CN220981643U - Brominated epoxy resin condensation recovery plant - Google Patents

Abstract

The utility model provides brominated epoxy resin condensation recovery equipment, relates to the technical field of epoxy resin, and aims to solve the problem that the work efficiency of condensation work is not improved when the epoxy resin is naturally cooled in low-temperature equipment, and comprises a cooling structure and a control structure; the cooling structure is movably connected to the top of the supporting structure; the control structure is respectively with cooling structure, bearing structure swing joint, and inside of cooling structure is swing joint respectively has reciprocating mechanism and ventilation mechanism, and ventilation mechanism includes: motor B, the pivot, the flabellum, the gear, the rack, motor B's one end fixedly connected with pivot, two sets of flabellum of while fixedly connected with in the pivot, gear fixed connection is in the one end of pivot, the gear meshes with the rack simultaneously, can control the flabellum to rotate through motor B, the flabellum can control the air and flow into the loading board through reservation groove A in the pivoted, the effectual work efficiency of condensation work when improving the epoxy condensation.

Description

Brominated epoxy resin condensation recovery plant

Technical Field

The utility model relates to the technical field of epoxy resin, in particular to brominated epoxy resin condensation recovery equipment.

Background

The brominated epoxy resin has good self-extinguishing function, and the common characteristics of the epoxy resin are self-extinguishing property and good heat resistance. The flame-retardant composite material is mainly used as flame-retardant composite materials, structural materials, adhesives and coatings, and is used in the industries of construction, aviation, ships, electronics and electrical appliances.

The inventor discovers that most of the existing brominated epoxy resin condensation recovery equipment has complicated processing procedures when in use, and needs to control the processed materials to be collected again after cooling and solidification, but the existing epoxy resin is naturally cooled in low-temperature equipment when being cooled, which is not beneficial to improving the working efficiency of the epoxy resin condensation work.

Disclosure of utility model

The utility model aims to provide brominated epoxy resin condensation recovery equipment, which solves the problem that the working efficiency of condensation work is not improved when the epoxy resin provided in the background art is naturally cooled in low-temperature equipment.

The utility model discloses brominated epoxy resin condensation recovery plant is reached by following concrete technical means:

A brominated epoxy resin condensation recovery device comprises a cooling structure and a control structure; the cooling structure is movably connected to the top of the supporting structure; the control structure is respectively with cooling structure, bearing structure swing joint, and inside of cooling structure is swing joint respectively has reciprocating mechanism and ventilation mechanism, and ventilation mechanism includes: motor B, pivot, flabellum, gear, rack, motor B's one end fixedly connected with pivot, two sets of flabellum of fixedly connected with simultaneously in the pivot, gear fixed connection is in the one end of pivot, and the gear meshes with the rack simultaneously.

Further, the cooling structure includes: the bearing plate comprises a bearing plate body, a connecting shaft, a containing groove, a sliding groove A, a reserved groove A, a ventilation groove and a fixing rod A, wherein the connecting shaft is fixedly connected to two sides of the bearing plate body respectively, the containing groove, the sliding groove A, the reserved groove A and the ventilation groove are formed in the bearing plate body respectively, and the fixing rod A is fixedly connected to the bearing plate body.

Further, the support structure includes: bottom plate, support column, reservation groove B, guide bar, elastic component A, the top fixedly connected with support column of bottom plate, the support column rotates with the connecting axle respectively and is connected, and the inside of bottom plate is equipped with reservation groove B, and the guide bar passes through reservation groove B fixed connection in the bottom plate, and swing joint has elastic component A on the guide bar, and elastic component A's one end is laminated mutually with the bottom plate respectively.

Further, the control structure includes: slider, connecting rod, dial button, preformed hole, go-between A, go-between B, dead lever B, the inside of slider is equipped with the preformed hole, the slider passes through the preformed hole respectively with bottom plate, guide bar sliding connection, one side of slider is laminated mutually with elastic component A, slider simultaneous fixed connection is on the connecting rod, the connecting rod passes through preformed groove B and bottom plate sliding connection, the both ends of connecting rod are fixedly connected with respectively dials the button, go-between A rotates with the slider to be connected, go-between B rotates with the connecting axle simultaneously to be connected, dead lever B's both ends respectively with go-between A, go-between B fixed connection.

