CN220524489U - Modularized ion exchange equipment - Google Patents

Abstract

The utility model discloses modularized ion exchange equipment, which relates to the technical field of ion exchange resins and comprises an outer cylinder, wherein a rod body part of a rotating shaft positioned in the cylinder is fixedly connected with a group of first bevel gears, one end of a first rotating rod positioned in the cylinder is fixedly connected with second bevel gears, and the top and the bottom of the first rotating rod positioned at the outer end of the cylinder are fixedly connected with turnover plates.

Description

Modularized ion exchange equipment

Technical Field

The utility model relates to the technical field of ion exchange resins, in particular to modularized ion exchange equipment.

Background

The ion exchange resin is a high molecular compound, has different physical properties according to different structures, can be used in various fields such as water treatment, food industry, pharmaceutical industry and the like, and is mainly granular in raw materials, and the raw materials of the ion exchange resin particles need to be purified and dehydrated before being used.

Through patent retrieval discovery, an ion exchange resin dewatering equipment of publication number CN214009727U, including box, tight locking device, dewatering device, one-level filter equipment, secondary filter equipment and sewage treatment plant, dewatering device locates inside the box, and the box is one end open-ended cavity setting, tight locking device locates dewatering device upper end, the dewatering device below is located to the primary filter equipment, the device outside is located to the secondary filter equipment, sewage treatment plant locates secondary filter equipment one side. The utility model is time-saving, high-efficiency, firm and durable, improves the dehydration efficiency and saves the manpower.

The above patent can achieve dehydration of ion exchange resins, but a large amount of ion exchange resins are stuck to the inner side of the drainage cylinder under the action of centrifugal force, so that the ion exchange resins are piled up, the water in the piled ion exchange resins is difficult to sufficiently dehydrate, the piled ion exchange resins are difficult to purify, the treatment purification efficiency of the ion exchange resins is low, and the purification effect of the ion exchange resin particle raw materials is affected. For this reason, a modular ion exchange apparatus is needed to solve the above technical problems.

Disclosure of Invention

The utility model aims to make up the defects of the prior art and provides modularized ion exchange equipment.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the modularized ion exchange equipment comprises an outer barrel, wherein a netlike inner barrel is arranged in the outer barrel, a first threaded feed inlet is formed in the top end of the outer barrel, a second threaded feed inlet is formed in the top end of the inner barrel, and a dehydration and purification mechanism is arranged in the inner barrel;

the dehydration purification mechanism comprises a motor arranged at the top of an outer cylinder, a speed reducer is fixedly connected to the output end of the motor, a rotating shaft is fixedly connected to the output end of the speed reducer, the bottom end of the rotating shaft extends into an inner cylinder (2), the rotating shaft is fixedly connected with the inner cylinder, a cylinder is rotationally connected to the outer side of the rotating shaft, a group of first bevel gears are fixedly connected to the rod body part of the rotating shaft, a first rotating rod is rotationally connected to the two sides of the cylinder, a second bevel gear is fixedly connected to one end of the first rotating rod, the second bevel gear is meshed with the first bevel gear, a turnover plate is fixedly connected to the top and the bottom of the first rotating rod, the bottom end of the first rotating rod is fixedly connected with a fixing rod, and the fixing rod extends into the inner cylinder and is fixedly connected with the bottom end of the cylinder.

Preferably, the top of inner tube is equipped with sealing mechanism, sealing mechanism includes threaded connection at the inside screw cap of screw feed inlet No. two, screw feed inlet internal thread connection has No. two screw caps, the inside sliding connection of No. two screw caps has T shape slide bar, the common rigid coupling has a set of spring between the top of No. two screw caps and the top of T shape slide bar, the inside rotation of T shape slide bar is connected with No. two bull sticks, and the top and the bottom of No. two bull sticks extend to the top and the bottom of No. two screw caps respectively, the fixture block has all been fixedly connected with in the bottom of No. two bull sticks both sides, the round hole has been seted up on the top of No. one screw cap, the adaptation hole has all been seted up to the both sides of round hole, the recess has been seted up to the bottom of round hole.

