JP2019181443A - Sewage treatment device that removes contaminants on daylighting panels - Google Patents

Abstract

To provide a highly efficient daylighting panel device.SOLUTION: A daylighting panel device includes a box housing; at the four bottoms of the box housing, prisms are installed at the same time; a screw hole is installed at the bottom of each prism; a rotational pitch angle is engaged with and attached to the screw hole; the rotational pitch angle is used to adjust for elevation when the ground is not flat; thereby increasing the stability of the box housing. The box housing is provided with a filter cabinet; first symmetrical, empty grooves are installed so as to communicate with the left and right inner walls of the filter cabinet; second symmetrical, empty grooves are installed so that the first empty grooves communicate with an inner wall that is separated from the center of the filter cabinet; and third empty groove is installed so as to communicate with the rear end of the filter cabinet.SELECTED DRAWING: Figure 4

Description

The present invention relates to a daylighting panel processing technical field, and specifically relates to a highly efficient daylighting panel device.

Daylighting panels are widely used because they have good light transmission, and it is necessary to perform clean operations in the process of producing and manufacturing daylighting panels, but traditionally the sewage after cleaning the daylighting panels is discharged directly, Providing a device that not only pollutes the surrounding environment, but at the same time causes waste of water resources and therefore effectively removes solid particulate contaminants of sewage and cleans the lighting panel twice, Reduce waste.

Chinese Patent Application No. 105711199 Specification

The present invention provides a highly efficient daylighting panel apparatus for the necessary technical problems to be solved, which can solve the above-mentioned current technical problems.

The present invention is realized by employing the following technical scheme. The highly efficient daylighting panel device of the present invention includes a box housing, and a prism is installed at the bottom of four corners of the box housing at the same time, a screw hole is installed at the bottom of the prism, and a rotation pitch angle is associated with the screw hole. When the ground is not flat using the rotation pitch angle, the lift adjustment is performed, thereby increasing the stability of the box housing, and the filtration housing is installed in the box housing. A first air groove that is symmetrical so as to communicate with the left and right inner walls of the filter is installed, and a second air groove that is symmetrical so that the first air groove communicates with an inner wall that is separated from the center of the filtration housing is installed, and the filtration A third air groove is installed to communicate with the rear end of the housing, a first strainer is installed in the filtration housing, a second strainer is installed at the lower end of the first strainer, and a lower end of the second strainer Saving A box is fixedly connected, a through pipe is installed so as to communicate between the bottom of the storage box and the first empty groove, and a drainage groove is installed so as to communicate with the front end inner wall of the first empty groove. The other end of the drainage groove passes through the front end face of the box housing and is slidably engaged with and connected to the top end face of the first strainer, and the left and right ends of the first strainer. A first swash plate extending symmetrically to the first air groove is fixedly connected, and a second scraper is slidably engaged with and connected to the top of the second strainer. A second swash plate extending symmetrically to the second air groove is fixedly connected to the left and right ends so that a conductive block located at the rear end of the storage box can slide on the bottom end surface of the second strainer. Engaged and connected, the conductive transfer block A first conductive movement groove extending vertically is installed in the hook, and a second conductive movement lever located below the first conductive movement groove and extending left and right is slidably engaged with the conductive movement block. E, the left and right ends of the second conductive movement lever are fixedly connected to the inner walls of the left and right ends of the filtration case, and the rear end inner wall of the filtration case is located on the rear end of the first scraper The first sliding block, the second scraper, and the rear end of the sliding block are fixedly connected to the front end of the E type sliding block. A first electric rotating machine is installed on the inner wall of the top of the second air groove, a dredging load device is installed outside the first electric rotating machine, and the dredging load device includes an impact absorbing block and a cooling piece, The first electric rotating machine extends downward Connected to the rotating pin shaft so that power can be transmitted, a blade to be crushed around the first rotating pin shaft is fixedly connected, and a third swash plate extending downward symmetrically is installed at the lower end of the crushed blade One end of the third swash plate away from the center of the second air groove is fixedly connected to the second air groove, and the second air groove is positioned at the lower end of the third swash plate and symmetrical to the left and right. A second rotating pin shaft that extends in the squeezing roller and extends back and forth, and the rear end passes through the inner wall of the rear end of the second air groove and extends into the third air groove. A second conductive movement groove having a front end of the second rotation pin shaft rotatably attached to the box housing through a bearing and having a mouth at the bottom of the second empty groove that is separated from the center of the second empty groove. So that the storage box can slide in the second conductive movement groove. A second electric rotating machine is installed on the inner wall of the rear end of the third air groove, and extends forward to the second electric rotating machine, passes through the inner wall of the front end of the third air groove, and is filtered. A first rotating pin shaft extending to the housing is connected so that power can be transmitted, and the first rotating pin shaft is rotatably attached to the inner wall of the front end of the third air groove through a bearing. A cam is fixedly connected to the front end of the pin shaft, a first conductive movement lever extending in front of the first conductive movement groove is installed on the convex portion of the cam, and a turbine is engaged with the first rotary pin shaft. A third rotating pin shaft extending to the left and right is fixedly connected to the turbine, and left and right ends of the third rotating pin shaft are rotatably attached to the box housing through bearings, and the third rotation Double-sided cone symmetrical to the pin axis Pulley is fixedly connected, said first conical pulleys are engaged connected to both sides conical pulley, the first conical pulley is fixedly connected to the terminal after the second rotation pin axis.

