阅读说明：本技术 一种颗粒状化工材料加工用快速干燥设备 (Quick drying equipment is used in processing of graininess chemical material ) 是由 张成龙 于 2021-07-22 设计创作，主要内容包括：本发明提供一种颗粒状化工材料加工用快速干燥设备,涉及化工材料生产技术领域,解决了不能够通过结构上的改进在烘干过程中联动实现颗粒材料的辅助筛选以及通过震动筛选使颗粒物料与托料座的接触位置进行转换,已实现全方位烘干的效果；不能够通过结构上的改进实现风力与颗粒材料的均匀接触的问题。一种颗粒状化工材料加工用快速干燥设备,包括主体架；所述主体架上安装有托料结构。因矩形阵列状开设的通孔组成了风力分散结构,从而可保证叶片产生的风力能够均匀的与颗粒物料接触；因受力块头端与受力块右端面接触,且受力块右端面为倾斜状结构,从而当拨动杆向上移动时可实现受力块以及齿排的移动。(The invention provides rapid drying equipment for processing granular chemical materials, relates to the technical field of chemical material production, and solves the problems that auxiliary screening of the granular materials cannot be realized in a linkage manner in the drying process through structural improvement, and the contact positions of the granular materials and a material supporting seat are converted through vibration screening, so that the omnibearing drying effect is realized; the problem of uniform contact of wind force with the particulate material cannot be achieved by structural improvement. A rapid drying device for processing granular chemical materials comprises a main body frame; the main body frame is provided with a material supporting structure. The wind power dispersing structure is formed by the through holes arranged in the rectangular array, so that the wind power generated by the blades can be ensured to be uniformly contacted with the granular materials; because of the contact of the head end of the stress block and the right end face of the stress block, and the right end face of the stress block is of an inclined structure, the movement of the stress block and the tooth row can be realized when the poke rod moves upwards.)

1. The utility model provides a quick drying equipment is used in processing of granular chemical material which characterized in that: comprises a main body frame (1); the main body frame (1) is provided with a material supporting structure (2), and the main body frame (1) is also provided with a driving structure (3); the heat dissipation structure (4) is installed on the main body frame (1), the transmission structure (5) is further installed on the main body frame (1), and the shifting structure (6) is further installed on the main body frame (1); the heat dissipation structure (4) comprises a blocking frame (404) and a through hole (405), the blocking frame (404) is welded on the main body frame (1), and the blocking frame (404) is of a concave frame-shaped structure; the bottom end surface of the inner wall of the blocking frame (404) is provided with through holes (405) in a rectangular array shape, and the through holes (405) in the rectangular array shape form a wind power dispersing structure; the transmission structure (5) comprises a stress block (504), and the stress block (504) is welded on the sliding rod (502); the toggle structure (6) comprises a sliding seat (601) and a toggle rod (602), the sliding seat (601) is welded on the main body frame (1), and the toggle rod (602) is connected on the sliding seat (601) in a sliding manner; the head end of the poke rod (602) is contacted with the right end face of the stress block (504), and the right end face of the stress block (504) is of an inclined structure.

2. The rapid drying apparatus for processing granular chemical materials according to claim 1, wherein: the main body frame (1) comprises rectangular plates (101) and connecting rods (102), the two rectangular plates (101) are arranged, the two rectangular plates (101) are connected through the two connecting rods (102) in a welded mode, and the rectangular plates (101) and the connecting rods (102) jointly form the main body frame (1).

3. The rapid drying apparatus for processing granular chemical materials according to claim 1, wherein: the main body frame (1) further comprises two blocking rods (103), the two blocking rods (103) are arranged, and the two blocking rods (103) are respectively welded on the two rectangular plates (101); the material supporting structure (2) comprises a rotating shaft A (201) and a material supporting seat (202), the rotating shaft A (201) is welded between the two rectangular plates (101), and the rotating shaft A (201) is rotatably connected with the material supporting seat (202); the material supporting seat (202) is of an L-shaped plate structure, the bottom end face of the material supporting seat (202) is in contact with the blocking rod (103), and the material supporting seat (202) is in an inclined state when the material supporting seat (202) is in contact with the blocking rod (103).

4. A rapid drying apparatus for processing a granular chemical material as claimed in claim 3, wherein: the material supporting structure (2) further comprises sieve holes (203) and bulges (204), the sieve holes (203) are formed in the material supporting seat (202) in a rectangular array shape, and the bulges (204) are welded on the material supporting seat (202) in an annular array shape; the bulges (204) are in semi-cylindrical structures, and the bulges (204) are positioned at the gap positions of the sieve holes (203).