Preferably, the front side and the rear side of the top end of the groove are provided with clamping grooves, and the sizes of the clamping grooves and the clamping blocks are the same.

Preferably, the bottom of the groove is fixedly connected with a second spring, and the top of the second spring is fixedly connected with a pressure plate.

Preferably, the bottom inside the urceolus has offered the support annular, the bottom rigid coupling of inner tube has the support ring board, and the bottom of support ring board is located the support annular.

Preferably, the surface of the turnover plate is provided with a plurality of flow holes.

Preferably, the bottom end of the outer cylinder is fixedly connected with a drain pipe, and the end part of the drain pipe is fixedly connected with a valve.

The beneficial effects are that:

compared with the prior art, the modularized ion exchange equipment has the following beneficial effects:

1. according to the utility model, the motor drives the rotating shaft to rotate, the rotating shaft drives the first bevel gear to rotate, the first bevel gear drives the second bevel gear to rotate, the second bevel gear drives the first rotary rod to rotate, the first rotary rod drives the turnover plate to rotate, the ion exchange resin is dehydrated under the action of centrifugal force while the inner cylinder rotates, the ion exchange resin is continuously turned through the turnover plate, the ion exchange resin in the stacked ion exchange resins is turned out, the ion exchange resins are prevented from being stacked together, so that the ion exchange resin in the ion exchange resins can be dehydrated well, the full purification of ion exchange resin particle raw materials is facilitated, and the purification efficiency is improved.

2. According to the utility model, the T-shaped sliding rod is driven to move downwards by the second rotating rod, the second rotating rod passes through the round hole and enters the groove, the second rotating rod rotates to drive the clamping block to rotate, the clamping block is far away from the adapting hole, then the second rotating rod is lifted, the first threaded cover and the second threaded cover are lifted, the first threaded cover passes through the first threaded charging hole and enters the second threaded charging hole, then the second rotating rod is reversely rotated, the second rotating rod drives the clamping block to enter the adapting hole, and the second rotating rod rotates to drive the first threaded cover to be in threaded connection with the second threaded charging hole through the adapting hole, at the moment, the sealing of the inner cylinder is realized, the second rotating rod is loosened, the second rotating rod moves upwards under the action of the first spring to drive the clamping block to be separated from the adapting hole, and then the second threaded cover is rotated to be connected with the first threaded charging hole, so that the outer cylinder is sealed, and liquid and ion exchange resin are prevented from splashing out of the first threaded charging hole and the second threaded charging hole during working.

Drawings

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

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

FIG. 3 is a schematic diagram of a dehydration purification mechanism according to the present utility model;

fig. 4 is a schematic structural view of the sealing mechanism in the present utility model.

In the figure: 1. the outer cylinder, the inner cylinder, the 3, the first screw feed inlet, the 4, the second screw feed inlet, the 5, the dehydration purifying mechanism, the 50, the motor, the 51, the speed reducer, the 52, the rotating shaft, the 53, the cylinder, the 54, the first bevel gear, the 55, the first rotating rod, the 56, the second bevel gear, the 57, the turnover plate, the 58, the fixed rod, the 6, the sealing mechanism, the 60 and the first screw cap, 61, a second screw cap, 62, a T-shaped slide bar, 63, a first spring, 64, a second rotating rod, 65, a clamping block, 66, a round hole, 67, an adapting hole, 68, a groove, 7, a clamping groove, 8, a second spring, 9, a pressure plate, 10, a supporting ring groove, 11, a supporting ring plate, 12, a circulation hole, 13, a drain pipe, 14 and a valve.

Detailed Description

The principles and features of the present utility model are described below with reference to the drawings, the examples are illustrated for the purpose of illustrating the utility model and are not to be construed as limiting the scope of the utility model.

As shown in fig. 1 to 4, a modular ion exchange apparatus includes an outer tub 1, and a mesh inner tub 2 is provided inside the outer tub 1. The supporting ring groove 10 is formed in the bottom end of the inner cylinder 1, the supporting ring plate 11 is fixedly connected to the bottom end of the inner cylinder 2, the bottom end of the supporting ring plate 11 is located in the supporting ring groove 10, and the supporting ring groove 10 and the supporting ring plate 11 are designed to play a supporting role on the inner cylinder 2. A first threaded feed inlet 3 is formed in the top end of the outer barrel 1, and a second threaded feed inlet 4 is formed in the top end of the inner barrel 2. The bottom end of the outer cylinder 1 is fixedly connected with a drain pipe 13, and the end part of the drain pipe 13 is fixedly connected with a valve 14, so that liquid can be discharged. The inner cylinder 2 is internally provided with a dehydration and purification mechanism 5.

