Conductivity detection sampling device for pigment production

By designing the stirring and sieving components of the conductivity detection sampling device for pigment production, the problems of uneven pigment samples and the influence of impurities were solved, thus achieving stability of pigment quality and accuracy of measurement results.

CN224500033UActive Publication Date: 2026-07-14ZHEJIANG EUCHEM CHEM

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ZHEJIANG EUCHEM CHEM
Filing Date
2025-07-30
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

Existing pigment samplers cannot stir and mix the sample or filter impurities, resulting in uneven particle distribution inside the sample, affecting the conductivity measurement results, and thus interfering with the stability of pigment quality.

Method used

A conductivity detection and sampling device for pigment production was designed, comprising a stirring component and a sieving component, which can stir and mix pigment particles and filter impurities. The device includes structures such as a push-pull rod, a receiving shell, and a sieving component to achieve uniform mixing of pigment particles and separation of impurities.

Benefits of technology

The design of the stirring and sieving components ensures the uniformity and purity of the pigment samples, improves the accuracy of conductivity measurement, and ensures the stability of pigment quality.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a conductivity detection sampling device for pigment production, including connecting bucket, the connecting bucket one side is equipped with two groups of mounting hole, and one group of mounting hole inserts the connecting pipe in the inside, the connecting pipe inside slide connection has the pull rod, the pull rod one end welds the material receiving shell, the material receiving shell one end welds the baffle, the connecting pipe lower extreme welds the connecting shell, the connecting shell surface is provided with the screening subassembly, is applied to the pigment production technical field, the utility model discloses when using, will stir the component and carry out the stirring mixture to the pigment particle of inside, when stirring mixes, in the front push pull rod, and the pull rod will drive the material receiving shell and remove to the sampling of connecting bucket inside, when sampling is completed and back pull pull rod, when the material receiving shell moves to the position of connecting shell in the connecting pipe inside, rotates the pull rod, will pour the pigment particle inside the material receiving shell into the screening subassembly inside at this moment, finally utilizes the screening subassembly to separate the impurity in the pigment particle inside.
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Description

TECHNICAL FIELD

[0001] The utility model belongs to pigment production technical field, especially relate to conductivity detection sampling device for pigment production. BACKGROUND

[0002] In the production process of pigment, some impurities such as by-products, unreacted raw materials, residues in production equipment are mixed together with the required product, affecting the purity of pigment, which needs to be removed and purified by means of dissolution, washing and the like. Conductivity is an important index, which can reflect the concentration and activity of ions in solution. Through dynamic monitoring of conductivity, the overall situation of ions can be quickly known and the washing end point can be judged, which is crucial to control the quality performance of pigment. However, the existing pigment sampler cannot stir and mix the materials for sampling, resulting in uneven distribution of particle size in the sample, and does not have the function of filtering impurities, which leads to deviation of the measurement result from the actual conductivity, thereby affecting the effective execution of production operation and interfering with the quality stability of intermediates, finished products and the like. SUMMARY

[0003] The utility model discloses a conductivity detection sampling device for pigment production, which has the advantages of stirring and mixing pigment particles and filtering impurities.

[0004] The above technical purpose of the utility model is realized by the following technical scheme: a conductivity detection sampling device for pigment production, comprising a connecting barrel, two groups of mounting holes are formed on one side of the connecting barrel, one group of the mounting holes is inserted with a connecting pipe inside, a push-pull rod is slidably connected inside the connecting pipe, a material receiving shell is welded to one end of the push-pull rod, a baffle is welded to one end of the material receiving shell, a connecting shell is welded to the lower end of the connecting pipe, a screening assembly is arranged on the surface of the connecting shell, and a stirring assembly is arranged at the bottom inside the connecting barrel.