5. The rapid drying apparatus for processing granular chemical materials according to claim 1, wherein: the driving structure (3) comprises a rotating shaft B (301), a driving motor (302) and a toggle block (303), the rotating shaft B (301) is rotatably connected to the main body frame (1), the head end of the rotating shaft B (301) is connected with the driving motor (302), and the driving motor (302) is fixedly connected to the main body frame (1) through a bolt; two shifting blocks (303) are installed on the rotating shaft B (301), and the shifting blocks (303) are in surface contact with the bottom end of the material supporting seat (202).

6. The rapid drying apparatus for processing granular chemical materials according to claim 1, wherein: the heat dissipation structure (4) comprises four rotating shafts C (401) and blades (402), and the four rotating shafts C (401) are rotatably connected to the main body frame (1); four blades (402) are arranged on each rotating shaft C (401) in a rectangular array mode, and the rotating shafts C (401) and the blades (402) are located above the material supporting structure (2).

7. The rapid drying apparatus for processing granular chemical materials according to claim 1, wherein: the heat dissipation structure (4) further comprises four gears (403), wherein the number of the gears (403) is four, and the four gears (403) are respectively arranged on the four rotating shafts C (401); the transmission structure (5) comprises a tooth row (501), sliding rods (502) and elastic pieces (503), the head end and the tail end of the tooth row (501) are respectively welded with one sliding rod (502), the two sliding rods (502) are connected to the main body frame (1) in a sliding mode, and the tooth row (501) is meshed with the gear (403); an elastic piece (503) is sleeved on a sliding rod (502) at the tail end of the tooth row (501), and the elastic piece (503) forms an elastic reset structure of the tooth row (501).

8. The rapid drying apparatus for processing granular chemical materials according to claim 1, wherein: the toggle structure (6) further comprises a stop block (603), the stop block (603) is welded on the toggle rod (602), the stop block (603) forms a sliding limiting structure of the toggle rod (602), and the tail end of the toggle rod (602) is in contact with the material supporting seat (202).

Technical Field

The invention belongs to the technical field of chemical material production, and particularly relates to rapid drying equipment for processing granular chemical materials.

Background

According to the demand of difference, required chemical material's shape is also different, therefore chemical material can appear graininess, strip, slice etc. and wherein graininess chemical material is comparatively common, and graininess chemical material needs drying device to carry out drying operation in the course of working usually.

As in application No.: CN201921877195.2, the utility model discloses a quick drying device is used in processing of graininess chemical material, including shell, mounting panel, electric telescopic handle and flourishing workbin, the conveyer belt is installed to the inboard of shell, flourishing workbin is located the right side of mounting panel, and flourishing workbin and shell fixed connection, the upper end left side of flourishing workbin is run through there is the baffle, the middle part of installation piece is run through there is the transfer line, and the left end of transfer line rotates and installs the backing roll, the right-hand member nestification of transfer line has the spring that is located the installation piece right side, and the right side of transfer line installs the carousel that is connected with the motor output. This quick drying device is used in processing of graininess chemical material can the accelerated drying to the material, has improved production efficiency, and can effectually carry out comprehensive drying to the material, has guaranteed drying effect to the material is carried out drying operation to the material of different sizes granule to the convenience, has improved the device's practicality, can effectually avoid the phenomenon of jam moreover.

The rapid drying equipment for processing chemical materials similar to the above application has the following disadvantages:

one is that the existing device has single function, can not realize the auxiliary screening of the particle materials in linkage in the drying process through structural improvement and can not realize the omnibearing drying effect by converting the contact position of the particle materials and the material supporting seat through vibration screening; moreover, the drying angle of the existing device is limited during drying, and the uniform contact between wind power and particle materials cannot be realized through structural improvement.

In view of the above, research and improvement are made on the existing structure and defects, and a rapid drying device for processing granular chemical materials is provided, so as to achieve the purpose of higher practical value.

Disclosure of Invention

In order to solve the technical problems, the invention provides a rapid drying device for processing granular chemical materials, aiming at solving the problems that the existing device has single function, can not realize auxiliary screening of the granular materials in a linkage manner in the drying process through structural improvement and can not realize the conversion of the contact position of the granular materials and a material supporting seat through vibration screening, thereby realizing the effect of all-directional drying; moreover, the drying angle of the existing device is limited during drying, and the problem of uniform contact between wind power and particle materials cannot be realized through structural improvement.