The dehydration purification mechanism 5 comprises a motor 50 arranged at the top of the outer cylinder 1, a speed reducer 51 is fixedly connected to the output end of the motor 50, a rotating shaft 52 is fixedly connected to the output end of the speed reducer 51, the bottom end of the rotating shaft 52 extends into the inner cylinder 2, the rotating shaft 52 is fixedly connected with the inner cylinder 2, a cylinder 53 is rotationally connected to the outer side of the rotating shaft 52, a group of first bevel gears 54 are fixedly connected to the rod body part of the rotating shaft 52 positioned in the cylinder 53, a first rotating rod 55 is rotationally connected to the two sides of the cylinder 53, a second bevel gear 56 is fixedly connected to one end of the first rotating rod 55 positioned in the cylinder 53, the second bevel gears 56 are meshed with the first bevel gears 54, and a turnover plate 57 is fixedly connected to the top and the bottom of one end of the first rotating rod 55 positioned outside the cylinder 53. The surface of the turnover plate 57 is provided with a plurality of flow holes 12, and the flow holes 12 can increase the flow of the ion exchange resin when the ion exchange resin is turned over, and each group is at least three, so that the flow of the ion exchange resin is further increased, and the efficiency of dehydration and purification is improved. The bottom end of the inner part of the outer cylinder 1 is fixedly connected with a fixing rod 58, and the fixing rod 58 extends into the inner cylinder 2 and is fixedly connected with the bottom end of the cylinder 53.

During operation, ion exchange resin is added into the inner cylinder 2 through the first threaded feed port 3 and the second threaded feed port 4, the motor 50 drives the rotating shaft 52 to rotate through the speed reducer 51, the rotating shaft 52 drives the first bevel gear 54 to rotate, the first bevel gear 54 drives the second bevel gear 56 to rotate, the cylinder 53 is in rotary connection with the rotating shaft 52, and the fixed rod 58 is in a fixed state, so that the cylinder 53 is in a fixed state, the second bevel gear 56 drives the first rotary rod 55 to rotate, the first rotary rod 55 drives the turnover plate 57 to rotate, the inner cylinder 2 rotates and simultaneously, the ion exchange resin can dehydrate the ion exchange resin under the action of centrifugal force, and continuously turnover the ion exchange resin through the turnover plate 57, so that the ion exchange resin in the stacked ion exchange resin can be turned over, the ion exchange resin is prevented from being stacked together, the ion exchange resin in the inner part can be dehydrated well, the ion exchange resin particle raw materials can be purified sufficiently, and the purification efficiency is improved.

The top of inner tube 2 is equipped with sealing mechanism 6, sealing mechanism 6 includes threaded connection at the inside screw cap 60 of screw feed inlet No. 4, the internal thread connection of screw feed inlet No. 3 has screw cap No. 61, the inside sliding connection of screw cap No. 61 has T shape slide bar 62, the common rigid coupling has a set of spring 63 between the top of screw cap No. 61 and the top of T shape slide bar 62, the inside rotation of T shape slide bar 62 is connected with No. two bull sticks 64, and top and the bottom of No. two bull sticks 64 extend to the top and the bottom of screw cap No. 61 respectively, fixture block 65 has all been fixedly connected to the bottom of No. two bull sticks 64 both sides, round hole 66 has been seted up on the top of No. 60, adapting hole 67 has all been seted up to the both sides of round hole 66, recess 68 has been seted up to the bottom of round hole 66. The clamping grooves 7 are formed in the front side and the rear side of the top end of the groove 68, the sizes of the clamping grooves 7 and the clamping blocks 65 are the same, the clamping blocks 65 are clamped into the clamping grooves 7, and screwing of the second threaded cover 61 is facilitated. The bottom rigid coupling of recess 68 has No. two spring 8, no. two spring 8's top rigid coupling has pressure plate 9, when opening screw cap 60, push down No. two bull stick 64 with effort, no. two bull stick 64 extrudees pressure plate 9, make pressure plate 9 move down, and ninety degrees rotation No. two bull sticks 64 afterwards, no. two bull stick 64 drive fixture block 65 and rotate ninety degrees, loosen No. two bull sticks 64, under No. two spring 8's effect, pressure plate 9 moves up, can block fixture block 65 into draw-in groove 7, rotate No. two bull stick 64 this moment, no. two bull sticks 64 drive screw cap 60 through fixture block 65 and rotate, and after not having become flexible screw cap 60, directly upwards lift up screw cap 60, can realize the separation, this kind of structure makes when installing screw cap 60, it is more convenient and simple.