Further, the reciprocating mechanism includes: the motor A is fixedly connected in the bearing plate through the accommodating groove, the bevel gear A is fixedly connected with the top of the motor A and simultaneously meshed with the bevel gear B, the bevel gear B is fixedly connected at one end of the driving shaft, the driving shaft is rotationally connected in the bearing plate, the two sides of the connecting plate are respectively fixedly connected with the connecting blocks, and the connecting blocks are respectively and movably connected with the driving shaft and the fixing rod A.

Further, the ventilation mechanism further includes: the guide frame is connected with the rack in a sliding mode, the rack is fixedly connected with one end of the sliding rod, the sliding rod and the elastic piece B are respectively connected in the bearing plate through the sliding groove A, and two ends of the elastic piece B are respectively attached to the bearing plate and the sliding rod.

Compared with the prior structure, the utility model has the following advantages:

1. According to the utility model, the fan blade can be controlled to rotate through the motor B, and the fan blade can control air to flow into the bearing plate through the reserved groove A while rotating, so that the working efficiency of condensation work during condensation of epoxy resin can be effectively improved when materials are placed on the bearing plate, the cost during processing of the epoxy resin is reduced, and the motor B can also carry racks to reciprocate through the elastic piece B after being started, thereby controlling the bearing plate to vibrate, and facilitating extraction of the condensed materials.

2. According to the utility model, the driving shaft can be driven to rotate through the motor A, the driving shaft can also control the connecting plate to reciprocate while rotating, and when the connecting plate reciprocates, the epoxy resin on the bearing plate can be controlled to be automatically discharged to one end of the bearing plate, so that the working efficiency of the epoxy resin collection is further improved.

3. The control structure is arranged, the sliding block can be controlled to slide through the connecting rod, the sliding block can also control the bearing plate to overturn while sliding, the bearing plate can also facilitate discharging materials while overturning, the sliding block can also automatically slide to one end through the control of the elastic piece A, the control mode is simpler, and the quick resetting of the bearing plate can be controlled conveniently.

Drawings

FIG. 1 is a schematic top view of the present utility model;

FIG. 2 is a schematic cross-sectional view of the present utility model;

FIG. 3 is a schematic cross-sectional view of a cooling structure according to the present utility model;

FIG. 4 is a schematic view of a support structure according to the present utility model;

FIG. 5 is a schematic structural view of a control structure according to the present utility model;

FIG. 6 is a schematic view of the reciprocating mechanism of the present utility model;

fig. 7 is a schematic structural view of the ventilating mechanism of the present utility model.

In the figure:

1. A cooling structure; 101. a carrying plate; 102. a connecting shaft; 103. a receiving groove; 104. a sliding groove A; 105. reserving a groove A; 106. a ventilation groove; 107. a fixed rod A;

2. A support structure; 201. a bottom plate; 202. a support column; 203. a reserved groove B; 204. a guide rod; 205. an elastic member A;

3. A control structure; 301. a slide block; 302. a connecting rod; 303. a dial button; 304. a preformed hole; 305. a connecting ring A; 306. a connecting ring B; 307. a fixed rod B;

4. A reciprocating mechanism; 401. a drive shaft; 402. bevel gears A; 403. bevel gear B; 404. a motor A; 405. a connecting plate; 406. a connecting block;

5. A ventilation mechanism; 501. a motor B; 502. a connecting shaft; 503. a fan blade; 504. a gear; 505. a rack; 506. a sliding groove B; 507. a guide frame; 508. a slide bar; 509. and an elastic member B.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples.