The invention relates to a rapid drying device for processing granular chemical materials, which has the purpose and the effect achieved by the following specific technical means:

a rapid drying device for processing granular chemical materials comprises a main body frame; the main body frame is provided with a material supporting structure, and the main body frame is also provided with a driving structure; the main body frame is provided with a heat dissipation structure, a transmission structure and a shifting structure; the heat dissipation structure comprises a blocking frame and a through hole, the blocking frame is welded on the main body frame, and the blocking frame is of a concave frame-shaped structure; the bottom end surface of the inner wall of the blocking frame is provided with through holes in a rectangular array shape, and the through holes in the rectangular array shape form a wind power dispersing structure; the transmission structure comprises a stress block, and the stress block is welded on the sliding rod; the shifting structure comprises a sliding seat and a shifting rod, the sliding seat is welded on the main body frame, and the shifting rod is connected to the sliding seat in a sliding manner; the head end of the toggle rod is in contact with the right end face of the stress block, and the right end face of the stress block is of an inclined structure.

Further, the main body frame comprises two rectangular plates and two connecting rods, the two rectangular plates are connected through the two connecting rods in a welded mode, and the main body frame is formed by the rectangular plates and the connecting rods.

Furthermore, the main body frame also comprises two blocking rods which are respectively welded on the two rectangular plates; the material supporting structure comprises a rotating shaft A and a material supporting seat, the rotating shaft A is welded between the two rectangular plates, and the rotating shaft A is rotatably connected with the material supporting seat; the material supporting seat is of an L-shaped plate structure, the bottom end face of the material supporting seat is in contact with the blocking rod, and the material supporting seat is in an inclined state when the material supporting seat is in contact with the blocking rod.

Furthermore, the material supporting structure also comprises sieve pores and bulges, the sieve pores are arranged on the material supporting seat in a rectangular array shape, and the bulges are welded on the material supporting seat in an annular array shape; the bulges are in semi-cylindrical structures and are positioned in the positions of the sieve pore gaps.

Furthermore, the driving structure comprises a rotating shaft B, a driving motor and a shifting block, wherein the rotating shaft B is rotatably connected to the main body frame, the head end of the rotating shaft B is connected with the driving motor, and the driving motor is fixedly connected to the main body frame through a bolt; and two shifting blocks are arranged on the rotating shaft B and are in contact with the bottom end face of the material supporting seat.

Furthermore, the heat dissipation structure comprises four rotating shafts C and blades, and the four rotating shafts C are rotatably connected to the main body frame; four blades are arranged on each rotating shaft C in a rectangular array mode, and the rotating shafts C and the blades are located above the material supporting structure.

Furthermore, the heat dissipation structure also comprises four gears, and the four gears are respectively arranged on the four rotating shafts C; the transmission structure comprises a gear row, sliding rods and an elastic piece, wherein the head end and the tail end of the gear row are respectively welded with one sliding rod, the two sliding rods are connected to the main body frame in a sliding mode, and the gear row is meshed with the gear; and the sliding rod at the tail end of the tooth row is sleeved with an elastic piece, and the elastic piece forms an elastic reset structure of the tooth row.

Furthermore, the toggle structure further comprises a stop block, the stop block is welded on the toggle rod, the stop block forms a sliding limiting structure of the toggle rod, and the tail end of the toggle rod is contacted with the material supporting seat.

Compared with the prior art, the invention has the following beneficial effects:

through the arrangement of the material supporting structure, firstly, the material supporting seat is of an L-shaped plate structure, the bottom end face of the material supporting seat is in contact with the blocking rod, and the material supporting seat is in an inclined state when the material supporting seat is in contact with the blocking rod, so that the material of the granular materials can be conveniently discharged; secondly, sieve pores are arranged on the material supporting seat in a rectangular array shape, and bulges are welded on the material supporting seat in an annular array shape; the bulges are of semi-cylindrical structures and are positioned in the positions of the sieve mesh gaps, so that on one hand, the granular materials can be screened and cleaned, and on the other hand, the moving speed of the granular materials in the material supporting seat can be reduced through the bulges, and the drying quality is further ensured.

