CN210604049U

CN210604049U - Epoxy reation kettle sampling device

Info

Publication number: CN210604049U
Application number: CN201921572031.9U
Authority: CN
Inventors: 汪年华; 罗乐平; 程殿辉; 江蓉; 柴雅倩; 李海云
Original assignee: Huangshan Wuhuan Technology Co ltd
Current assignee: Huangshan Wuhuan Technology Co ltd
Priority date: 2019-09-20
Filing date: 2019-09-20
Publication date: 2020-05-22
Anticipated expiration: 2029-09-20

Abstract

The utility model discloses an epoxy reaction kettle sampling device, an air pressure adjusting mechanism, a feed inlet and a first sampling part are arranged on the side wall of a sampling box, the first sampling part is connected with a first sampler, the sampling box is communicated with the feed inlet through a connecting pipe, the sampling pipe is arranged at the bottom of the sampling box and is communicated with a sampling cavity, the side wall of the sampling pipe is circumferentially provided with a first sampling port, a second sampling port and a third sampling port which have different directions and positions, and the sampling pipe or the second sampling part on the sampling box is connected with a second sampler; be connected with first arc, second arc and third arc on the regulation pole in the sample tube, first arc, second arc and third arc can realize opening or closing first sample connection, second sample connection and third sample connection. The utility model provides an epoxy reation kettle sampling device can mix the detection or independently detect the reactant in the reation kettle, increases the accuracy of sampling test.

Description

Epoxy reation kettle sampling device

Technical Field

The utility model relates to a chemical production technical field especially relates to an epoxy reation kettle sampling device.

Background

Epoxy resins are also known as artificial resins, synthetic resins, resin glues, and the like. Is an important thermosetting plastic and is widely used for adhesives, coatings and the like. The molecular structure of the epoxy resin is characterized in that a molecular chain contains active epoxy groups, and the epoxy groups can be positioned at the tail ends, in the middle or in a ring structure. Because the molecular structure contains active epoxy group, they can produce cross-linking reaction with several curing agents to form infusible high polymer with three-dimensional network structure.

The production of epoxy resin is often carried out in a reaction kettle, and in the process of producing the epoxy resin by using the reaction kettle, sampling needs to be carried out in the reaction kettle for detecting the condition in the production process of the epoxy resin; meanwhile, the reaction in the reaction kettle usually has toxic gas release or liquid corrosivity which is large, the sampling mode is adopted to cause great harm to human bodies, and the surrounding environment is also polluted. In addition, a sampler adopting a vacuumizing principle is partially used for sampling, and the defects that the sampling position of a sampling tube is fixed, independent sampling or comprehensive sampling analysis can not be carried out on reactants with different heights and angles in the reaction kettle, and the reaction condition in the reaction kettle can not be judged.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an epoxy reation kettle sampling device to solve the above-mentioned weak point among the prior art.

In order to achieve the above object, the present invention provides the following technical solutions:

an epoxy reation kettle sampling device includes:

the sampling device comprises a sampling box, a first sampling part and a second sampling part, wherein an air pressure adjusting mechanism, a feeding hole and the first sampling part are arranged on the side wall of the sampling box;

the sampling mechanism comprises a sampling tube and a sampling box, a sampling cavity is arranged in the sampling box and communicated with the feed inlet through a connecting tube, the sampling tube is arranged at the bottom of the sampling box and communicated with the sampling cavity, a first sampling port, a second sampling port and a third sampling port which are different in orientation are arranged on the side wall of the sampling tube along the circumferential direction, the first sampling port, the second sampling port and the third sampling port are arranged at different heights of the sampling tube, a second sampling part is arranged on the sampling tube or the sampling box, and a second sampler is connected to the second sampling part;

the adjusting part comprises an adjusting rod, the adjusting rod is located in the sampling tube, a first arc-shaped plate, a second arc-shaped plate and a third arc-shaped plate are connected to the adjusting rod, a first annular rotary groove, a second annular rotary groove and a third annular rotary groove are formed in the side wall of the sampling tube, the first annular rotary groove, the second annular rotary groove and the third annular rotary groove are in one-to-one correspondence with the first sampling opening, the second sampling opening and the third sampling opening, the first arc-shaped plate, the second arc-shaped plate and the third arc-shaped plate are rotatably arranged in the first annular rotary groove, the second annular rotary groove and the third annular rotary groove respectively, a rotary driving part connected with the adjusting rod is arranged in the sampling box, the rotary driving part can drive the adjusting rod to rotate to drive the first arc-shaped plate, the second arc-shaped plate and the third arc-shaped plate to rotate to realize the alignment of the first sampling opening, The second sampling port and the third sampling port are opened or closed.

Foretell epoxy reation kettle sampling device, first annular rotary tank, second annular rotary tank and third annular rotary tank all follow the inner wall circumference setting of sampling tube, first sample connection, second sample connection and third sample connection are located the inside one end of sampling tube is equallyd divide and is do not at first annular rotary tank, second annular rotary tank and third annular rotary tank.

In the epoxy resin reaction kettle sampling device, the circumferential lengths of the first arc-shaped plate, the second arc-shaped plate and the third arc-shaped plate are different, the circumferential length of the second arc-shaped plate is more than or equal to two times of the circumferential length of the first arc-shaped plate, and the circumferential length of the third arc-shaped plate is more than or equal to two times of the circumferential length of the second arc-shaped plate.