Embodiment one:

Referring to fig. 1 to 7, a brominated epoxy resin condensation recovery apparatus includes a cooling structure 1 and a control structure 3; the cooling structure 1 is movably connected to the top of the supporting structure 2; the control structure 3 is movably connected with the cooling structure 1 and the supporting structure 2 respectively, the inside of the cooling structure 1 is movably connected with the reciprocating mechanism 4 and the ventilation mechanism 5 respectively, and the ventilation mechanism 5 comprises: the motor B501, the rotating shaft 502, the fan blades 503, the gears 504 and the racks 505, wherein one end of the motor B501 is fixedly connected with the rotating shaft 502, two groups of fan blades 503 are fixedly connected to the rotating shaft 502, the gears 504 are fixedly connected to one end of the rotating shaft 502, and the gears 504 are simultaneously meshed with the racks 505.

As shown in fig. 7, wherein the ventilation mechanism 5 further includes: the sliding device comprises a sliding groove B506, a guide frame 507, a sliding rod 508 and an elastic piece B509, wherein the sliding groove B506 is arranged in a rack 505, the guide frame 507 is fixedly connected in a bearing plate 101, the guide frame 507 is in sliding connection with the rack 505 through the sliding groove B506, the rack 505 is fixedly connected at one end of the sliding rod 508, the sliding rod 508 and the elastic piece B509 are respectively and movably connected in the bearing plate 101 through a sliding groove A104, two ends of the elastic piece B509 are respectively attached to the bearing plate 101 and the sliding rod 508, a gear 504 adopts an incomplete gear, the gear 504 is used for automatically switching the meshing relationship between the gear 504 and the rack 505 when the gear 504 continuously rotates, the sliding rod 508 is in a step-shaped arrangement, the sliding distance of the sliding rod 508 can be limited through the sliding rod 508 which is arranged in a step-shaped manner, the elastic piece B509 adopts a spring, the sliding rod 508 can be controlled to automatically slide towards one end through the elastic piece B509, and a motor B501 adopts a servo motor, so that the servo motor can control the speed and the position accuracy is very accurate.

As shown in fig. 3, wherein the cooling structure 1 comprises: the bearing plate 101, the connecting axle 102, the holding groove 103, sliding groove A104, reserve groove A105, ventilation groove 106, dead lever A107, the both sides of bearing plate 101 are fixedly connected with connecting axle 102 respectively, the inside of bearing plate 101 is equipped with holding groove 103 respectively, sliding groove A104, reserve groove A105, ventilation groove 106 respectively, dead lever A107 fixed connection is on bearing plate 101, can control the flabellum 503 through motor B501 and rotate, the flabellum 503 can control the air to flow into bearing plate 101 through reserve groove A105 in the pivoted, can effectually improve the work efficiency of condensation work when the epoxy is condensed when the material is placed on bearing plate 101, and the cost when the epoxy processing has been reduced, can also carry rack 505 through elastic component B509 and reciprocate after the motor B501 is opened, thereby control bearing plate 101 and shake, the material extraction after the condensation of being convenient for.

Embodiment two:

On the basis of the first embodiment, as shown in fig. 4, the support structure 2 includes: bottom plate 201, support column 202, reservation groove B203, guide bar 204, elastic component A205, the top fixedly connected with support column 202 of bottom plate 201, support column 202 rotates with connecting axle 102 respectively to be connected, the inside of bottom plate 201 is equipped with reservation groove B203, guide bar 204 passes through reservation groove B203 fixed connection in bottom plate 201, swing joint has elastic component A205 on the guide bar 204, the one end of elastic component A205 is laminated mutually with bottom plate 201 respectively, the top of support column 202 is annular setting, its effect is, can make loading board 101 and connecting axle 102 rotate around support column 202 through the support column 202 that the arc set up, elastic component A205 adopts the spring, its effect is, can control slider 301 to slide to one end automatically through elastic component A205.