As a preferred technical solution, a screw is installed at a portion where the first rotating pin shaft contacts the turbine.

As a preferred technical solution, the first filtration hole of the first strainer is larger than the second filtration hole of the second strainer.

As a preferred technical solution, the shock absorbing blocks are installed at the upper and lower ends of the first electric rotating machine and fixedly connected to the first electric rotating machine, and the cooling pieces are the front and rear ends of the first electric rotating machine. Fixedly connected to the shell of the first electric rotating machine, the upper end and the lower end of the cooling piece are fixedly connected to the shock absorbing block, and the front end and the rear end of the first electric rotating machine, respectively. One or more cooling pieces are installed.

The beneficial effect of the present invention is that when the equipment according to the present invention is in an initial state, the first scraper is positioned at the leftmost end of the first strainer, and the second scraper is positioned at the leftmost end of the second strainer. Wherein the cam is in a horizontal state, the first conduction movement lever is located at the center of the first conduction movement groove, and the rear end face of the storage box is closely attached to the box housing, and the drainage groove Is in a closed state.

When using, the sewage after cleaning the daylighting panel is introduced into the filtration housing, the drainage groove is opened, the second electric rotating machine is started and in conjunction with the first scraper, the second scraper Reciprocating with the first strainer and the second strainer, respectively, starting the first electric rotating machine and rotating in conjunction with the crushing blade, starting the second electric rotating machine and interlocking with the squeezing roller Rotate.

After use, it is convenient to control the first electric rotating machine and the second electric rotating machine to stop the rotation, collect the solid particles in the storage box and unify them together.

The structure of the facility according to the present invention is simple, the operation is convenient, the sewage after the daylighting panel is cleaned is rapidly filtered, the sewage is used twice, and the waste of water resources is greatly reduced.

The beneficial effect of the present invention is that when the equipment according to the present invention is in an initial state, the first scraper is positioned at the leftmost end of the first strainer, and the second scraper is positioned at the leftmost end of the second strainer. Wherein the cam is in a horizontal state, the first conduction movement lever is located at the center of the first conduction movement groove, and the rear end face of the storage box is closely attached to the box housing, and the drainage groove Is in a closed state.

When using, the sewage after cleaning the daylighting panel is introduced into the filtration housing, the drainage groove is opened, the second electric rotating machine is started and in conjunction with the first scraper, the second scraper Reciprocating with the first strainer and the second strainer, respectively, starting the first electric rotating machine and rotating in conjunction with the crushing blade, starting the second electric rotating machine and interlocking with the squeezing roller Rotate.

After use, it is convenient to control the first electric rotating machine and the second electric rotating machine to stop the rotation, collect the solid particles in the storage box and unify them together.

The structure of the facility according to the present invention is simple, the operation is convenient, the sewage after the daylighting panel is cleaned is rapidly filtered, the sewage is used twice, and the waste of water resources is greatly reduced.

FIG. 1 is a schematic diagram of the overall structure of a highly efficient daylighting panel device according to the present invention. FIG. 2 is a cross-sectional view in the AA direction in FIG. FIG. 3 is a cross-sectional view in the BB direction in FIG. FIG. 4 is a schematic diagram of the internal structure of a prism in the present invention.

For ease of explanation, the present invention will be described in detail with reference to the following specific embodiments and drawings.

