CN214666089U - Activating furnace discharging cooling device for production of voc adsorbent - Google Patents

Abstract

The utility model discloses an activation furnace ejection of compact cooling device is used in voc adsorbent production, including feed inlet, casing and mount pad, the vertical casing of installing in top of mount pad, and the inside bottom intermediate position department of casing installs the row's of running through the mount pad ash mouth, the mounting groove is installed to the lower extreme of the inside one side of casing, and inside one side sliding connection of mounting groove has the sieve that extends to the casing outside, the bin outlet has been seted up to the lower extreme of casing opposite side, the baffle is installed to the inside both sides of casing equidistant, and the casing internally mounted of baffle top has the orifice plate, the feed inlet is installed to one side on casing top, the vertical dwang that extends to the inside lower extreme of casing of installing of driving motor output, and the rotor plate is installed to the surface equidistant of dwang. The utility model discloses a set up rotor plate and stock guide for the adsorbent can be faster, continuity expansion heat dissipation, avoids traditional cooling method's limitation, improves off-the-shelf work efficiency.

Description

Activating furnace discharging cooling device for production of voc adsorbent

Technical Field

The utility model relates to a voc adsorbent production facility technical field specifically is an activation furnace ejection of compact cooling device is used in voc adsorbent production.

Background

The main component of the voc adsorbent is zeolite powder, and the voc adsorbent has good performance in treatment and adsorption of wastewater, waste gas and the like due to excellent adsorption, so the market demand is increasing, and in the production process, an activation furnace is used, and cooling operation is usually required after discharging the zeolite powder to improve the production efficiency, but the conventional activation furnace discharging cooling device for producing the voc adsorbent has many problems or defects:

first, the traditional activating furnace discharge cooling device for voc adsorbent production does not have a continuous structure when in use, generally needs to be spread for air cooling and heat dissipation, and has no continuity and low efficiency.

Secondly, traditional voc adsorbent production is with activation furnace ejection of compact cooling device, does not have the screening structure during the use, has a small amount of tiny particle or dust in the adsorbent, can influence finished product quality.

Thirdly, the traditional activating furnace discharging cooling device for producing the voc absorbent has no collecting structure during use, and discharged gas contains more dust and heat and is directly discharged to cause environmental pollution.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an activation furnace ejection of compact cooling device is used in voc adsorbent production to solve the inconvenient continuous, inconvenient screening and the inconvenient problem of collecting that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: an activating furnace discharge cooling device for producing voc adsorbent comprises a feed inlet, a shell and a mounting seat, and further comprises a screening structure for improving the quality of finished products, a collecting mechanism for preventing dust from flying and a connecting structure for improving the efficiency of the finished products;

a shell is vertically installed at the top end of the installation seat, an ash discharge port penetrating through the installation seat is installed in the middle position of the bottom end in the shell, an installation groove is installed at the lower end of one side in the shell, a sieve plate extending to the outside of the shell is connected to one side in the installation groove in a sliding mode, a discharge port is formed in the lower end of the other side of the shell, and a screening structure is arranged at the bottom end, close to the discharge port, of the inner portion of the shell below the sieve plate;

the two sides in the shell are provided with guide plates at equal intervals, the shell above the guide plates is internally provided with a pore plate, the upper end of the other side of the shell and the lower end of one side of the shell are respectively provided with a blower, the middle position of the other side of the shell is provided with a PLC (programmable logic controller), and the collecting mechanism is arranged at the top end of one side of the shell close to the mounting groove;

the feed inlet is installed to one side on casing top, and the casing top intermediate position department of feed inlet one side installs driving motor, the vertical dwang that extends to the inside lower extreme of casing of installing of driving motor output, and the equidistant rotor plate of installing in surface of dwang, connection structure sets up the inside at the rotor plate.

Preferably, connection structure includes the fixed slot, the lower extreme at the rotor plate inside is seted up to the fixed slot equidistant, and the inside top of fixed slot installs fixed spring, fixed spring bottom sliding connection has the connecting block that extends to the rotor plate outside, and the bottom transverse mounting of connecting block has the brush.

Preferably, U type cooling tube has been laid to the inside bottom of stock guide, U type cooling tube one end has the water inlet that extends to the casing outside through the pipe mounting, and the U type cooling tube other end has the outlet that extends to the casing outside through the pipe mounting.

Preferably, the inclination angle of the top end of the material guide plate and the horizontal direction is 20 degrees, and the material guide plate is symmetrically distributed about the vertical central axis of the shell.