[0005] When in use, the connecting pipe is installed inside the required mounting hole, then the other mounting hole is sealed, pigment particles are poured into the connecting barrel, after the pigment particles inside the connecting barrel are poured to a certain amount, the stirring assembly is unfolded and the pigment particles inside are stirred and mixed, then the push-pull rod is pushed forward, the push-pull rod drives the material receiving shell to move to the inside of the connecting barrel for sampling, after sampling is completed, the push-pull rod is pulled back, when the material receiving shell moves to the position of the connecting shell inside the connecting pipe, the push-pull rod is rotated, then the pigment particles inside the material receiving shell are poured into the screening assembly, finally the screening assembly is used to separate the impurities inside the pigment particles.

[0006] The utility model further sets up: the stirring subassembly includes the support, the support is welded in the connecting bucket inner bottom middle part, the support upper end rotationally connected with first rotating shaft, the first rotating shaft upper end fixedly connected with telescopic pipe, the telescopic pipe upper end is welded with the inner column.

[0007] Adopt above technical scheme, the inner column can utilize telescopic pipe and adjust height.

[0008] The utility model further sets up: the inner column surface upper end fixedly connected with second rotating shaft, the second rotating shaft lower end is welded with the baffle pipe, the baffle pipe rotationally connected in the inner column surface, the baffle pipe with the inner column surface all are set up with two group second screw hole, and the second bolt is screw connected with the corresponding two group screw hole.

[0009] Adopt above technical scheme, the baffle pipe can seal the strip hole of the inner column surface, and the second bolt is used for fixing the baffle pipe.

[0010] The utility model further sets up: the inner column is internally provided with pull column, the pull column with the inner column surface all are welded with the limit board, the inner column with pull column are set up with two group first screw hole in common, and the first bolt is screw connected with the corresponding two group first screw hole.

[0011] Adopt above technical scheme, the first bolt is used for fixing the pull column in the inner column, and the limit board is used for limiting the moving height of the pull column, and when two limit boards are attached, the first bolt can be positioned in the pull column from the first screw hole of the upper end.

[0012] The utility model further sets up: pull column surface four sides all are welded with first installation shell, first rotating lever is welded in the first installation shell, rotating plate is rotationally connected on the surface of first rotating lever, second rotating lever is rotationally connected on the other side in the rotating plate.

[0013] Adopt above technical scheme, the rotating plate can rotate by first rotating lever and second rotating lever.

[0014] The utility model further sets up: second rotating lever surface is welded with second installation shell, stirring rod is welded on one side of second installation shell, third rotating lever is rotationally connected in the stirring rod, and third rotating lever is welded in the inner column.

[0015] Adopt above technical scheme, the stirring rod can rotate by third rotating lever.

[0016] The utility model further sets up: the screening subassembly includes thread ring, the thread ring is screw connected on the surface of link shell, the surface of thread ring is rotationally connected with movable sleeve, second mounting plate is welded on one side of movable sleeve, three groups of mounting column are welded on the lower end of second mounting plate, and first mounting plate is commonly welded on the lower end of three groups of mounting column.

[0017] By adopting the technical scheme, the threaded ring inside the rotating movable sleeve can be connected to the surface of the connecting shell.

[0018] The utility model discloses further set up as: first mounting plate one side welding has the rectangular shell, the rectangular shell inside sliding connection has the slide, the slide inside detachable connection has the sieve plate, the slide with sieve plate between common screw joint has the third bolt.

[0019] By adopting the technical scheme, the third bolt can fix the sieve plate inside the slide.

[0020] The utility model discloses further set up as: the slide inside both sides all detachable connection has the moving plate, the moving plate with slide between common insertion has the clamping plate, the slide one side upper end welding has a plurality of groups of teeth, the slide one side welding has the push handle.

[0021] By adopting the technical scheme, pushing the push handle can make the slide move inside the rectangular shell, and the moving plate can be fixed inside the slide by the clamping plate.

[0022] The utility model discloses further set up as: rectangular shell inner wall welding has the scraper, the scraper with sieve plate between slidable connection setting, the rectangular shell inside rotation connection has the anti - jamming brush, the anti - jamming brush one end screw connection has the gear, the anti - jamming brush other end screw connection has the round plate.

[0023] By adopting the technical scheme, when the slide moves, the teeth can drive the gear to rotate, the gear drives the anti - jamming brush to clean the impurity and pigment particle in the screen hole on the surface of the sieve, and the scraper is used for cleaning the impurity on the surface of the sieve.