During operation, the second rotating rod 64 is pressed downwards, the second rotating rod 64 drives the T-shaped sliding rod 62 to move downwards, the second rotating rod 64 passes through the round hole 66, and the clamping block 65 passes through the adapting hole 67 and enters the groove 68 together, the second rotating rod 64 is rotated, the second rotating rod 64 drives the clamping block 65 to rotate, the clamping block 65 is far away from the adapting hole 67, the second rotating rod 64 is lifted, the second rotating rod 64 lifts the first threaded cover 60 and the second threaded cover 61, the first threaded cover 60 passes through the first threaded charging hole 3 and enters the second threaded charging hole 4, the second rotating rod 64 is reversely rotated, the second rotating rod 64 is enabled to correspond to the adapting hole 67, the second rotating rod 64 is lifted upwards, the second rotating rod 64 drives the clamping block 65 to enter the adapting hole 67, the second rotating rod 64 is rotated, the second rotating rod 64 drives the first threaded cover 60 to be in threaded connection with the second threaded charging hole 4 through the adapting hole 67, at the moment, the second threaded cover 2 is loosened, the second rotating rod 64 is lifted, the second threaded cover 64 moves upwards under the action of the first spring 63, the second threaded cover is separated from the second threaded cover 3 and the second threaded charging hole 4 is further prevented from being in threaded connection with the second threaded charging hole 3.

Working principle: the ion exchange resin is added into the inner cylinder 2 through the first threaded feed port 3 and the second threaded feed port 4, the motor 50 drives the rotating shaft 52 to rotate through the speed reducer 51, the rotating shaft 52 drives the first bevel gear 54 to rotate, the first bevel gear 54 drives the second bevel gear 56 to rotate, the cylinder 53 is rotationally connected with the rotating shaft 52, and the fixed rod 58 is in a fixed state, so that the cylinder 53 is in a fixed state, the second bevel gear 56 drives the first rotating rod 55 to rotate, the first rotating rod 55 drives the turnover plate 57 to rotate, the ion exchange resin can dehydrate under the action of centrifugal force while the inner cylinder 2 rotates, the turnover plate 57 continuously turns over the ion exchange resin, the ion exchange resin inside the stacked ion exchange resin is turned over, the ion exchange resin is prevented from being stacked together, the ion exchange resin inside can be dehydrated well, the ion exchange resin particle raw materials are purified sufficiently, and the purification efficiency is improved.

Pressing down No. two bull sticks 64, no. two bull sticks 64 drive T shape slide bar 62 and move down, pass No. two bull sticks 64 and round hole 66, and make fixture block 65 pass adapter hole 67, together get into recess 68, rotate No. two bull sticks 64, no. two bull sticks 64 drive fixture block 65 rotation, make fixture block 65 keep away from adapter hole 67, then pick up No. two bull sticks 64, no. two bull sticks 64 lift screw cap 60 and No. two screw cap 61, pass No. one screw cap 60 and get into No. two screw feed inlets 4 with No. one screw feed inlet 3, then reverse rotation No. two bull sticks 64, make No. two bull sticks 64 correspond with adapter hole 67, then upwards lift No. two bull sticks 64, make No. two bull sticks 64 drive fixture block 65 and get into adapter hole 67, rotate No. two bull sticks 64, no. two bull sticks 64 drive No. one screw cap 60 and No. two screw feed inlets 4 threaded connection through adapter hole 67, at this moment, realize the seal to inner tube 2, then loosen No. two bull sticks 64, under the effect of No. one spring 63, move up No. two screw cap 65, drive fixture block 65 and move up and separate with No. two screw cap 67, no. 3 and No. 3 are screwed into the feed inlet 4 when the water inlet is sealed with No. 3, thereby, and No. 3 is screwed into the water inlet is sealed.