As shown in FIGS. 1 to 4, the highly efficient daylighting panel device of the present invention includes a box housing 100, and prisms 188 are simultaneously installed at the four corner bottoms of the box housing 100, and screw holes are formed at the bottoms of the prisms 188. 189 is installed and a rotational pitch angle 190 is engaged with and attached to the screw hole 189, and the rotational pitch angle 190 is used to adjust the elevation when the ground is not flat, thereby improving the stability of the box housing 100. The filter housing 110 is installed in the box housing 100, the first empty groove 111 that is symmetrical so as to communicate with the left and right inner walls of the filter housing 110 is installed, and the first empty groove 111 is installed in the filter housing 110. A second empty groove 112 that is symmetrical to communicate with an inner wall that is separated from the center of the body 110 is installed, and a third empty groove 113 is installed to communicate with the rear end of the filtration casing 110, and the filtration casing 110 The first strainer 135 is installed at the bottom of the first strainer 135. The second strainer 136 is installed, and a storage box 137 is fixedly connected to the lower end of the second strainer 136, and a pipe 143 is connected between the bottom of the storage box 137 and the first empty groove 111. The drainage groove 101 is installed so as to communicate with the inner wall of the front end of the first empty groove 111, the other end of the drainage groove 101 passes through the front end end surface of the box housing 100, and the first strainer 135 The first scraper 131 is slidably engaged with and connected to the top end surface, and the first swash plate 133 extending in the first air groove 111 is fixedly connected to the left and right ends of the first strainer 135. A second scraper 132 is slidably engaged with and connected to the top of the second strainer 136, and extends to the second empty groove 112 symmetrically at both left and right ends of the second strainer 136. The swash plate 134 is fixedly connected, and the second strainer A conductive block 140 located at the rear end of the storage box 137 is slidably engaged with and connected to the bottom end surface of the storage box 137, and a first conductive movement groove 142 extending vertically is installed in the conductive movement block 140. The second conduction movement lever 141 is slidably engaged with and connected to the conduction movement block 140 and extends to the left and right under the first conduction movement groove 142. The left and right ends are fixedly connected to the inner walls of the left and right ends of the filtration casing 110, and the E-type sliding movement block 201 located at the rear end of the first scraper 131 slides to the left and right inner walls of the filtration casing 110. The first scraper 131, the second scraper 132, and the rear end of the sliding movement block 140 are fixedly connected to the front end of the E-type sliding movement block 201. A first electric rotating machine 121 is provided on the top inner wall of the second air groove 112. A dredger load device is installed outside the first electric rotating machine 121, the dredge load device includes an impact absorbing block 1214 and a cooling piece 1215, and the first electric rotating machine 121 extends downward. A third swash plate that is connected to a shaft 151 so that power can be transmitted, is fixedly connected to a blade 152 that crushes around the first rotating pin shaft 151, and extends downward symmetrically to the lower end of the crushing blade 152 144 is installed, one end of the third swash plate 144 away from the center of the second air groove 112 is fixedly connected to the second air groove 112, and the third swash plate 144 is connected to the second air groove 112. A squeezing roller 153 located at the lower end of the squeezing roller is installed, extends in the squeezing roller 153 in the front-rear direction, and the rear end passes through the inner wall of the rear end of the second empty groove 112 to the third empty groove 113. The second rotating pin shaft 300 extending in a fixed manner is connected to the front end of the second rotating pin shaft 300. A second conductive movement groove 145 is installed in the box housing 100 through a ring so as to be rotatable, and a second conductive movement groove 145 is provided at the bottom of the second empty groove 112 with a mouth away from the center of the second empty groove 112. A storage box 154 is slidably engaged with and connected to the moving groove 145, and a second electric rotating machine 122 is installed on the inner wall of the rear end of the third empty groove 113. A first rotating pin shaft 202 extending forward and passing through the inner wall of the third empty groove 113 and extending to the filtration housing 110 is connected so that power can be transmitted, and the first rotating pin shaft 202 is connected through a bearing. A cam 138 is fixedly connected to the front end of the first rotary pin shaft 202, and is fixed to the front end of the third air groove 113. A first conductive movement lever 139 extending in the conductive movement groove 142 is installed, and the first rotary pin shaft 202 A third rotating pin shaft 303 extending to the left and right is fixedly connected to the turbine 203, and both left and right ends of the third rotating pin shaft 303 are rotatable to the box housing 100 through bearings. The double-sided conical pulley 302 is fixedly connected to the third rotating pin shaft 303 symmetrically, and the first-conical pulley 301 is engaged with and connected to the double-sided conical pulley 302. A conical pulley 301 is fixedly connected to the rear end of the second rotating pin shaft 300.