[0024] In conclusion, the utility model has the following beneficial effects:

[0025] In use, install the connecting pipe in the required mounting hole, then seal the other mounting hole, pour the pigment particles into the connecting barrel, when the pigment particles in the connecting barrel reach a certain amount, unfold the stirring assembly and stir the pigment particles, then push the push - pull rod, the push - pull rod drives the receiving shell to move into the connecting barrel for sampling, then pull the push - pull rod back, when the receiving shell moves to the position of the connecting shell in the connecting pipe, rotate the push - pull rod, then pour the pigment particles in the receiving shell into the screening assembly, finally separate the impurities in the pigment particles by the screening assembly. BRIEF DESCRIPTION OF DRAWINGS

[0026] Figure 1 It is the whole structure schematic perspective drawing of the utility model;

[0027] Figure 2is a schematic perspective view of a pull column structure of the utility model;

[0028] Figure 3 is a schematic perspective view of a support structure of the utility model;

[0029] Figure 4 is a schematic perspective view of a first rotating shaft structure of the utility model;

[0030] Figure 5 is a schematic perspective view of an inner column structure of the utility model;

[0031] Figure 6 is a schematic perspective view of a first bolt structure of the utility model;

[0032] Figure 7 is a schematic perspective view of a third rotating rod structure of the utility model;

[0033] Figure 8 is a schematic perspective view of a stirring rod structure of the utility model;

[0034] Figure 9 is a schematic perspective view of a material receiving shell structure of the utility model;

[0035] Figure 10 is a schematic perspective view of a screen plate structure of the utility model;

[0036] Figure 11 is a schematic perspective view of a rectangular shell structure of the utility model.

[0037] Reference signs:

[0038] 1, connecting barrel; 2, connecting pipe; 3, mounting hole; 4, push-pull rod; 5, material receiving shell; 6, baffle; 7, connecting shell; 8, screening assembly; 801, rectangular shell; 802, gear; 803, anti-blocking brush; 804, round plate; 805, sliding plate; 806, moving plate; 807, screen plate; 808, third bolt; 809, movable sleeve; 810, threaded ring; 811, mounting column; 812, first mounting plate; 813, push handle; 814, clamping plate; 815, scraper; 816, second mounting plate; 817, gear tooth; 9, stirring assembly; 901, support; 902, first rotating shaft; 903, telescopic pipe; 904, blocking pipe; 905, second rotating shaft; 906, first mounting shell; 907, first rotating rod; 908, rotating plate; 909, second mounting shell; 910, second rotating rod; 911, third rotating rod; 912, stirring rod; 913, first bolt; 914, second bolt; 915, limiting plate; 916, pull column; 917, first screw hole; 918, second screw hole; 919, inner column. DETAILED DESCRIPTION

[0039] The utility model will be further explained in detail in connection with the drawings.

[0040] Embodiment 1:

[0041] Reference Figures 1-11 The conductivity detection sampling device for pigment production comprises a connecting barrel 1, two groups of mounting holes 3 are formed on one side of the connecting barrel 1, one group of mounting holes 3 is inserted with a connecting pipe 2, the connecting pipe 2 is slidably connected with a push-pull rod 4, one end of the push-pull rod 4 is welded with a receiving shell 5, one end of the receiving shell 5 is welded with a baffle 6, the lower end of the connecting pipe 2 is welded with a connecting shell 7, the surface of the connecting shell 7 is provided with a screening assembly 8, and the inner bottom of the connecting barrel 1 is provided with a stirring assembly 9.

[0042] The use process is briefly described as follows: in use, the connecting pipe 2 is installed in the required mounting hole 3, then the other mounting hole 3 is sealed, pigment particles are poured into the connecting barrel 1, after the pigment particles in the connecting barrel 1 are poured to a certain amount, the stirring assembly 9 is unfolded to stir and mix the pigment particles in the connecting barrel 1, after the stirring and mixing, the push-pull rod 4 is pushed forward, the push-pull rod 4 drives the receiving shell 5 to move into the connecting barrel 1 for sampling, after the sampling is completed, the push-pull rod 4 is pulled back, when the receiving shell 5 moves to the position of the connecting shell 7 in the connecting pipe 2, the push-pull rod 4 is rotated, at this time, the pigment particles in the receiving shell 5 are poured into the screening assembly 8, and finally the screening assembly 8 is used to separate the impurities in the pigment particles.

