CN115446702A - Sieve machine and hot-fix rhinestone equipment - Google Patents

Abstract

The application provides a sieve machine and scalds brill equipment. The screening machine comprises a shaking mechanism, wherein the shaking mechanism comprises a rack, a shaking bottom plate, a left and right shaking assembly and an inclination adjusting assembly. Wherein the rocking base plate is mounted on the frame; the left and right shaking assembly is mounted on the shaking bottom plate, a detachable screen tray is arranged on the left and right shaking assembly, and the screen tray is driven by the left and right shaking assembly to shake left and right; the inclination adjusting component is arranged on the rack to adjust the inclination angle of the shaking bottom plate. The utility model provides a sieve machine and hot-fix rhinestone equipment can solve the sieve machine among the prior art and not only be difficult to adapt to arranging of the brill material of different grade type, and the problem that the efficiency ratio is lower of arranging of brill material.

Description

Sieve machine and hot-fix rhinestone equipment

Technical Field

The application relates to the technical field of machining, particularly, relate to a sieve machine and scald brill equipment.

Background

The hot-fix rhinestone or the rhinestone is a diamond-like decorative material which is processed by artificial glass, resin or glass resin and the like through the processes of film coating, paint spraying, gluing and the like. The appearance of the hot-fix rhinestone or the rhinestone is composed of a small surface (cone tip surface) and a large surface similar to a circular arc.

In the production process of the rhinestone or the rhinestone, the small face (conical tip face) of the rhinestone or the rhinestone is required to be arranged on the sieve tray upwards, the rhinestone or the rhinestone with the small face upwards on the sieve tray is turned over by the baking tray, and then the plastic plate is placed on the baking tray, so that the large face of the rhinestone or the rhinestone is adhered to the plastic plate. Therefore, the rhinestone or the rhinestone fixed on the plastic plate can be ground subsequently, and the qualified rhinestone is obtained.

At present, in order to arrange hot-fix rhinestones or rhinestones with small surfaces (conical tip surfaces) upward on a sieve tray, a sieve machine is usually arranged in hot-fix rhinestones, however, most of the existing sieve machines only have a left-right sieve shaking function, the left-right sieve shaking function of the sieve machine is difficult to adapt to arrangement of different types of drilling materials, and arrangement efficiency of the drilling materials is low.

Disclosure of Invention

The utility model provides a main aim at provides a sieve machine and scalds brill equipment to sieve machine among the solution prior art not only is difficult to adapt to arranging of the brill material of different grade type, and the problem that the efficiency ratio is lower of arranging of brill material.

According to an aspect of embodiments of the present application, there is provided a screen machine including a shaking mechanism including:

a frame;

the shaking bottom plate is arranged on the rack;

the left and right shaking assembly is mounted on the shaking bottom plate, a detachable screen tray is arranged on the left and right shaking assembly, and the screen tray is driven by the left and right shaking assembly to shake left and right;

the inclination adjusting component is arranged on the rack to adjust the inclination angle of the shaking bottom plate.

Further, the roll assembly includes:

the supporting plate is mounted on the shaking bottom plate through a linear bearing;

the tray is fixedly arranged on the upper surface of the supporting plate, and the sieve tray is detachably arranged in the tray;

the driving motor is installed on the shaking bottom plate and connected with the supporting plate through an eccentric wheel, and the driving motor rotates to drive the eccentric wheel to rotate so as to drive the supporting plate to shake in a reciprocating mode along the axis direction of the linear bearing.

Further, the first end of the shaking bottom plate is rotatably connected to the rack;

the inclination adjusting assembly comprises an electric cylinder, the electric cylinder is installed on the rack and stretches along the height direction of the rack, and the top end of the electric cylinder is rotatably connected with a second end, opposite to the first end, of the shaking bottom plate.

Furthermore, the shaking mechanism further comprises a material receiving disc, wherein the material receiving disc is connected with the shaking bottom plate and is arranged above the sieve disc to receive the drilling materials.

Furthermore, the shaking mechanism further comprises a driving part, and the driving part is in driving connection with the material receiving disc so as to drive the material receiving disc to be close to or deviate from the center of the sieve disc.

Further, the driving part includes:

the offset cylinder is arranged on the shaking bottom plate, and the telescopic direction of the offset cylinder is consistent with the axial direction of the linear bearing;

the connecting plate, the connecting plate vertical set up in the periphery of tray, just the bottom of connecting plate with the piston rod of skew cylinder is connected, the top of connecting plate with the take-up (stock) pan is connected.

