed into sandy soil, then the soil is sieved, namely sundries such as stones are sieved out, and finally the soil is dried to reduce the moisture content of the soil. The concrete operation is that the soil to be restored is firstly poured on a soil carrying plate 1-11 through a first hopper 1-3, a first motor 2-1 is started, an output shaft of the first motor 2-1 drives a first belt wheel 2-2 to rotate around the self axis, the first belt wheel 2-2 drives a second belt wheel 2-3 to rotate around the self axis through a transmission belt, the second belt wheel 2-3 drives a shaft 2-4 to rotate around the self axis, the shaft 2-4 drives a first connecting rod 2-5 to rotate around the shaft 2-4 as a rotation center, the first connecting rod 2-5 drives a second connecting rod 2-6 to swing, the second connecting rod 2-6 enables a breaking plate 2-8 to move up and down, the breaking plate 2-8 moves down until contacting the soil, the soil is driven to move down, the soil and the soil carrying plate 1-11 synchronously move down, when the soil-carrying plate 1-11 moves downwards, the soil-carrying plate cannot continuously block the soil outlets 1-4, at the moment, the soil at the lower end of the soil on the soil-carrying plate 1-11 can be separated from the soil-carrying plate 1-11 through the two soil outlets 1-4, and the soil falls on the right side of the upper end of the screening plate 3-3 through the second hopper 1-10, namely the breaking mechanism I1 and the breaking mechanism II 2 have the function of intermittently conveying the soil while breaking the soil blocks in the soil into sandy soil, so that a large amount of soil cannot exist while screening the soil, and the screening quality is ensured; when soil appears on the screening plate 3-3, the two vibration exciters 3-5 are started, as can be seen from fig. 9 to 11, the first damping mechanism 4-1 provides the freedom degree of the screening plate 3-3 in the up-and-down direction and provides damping in the direction, the second damping mechanism 4-2 provides the freedom degree of the screening plate 3-3 in the left-and-right direction and provides damping in the direction, as a result, the screening plate 3-3 vibrates in the up-and-down direction and the left-and-right direction, the vibration of the screening plate 3-3 vibrates the impurities on the screening plate, which cannot pass through the screening holes 3-4, to the left end, and sand and soil and the like fall to the third hopper 3-9 through the screening holes 3-4; soil finally falls into the drying cylinder 6-1 through the third hopper 3-9, the heating pipe 6-3 dries the soil, the second motor 5-2 is started at the moment, the second motor 5-2 drives the third belt wheel 5-3 to rotate around the axis of the third belt wheel, the third belt wheel 5-3 drives the fourth belt wheel 6-4 to rotate around the axis of the third belt wheel through a driving belt, the drying cylinder 6-1 further rotates around the axis of the third belt wheel, the drying cylinder 6-1 drives the soil to roll in a turnover mode, and the rotation of the drying cylinder 6-1 is beneficial to uniform and sufficient drying of the soil.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (5)