[0043] Embodiment 2:

[0044] On the basis of embodiment 1, reference is made to Figures 2-8 The stirring assembly 9 comprises a support 901, the support 901 is welded to the middle part of the inner bottom of the connecting barrel 1, a first rotating shaft 902 is rotatably connected to the upper end of the support 901, a telescopic pipe 903 is fixedly connected to the upper end of the first rotating shaft 902, and an inner column 919 is welded to the upper end of the telescopic pipe 903.

[0045] A second rotating shaft 905 is fixedly connected to the surface of the upper end of the inner column 919, a baffle pipe 904 is welded to the lower end of the second rotating shaft 905, the baffle pipe 904 is rotatably connected to the surface of the inner column 919, and the baffle pipe 904 and the surface of the inner column 919 are both provided with two groups of second screw holes 918.

[0046] The inner column 919 is provided with a pull column 916, the pull column 916 and the surface of the inner column 919 are both welded with a limiting plate 915, the inner column 919 and the pull column 916 are both provided with two groups of first screw holes 917, and the first screw holes 917 are threadedly connected with a first screw 913.

[0047] The first mounting shell 906 is welded on the surface of the pull column 916, the first rotating rod 907 is welded in the first mounting shell 906, the rotating plate 908 is rotatably connected to the surface of the first rotating rod 907, and the second rotating rod 910 is rotatably connected to the inside of the other side of the rotating plate 908.

[0048] The second mounting shell 909 is welded on the surface of the second rotating rod 910, the stirring rod 912 is welded on one side of the second mounting shell 909, the third rotating rod 911 is rotatably connected to the inside of the stirring rod 912, and the third rotating rod 911 is welded in the inner column 919.

[0049] Brief use process: when the pigment particles need to be stirred, the second bolt 914 is removed, the blocking pipe 904 is rotated to the fully open state through the second rotating shaft 905, the strip-shaped hole on the surface of the inner column 919 is exposed, the first bolt 913 is removed from the first screw hole 917, then the pull column 916 is lifted, in the lifting process, the pull column 916 drives the first mounting shell 906 to move upwards synchronously, in the upward movement process, the rotating plate 908 rotates on the surface of the first rotating rod 907 and the second rotating rod 910, because the rotating plate 908 is lifted by the pull column 916 to the state of upward movement at an angle, the stirring rod 912 rotates outwardly from the inner column 919 by the third rotating rod 911, when the stirring rod 912 is unfolded to the appropriate state, the two sets of limiting plates 915 are in close contact, then the first bolt 913 is connected in the pull column 916 through the first screw hole 917 at the upper end, in the process of stirring the pigment particles, the pull column 916 is rotated, the stirring rod 912 is rotated by the first rotating shaft 902, so that the mixing of the pigment particles is realized, and the height of the stirring rod 912 can be adjusted by the telescopic pipe 903, which is convenient for mixing the pigment at multiple positions, when the pigment enters the inner column 919 from the rectangular hole on the surface of the inner column 919 during the stirring process, and the pigment particles in the connecting barrel 1 are poured out after use, the pigment particles in the inner column 919 slide from the telescopic pipe 903 and the first rotating shaft 902 to the bottom of the support 901, because the telescopic pipe 903 and the first rotating shaft 902 are in a hollow state, when the device is not used, the stirring rod 912 is rotated into the inner column 919 by the third rotating rod 911, and the blocking pipe 904 is rotated by the second rotating shaft 905 to seal the stirring rod 912, when the sealing is completed, the second bolt 914 is positioned in the inner column 919 through the second screw hole 918 to fix the blocking pipe 904, when the material receiving shell 5 is used to take the material, the stirring rod 912 stops rotating, and the material receiving shell 5 is located in the middle position of the two stirring rods 912, which does not affect the taking of the material receiving shell 5.