Preferably, a screw is installed at a portion where the first rotating pin shaft 202 contacts the turbine 203, and it is convenient that the first rotating pin shaft 202 and the turbine rotate simultaneously.

Preferably, the first filtration hole of the first strainer 135 is larger than the second filtration hole of the second strainer 136, and it is convenient to treat sewage.

Preferably, the shock absorbing block 1214 is installed at an upper end and a lower end of the first electric rotating machine 121 and fixedly connected to the first electric rotating machine 121, and the cooling piece 1215 is connected to the first electric rotating machine 121. The first electric rotating machine is installed at a front end and a rear end and fixedly connected to the shell of the first electric rotating machine 121, and an upper end and a lower end of the cooling piece 1215 are fixedly connected to the shock absorbing block 1214. One or more cooling pieces 1215 are installed at the front end and the rear end of 121, respectively, and the cooling pieces 1215 absorb and radiate heat generated when the first electric rotating machine 121 operates, and the shock absorbing block 1214 However, the vibration force generated when the first electric rotating machine 121 operates is reduced to prevent the vibration force from being too large and affecting the normal operation of the apparatus.

When the equipment according to the present invention is in an initial state, the first scraper 131 is located at the leftmost end of the first strainer 135, the second scraper 131 is located at the leftmost end of the second strainer 136, The cam 223 is in a horizontal state, the first conductive movement lever 139 is located at the center of the first conductive movement groove 142, and the rear end face of the storage box 154 is closely attached to the box housing 100, and the drainage The groove 101 is in a closed state.

When used, the sewage after cleaning the daylighting panel is introduced into the filtration housing 110, the drainage groove 101 is opened, the second electric rotating machine 122 is started and in conjunction with the first scraper 131, The second scraper 132 is reciprocated by the first strainer 135 and the second strainer 136, respectively, starts the first electric rotating machine 121 and rotates in conjunction with the crushing blade 152, and the second electric rotating machine 122 Is activated and rotated in conjunction with the expression roller 153.

After use, it is convenient to control the first electric rotating machine 121 and the second electric rotating machine 122 to stop the rotation, collect the solid particles in the storage box 154, and clean them up in a unified manner.

What has been described above is merely a specific implementation method of the present invention, but the protection scope of the present invention is not limited thereto. Changes and replacements that have been conceived not through all creative labor are covered by the protection scope of the present invention. Therefore, the protection scope of the present invention is based on the protection scope to which the claims are limited.

The present invention relates to a lighting panel processing technical field, and more particularly, to a sewage treatment apparatus that removes contaminants from a lighting panel .

Daylighting panels are widely used because they have good light transmission, and it is necessary to perform clean operations in the process of producing and manufacturing daylighting panels, but traditionally the sewage after cleaning the daylighting panels is discharged directly, Providing a device that not only pollutes the surrounding environment, but at the same time causes waste of water resources and therefore effectively removes solid particulate contaminants of sewage and cleans the lighting panel twice, Reduce waste.

Chinese Patent Application No. 105711199 Specification

The present invention provides a sewage treatment apparatus for removing the contamination of the daylighting panel for the necessary technical problem to be solved, which can solve the above-mentioned current technical problem.