Furthermore, a discharge bin is arranged on the tray, and a flow guide part used for guiding the drilling materials in the tray to the discharge bin is arranged on the tray.

Further, a beating component is arranged on the tray and used for beating the screen tray.

Furthermore, the bottom of the sieve tray is provided with two sieve tray fixing seats, the two sieve tray fixing seats are arranged on two opposite sides of the sieve tray, and each sieve tray fixing seat is provided with a sieve tray clamping part.

According to another aspect of the present application, there is provided a rhinestone apparatus including the above-described screen machine.

The utility model provides a sieve machine during operation, after boring the material and put in to the sieve machine, bore the material and can drop to the sieve tray on, at this moment, through the effect of controlling and rocking the subassembly, can drive and rock about the sieve tray, and then can rock the drilling material on the sieve tray so that the big face of drilling the material and the recess looks adaptation on the sieve tray, then make the awl point face of boring the material upwards. Meanwhile, because the screen (ing) machine in this application is provided with the slope adjustment subassembly, through the effect of this slope adjustment subassembly, can adjust the inclination of rocking the bottom plate, be more convenient for rock the brill material of different grade type as required and place in the position that the sieve tray corresponds. That is to say, the screen (ing) machine in this application rocks the synergism of subassembly and slope adjusting part through controlling, can rock the brill material of different grade type according to the demand effectively fast and place in the recess of sieve tray, can improve work efficiency and the operational reliability who uses this screen (ing) machine's boiling hot brill equipment.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the application and, together with the description, serve to explain the application and are not intended to limit the application. In the drawings:

FIG. 1 is a schematic structural diagram of a screening machine disclosed in an embodiment of the present application;

FIG. 2 is a schematic structural view of a screen machine disclosed in an embodiment of the present application after being cut;

FIG. 3 is a schematic structural view of the screening machine disclosed in the embodiment of the present application with the take-up pan removed;

FIG. 4 is a schematic structural view of a screening machine disclosed in an embodiment of the present application with a screening disk removed;

FIG. 5 is a schematic structural view of the screening machine disclosed in the embodiment of the present application with the upper part of the tray removed;

FIG. 6 is a schematic structural view of a screening machine disclosed in an embodiment of the present application with a portion above the support plate removed;

FIG. 7 is a schematic structural diagram of a sieve tray disclosed in an embodiment of the present application;

FIG. 8 is a schematic structural view of a sieve tray and a baking tray stacked together according to an embodiment of the present disclosure;

fig. 9 is an enlarged view of the region B in fig. 8.

Wherein the figures include the following reference numerals:

in the figure: 30. a screening machine; 31. a shaking mechanism; 311. shaking the bottom plate; 312. the left and right shaking assembly; 3121. a support plate; 3122. a tray; 31221. a discharging bin; 31222. a flow guide part; 3123. a drive motor; 3124. an eccentric wheel; 313. a tilt adjustment assembly; 3131. an electric cylinder; 314. a take-up pan; 3141. an avoidance part; 315. a drive section; 3151. an offset cylinder; 3152. a connecting plate; 32. a sieve tray; 321. a sieve tray fixing seat; 3211. a screen tray holding part; 322. a positioning member; 323. a connecting groove; 33. a rapping component; 34. a linear bearing; 36. positioning a plate; 361. a connecting projection; 37. a positioning column; 38. a sliding assembly; 381. a slider; 382. a slide rail; 100. baking trays; 103. and (7) positioning the holes.

Detailed Description

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present application will be described in detail below with reference to the embodiments with reference to the attached drawings.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments according to the present application. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, and it should be understood that when the terms "comprises" and/or "comprising" are used in this specification, they specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof, unless the context clearly indicates otherwise.

The relative arrangement of the components and steps, the numerical expressions, and numerical values set forth in these embodiments do not limit the scope of the present application unless specifically stated otherwise. Meanwhile, it should be understood that the sizes of the respective portions shown in the drawings are not drawn in an actual proportional relationship for the convenience of description. Techniques, methods, and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail but are intended to be part of the specification where appropriate. In all examples shown and discussed herein, any particular value should be construed as merely illustrative, and not limiting. Thus, other examples of the exemplary embodiments may have different values. It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, further discussion thereof is not required in subsequent figures.