As shown in fig. 5, wherein the control structure 3 comprises: the novel anti-theft device comprises a sliding block 301, a connecting rod 302, a poking button 303, a reserved hole 304, a connecting ring A305, a connecting ring B306 and a fixing rod B307, wherein the reserved hole 304 is formed in the sliding block 301, the sliding block 301 is respectively connected with a bottom plate 201 and a guide rod 204 in a sliding mode through the reserved hole 304, one side of the sliding block 301 is attached to an elastic piece A205, the sliding block 301 is simultaneously and fixedly connected to the connecting rod 302, the connecting rod 302 is connected with the bottom plate 201 in a sliding mode through a reserved groove B203, the two ends of the connecting rod 302 are respectively and fixedly connected with the poking button 303, the connecting ring A305 is rotationally connected with the sliding block 301, the connecting ring B306 is simultaneously and rotationally connected with a connecting shaft 102, the two ends of the fixing rod B307 are respectively connected with the connecting ring A305 and the connecting ring B306 in a fixed mode, the sliding block 301 can be controlled to slide through the connecting rod 302, the sliding block 301 can also control the bearing plate 101 to overturn, materials can be discharged conveniently when the bearing plate 101 overturn, the sliding block 301 can also be controlled to slide to one end through the elastic piece A205, and the resetting of the bearing plate 101 can be controlled easily and conveniently.

Embodiment III:

On the basis of the first and second embodiments, as shown in fig. 6, the reciprocation mechanism 4 includes: the driving shaft 401, the bevel gear A402, the bevel gear B403, the motor A404, the connecting plate 405, the connecting block 406, motor A404 passes through accommodation groove 103 fixed connection in loading board 101, motor A404's top fixedly connected with bevel gear A402, bevel gear A402 meshes with bevel gear B403 simultaneously, bevel gear B403 fixed connection is in the one end of driving shaft 401, driving shaft 401 rotates and connects in loading board 101, the both sides of connecting plate 405 are fixedly connected with connecting block 406 respectively, connecting block 406 is connected with driving shaft 401, dead lever A107 swing joint respectively, can drive driving shaft 401 through motor A404 and rotate, driving shaft 401 still can control connecting plate 405 to reciprocate when rotating, connecting plate 405 can control epoxy on the loading board 101 to discharge to the one end of loading board 101 automatically during reciprocating, further improve the work efficiency when epoxy collects, the surface of driving shaft 401 is equipped with the screw thread, it is in effect, when driving shaft 401 rotates, can control connecting plate 405 and connecting block 406 through driving shaft 401 and slide.

The working principle of the embodiment is as follows:

In the utility model, firstly, the processed epoxy resin is uniformly placed on the bearing plate 101, after the placement is finished, the motor B501 is started, the fan blades 503 are controlled to rotate by the motor B501, so that air flows into the bottom of the bearing plate 101 through the reserved groove A105, the temperature of the bearing plate 101 is reduced, the condensation work of the epoxy resin is conveniently and rapidly controlled, after the condensation is finished, the slide block 301 can be controlled to slide towards one end through the connecting rod 302, the slide block 301 can be controlled to overturn by the connecting ring A305, the connecting ring B306 and the fixing rod B307 after the sliding, the connecting shaft 502 can be controlled to reciprocate by the gear 504 and the elastic piece B509 when the connecting shaft 502 rotates, the bearing plate 101 is driven to vibrate by the rack 505 through the rack striking the bearing plate 101, the motor A404 can be started after the bearing plate 101 is overturned, the connecting plate 405 and the connecting block 406 are controlled to reciprocate by the driving shaft 401, the condensed epoxy resin is conveniently and rapidly collected 303, and after the toggle button is released and the elastic piece A205 is controlled, and the bearing plate 101 is automatically reset.

Claims (10)

1. A brominated epoxy resin condensation recovery device is characterized in that: comprises a cooling structure (1) and a control structure (3); the cooling structure (1) is movably connected to the top of the supporting structure (2); the control structure (3) is respectively movably connected with the cooling structure (1) and the supporting structure (2), the inside of the cooling structure (1) is respectively movably connected with the reciprocating mechanism (4) and the ventilation mechanism (5), and the ventilation mechanism (5) comprises: the motor comprises a motor B (501), a rotating shaft (502), fan blades (503), a gear (504) and a rack (505), wherein one end of the motor B (501) is fixedly connected with the rotating shaft (502), two groups of fan blades (503) are fixedly connected to the rotating shaft (502) at the same time, the gear (504) is fixedly connected to one end of the rotating shaft (502), and the gear (504) is meshed with the rack (505) at the same time.