Through the matching arrangement of the material supporting structure, the driving structure, the heat dissipation structure, the transmission structure and the shifting structure, firstly, the shifting block is in contact with the bottom end face of the material supporting seat, so that the material supporting seat is in a reciprocating vibration state when the driving motor rotates, the contact position of the granular materials and the material supporting seat is switched, and the drying comprehensiveness of the granular materials is finally improved; secondly, as the rotating shaft C and the blades are positioned above the material supporting structure, the drying of the granular materials on the material supporting structure can be realized through the rotation of the blades; thirdly, the wind power dispersing structure is formed by the through holes arranged in the rectangular array, so that the wind power generated by the blades can be ensured to be uniformly contacted with the particle materials; fourthly, the head end of the stress block is in contact with the right end face of the stress block, and the right end face of the stress block is of an inclined structure, so that the stress block and the gear row can move when the poke rod moves upwards; fifthly, the stop blocks are welded on the poking rod, the stop blocks form a sliding limiting structure of the poking rod, and the tail end of the poking rod is contacted with the material supporting seat, so that the poking rod can be pushed to move up and down when the material supporting seat moves up and down, and finally, the reciprocating rotation of the blades is realized.

Drawings

Fig. 1 is a schematic axial view of the present invention.

Fig. 2 is a schematic top view of the present invention.

Fig. 3 is a schematic axial view of the main body frame of the present invention after being disassembled.

Fig. 4 is an enlarged schematic view of fig. 3 a according to the present invention.

Fig. 5 is an enlarged view of the structure of fig. 3B according to the present invention.

Fig. 6 is a schematic front view of fig. 3 according to the present invention.

Fig. 7 is an enlarged view of the structure of fig. 6 according to the present invention.

Fig. 8 is an enlarged view of fig. 6D according to the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a main body frame; 101. a rectangular plate; 102. a connecting rod; 103. a gear lever; 2. a material supporting structure; 201. a rotating shaft A; 202. a material supporting seat; 203. screening holes; 204. a protrusion; 3. a drive structure; 301. a rotating shaft B; 302. a drive motor; 303. a shifting block; 4. a heat dissipation structure; 401. a rotating shaft C; 402. a blade; 403. a gear; 404. a blocking frame; 405. a through hole; 5. a transmission structure; 501. a tooth row; 502. a slide bar; 503. an elastic member; 504. a stress block; 6. a toggle structure; 601. a sliding seat; 602. a poke rod; 603. and a stop block.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 8:

the invention provides a rapid drying device for processing granular chemical materials, which comprises a main body frame 1; the main body frame 1 is provided with a material supporting structure 2, and the main body frame 1 is also provided with a driving structure 3; the main body frame 1 is provided with a heat dissipation structure 4, the main body frame 1 is also provided with a transmission structure 5, and the main body frame 1 is also provided with a shifting structure 6; referring to fig. 3, the heat dissipation structure 4 includes a blocking frame 404 and a through hole 405, the blocking frame 404 is welded on the main body frame 1, and the blocking frame 404 is a concave frame-shaped structure; the bottom end surface of the inner wall of the blocking frame 404 is provided with through holes 405 in a rectangular array shape, and the through holes 405 in the rectangular array shape form a wind power dispersing structure, so that wind power generated by the blades 402 can be ensured to be uniformly contacted with particle materials; referring to fig. 6 and 8, the transmission structure 5 includes a force receiving block 504, and the force receiving block 504 is welded to the sliding rod 502; the toggle structure 6 comprises a sliding seat 601 and a toggle rod 602, the sliding seat 601 is welded on the main body frame 1, and the toggle rod 602 is connected on the sliding seat 601 in a sliding manner; the head end of the toggle rod 602 is in contact with the right end face of the force-bearing block 504, and the right end face of the force-bearing block 504 is an inclined structure, so that when the toggle rod 602 moves upwards, the force-bearing block 504 and the gear row 501 can move.

Referring to fig. 3, the main body frame 1 includes rectangular plates 101 and connecting rods 102, the rectangular plates 101 are provided in two, the two rectangular plates 101 are welded and connected by the two connecting rods 102, and the rectangular plates 101 and the connecting rods 102 together constitute the main body frame 1.

Referring to fig. 6, the main body frame 1 further includes two stopper rods 103, and the two stopper rods 103 are respectively welded on the two rectangular plates 101; the material supporting structure 2 comprises a rotating shaft A201 and a material supporting seat 202, the rotating shaft A201 is welded between the two rectangular plates 101, and the rotating shaft A201 is rotatably connected with the material supporting seat 202; the material supporting base 202 is an L-shaped plate structure, the bottom end surface of the material supporting base 202 is in contact with the blocking rod 103, and the material supporting base 202 is in an inclined state when the material supporting base 202 is in contact with the blocking rod 103, so that the material discharging of the particle materials can be facilitated.