Referring to fig. 1 and 2, according to an embodiment of the present application, a screen 30 is provided, and the screen 30 is particularly suitable for shaking drilling materials so as to arrange the drilling materials on a screen disc 32 according to requirements. Specifically, the screening tray 32 is provided with a groove (not shown in the figure), which is particularly suitable for matching a large surface of the drilled material, so that the large surface of the drilled material can be matched in the groove of the screening tray 32 in the working process of the screening machine 30, thereby completing the arrangement of the drilled material on the screening tray 32 and providing necessary guarantee for the subsequent treatment process of the drilled material.

Particularly, sieve machine 30 in this embodiment includes and rocks mechanism 31, after will boring the material and put in sieve machine 30, through the effect of rocking mechanism 31 on this sieve machine 30, can arrange boring the material, makes the big face of boring the material just in time place in the recess of sieve tray 32.

Specifically, the rocking mechanism 31 includes a frame (not shown), a rocking base plate 311, a left-right rocking assembly 312, and a tilt adjusting assembly 313.

Wherein, the shaking bottom plate 311 is installed on the frame; the left-right shaking assembly 312 is arranged on the shaking bottom plate 311, and the screen tray 32 is detachably arranged on the left-right shaking assembly 312 and is driven by the left-right shaking assembly 312 to shake left and right; the inclination adjusting assembly 313 is disposed at the frame to adjust an inclination angle of the shaking base plate 311.

After the drilling material is put into sieve machine 30, the drilling material can drop to sieve tray 32, at this moment, through the effect of left and right rocking subassembly 312, can drive sieve tray 32 and rock left and right, and then can rock the drilling material on sieve tray 32 so that the big face of drilling the material and the recess looks adaptation on the sieve tray 32, then make the awl point face of drilling the material upwards. Meanwhile, because the screen machine 30 in this embodiment is provided with the inclination adjusting component 313, the inclination angle of the shaking bottom plate 311 can be adjusted by the action of the inclination adjusting component 313, and different types of drilling materials can be more conveniently shaken and placed in the corresponding positions of the screen tray 32 as required. That is to say, the screen (30) in this application can rock the brill material of different grade type according to the demand fast effectively and place in the recess of sieve tray (32) through the synergism of rocking subassembly (312) and slope adjustment subassembly (313) about, can improve the work efficiency and the operational reliability who uses this screen (30) to scald the brill equipment.

Referring to fig. 1, 2 and 4, the leftward and rightward rocking assembly 312 in the present embodiment includes a support plate 3121, a tray 3122, a driving motor 3123 and an eccentric wheel 3124. Wherein, the supporting plate 3121 is installed on the rocking base plate 311 through the linear bearing 34; the tray 3122 is fixedly installed on the upper surface of the support plate 3121, and the sieve tray 32 is detachably installed in the tray 3122; the driving motor 3123 is installed on rocking bottom plate 311, and driving motor 3123 is connected through eccentric 3124 with backup pad 3121, and driving motor 3123 rotates and drives eccentric 3124 and rotate to can drive backup pad 3121 and rock along the axis direction of linear bearing 34 to reciprocating.

Optionally, the supporting plate 3121 in this embodiment may be a square plate, a circular plate, or another irregular plate, as long as it can support the tray 3122 and the structure above the tray 3122, which is not specifically limited in this application. Tray 3122 includes a bottom plate face and sets up the flange in bottom plate face periphery, through the effect of bottom plate face, can support and install sieve tray 32, and the periphery at the bottom plate face is enclosed to the flange, is convenient for block the brill material, prevents to bore the material and drops out from tray 3122.

During actual work, driving motor 3123 rotates, can drive eccentric wheel 3124 and rotate, and then can drive backup pad 3121 that is connected with eccentric wheel 3124 along linear bearing 34 reciprocating motion, and then can drive tray 3122 and install the synchronous reciprocating motion of sieve tray 32 in tray 3122, finally to boring the material on the sieve tray 32 reciprocating rock so that bore the material and arrange in sieve tray 32 as required. This embodiment is through above-mentioned structure for the simple structure of sieve machine, and the control of being convenient for.

In other embodiments of the present application, the left-right rocking assembly 312 may be a link mechanism or a lead screw mechanism, etc. capable of driving the tray 3122 to reciprocate, and any other modifications under the concept of the present application are within the scope of the present application.