[0050] Example 3:

[0051] On the basis of example 2, reference is made to Figures 10-11The screening assembly 8 comprises a threaded ring 810 which is screwed to the surface of the connecting shell 7, the surface of the threaded ring 810 is rotationally connected with a movable sleeve 809, one side of the movable sleeve 809 is welded with a second mounting plate 816, the lower end of the second mounting plate 816 is welded with three groups of mounting columns 811, and the lower end of the three groups of mounting columns 811 is commonly welded with a first mounting plate 812.

[0052] One side of the first mounting plate 812 is welded with a rectangular shell 801, the inside of the rectangular shell 801 is slidably connected with a sliding plate 805, the inside of the sliding plate 805 is detachably connected with a sieve plate 807, and the sliding plate 805 and the sieve plate 807 are commonly screwed with a third bolt 808.

[0053] Both sides of the inside of the sliding plate 805 are detachably connected with a moving plate 806, the moving plate 806 and the sliding plate 805 are commonly inserted with a clamping plate 814, one side of the upper end of the sliding plate 805 is welded with a plurality of groups of teeth 817, and one side of the sliding plate 805 is welded with a push handle 813.

[0054] The inner wall of the rectangular shell 801 is welded with a scraper 815, the scraper 815 and the sieve plate 807 are slidably connected, the inside of the rectangular shell 801 is rotationally connected with an anti-blocking brush 803, one end of the anti-blocking brush 803 is screwed with a gear 802, and the other end of the anti-blocking brush 803 is screwed with a round plate 804.

[0055] Use process: when screening impurities, rotate the threaded ring 810 inside the movable sleeve 809 to connect the threaded ring 810 to the surface of the connecting shell 7. The screen plate 807 adopts a detachable structure, and different mesh (recommended 80-200 mesh) screens can be replaced according to the particle size of the pigment particles to meet the screening needs of different types of pigments such as titanium dioxide and iron oxide. When the material receiving shell 5 finishes taking the material, the pigment particles will be poured on the surface of the screen plate 807 from the position of the connecting shell 7. Then hold the push handle 813 to drive the sliding plate 805 on which the screen plate 807 is installed to move back and forth inside the rectangular shell 801 and hit one end of the inner wall of the rectangular shell 801. The vibration and movement will make the normal pigment particles fall through the screen holes into the corresponding box (two boxes for receiving normal pigment particles and impurities are placed at the lower end of the rectangular shell 801 before use). When a batch of pigment particles is screened, move the sliding plate 805 back and forth to move the impurities on the surface of the screen plate 807 to the middle. Then remove the clamping plate 814, and then remove the moving plate 806. Then move the sliding plate 805 forward. In the process of moving forward, the scraper 815 will scrape the impurities on the surface of the screen plate 807 into the box below. When the sliding plate 805 continues to move, the gear teeth 817 will drive the gear 802 to rotate. The rotation of the gear 802 will drive the anti-blocking brush 803 to rotate on the surface of the screen plate 807. The anti-blocking brush 803 can remove the impurities and pigment particles blocked in the screen holes on the surface of the screen plate 807, thereby completing the screening of the pigment particles and preventing the screen holes from being blocked. When the screen plate 807 needs to be replaced, the third bolt 808 can be removed, and then the screen plate 807 can be removed and replaced.

[0056] It should be noted that: parts have a life cycle, and can be replaced during regular maintenance when the use performance cannot be met in the later period. The use effect is poor due to long-term use of the parts, which is not a design defect of the application.

[0057] The specific embodiment is only an explanation of the application, and is not a limitation of the application. Those skilled in the art can make non-creative modifications to the embodiment according to needs after reading the specification, but as long as the modifications are within the scope of the claims of the application, they are protected by the patent law.