The present invention is realized by employing the following technical scheme. The sewage treatment apparatus for removing contaminants of the daylighting panel of the present invention includes a box housing, and a prism is simultaneously installed at the four square bottoms of the box housing, screw holes are installed at the bottom of the prisms, Rotation pitch angle is engaged and mounted, and the rotation pitch angle is used to adjust the elevation when the ground is not flat, thereby increasing the stability of the box housing and the filtration housing is installed in the box housing A symmetric first air groove is provided so as to communicate with the left and right inner walls of the filtration housing, and a second air groove symmetric so that the first air groove communicates with an inner wall away from the center of the filtration housing. Installed, a third air groove is installed so as to communicate with the rear end of the filtration housing, a first strainer is installed in the filtration housing, a second strainer is installed below the first strainer, Second strike Storage box below the Na is fixedly connected, said passage tube to the phase Tsusuru so on between the bottom of the storage box and the first air groove is disposed, the first air groove of the front inner wall phase Tsusuru so on A drainage groove is installed, the other end of the drainage groove passes through the front end surface of the box housing, and a first scraper is slidably engaged with and connected to the top end surface of the first strainer. A first swash plate extending symmetrically to the first air groove is fixedly connected to the left and right ends of one strainer, and a second scraper is slidably engaged and connected to the top of the second strainer, A second swash plate that extends symmetrically to the second empty groove is fixedly connected to the left and right ends of the second strainer, and a conductive movement block located at the rear end of the storage box is provided on the bottom end surface of the second strainer. Engage so that it can slide A first conductive movement groove extending up and down is installed in the conduction movement block, and a second conduction movement lever that is positioned below the first conduction movement groove and extends left and right is slidable in the conduction movement block. The left and right ends of the second conductive movement lever are fixedly connected to the inner walls of the left and right ends of the filtration casing, and the rear end of the first scraper is set to the left and right inner walls of the filtration casing. The E-type sliding moving block located at the position is slidably engaged and connected, and the rear end of the first scraper, the second scraper, and the conductive moving block is connected to the front end of the E-type sliding moving block. Fixedly connected, a first electric rotating machine is installed on the top inner wall of the second air groove, a dredging load device is installed outside the first electric rotating machine, and the dredging load device is cooled with the shock absorbing block Said first electric Rolling machine is connected to the first rotating pin shaft and power extending down possible transmission, blade pounding around the first rotation pin shaft is fixedly connected, under symmetrically below the Pounds blade A third swash plate extending to the second swash plate is fixedly connected to the second swash plate at one end of the third swash plate away from the center of the second swash plate. A squeeze roller symmetrically placed on the left and right is installed in the lower part of the squeeze roller and extends back and forth, and a rear end extends through the inner wall of the rear end of the second empty groove and extends to the third empty groove. A rotating pin shaft is fixedly connected, a front end of the second rotating pin shaft is rotatably attached to the box housing through a bearing, and a mouth is formed at the bottom of the second empty groove. A second conductive movement groove that is separated from the center is installed. A container is slidably engaged and connected, and a second electric rotating machine is installed on the inner wall of the rear end of the third empty groove. A first rotating pin shaft extending through the front end inner wall of the groove and extending to the filtration housing is connected so that power can be transmitted, and the first rotating pin shaft is rotatable to the front end inner wall of the third empty groove through a bearing. A cam is fixedly connected to the front end of the first rotating pin shaft, and a first conductive movement lever extending in front of the first conductive movement groove is installed on the convex portion of the cam. A turbine is engaged with and connected to a rotating pin shaft, a third rotating pin shaft extending to the left and right is fixedly connected to the turbine, and both left and right ends of the third rotating pin shaft are rotatable to the box housing through bearings. The third rotating pin shaft A double-sided conical pulley is fixedly connected to the left-right symmetrically, and a first-conical pulley is engaged and connected to the double-sided conical pulley, and the first-conical pulley is connected to the rear end of the second rotating pin shaft. Connect permanently.

As a preferred technical solution, a screw is installed at a portion where the first rotating pin shaft contacts the turbine.

As a preferred technical solution, the first filtration hole of the first strainer is larger than the second filtration hole of the second strainer.

As a preferred technical solution, the shock absorbing blocks are installed at the upper and lower ends of the first electric rotating machine and fixedly connected to the first electric rotating machine, and the cooling pieces are the front and rear ends of the first electric rotating machine. Fixedly connected to the shell of the first electric rotating machine, the upper end and the lower end of the cooling piece are fixedly connected to the shock absorbing block, and the front end and the rear end of the first electric rotating machine, respectively. One or more cooling pieces are installed.

The beneficial effect of the present invention is that when the equipment according to the present invention is in an initial state, the first scraper is positioned at the leftmost end of the first strainer, and the second scraper is positioned at the leftmost end of the second strainer. Wherein the cam is in a horizontal state, the first conduction movement lever is located at the center of the first conduction movement groove, and the rear end face of the storage box is closely attached to the box housing, and the drainage groove Is in a closed state.

When using, the sewage after cleaning the daylighting panel is introduced into the filtration housing, the drainage groove is opened, the second electric rotating machine is started and in conjunction with the first scraper, the second scraper Reciprocating with the first strainer and the second strainer, respectively, starting the first electric rotating machine and rotating in conjunction with the crushing blade, starting the second electric rotating machine and interlocking with the squeezing roller Rotate.

After use, it is convenient to control the first electric rotating machine and the second electric rotating machine to stop the rotation, collect the solid particles in the storage box and unify them together.

The structure of the facility according to the present invention is simple, the operation is convenient, the sewage after the daylighting panel is cleaned is rapidly filtered, the sewage is used twice, and the waste of water resources is greatly reduced.