Referring to fig. 1 to 4, the tilt adjusting assembly 313 in the present embodiment includes an electric cylinder 3131, and the tilt angle of the shaking base plate 311 can be adjusted by the electric cylinder 3131. During actual installation, the first end of the shaking bottom plate 311 is rotatably connected to the frame; and an electric cylinder 3131 is installed on the frame such that the electric cylinder 3131 extends and contracts in a height direction of the frame, and a top end of the electric cylinder 3131 is rotatably connected to a second end of the shaking base plate 311 opposite to the first end. When the electric cylinder 3131 rises and falls along the height direction of the frame, the second end of the swinging bottom plate 311 can be driven to rotate along the first end, and the inclination angle of the swinging bottom plate 311 can be adjusted. Meanwhile, in this embodiment, the electric cylinder 3131 is used to drive the swinging bottom plate 311 to ascend and descend for angle adjustment, so that the adjustment range is wider.

Of course, in other embodiments of the present application, the tilt adjusting assembly 313 may also be provided as other structural members capable of ascending and descending, such as an ascending and descending cylinder, a ascending and descending hydraulic cylinder, or a liftable and descending screw structure, and any other modifications within the spirit of the present application are within the scope of the present application. In actual design, the first end of the swinging base plate 311 may be connected to the frame through a rotating shaft, a hinge, or the like, and the second end of the swinging base plate 311 may also be connected to the top end of the electric cylinder 3131 through a rotating shaft, a hinge, or the like.

Furthermore, the shaking mechanism 31 in this embodiment further includes a receiving tray 314, the receiving tray 314 is connected to the shaking bottom plate 311, the receiving tray 314 is disposed above the sieve tray 32 to receive the drilling materials screened by the screening mechanism on the rhinestone ironing device, and an avoiding portion 3141 for avoiding the sieve tray 32 is disposed on the receiving tray 314. Through the effect of the take-up pan 314 that sets up above sieve tray 32, can accept the brill material that the last procedure was transmitted to rock the in-process that subassembly 312 rocked and put in on sieve tray 32 with the brill material that it accepted. Optionally, the avoiding portion 3141 is an avoiding groove, and the avoiding groove can avoid the sieve tray 32, and is more suitable for putting the drilling material on the sieve tray 32 in a comprehensive manner.

Referring to fig. 1, 3 to 7, the shaking mechanism 31 further includes a driving portion 315, and the driving portion 315 is drivingly connected to the receiving tray 314 and can drive the receiving tray 314 to approach or deviate from the center of the sieve tray 32. That is, the driving portion 315 may drive the material receiving tray 314 to reciprocate to approach or deviate from the sieve tray 32, so that the material receiving tray 314 may not only receive the drilling material well, but also facilitate the drilling material to be thrown onto the sieve tray 32, and during the movement of the sieve tray 32, the material receiving tray 314 may avoid the sieve tray 32 to rapidly move the sieve tray 32.

Specifically, the driving part 315 includes a shift cylinder 3151 and a connection plate 3152. Wherein, the offset cylinder 3151 is arranged on the shaking bottom plate 311, and the expansion direction of the offset cylinder 3151 is consistent with the axial direction of the linear bearing 34; the connecting plate 3152 is vertically arranged on the outer periphery of the tray 3122, the bottom end of the connecting plate 3152 is connected with the piston rod of the deviation cylinder 3151, and the top end of the connecting plate 3152 is connected with the material receiving tray 314. When the offset cylinder 3151 extends and retracts along the axial direction of the linear bearing 34, the connecting plate 3152 can be driven to drive the receiving tray 314 to approach or deviate from the sieve tray 32 along the horizontal direction, and therefore the structure is simple and the control is convenient. Of course, in other embodiments of the present application, the driving unit 315 may be a screw assembly or the like.

In order to ensure the stability of the take-up pan 314 during the moving process, a sliding assembly 38 may be further disposed on the supporting plate 3121, and the take-up pan 314 is slidably mounted on the sliding assembly 38 during the installation. Optionally, the sliding assembly 38 includes a sliding block 381 and a sliding rail 382, and during actual installation, the sliding rail 382 is installed on the supporting plate 3121, the length direction of the sliding rail 382 coincides with the axial direction of the linear bearing 34, the sliding block 381 is installed on the sliding rail 382, and the receiving tray 314 is fixedly installed on the sliding block 381. When the deviation cylinder 3151 moves, the material receiving tray 314 can be driven to move along the slide rail 382, and the material receiving tray 314 can be supported by the action of the sliding assembly 38, so that the structure is stable and reliable.