1. Power supersound promotes soil prosthetic devices and uses vibration screening device, including breaking mechanism I (1), breaking mechanism II (2), screening mechanism (3), multidirectional damper (4), base (5) and stoving mechanism (6), its characterized in that: the breaking mechanism I (1) comprises a first shell (1-1), a soil inlet (1-2), a first funnel (1-3), a soil outlet (1-4), an upper cover (1-5), an opening (1-6), a first bearing with a seat (1-7), a support (1-8), a second shell (1-9), a second funnel (1-10), a soil carrying plate (1-11), a mounting plate (1-12), A first sliding column (1-13) and a first spring (1-14), wherein the front side of the upper end of a first shell (1-1) is provided with a soil inlet (1-2) and is fixedly connected with a first funnel (1-3), the left side and the right side of the lower end of the first shell (1-1) are respectively provided with a soil outlet (1-4), an upper cover (1-5) is fixedly connected with the upper end of the first shell (1-1), the upper end of the upper cover (1-5) is provided with an opening (1-6) and is fixedly connected with a first bearing with a seat (1-7), the front side and the rear side of the lower end of the first shell (1-1) are respectively and fixedly connected with a support (1-8), a second shell (1-9) is fixedly connected with the lower end of the first shell (1-1), and a second funnel (1-10) is fixedly connected with the lower end of the second shell (, the soil carrying plate (1-11) is connected to the inner end of the first shell (1-1) in a sliding mode, the lower end of the soil carrying plate (1-11) is fixedly connected with a mounting plate (1-12), the lower end of the mounting plate (1-12) is fixedly connected with a first sliding column (1-13), the first sliding column (1-13) is connected to the lower end of the first shell (1-1) in a sliding mode and sleeved with a first spring (1-14), the lower end of the first spring (1-14) is in contact with the lower end of the first shell (1-1), the breaking mechanism II (2) comprises a first motor (2-1), a first belt wheel (2-2), a second belt wheel (2-3), a shaft (2-4), a first connecting rod (2-5), a second connecting rod (2-6), a hinged seat (2-7), The breaking plate comprises a breaking plate (2-8) and breaking grooves (2-9), wherein a first belt wheel (2-2) is fixedly connected to an output shaft of a first motor (2-1), the first belt wheel (2-2) is in transmission connection with a second belt wheel (2-3) through a transmission belt, the second belt wheel (2-3) is fixedly connected to the front end of a shaft (2-4), the rear end of the shaft (2-4) is rotatably connected with one end of a first connecting rod (2-5), the other end of the first connecting rod (2-5) is hinged to one end of a second connecting rod (2-6), the other end of the second connecting rod (2-6) is hinged to a hinged seat (2-7), the hinged seat (2-7) is fixedly connected to the breaking plate (2-8), and the breaking plate (2-8) is provided with a plurality of breaking grooves (2-9); the first motor (2-1) is fixedly connected to the front end of the first shell (1-1), the middle end of the shaft (2-4) is rotatably connected into the first bearing with a seat (1-7), the breaking plate (2-8) is slidably connected to the inner end of the first shell (1-1), the soil carrying plate (1-11) is positioned in the soil outlet (1-4), the soil carrying plate (1-11) is positioned at the upper end of the soil outlet (1-4) through a first spring (1-14), if soil exists on the soil carrying plate (1-11), the soil carrying plate (1-11) cannot be caused to descend, namely the soil carrying plate (1-11) seals the soil outlet (1-4), the soil cannot be separated from the soil carrying plate (1-11) through the soil outlet (1-4), the breaking plate (2-8) moves downwards until the soil is contacted, the soil is driven to move downwards, the soil and the soil carrying plates (1-11) synchronously descend and move, when the soil carrying plates (1-11) move downwards, the soil cannot continuously block the soil outlets (1-4), at the moment, the soil at the lower end in the soil on the soil carrying plates (1-11) can be separated from the soil carrying plates (1-11) through the two soil outlets (1-4), the breaking mechanisms I (1) and the breaking mechanisms II (2) have the function of intermittently conveying the soil while breaking soil blocks in the soil into sandy soil, and the breaking plates (2-8) are located right above the soil carrying plates (1-11).

2. The vibratory screening apparatus for a power ultrasound enhanced soil remediation device of claim 1, wherein: the screening mechanism (3) comprises a screening frame (3-1), wedge-shaped grooves (3-2), a screening plate (3-3), screening holes (3-4), vibration exciters (3-5), a stop door (3-6), a first handle (3-7), wedge-shaped sliding blocks (3-8) and a third hopper (3-9), the wedge-shaped grooves (3-2) are respectively arranged on the front side and the rear side of the left end of the screening frame (3-1), the screening plate (3-3) is fixedly connected with the lower side of the inner end of the screening frame (3-1), a plurality of screening holes (3-4) are arranged on the screening plate (3-3), the vibration exciters (3-5) are respectively and fixedly connected with the front end and the rear end of the screening frame (3-1), the wedge-shaped sliding blocks (3-8) are respectively and fixedly connected with the front end and the rear end of the stop door (3-6, the two wedge-shaped sliding blocks (3-8) are respectively connected in the two wedge-shaped grooves (3-2) in a sliding manner, the upper ends of the stop gates (3-6) are fixedly connected with a first handle (3-7), and the third hopper (3-9) is fixedly connected with the lower end of the screening frame (3-1); the right end of the screening plate (3-3) is positioned right below the second hopper (1-10).