Referring to fig. 3, the supporting structure 2 further includes sieve holes 203 and protrusions 204, the material supporting base 202 is provided with the sieve holes 203 in a rectangular array, and the protrusions 204 are welded on the material supporting base 202 in an annular array; the bulge 204 is of a semi-cylindrical structure, and the bulge 204 is positioned in the gap position of the sieve holes 203, so that on one hand, the granular materials can be screened and cleared, and on the other hand, the moving speed of the granular materials in the material supporting seat 202 can be reduced through the bulge 204, and the drying quality is further ensured.

Referring to fig. 3, the driving structure 3 includes a rotating shaft B301, a driving motor 302 and a dial block 303, the rotating shaft B301 is rotatably connected to the main body frame 1, a head end of the rotating shaft B301 is connected to the driving motor 302, and the driving motor 302 is fixedly connected to the main body frame 1 through bolts; two stirring blocks 303 are installed on the rotating shaft B301, and the stirring blocks 303 are in surface contact with the bottom end of the material supporting seat 202, so that the material supporting seat 202 is in a reciprocating vibration state when the driving motor 302 rotates, the contact position of the granular materials and the material supporting seat 202 is changed, and finally the drying comprehensiveness of the granular materials is improved.

Referring to fig. 3, the heat dissipation structure 4 includes four rotation shafts C401 and four blades 402, the rotation shafts C401 are all rotatably connected to the main body frame 1; four blades 402 are installed on each rotating shaft C401 in a rectangular array mode, and the rotating shafts C401 and the blades 402 are located above the material supporting structure 2, so that drying of particle materials on the material supporting structure 2 can be achieved through rotation of the blades 402.

Referring to fig. 3 and 5, the heat dissipation structure 4 further includes four gears 403, the four gears 403 are respectively mounted on the four rotating shafts C401; the transmission structure 5 comprises a tooth row 501, sliding rods 502 and elastic pieces 503, the head end and the tail end of the tooth row 501 are welded with one sliding rod 502, the two sliding rods 502 are connected to the main body frame 1 in a sliding manner, and the tooth row 501 is meshed with the gear 403; the sliding rod 502 at the tail end of the row of teeth 501 is sleeved with an elastic part 503, and the elastic part 503 forms an elastic reset structure of the row of teeth 501, so that the row of teeth 501 can be reset elastically after moving, and further the reciprocating rotation of the blade 402 is realized.

Referring to fig. 6, the toggle structure 6 further includes a stopper 603, the stopper 603 is welded on the toggle rod 602, and the stopper 603 constitutes a sliding limiting structure of the toggle rod 602, and the tail end of the toggle rod 602 is in contact with the material supporting seat 202, so that when the material supporting seat 202 moves up and down, the toggle rod 602 can be pushed to move up and down, and finally, the reciprocating rotation of the blade 402 is also achieved.

The specific use mode and function of the embodiment are as follows:

when the particle material drying machine is used, when the driving motor 302 rotates, firstly, the material supporting seat 202 can be shifted through the shifting block 303 to vibrate up and down, so that on one hand, residue can be cleaned, on the other hand, the contact position of particle materials and the material supporting seat 202 is converted, and finally the particle material drying comprehensiveness is improved; meanwhile, the material supporting seat 202 pushes the poke rod 602 to move up and down, at the moment, due to the arrangement of the stress block 504, the reciprocating motion of the tooth row 501 can be realized under the poke of the poke rod 602, at the moment, due to the meshing of the tooth row 501 and the gear 403, the rotation of the rotating shaft C401 and the blade 402 can be realized, and finally, the wind power drying of the particle materials on the material supporting seat 202 is realized;

in the using process, firstly, the material supporting seat 202 is in an L-shaped plate structure, the bottom end surface of the material supporting seat 202 is in contact with the blocking rod 103, and the material supporting seat 202 is in an inclined state when the material supporting seat 202 is in contact with the blocking rod 103, so that the material discharging of the granular materials can be facilitated; secondly, the material supporting seat 202 is provided with sieve holes 203 in a rectangular array shape, and the material supporting seat 202 is welded with bulges 204 in an annular array shape; the bulge 204 is of a semi-cylindrical structure, and the bulge 204 is positioned in the gap position of the sieve holes 203, so that on one hand, the granular materials can be screened and cleared, and on the other hand, the moving speed of the granular materials in the material supporting seat 202 can be reduced through the bulge 204, and the drying quality is further ensured.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.