The beneficial effect of the present invention is that when the equipment according to the present invention is in an initial state, the first scraper is positioned at the leftmost end of the first strainer, and the second scraper is positioned at the leftmost end of the second strainer. Wherein the cam is in a horizontal state, the first conduction movement lever is located at the center of the first conduction movement groove, and the rear end face of the storage box is closely attached to the box housing, and the drainage groove Is in a closed state.

When using, the sewage after cleaning the daylighting panel is introduced into the filtration housing, the drainage groove is opened, the second electric rotating machine is started and in conjunction with the first scraper, the second scraper Reciprocating with the first strainer and the second strainer, respectively, starting the first electric rotating machine and rotating in conjunction with the crushing blade, starting the second electric rotating machine and interlocking with the squeezing roller Rotate.

After use, it is convenient to control the first electric rotating machine and the second electric rotating machine to stop the rotation, collect the solid particles in the storage box and unify them together.

The structure of the facility according to the present invention is simple, the operation is convenient, the sewage after the daylighting panel is cleaned is rapidly filtered, the sewage is used twice, and the waste of water resources is greatly reduced.

FIG. 1 is a schematic diagram of the overall structure of a sewage treatment apparatus for removing contaminants from a lighting panel according to the present invention. FIG. 2 is a cross-sectional view in the AA direction in FIG. FIG. 3 is a cross-sectional view in the BB direction in FIG. FIG. 4 is a schematic diagram of the internal structure of a prism in the present invention.

For ease of explanation, the present invention will be described in detail with reference to the following specific embodiments and drawings.

As shown in FIGS. 1 to 4, the sewage treatment apparatus for removing contaminants of the daylighting panel of the present invention includes a box housing 100, and prisms 188 are simultaneously installed at four corner bottoms of the box housing 100. A screw hole 189 is installed at the bottom of the box, and a rotation pitch angle 190 is engaged with and attached to the screw hole 189. When the ground is not flat using the rotation pitch angle 190, the height of the box housing is adjusted. The filter housing 110 is installed in the box housing 100, and the first empty groove 111 that is symmetrical so as to communicate with the left and right inner walls of the filter housing 110 is installed. Symmetrical second air groove 112 is installed so that 111 communicates with the inner wall away from the center of the filtration housing 110, and third air groove 113 is installed so as to communicate with the rear end of the filtration housing 110, A first strainer 135 is installed in the filtration casing 110, and the first strainer Second strainer 136 is installed under the trainer 135, the storage box 137 below the second strainer 136 is fixedly connected, phase Tsusuru so on between the bottom and the first air groove 111 of the storage box 137 And a drainage groove 101 is provided so as to communicate with the inner wall of the front end of the first empty groove 111, and the other end of the drainage groove 101 passes through the front end surface of the box housing 100, A first swash plate 133 is slidably engaged with and connected to the top end surface of one strainer 135, and symmetrically extends to the first empty groove 111 at both left and right ends of the first strainer 135. A second scraper 132 is slidably engaged with and connected to the top of the second strainer 136, and the second empty groove 112 is symmetrically connected to the left and right ends of the second strainer 136. A second swash plate 134 extending to The first transfer movement extending vertically to the conduction movement block 140 is connected to the bottom end face of the second strainer 136 by slidably engaging the conduction movement block 140 located at the rear end of the storage box 137. A groove 142 is provided, and a second conductive movement lever 141 that is positioned below the first conductive movement groove 142 and extends to the left and right is slidably engaged with and connected to the conductive movement block 140. The left and right ends of the conductive movement lever 141 are fixedly connected to the inner walls of the left and right ends of the filtration casing 110, and the E-type slip is located on the rear end inner wall of the filtration casing 110 to the left and right at the rear end of the first scraper 131. The moving block 201 is slidably engaged and connected, and the rear ends of the first scraper 131, the second scraper 132, and the conductive moving block 140 are fixed to the front end of the E-type sliding moving block 201. Connected to the top inner wall of the second air groove 112 One electric rotating machine 121 is installed, and a kite load device is installed outside the first electric rotating machine 121. The kite load device includes an impact absorbing block 1214 and a cooling piece 1215, and the first electric rotating machine 121 The first rotating pin shaft 151 that extends downward is connected so that power can be transmitted, and a blade 152 that is crushed around the first rotating pin shaft 151 is fixedly connected, and symmetrically below the crushing blade 152. A third swash plate 144 extending downward is installed, one end of the third swash plate 144 away from the center of the second empty groove 112 is fixedly connected to the second empty groove 112, and the second empty groove 112 A squeezing roller 153 located below the third swash plate 144 and symmetrical to the left and right is installed, extends into the squeezing roller 153 in the front-rear direction, and a rear end passes through a rear end inner wall of the second empty groove 112. The second rotation pin shaft 300 extending in the third empty groove 113 is fixedly connected, and the second rotation A front end of the pin shaft 300 is rotatably attached to the box housing 100 through a bearing, and a second conductive movement groove 145 whose mouth is separated from the center of the second air groove 112 is formed at the bottom of the second air groove 112. Installed, and slidably engaged with and connected to the second conductive movement groove 145, a second electric rotating machine 122 is installed on the inner wall of the rear end of the third empty groove 113, A fourth rotary pin shaft 202 extending forward to the second electric rotating machine 122, passing through the inner wall of the front end of the third air groove 113 and extending to the filtration housing 110 is connected so that power can be transmitted, and the fourth A rotating pin shaft 202 is rotatably attached to a front end inner wall of the third air groove 113 through a bearing, and a cam 138 is fixedly connected to a front end of the fourth rotating pin shaft 202, and the convex of the cam 138 is the first conductive moving lever 139 extending in the first conductive moving groove 142 is placed before the parts, Turbine 203 is engaged connected to serial fourth rotating pin shaft 202, a third rotation pin shaft 303 extending horizontally to the turbine 203 is fixedly connected, right and left ends of the third rotation pin shaft 303 through bearings A double-sided conical pulley 302 is fixedly connected to the third rotating pin shaft 303 symmetrically to the box housing 100, and a first conical pulley 301 is connected to the double-sided conical pulley 302. Engaged and connected, the first conical pulley 301 is fixedly connected to the rear end of the second rotating pin shaft 300.