3. The vibratory screening apparatus for a power ultrasound enhanced soil remediation device of claim 2, wherein: the multidirectional damping mechanism (4) comprises a first damping mechanism (4-1), a second damping mechanism (4-2) and a second connecting beam (4-3), the first damping mechanism (4-1) comprises a second sliding column (4-1-1), a first connecting block (4-1-2), a first cross beam (4-1-3), a second cross beam (4-1-4), a second spring (4-1-5), a third spring (4-1-6), a third sliding column (4-1-7), a second connecting block (4-1-8), a fourth spring (4-1-9) and a fifth spring (4-1-10), the middle end of the second sliding column (4-1-1) is fixedly connected with the first connecting block (4-1-2), the upper end and the lower end of the second sliding column (4-1-1) are respectively connected with the left end of the first beam (4-1-3) and the left end of the second beam (4-1-4) in a sliding manner, the second sliding column (4-1-1) is sleeved with a second spring (4-1-5) and a third spring (4-1-6), the second spring (4-1-5) is positioned between the first connecting block (4-1-2) and the first beam (4-1-3), the third spring (4-1-6) is positioned between the first connecting block (4-1-2) and the second beam (4-1-4), the middle end of the third sliding column (4-1-7) is fixedly connected with a second connecting block (4-1-8), the upper end and the lower end of a third sliding column (4-1-7) are respectively connected with the right end of a first cross beam (4-1-3) and the right end of a second cross beam (4-1-4) in a sliding mode, a fourth spring (4-1-9) and a fifth spring (4-1-10) are sleeved on the third sliding column (4-1-7), the fourth spring (4-1-9) is located between the first cross beam (4-1-3) and a second connecting block (4-1-8), the fifth spring (4-1-10) is located between the second cross beam (4-1-4) and the second connecting block (4-1-8), two first damping mechanisms (4-1) are arranged, and the second damping mechanism (4-2) comprises a third cross beam (4-2-1), A fourth sliding column (4-2-2), a first connecting beam (4-2-3) and a sixth spring (4-2-4), wherein the left end of the third beam (4-2-1) is fixedly connected with the fourth sliding column (4-2-2), the left end of the fourth sliding column (4-2-2) is slidably connected with the first connecting beam (4-2-3), the middle end of the fourth sliding column (4-2-2) is sleeved with the sixth spring (4-2-4), two damping mechanisms (4-2) are arranged, one third beam (4-2-1) is fixedly connected with the left ends of the two first beams (4-1-3) and the two second beams (4-1-4), and the other third beam (4-2-1) is fixedly connected with the left ends of the two first beams (4-1-3) and the two second beams (4-1-4) The front end and the rear end of one first connecting beam (4-2-3) are fixedly connected to the left ends of the two second connecting beams (4-3), and the front end and the rear end of the other first connecting beam (4-2-3) are fixedly connected to the right ends of the two second connecting beams (4-3); the left side and the right side of the front end and the rear end of the screening frame (3-1) are respectively and fixedly connected with a first connecting block (4-1-2) and a second connecting block (4-1-8), and the two supports (1-8) are respectively and fixedly connected to the upper ends of the two second connecting beams (4-3).

4. The vibratory screening apparatus for a power ultrasound enhanced soil remediation device of claim 3, wherein: the base (5) comprises a base main body (5-1), a second motor (5-2), a third belt wheel (5-3), a second belt seat bearing (5-4) and a third belt seat bearing (5-5), the upper end of the base main body (5-1) is fixedly connected with the second motor (5-2), an output shaft of the second motor (5-2) is fixedly connected with the third belt wheel (5-3), and the left end and the right end of the base main body (5-1) are respectively fixedly connected with the second belt seat bearing (5-4) and the third belt seat bearing (5-5); the front side and the rear side of the upper end of the base main body (5-1) are fixedly connected with second connecting beams (4-3).

5. The vibratory screening apparatus for a power ultrasound enhanced soil remediation device of claim 4, wherein: the drying mechanism (6) comprises a drying cylinder (6-1), an inner frame (6-2), a heating pipe (6-3), a fourth belt wheel (6-4), a baffle ring (6-5), a back cover (6-6), a main shaft (6-7), a door platform (6-8), a door (6-9), a second handle (6-10) and a permanent magnet (6-11), the inner end of the drying cylinder (6-1) is fixedly connected with the inner frame (6-2), the heating pipe (6-3) is fixedly connected in the inner frame (6-2), the fourth belt wheel (6-4) is fixedly connected on the drying cylinder (6-1), the left end and the right end of the drying cylinder (6-1) are respectively fixedly connected with the baffle ring (6-5) and the back cover (6-6), the main shaft (6-7) is fixedly connected at the right end of the back cover (6-6), a door platform (6-8) is fixedly connected to the right side of the lower end of the drying cylinder (6-1), the drying cylinder (6-1) is communicated with the door platform (6-8), a door (6-9) is inserted into the door platform (6-8), the rear end of the door (6-9) is fixedly connected with a second handle (6-10), and a permanent magnet (6-11) is fixedly connected to the front end of the door platform (6-8); the left end and the right end of the drying cylinder (6-1) are respectively and rotatably connected into a second bearing with a seat (5-4) and a third bearing with a seat (5-5), a third belt wheel (5-3) and a fourth belt wheel (6-4) are in transmission connection through a transmission belt, and the right side of the lower end of a third funnel (3-9) is positioned in a retaining ring (6-5).

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