Preferably, the screening structure includes reset spring, case that resets, resets board, driving lever and fixed block, the case that resets is installed in the inside bottom that is close to bin outlet one side of casing, and the equidistant reset spring of installing in one side of the incasement portion that resets, reset spring one side sliding connection has the board that resets that extends to the case outside that resets, and the top and sieve bottom one side fixed connection of the board one side that resets, the fixed block is installed to the intermediate position department of sieve top one side, and installs the driving lever with fixed block matched with in the dwang bottom.

Preferably, the collecting mechanism comprises a negative pressure fan, a filter screen, a sliding block, a sliding groove and a collecting box, the collecting box is installed on the top end, close to one side of the mounting groove, of the shell, one side of the top end of the collecting box is communicated with one side of the top end of the shell through a guide pipe, the sliding groove is formed in the lower ends of the two sides of the inside of the collecting box, the sliding block is connected to the inside of the sliding groove, the filter screen is installed inside the collecting box on one side of the sliding block, and the negative pressure fan is installed at the bottom end of the inside of the collecting box.

Preferably, the shape of filter screen is the V type, and is the welding integrated structure between filter screen both sides and one side of slider.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) by arranging the rotating plate, the pore plate, the rotating rod and the brush, the rotating rod is driven to rotate by starting the driving motor, meanwhile, the elasticity of the fixed spring is utilized, the connecting block is moved to drive the brush to be tightly attached to the top end of the pore plate, so that the adsorbent is spread, the contact area of the adsorbent and cold air is increased, the heat dissipation is facilitated, then, cooling water is injected into the U-shaped cooling pipe through the water inlet, the contact area of the U-shaped cooling pipe of the U-shaped pipe and the adsorbent at the top end of the guide plate is increased, the heat exchange efficiency of the adsorbent and the guide plate is increased, the heat loss of the adsorbent is quicker, meanwhile, multiple heat dissipation is carried out on the adsorbent through the guide plates and the pore plates of multiple groups, continuous operation can be carried out, the complexity that the traditional method can only carry out intermittent heat dissipation is avoided, and the working efficiency of adsorbent cooling is improved;

(2) through the arrangement of the sieve plate and the screening structure, the rotating rod rotates to drive the shifting rod to rotate, so that the fixed block is periodically impacted, the sieve plate drives the reset plate to slide and stretch the reset spring, then under the elastic action of the reset spring, the reset plate moves to drive the sieve plate to recover the original position, so that the sieve plate vibrates left and right, powder and fine particles in the adsorbent fall down and are discharged and collected through the ash discharge port, and the proper adsorbent is discharged and collected through the discharge port, so that the mixing of the powder and the fine particles is avoided, the quality of a finished product is reduced, and the qualified rate of the finished product is ensured;

(3) through being provided with the collection mechanism, the inside air of casing can be taken the powder and the heat up removal of adsorbent to the air-blower work drum, start negative-pressure air fan simultaneously, make the air pass through the inside of pipe suction collecting box, the filter screen that utilizes the V type simultaneously filters the powder, and hot-air accessible pipe is carried to the place of other needs, avoid thermal waste, realize the recovery of heat energy, the accessible slider is convenient for take out the filter screen in the inside slip of spout simultaneously, and then unified recovery powder, when avoiding the direct emission of powder to cause environmental pollution, also cause the waste of adsorbent powder, increase manufacturing cost.

Drawings

Fig. 1 is a schematic front view of a cross-sectional structure of the present invention;

fig. 2 is a schematic side view of the cross-sectional structure of the present invention;

fig. 3 is a schematic view of a top-view cross-sectional structure of a material guide plate according to the present invention;

fig. 4 is an enlarged schematic view of a portion a of fig. 1 according to the present invention.

In the figure: 1. a drive motor; 2. a feed inlet; 3. a housing; 4. a rotating plate; 5. a material guide plate; 6. a blower; 7. a PLC controller; 8. a water inlet; 9. a discharge outlet; 10. a sieve plate; 11. screening the structure; 1101. a return spring; 1102. a reset box; 1103. a reset plate; 1104. a deflector rod; 1105. a fixed block; 12. a mounting seat; 13. an ash discharge port; 14. mounting grooves; 15. an orifice plate; 16. a U-shaped cooling tube; 17. a collection mechanism; 1701. a negative pressure fan; 1702. filtering with a screen; 1703. a slider; 1704. a chute; 1705. a collection box; 18. rotating the rod; 19. a water outlet; 20. a brush; 21. connecting blocks; 22. fixing the spring; 23. and fixing the grooves.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example 1: referring to fig. 1-4, an activating furnace discharge cooling device for voc adsorbent production includes a feed inlet 2, a shell 3 and a mounting seat 12, and further includes a screening structure 11 for improving the quality of finished products, a collecting mechanism 17 for preventing dust from flying up, and a connecting structure for improving the efficiency of finished products;