The discharging bin 31221 is provided on the tray 3122 in this embodiment, and the flow guide portion 31222 for guiding the drilling material in the tray 3122 to the discharging bin 31221 is provided on the tray 3122. So set up, when shaking left and right subassembly 312 motion, the brill material that scatters on the sieve dish 32 can fall into tray 3122 in, when tray 3122 constantly rocked, this water conservancy diversion portion 31222 can be with the brill material water conservancy diversion in the tray 3122 to go out in the feed bin 31221.

Optionally, the discharging bin 31221 in this embodiment is disposed at a side of the tray 3122 near the first end of the shaking base 311, so that the drilling material in the tray 3122 can be poured into the discharging bin 31221 when the electric cylinder 3131 is lifted. Optionally, the guiding portion 31222 is a guiding groove or a guiding baffle, which may be any structure that facilitates guiding the drilling material in the tray 3122 to the discharging bin 31221.

Further, the tray 3122 in this embodiment is provided with a beating assembly 33, and the beating assembly 33 is used for beating the sieve tray 32, so that the large surface of the drilling material on the sieve tray 32 can be quickly and accurately dropped into the groove on the sieve tray 32. Alternatively, the beating assembly 33 in this embodiment is a beating cylinder, which extends and retracts in the same radial direction as the sieve tray 32 placed on the tray 3122, and the beating cylinder is used to facilitate beating of the sieve tray 32.

Optionally, the number of the beating assemblies 33 in this embodiment is multiple, and multiple beating assemblies 33 are spaced around the periphery of the tray 3122, so as to facilitate effective beating of the sieve tray 32. Illustratively, the number of the beating assemblies 33 can be two, three or more, and the drawings in the present embodiment show the case where there are four beating assemblies 33.

Optionally, in order to support and fix a position sieve dish 32, be provided with positioning disk 36 and reference column 37 on the tray 3122 in this embodiment, be provided with connecting protrusion 361 on the positioning disk 36, be provided with the connecting groove 323 that corresponds with this connecting protrusion 361 on the sieve dish 32, reference column 37 is many, many reference columns set up the periphery at positioning disk 36, be provided with the hole (not shown in the figure) with this reference column 37 looks adaptation on the sieve dish 32, positioning effect through positioning disk 36 and reference column 37 can prescribe a limit to sieve dish 32 in tray 3122 steadily, avoid sieve dish 32 to take place to rock relative tray 3122 at the in-process that rocks mechanism 31 rocked.

In the actual working process, after the drilling material is arranged on the sieve tray 32, the roasting tray 100 is usually placed on the sieve tray 32, and then the roasting tray 100 and the sieve tray 32 are clamped and the sieve tray 32 and the roasting tray 100 are turned over simultaneously, so that the large surface of the drilling material faces downwards and the conical tip faces downwards. In order to carry out the centre gripping to sieve dish 32, set up two sieve dish fixing bases 321 in the bottom of sieve dish 32 in this embodiment, two sieve dish fixing bases 321 set up respectively in the relative both sides of sieve dish 32, and the in-process of actual centre gripping and upset sieve dish 32 carries out the centre gripping through the manipulator to the sieve dish fixing base 321 of the relative both sides of sieve dish 32 and can carry out centre gripping and upset to sieve dish 32. In order to cooperate with the manipulator, the sieve tray fixing seat 321 in this embodiment is provided with a sieve tray retaining portion 3211, and the sieve tray retaining portion 3211 may be a retaining groove, a retaining protrusion, or a hook, and the like, and any structure that can cooperate with the manipulator to retain and turn over the sieve tray 32 is within the protection scope of the present application.

Referring to fig. 7 to 9, after the grill pan 100 is placed on the sieve pan 32, the grill pan 100 and the sieve pan 32 can sandwich the ingredients between the grill pan 100 and the sieve pan 32, so that the ingredients do not easily fall out from between the grill pan 100 and the sieve pan 32 when the grill pan 100 and the sieve pan 32 are turned over. In order to ensure the stability of the tray combination of the baking tray 100 and the sieve tray 32, the two opposite sides of the sieve tray 32 in this embodiment are provided with positioning parts 322, and the baking tray 100 is provided with positioning holes 103 matched with the positioning parts 322. Optionally, the positioning member 322 is a positioning pin, and the positioning pin is matched with the positioning hole 103, so that the sieve tray 32 and the baking tray 100 stacked together can be positioned, and the baking tray 100 and the sieve tray 32 can be clamped simultaneously, thereby facilitating the turning and transferring of the drilling material disposed therebetween.