Preferably, a screw is installed at a portion where the fourth rotating pin shaft 202 contacts the turbine 203, and it is convenient that the fourth rotating pin shaft 202 and the turbine rotate simultaneously.

Preferably, the first filtration hole of the first strainer 135 is larger than the second filtration hole of the second strainer 136, and it is convenient to treat sewage.

Preferably, the shock absorbing block 1214 is installed at an upper end and a lower end of the first electric rotating machine 121 and fixedly connected to the first electric rotating machine 121, and the cooling piece 1215 is connected to the first electric rotating machine 121. The first electric rotating machine is installed at a front end and a rear end and fixedly connected to the shell of the first electric rotating machine 121, and an upper end and a lower end of the cooling piece 1215 are fixedly connected to the shock absorbing block 1214. One or more cooling pieces 1215 are installed at the front end and the rear end of 121, respectively, and the cooling pieces 1215 absorb and radiate heat generated when the first electric rotating machine 121 operates, and the shock absorbing block 1214 However, the vibration force generated when the first electric rotating machine 121 operates is reduced to prevent the vibration force from being too large and affecting the normal operation of the apparatus.

When the equipment according to the present invention is in an initial state, the first scraper 131 is located at the leftmost end of the first strainer 135, the second scraper 131 is located at the leftmost end of the second strainer 136, The cam 223 is in a horizontal state, the first conductive movement lever 139 is located at the center of the first conductive movement groove 142, and the rear end face of the storage box 154 is closely attached to the box housing 100, and the drainage The groove 101 is in a closed state.

When used, the sewage after cleaning the daylighting panel is introduced into the filtration housing 110, the drainage groove 101 is opened, the second electric rotating machine 122 is started and in conjunction with the first scraper 131, The second scraper 132 is reciprocated by the first strainer 135 and the second strainer 136, respectively, starts the first electric rotating machine 121 and rotates in conjunction with the crushing blade 152, and the second electric rotating machine 122 Is activated and rotated in conjunction with the expression roller 153.

After use, it is convenient to control the first electric rotating machine 121 and the second electric rotating machine 122 to stop the rotation, collect the solid particles in the storage box 154, and clean them up in a unified manner.

What has been described above is merely a specific implementation method of the present invention, but the protection scope of the present invention is not limited thereto. Changes and replacements that have been conceived not through all creative labor are covered by the protection scope of the present invention. Therefore, the protection scope of the present invention is based on the protection scope to which the claims are limited.