the top end of the mounting seat 12 is vertically provided with the shell 3, the middle position of the bottom end in the shell 3 is provided with an ash discharge port 13 penetrating through the mounting seat 12, the lower end of one side in the shell 3 is provided with a mounting groove 14, one side in the mounting groove 14 is slidably connected with a sieve plate 10 extending to the outside of the shell 3, the lower end of the other side of the shell 3 is provided with a discharge port 9, and the sieving structure 11 is arranged at the bottom end of one side, close to the discharge port 9, in the shell 3 below the sieve plate 10;

the material guide plates 5 are arranged on two sides in the shell 3 at equal intervals, the pore plates 15 are arranged in the shell 3 above the material guide plates 5, the air blowers 6 are respectively arranged at the upper end of the other side and the lower end of one side of the shell 3, the type of the air blower 6 can be HSTF001, the PLC controller 7 is arranged in the middle position of the other side of the shell 3, the type of the PLC controller 7 can be FX3SA-10MT-CM, and the collecting mechanism 17 is arranged at the top end of one side, close to the mounting groove 14, of the shell 3;

a feed port 2 is arranged on one side of the top end of the shell 3, a driving motor 1 is arranged in the middle of the top end of the shell 3 on one side of the feed port 2, the type of the driving motor 1 can be YE2-132M1, a rotating rod 18 extending to the lower end of the inside of the shell 3 is vertically arranged at the output end of the driving motor 1, rotating plates 4 are arranged on the surfaces of the rotating rods 18 at equal intervals, and a connecting structure is arranged inside the rotating plates 4;

referring to fig. 1-4, the activating furnace discharge cooling device for producing voc adsorbent further comprises a connecting structure, the connecting structure comprises fixing grooves 23, the fixing grooves 23 are equidistantly arranged at the lower end inside the rotating plate 4, a fixing spring 22 is mounted at the top end inside the fixing grooves 23, the bottom end of the fixing spring 22 is slidably connected with a connecting block 21 extending to the outside of the rotating plate 4, and a brush 20 is transversely mounted at the bottom end of the connecting block 21;

a U-shaped cooling pipe 16 is laid at the bottom end inside the material guide plate 5, one end of the U-shaped cooling pipe 16 is provided with a water inlet 8 extending to the outside of the shell 3 through a guide pipe, and the other end of the U-shaped cooling pipe 16 is provided with a water outlet 19 extending to the outside of the shell 3 through a guide pipe;

the inclination angle of the top end of the material guide plate 5 and the horizontal direction is 20 degrees, and the material guide plate 5 is symmetrically distributed about the vertical central axis of the shell 3;

specifically, as shown in fig. 1, fig. 2, fig. 3 and fig. 4, the driving motor 1 is started to drive the rotating rod 18 to rotate, and meanwhile, the elastic force of the fixing spring 22 is utilized, so that the connecting block 21 moves to drive the brush 20 to cling to the top end of the pore plate 15, and further, the adsorbent is spread and expanded, the contact area between the adsorbent and cold air is increased, then cooling water is injected into the U-shaped cooling pipe 16 through the water inlet 8, the U-shaped cooling pipe 16 of the U-shaped pipe is reused to increase the contact area between the adsorbent and the adsorbent on the top end of the material guide plate 5, the heat exchange efficiency is increased, meanwhile, multiple heat dissipation is performed on the adsorbent through the material guide plates 5 and the pore plate 15, continuous operation can be performed, the work efficiency of adsorbent cooling is improved, and the inclined material guide plates 5 are utilized, and the adsorbent on the surface of the adsorbent is convenient to fall down more quickly.

Example 2: the screening structure 11 comprises a reset spring 1101, a reset box 1102, a reset plate 1103, a shifting rod 1104 and a fixed block 1105, wherein the reset box 1102 is installed at the bottom end of one side, close to the discharge port 9, of the shell 3, the reset spring 1101 is installed at one side of the interior of the reset box 1102 at equal intervals, the reset plate 1103 extending to the exterior of the reset box 1102 is connected to one side of the reset spring 1101 in a sliding mode, the top end of one side of the reset plate 1103 is fixedly connected with one side of the bottom end of the screening plate 10, the fixed block 1105 is installed in the middle position of one side of the top end of the screening plate 10, and the shifting rod 1104 matched with the fixed block 1105 is installed at the bottom end of the rotating rod 18;

specifically, as shown in fig. 1, the dwang 18 rotates and can drive the driving lever 1104 to rotate, and then periodic striking fixed block 1105, and then drive the reset plate 1103 through the sieve plate 10 and slide and stretch the reset spring 1101, later under the spring action of reset spring 1101, make the reset plate 1103 remove and drive the sieve plate 10 and resume the normal position, and then make vibrations about the sieve plate 10, make powder and tiny particle in the adsorbent down drop, the collection of rethread ash discharge port 13 discharge, and suitable adsorbent passes through bin outlet 9 discharge and collects, avoid the mixture of powder and tiny particle, and then reduce off-the-shelf quality.