Claims

1. A conductivity testing and sampling device for pigment production, comprising a connecting tank (1), characterized in that: The connecting barrel (1) has two sets of mounting holes (3) on one side. A connecting pipe (2) is inserted into one set of mounting holes (3). A push-pull rod (4) is slidably connected inside the connecting pipe (2). A receiving shell (5) is welded to one end of the push-pull rod (4). A baffle (6) is welded to one end of the receiving shell (5). A connecting shell (7) is welded to the lower end of the connecting pipe (2). A screening component (8) is provided on the surface of the connecting shell (7). A stirring component (9) is provided at the bottom of the connecting barrel (1).

2. The conductivity detection and sampling device for pigment production according to claim 1, characterized in that: The stirring assembly (9) includes a bracket (901), which is welded to the middle of the bottom of the connecting barrel (1). The upper end of the bracket (901) is rotatably connected to a first rotating shaft (902), and the upper end of the first rotating shaft (902) is fixedly connected to a telescopic tube (903). The upper end of the telescopic tube (903) is welded to an inner column (919).

3. The conductivity detection and sampling device for pigment production according to claim 2, characterized in that: The upper end of the inner column (919) is fixedly connected to a second rotating shaft (905), and a stop tube (904) is welded to the lower end of the second rotating shaft (905). The stop tube (904) is rotatably connected to the surface of the inner column (919). Both the stop tube (904) and the surface of the inner column (919) are provided with two sets of second screw holes (918), and a second bolt (914) is threaded between the two sets of screw holes.

4. The conductivity detection and sampling device for pigment production according to claim 3, characterized in that: The inner column (919) is provided with a tie column (916). The tie column (916) and the inner column (919) are both welded with limit plates (915). The inner column (919) and the tie column (916) are provided with two sets of first screw holes (917). The two sets of first screw holes (917) are connected by a first bolt (913) through a common thread.

5. The conductivity detection and sampling device for pigment production according to claim 4, characterized in that: The pull column (916) has a first mounting shell (906) welded on all four sides. A first rotating rod (907) is welded inside the first mounting shell (906). A rotating plate (908) is rotatably connected to the surface of the first rotating rod (907). A second rotating rod (910) is rotatably connected to the other side of the rotating plate (908).

6. The conductivity detection and sampling device for pigment production according to claim 5, characterized in that: The second rotating rod (910) has a second mounting shell (909) welded to its surface. A stirring rod (912) is welded to one side of the second mounting shell (909). A third rotating rod (911) is rotatably connected inside the stirring rod (912), and the third rotating rod (911) is welded to the inside of the inner column (919).

7. The conductivity detection and sampling device for pigment production according to claim 1, characterized in that: The screening component (8) includes a threaded ring (810), which is threadedly connected to the surface of the connecting shell (7). A movable sleeve (809) is rotatably connected to the surface of the threaded ring (810). A second mounting plate (816) is welded to one side of the movable sleeve (809). Three sets of mounting columns (811) are welded to the lower end of the second mounting plate (816). A first mounting plate (812) is welded to the lower end of the three sets of mounting columns (811).

8. The conductivity detection and sampling device for pigment production according to claim 7, characterized in that: A rectangular shell (801) is welded to one side of the first mounting plate (812). A sliding plate (805) is slidably connected inside the rectangular shell (801). A sieve plate (807) is detachably connected inside the sliding plate (805). A third bolt (808) is threadedly connected between the sliding plate (805) and the sieve plate (807).

9. The conductivity detection and sampling device for pigment production according to claim 8, characterized in that: The sliding plate (805) has detachable sliding plates (806) on both sides inside. The sliding plates (806) and the sliding plate (805) are connected by a locking plate (814). Several sets of teeth (817) are welded to the upper end of one side of the sliding plate (805). A push handle (813) is welded to one side of the sliding plate (805).

10. The conductivity detection and sampling device for pigment production according to claim 9, characterized in that: The inner wall of the rectangular shell (801) is welded with a scraper (815), and the scraper (815) and the sieve plate (807) are slidably connected. An anti-clogging brush (803) is rotatably connected inside the rectangular shell (801). One end of the anti-clogging brush (803) is threaded with a gear (802), and the other end of the anti-clogging brush (803) is threaded with a circular plate (804).