Claims (1)

A highly efficient daylighting panel device comprising a box housing, wherein a prism is installed at the bottom of four squares of the box housing at the same time, a screw hole is installed at the bottom of the prism, and a rotation pitch angle is associated with the screw hole. When the ground is not flat using the rotation pitch angle, the height adjustment is performed, the stability of the box housing is increased, and the filter housing is installed in the box housing. A symmetric first air groove is provided so as to communicate with the inner wall, and a second air groove is provided such that the first air groove communicates with the inner wall away from the center of the filtration housing, and the filtration housing is provided. A third air groove is installed so as to communicate with the rear end, a first strainer is installed in the filtration housing, a second strainer is installed at the lower end of the first strainer, and stored at the lower end of the second strainer. The box is solid Connected to the bottom of the storage box and the first empty groove, a drain pipe is installed to communicate with the inner wall of the front end of the first empty groove, the drainage The other end of the groove passes through the front end surface of the box housing and is slidably engaged with and connected to the top end surface of the first strainer, and symmetrically on the left and right ends of the first strainer. A first swash plate extending in the first air groove is fixedly connected, and a second scraper is slidably engaged with and connected to the top of the second strainer. A second swash plate that extends symmetrically to the second empty groove is fixedly connected, and a conductive block located at the rear end of the storage box is slidably engaged with the bottom end surface of the second strainer. Connected to the conductive moving block A first conductive movement groove extending downward is installed, and a second conductive movement lever that is positioned below the first conductive movement groove and extends to the left and right is slidably engaged with and connected to the conductive movement block; The left and right ends of the second conductive movement lever are fixedly connected to the inner walls of the left and right ends of the filtration casing, and the E-type sliding movement is located on the rear end inner wall of the filtration casing to the left and right at the rear end of the first scraper. A block is slidably engaged and connected, the rear end of the first scraper, the second scraper, and the sliding block is fixedly connected to the front end of the E-type sliding block, A first electric rotating machine is installed on the inner wall of the top of the second air groove, a dredging load device is installed outside the first electric rotating machine, the dredging load device includes an impact absorbing block and a cooling piece, The first rotating pin where the electric rotating machine extends downward A shaft is connected so that power can be transmitted, a blade to be crushed around the first rotating pin shaft is fixedly connected, and a third swash plate extending downward symmetrically is installed at the lower end of the crushed blade, One end of the third swash plate away from the center of the second air groove is fixedly connected to the second air groove, and the second air groove is located at the lower end of the third swash plate and is symmetrical to the left and right. A roller is installed, extends back and forth in the squeezing roller, and a second rotating pin shaft extending rearwardly through the rear end inner wall of the second air groove and extending to the third air groove is fixedly connected, The front end of the second rotary pin shaft is rotatably attached to the box housing through a bearing, and a second conductive movement groove is provided at the bottom of the second air groove so that the mouth is separated from the center of the second air groove. The receiving box is slidably engaged with the second conductive movement groove. And a second electric rotating machine is installed on the inner wall of the rear end of the third empty groove, extends forward to the second electric rotating machine, passes through the inner wall of the front end of the third empty groove, and extends to the filtration housing. A first rotary pin shaft is connected so that power can be transmitted, and the first rotary pin shaft is rotatably attached to the inner wall of the front end of the third air groove through a bearing, in front of the first rotary pin shaft. A cam is fixedly connected to the terminal, a first conduction movement lever extending in front of the first conduction movement groove is installed on the convex portion of the cam, a turbine is engaged with and connected to the first rotation pin shaft, A third rotating pin shaft extending to the left and right is fixedly connected to the turbine, and both left and right ends of the third rotating pin shaft are rotatably attached to the box housing through bearings. Symmetrically double-sided conical pulley Is fixedly connected, and a first conical pulley is engaged and connected to the double-sided conical pulley, and the first conical pulley is fixedly connected to a rear end of the second rotating pin shaft, A screw is installed at a portion where the one rotation pin shaft contacts the turbine, the first filtration hole of the first strainer is larger than the second filtration hole of the second strainer, and the shock absorbing block is the first electric rotating machine. Installed at the upper and lower ends of the first electric rotating machine and fixedly connected to the first electric rotating machine, and the cooling pieces are installed at the front and rear ends of the first electric rotating machine and fixed to the shell of the first electric rotating machine. Connecting, the upper end and the lower end of the cooling piece are fixedly connected to the shock absorbing block, and one or more cooling pieces are installed at the front end and the rear end of the first electric rotating machine, respectively. Highly efficient daylighting panel device.