Example 3: the collecting mechanism 17 comprises a negative pressure fan 1701, a filter screen 1702, a slider 1703, a chute 1704 and a collecting box 1705, the collecting box 1705 is installed at the top end of one side, close to the installation groove 14, of the shell 3, one side of the top end of the collecting box 1705 is communicated with one side of the top end in the shell 3 through a guide pipe, the chutes 1704 are formed in the lower ends of two sides in the collecting box 1705, the slider 1703 is connected in the chute 1704 in a sliding mode, the filter screen 1702 is installed in the collecting box 1705 on one side of the slider 1703, the negative pressure fan 1701 is installed at the bottom end in the collecting box 1705, and the model of the negative pressure fan 1701 can be FDR-02;

the shape of the filter screen 1702 is V-shaped, and the two sides of the filter screen 1702 and one side of the slider 1703 form a welded integrated structure;

specifically, as shown in fig. 1 and 2, the air blown into the inside of the housing 3 by the blower 6 moves upward with the powder and heat of the adsorbent, and the negative pressure fan 1701 is started at the same time, so that the air is sucked into the inside of the collection box 1705 through the duct, and the powder is filtered by the V-shaped filter screen 1702, and the hot air can be conveyed to other places where it is needed through the duct, thereby avoiding waste of heat, and the filter screen 1702 can be conveniently taken out by sliding the slider 1703 inside the chute 1704, so as to uniformly recover the powder, and avoid environmental pollution caused by direct discharge of the powder, and simultaneously, waste of the adsorbent powder is also caused.

The output end of the PLC controller 7 is electrically connected to the input ends of the driving motor 1, the blower 6, and the negative pressure fan 1701 through a wire.

The working principle is as follows: when the device is used, firstly, the voc adsorbent discharged from the activation furnace is added into the shell 3 through the feed inlet 2 and falls on the top end of the pore plate 15, the air blower 6 is started simultaneously, cold air is blown into the shell 3, then the driving motor 1 is started to drive the rotating rod 18 to rotate, meanwhile, the connecting block 21 is moved to drive the brush 20 to be clung to the top end of the pore plate 15 by utilizing the elasticity of the fixed spring 22, so that the adsorbent is spread and falls down on the surface of the guide plate 5 through the through holes on the pore plate 15, meanwhile, cooling water is injected into the U-shaped cooling pipe 16 through the water inlet 8, the contact area between the U-shaped cooling pipe 16 of the U-shaped pipe and the adsorbent on the top end of the guide plate 5 is increased, the heat exchange efficiency of the U-shaped pipe is increased, the heat loss of the adsorbent is quicker, then the adsorbent continues to fall, and multiple heat is dissipated to the adsorbent through the guide plate 5 and the pore plate 15, continuous operation can be carried out, and the working efficiency of cooling the adsorbent is improved;

the cooled adsorbent falls on the top end of the sieve plate 10, the rotating rod 18 rotates to drive the shifting lever 1104 to rotate, and then the fixed block 1105 is impacted periodically, so that the sieve plate 10 slides left and right, the reset plate 1103 is driven to slide in the reset box 1102 to stretch the reset spring 1101, then under the action of the elastic force of the reset spring 1101, the reset plate 1103 moves to drive the sieve plate 10 to restore to the original position, further the sieve plate 10 vibrates left and right, powder and fine particles in the adsorbent fall downwards, the adsorbent is discharged and collected through the ash discharge port 13, and the proper adsorbent is discharged and collected through the discharge port 9;