2. A brominated epoxy resin condensation recovery apparatus as defined in claim 1 wherein: the cooling structure (1) comprises: the bearing plate (101) and the connecting shaft (102), wherein the connecting shaft (102) is fixedly connected to two sides of the bearing plate (101) respectively.

3. A brominated epoxy resin condensation recovery apparatus as defined in claim 2 wherein: the cooling structure (1) further comprises: the bearing plate comprises a containing groove (103), a sliding groove A (104), a reserved groove A (105), a ventilation groove (106) and a fixing rod A (107), wherein the containing groove (103), the sliding groove A (104), the reserved groove A (105) and the ventilation groove (106) are respectively arranged in the bearing plate (101), and the fixing rod A (107) is fixedly connected to the bearing plate (101).

4. A brominated epoxy resin condensation recovery apparatus as defined in claim 2 wherein: the support structure (2) comprises: bottom plate (201), support column (202), reservation groove B (203), the top fixedly connected with support column (202) of bottom plate (201), support column (202) are connected with connecting axle (102) rotation respectively, and the inside of bottom plate (201) is equipped with reservation groove B (203).

5. A brominated epoxy resin condensation recovery apparatus as defined in claim 4 wherein: the support structure (2) further comprises: guide rod (204), elastic component A (205), guide rod (204) pass through reservation groove B (203) fixed connection in bottom plate (201), and swing joint has elastic component A (205) on guide rod (204), and the one end of elastic component A (205) is laminated with bottom plate (201) respectively.

6. A brominated epoxy resin condensation recovery apparatus as defined in claim 4 wherein: the control structure (3) comprises: slider (301), connecting rod (302), dial button (303), preformed hole (304), the inside of slider (301) is equipped with preformed hole (304), slider (301) pass through preformed hole (304) respectively with bottom plate (201), guide bar (204) sliding connection, one side of slider (301) is laminated mutually with elastic component A (205), slider (301) is fixed connection simultaneously on connecting rod (302), connecting rod (302) pass through preformed groove B (203) and bottom plate (201) sliding connection, the both ends of connecting rod (302) are fixedly connected with dial button (303) respectively.

7. A brominated epoxy resin condensation recovery apparatus as defined in claim 6 wherein: the control structure (3) further comprises: the connecting ring A (305), the connecting ring B (306) and the fixing rod B (307), wherein the connecting ring A (305) is rotationally connected with the sliding block (301), the connecting ring B (306) is simultaneously rotationally connected with the connecting shaft (102), and two ends of the fixing rod B (307) are respectively fixedly connected with the connecting ring A (305) and the connecting ring B (306).

8. A brominated epoxy resin condensation recovery apparatus as defined in claim 2 wherein: the reciprocation mechanism (4) includes: the device comprises a driving shaft (401), a bevel gear A (402), a bevel gear B (403) and a motor A (404), wherein the motor A (404) is fixedly connected in a bearing plate (101) through a containing groove (103), the bevel gear A (402) is fixedly connected to the top of the motor A (404), the bevel gear A (402) is meshed with the bevel gear B (403) at the same time, the bevel gear B (403) is fixedly connected to one end of the driving shaft (401), and the driving shaft (401) is rotationally connected in the bearing plate (101).

9. A brominated epoxy resin condensation recovery apparatus as defined in claim 8 wherein: the reciprocating mechanism (4) further comprises: connecting plate (405), connecting block (406) are fixedly connected with respectively at the both ends of connecting plate (405), connecting block (406) respectively with drive shaft (401), dead lever A (107) swing joint.

10. A brominated epoxy resin condensation recovery apparatus as defined in claim 2 wherein: the ventilation mechanism (5) further comprises: sliding tray B (506), leading truck (507), slide bar (508), elastic component B (509), be equipped with sliding tray B (506) in rack (505), leading truck (507) fixed connection is in loading board (101), leading truck (507) pass through sliding tray B (506) and rack (505) sliding connection, rack (505) fixed connection is in the one end of slide bar (508), elastic component B (509) pass through sliding tray A (104) swing joint respectively in loading board (101), the both ends of elastic component B (509) laminate with loading board (101), slide bar (508) respectively.