According to another embodiment of the present application, there is also provided a rhinestone ironing device, where the rhinestone ironing device includes the sieving machine in the above embodiment, and therefore, the rhinestone ironing device in this embodiment includes all the technical effects of the sieving machine in the above embodiment, and since the technical effects of the sieving machine have been described in detail in the foregoing, details are not described here.

For ease of description, spatially relative terms such as "over 8230 \ 8230;,"' over 8230;, \8230; upper surface "," above ", etc. may be used herein to describe the spatial relationship of one device or feature to another device or feature as shown in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if a device in the figures is turned over, devices described as "above" or "on" other devices or configurations would then be oriented "below" or "under" the other devices or configurations. Thus, the exemplary terms "at 8230; \8230; 'above" may include both orientations "at 8230; \8230;' above 8230; 'at 8230;' below 8230;" above ". The device may be otherwise variously oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

It should be noted that the terms "first", "second", and the like are used to define the components, and are only used for convenience of distinguishing the corresponding components, and the terms have no special meanings unless otherwise stated, and therefore, the scope of protection of the present application is not to be construed as being limited.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made to the present application by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (10)

1. A screen machine, characterized in that it comprises a shaking mechanism (31), said shaking mechanism (31) comprising:

a frame;

a rocking base plate (311), the rocking base plate (311) being mounted on the frame;

the left-right shaking assembly (312) is installed on the shaking bottom plate (311), a detachable screen disc (32) is arranged on the left-right shaking assembly (312), and the screen disc (32) is driven by the left-right shaking assembly (312) to shake left and right;

the inclination adjusting component (313), the inclination adjusting component (313) set up in the frame is in order to rock the inclination of bottom plate (311) and adjust.

2. The screen machine of claim 1, wherein the side-to-side shaking assembly (312) comprises:

a support plate (3121), the support plate (3121) being mounted on the wobble base plate (311) by means of a linear bearing (34);

a tray (3122), the tray (3122) being fixedly installed on an upper surface of the support plate (3121), the sieve tray (32) being detachably installed within the tray (3122);

the driving motor (3123), the driving motor (3123) is installed on the shaking bottom plate (311), the driving motor (3123) is connected with the supporting plate (3121) through an eccentric wheel (3124), and the driving motor (3123) drives the eccentric wheel (3124) to rotate so as to drive the supporting plate (3121) to shake in a reciprocating manner along the axial direction of the linear bearing (34).

3. The machine of claim 2, wherein the wobble plate (311) is rotatably connected at a first end to the frame;

the inclination adjusting assembly (313) comprises an electric cylinder (3131), the electric cylinder (3131) is mounted on the frame and extends and contracts along the height direction of the frame, and the top end of the electric cylinder (3131) is rotatably connected with a second end, opposite to the first end, of the shaking bottom plate (311).

4. The screen machine according to claim 3, characterized in that the shaking mechanism (31) further comprises a receiving tray (314), the receiving tray (314) is connected with the shaking bottom plate (311) and is arranged above the screen tray (32) to receive the drilling material.

5. The screen machine according to claim 4, characterized in that the shaking mechanism (31) further comprises a drive part (315), the drive part (315) being in driving connection with the take-up pan (314) to bring the take-up pan (314) closer to or away from the center of the screen disc (32).

6. The screen machine of claim 5, wherein the drive section (315) comprises:

the offset cylinder (3151), the said offset cylinder (3151) is set up on the said rocking bottom plate (311), the flexible direction of the said offset cylinder (3151) is identical with axial direction of the said linear bearing (34);

the connecting plate (3152) is vertically arranged on the periphery of the tray (3122), the bottom end of the connecting plate (3152) is connected with a piston rod of the offset cylinder (3151), and the top end of the connecting plate (3152) is connected with the material receiving plate (314).

7. The screen machine according to any one of claims 2 to 6, characterized in that a discharge bin (31221) is provided on the tray (3122), and a deflector portion (31222) for deflecting the drilling material in the tray (3122) to the discharge bin (31221) is provided on the tray (3122).

8. A screen machine according to any one of claims 2 to 6, characterized in that a rapping assembly (33) is provided on the tray (3122), said rapping assembly (33) being used for rapping the screen disc (32).

9. The screen machine according to any one of claims 1 to 6, characterized in that two screen tray fixing seats (321) are arranged at the bottom of the screen tray (32), the two screen tray fixing seats (321) are arranged at two opposite sides of the screen tray (32), and a screen tray clamping part (3211) is arranged on each screen tray fixing seat (321).

10. An ironing drill apparatus, characterized in that the ironing drill apparatus comprises a screen machine according to any one of claims 1-9.

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