meanwhile, the air blown into the shell 3 by the blower 6 can bring powder and heat of the adsorbent to move upwards, the negative pressure fan 1701 is started simultaneously, the air is sucked into the collecting box 1705 through the guide pipe, meanwhile, the powder is filtered by the V-shaped filter screen 1702, the hot air can be conveyed to other places needing the powder through the guide pipe, the waste of heat is avoided, meanwhile, the filter screen 1702 can be conveniently taken out by sliding the slider 1703 in the sliding groove 1704, the powder is recycled uniformly, and resources are reduced.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides an activation furnace ejection of compact cooling device is used in voc adsorbent production, includes feed inlet (2), casing (3) and mount pad (12), its characterized in that: the device also comprises a screening structure (11) for improving the quality of finished products, a collecting mechanism (17) for avoiding dust flying and a connecting structure for improving the efficiency of the finished products;

the screening device is characterized in that a shell (3) is vertically installed at the top end of the installation seat (12), an ash discharging opening (13) penetrating through the installation seat (12) is installed in the middle position of the bottom end in the shell (3), an installation groove (14) is installed at the lower end of one side in the shell (3), a screen plate (10) extending to the outside of the shell (3) is connected to one side in the installation groove (14) in a sliding mode, a discharging opening (9) is formed in the lower end of the other side of the shell (3), and a screening structure (11) is arranged at the bottom end, close to one side of the discharging opening (9), in the shell (3) below the screen plate (10);

the material guide plates (5) are arranged on two sides inside the shell (3) at equal intervals, the pore plates (15) are arranged inside the shell (3) above the material guide plates (5), the air blowers (6) are respectively arranged at the upper end of the other side and the lower end of one side of the shell (3), the PLC (programmable logic controller) is arranged in the middle of the other side of the shell (3), and the collecting mechanism (17) is arranged at the top end of one side, close to the mounting groove (14), of the shell (3);

feed inlet (2) are installed to one side on casing (3) top, and casing (3) top intermediate position department on feed inlet (2) one side installs driving motor (1), the vertical dwang (18) that extend to the inside lower extreme of casing (3) of installing of driving motor (1) output, and the equidistant rotor plate (4) of installing in surface of dwang (18), connection structure sets up the inside at rotor plate (4).

2. The activating furnace discharge cooling device for the production of voc absorbent according to claim 1, wherein: connection structure includes fixed slot (23), the lower extreme at rotor plate (4) inside is seted up to fixed slot (23) equidistant, and fixed spring (22) are installed on the inside top of fixed slot (23), fixed spring (22) bottom sliding connection has connecting block (21) that extend to rotor plate (4) outside, and the bottom transverse mounting of connecting block (21) has brush (20).

3. The activating furnace discharge cooling device for the production of voc absorbent according to claim 1, wherein: u type cooling tube (16) have been laid to the inside bottom of baffle (5), water inlet (8) that extend to casing (3) outside are installed through the pipe to U type cooling tube (16) one end, and U type cooling tube (16) other end installs outlet (19) that extend to casing (3) outside through the pipe.

4. The activating furnace discharge cooling device for the production of voc absorbent according to claim 1, wherein: the inclination angle of the top end of the material guide plate (5) and the horizontal direction is 20 degrees, and the material guide plate (5) is symmetrically distributed around the vertical central axis of the shell (3).

5. The activating furnace discharge cooling device for the production of voc absorbent according to claim 1, wherein: screening structure (11) are including reset spring (1101), reset box (1102), reset plate (1103), driving lever (1104) and fixed block (1105), the bottom that is close to bin outlet (9) one side inside casing (3) is installed to reset box (1102), and the equidistant reset spring (1101) of installing in one side of reset box (1102) inside, reset spring (1101) one side sliding connection has the board (1103) that resets that extends to reset box (1102) outside, and the top and sieve (10) bottom one side fixed connection of reset plate (1103) one side, fixed block (1105) are installed to the intermediate position department of sieve (10) top one side, and dwang (18) bottom install with fixed block (1105) matched with driving lever (1104).

6. The activating furnace discharge cooling device for the production of voc absorbent according to claim 1, wherein: collect mechanism (17) and include negative-pressure air fan (1701), filter screen (1702), slider (1703), spout (1704) and collecting box (1705), collecting box (1705) are installed and are being close to the top of mounting groove (14) one side in casing (3), and one side on collecting box (1705) top is through pipe and the inside top one side intercommunication of casing (3), spout (1704) have been seted up to the lower extreme of the inside both sides of collecting box (1705), and the inside sliding connection of spout (1704) has slider (1703), collecting box (1705) internally mounted of slider (1703) one side has filter screen (1702), and negative-pressure air fan (1701) are installed to the inside bottom of collecting box (1705).

7. The activating furnace discharge cooling device for the production of voc absorbent of claim 6 wherein: the shape of the filter screen (1702) is V-shaped, and a welding integrated structure is formed between two sides of the filter screen (1702) and one side of the sliding block (1703).

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