The foregoing description of the preferred embodiments of the utility model is not intended to limit the utility model to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the utility model are intended to be included within the scope of the utility model.

Claims (8)

1. A modular ion exchange device comprising an outer cartridge (1), characterized in that: the novel dewatering and purifying device is characterized in that a netlike inner cylinder (2) is arranged in the outer cylinder (1), a first threaded feed inlet (3) is formed in the top end of the outer cylinder (1), a second threaded feed inlet (4) is formed in the top end of the inner cylinder (2), and a dewatering and purifying mechanism (5) is arranged in the inner cylinder (2);

the dehydration purification mechanism (5) comprises a motor (50) arranged at the top of the outer cylinder (1), a speed reducer (51) is fixedly connected to the output end of the motor (50), a rotating shaft (52) is fixedly connected to the output end of the speed reducer (51), the bottom end of the rotating shaft (52) extends into the inner cylinder (2), the rotating shaft (52) is fixedly connected with the inner cylinder (2), a cylinder (53) is rotationally connected to the outer side of the rotating shaft (52), a group of first bevel gears (54) are fixedly connected to the rod body portion of the rotating shaft (52) located in the cylinder (53), a first rotary rod (55) is rotationally connected to the two sides of the cylinder (53), a second bevel gear (56) is fixedly connected to one end of the first rotary rod (55) located in the cylinder (53), the second bevel gear (56) is meshed with the first bevel gear (54), a turnover plate (57) is fixedly connected to one end of the first rotary rod (55) located outside the cylinder (53), a fixed rod (58) is fixedly connected to the inner cylinder (58), and the bottom end of the first rotary rod (53) extends into the cylinder (2).

2. A modular ion exchange unit according to claim 1, wherein: the top of inner tube (2) is equipped with sealing mechanism (6), sealing mechanism (6) are including threaded connection screw cap (60) No. one in No. two screw feed inlet (4) inside, no. one screw feed inlet (3) internal thread connection has No. two screw cap (61), the inside sliding connection of No. two screw cap (61) has T shape slide bar (62), the common rigid coupling has a set of spring (63) between the top of No. two screw cap (61) and the top of T shape slide bar (62).

3. A modular ion exchange unit according to claim 2, wherein: the inside rotation of T shape slide bar (62) is connected with No. two bull sticks (64), and the top and the bottom of No. two bull sticks (64) extend to the top and the bottom of No. two screw cap (61) respectively, the bottom of No. two bull sticks (64) both sides all fixedly connected with fixture block (65), round hole (66) have been seted up on the top of No. one screw cap (60), adaptation hole (67) have all been seted up to the both sides of round hole (66), recess (68) have been seted up to the bottom of round hole (66).

4. A modular ion exchange unit according to claim 3, wherein: clamping grooves (7) are formed in the front side and the rear side of the top end of the groove (68), and the clamping grooves (7) and the clamping blocks (65) are identical in size.

5. A modular ion exchange unit according to claim 3, wherein: the bottom of recess (68) rigid coupling has No. two spring (8), the top rigid coupling of No. two spring (8) has pressure plate (9).

6. A modular ion exchange unit according to claim 1, wherein: the bottom of the inner cylinder (2) is fixedly connected with a supporting ring plate (11), and the bottom of the supporting ring plate (11) is positioned in the supporting ring groove (10).

7. A modular ion exchange unit according to claim 1, wherein: the surface of the turnover plate (57) is provided with a plurality of flow holes (12).

8. A modular ion exchange unit according to claim 1, wherein: the bottom end of the outer barrel (1) is fixedly connected with a drain pipe (13), and the end part of the drain pipe (13) is fixedly connected with a valve (14).