In the epoxy resin reaction kettle sampling device, the rotary driving part comprises a circular driving plate, the circular driving plate is connected to the upper end of the adjusting rod, and the circular driving plate is connected with a driving button.

Foretell epoxy reation kettle sampling device, be provided with on the roof of sample box and rotate and mark, rotate mark with the circumference length phase-match setting of first arc, second arc and third arc.

The sampling device for the epoxy resin reaction kettle further comprises a water storage tank, wherein a water outlet is formed in the water storage tank, and the water outlet is communicated with the sampling box and the sampling pipe through a connecting water pipe.

In the above technical solution, the utility model provides an epoxy resin reation kettle sampling device, including the sampling case, sampling mechanism and regulating part, the sampling case is connected with sampling mechanism in order to accept the reactant that takes out from the reation kettle, be provided with first sample portion and the first sampler that sets up on first sample portion on the sampling case, sampling mechanism includes sampling tube and sampling box, be provided with first sample connection, second sample connection and third sample connection that all differ in height and orientation on the sampling tube, the regulating part can be opened or closed to first sample connection, second sample connection and third sample connection, can sample the reactant of different height and position in the reation kettle through first sample connection, second sample connection and third sample connection, can carry out the mixing detection or independently detect it respectively through first sampler and second sampler, so increase its sample detection's accuracy, effectively judge the condition of epoxy resin production in the reaction kettle.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to these drawings.

Fig. 1 is a schematic structural diagram of an epoxy resin reaction kettle sampling device provided by an embodiment of the present invention;

fig. 2 is a cross-sectional view of a sampling tube according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a sampling tube according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a first arc-shaped plate according to an embodiment of the present invention;

fig. 5 is a schematic structural view of a second arc-shaped plate according to an embodiment of the present invention;

fig. 6 is a schematic structural view of a third arc-shaped plate according to an embodiment of the present invention.

Description of reference numerals:

1. a sampling box; 1.1, an air pressure adjusting mechanism; 1.2, a feed inlet; 1.3, a first sampling part; 1.4, a first sampler; 1.5, a stirring mechanism; 2. a sampling box; 3. a sampling tube; 3.1, a first sampling port; 3.2, a second sampling port; 3.3, a third sampling port; 3.4, a second sampling part; 3.5, a second sampler; 3.6, a first annular rotating groove; 3.7, a second annular rotating groove; 3.8, a third annular rotating groove; 4. an adjustment member; 4.1, adjusting a rod; 4.2, a first arc-shaped plate; 4.3, a second arc-shaped plate; 4.4, a third arc-shaped plate; 5. a water storage tank; 6. and (5) a reaction kettle.

Detailed Description

In order to make the technical solution of the present invention better understood by those skilled in the art, the present invention will be further described in detail with reference to the accompanying drawings.

As shown in fig. 1-6, an embodiment of the present invention provides an epoxy resin reaction kettle sampling device, which includes a sampling box 1, a sampling mechanism and an adjusting member 4, wherein a side wall of the sampling box 1 is provided with an air pressure adjusting mechanism 1.1, a feeding port 1.2 and a first sampling portion 1.3, the first sampling portion 1.3 is connected with a first sampler 1.4, and the sampling box 1 is internally provided with a stirring mechanism 1.5; the sampling mechanism comprises a sampling tube 3 and a sampling box 2, a sampling cavity is arranged in the sampling box 2 and is communicated with the feeding port 1.2 through a connecting tube, the sampling tube 3 is arranged at the bottom of the sampling box 2 and is communicated with the sampling cavity, the side wall of the sampling tube 3 is circumferentially provided with a first sampling port 3.1, a second sampling port 3.2 and a third sampling port 3.3 which are different in orientation, the first sampling port 3.1, the second sampling port 3.2 and the third sampling port 3.3 are arranged at different heights of the sampling tube 3, the sampling tube 3 or the sampling box 2 is provided with a second sampling part 3.4, and the second sampling part 3.4 is connected with a second sampler 3.5; the adjusting part 4 comprises an adjusting rod 4.1, the adjusting rod 4.1 is positioned in the sampling tube 3, the adjusting rod 4.1 is connected with a first arc-shaped plate 4.2, a second arc-shaped plate 4.3 and a third arc-shaped plate 4.4, a first annular rotary groove 3.6, a second annular rotary groove 3.7 and a third annular rotary groove 3.8 are arranged on the side wall of the sampling tube 3, the first annular rotary groove 3.6, the second annular rotary groove 3.7 and the third annular rotary groove 3.8 are arranged in a one-to-one correspondence manner with the first sampling opening 3.1, the second sampling opening 3.2 and the third sampling opening 3.3, a rotary driving part connected with the adjusting rod 4.1 is arranged in the first annular rotary groove 3.6, the second annular rotary groove 3.7 and the third annular rotary groove 3.8 in the sampling box 2, the rotary driving part 4.1 rotates to drive the first arc-shaped plate 4.2, the second arc-shaped plate 4.7 and the third annular rotary groove 3.8 rotate to realize that the first arc-shaped plate 4.1 and the third arc-shaped plate 4.1 rotate to each other, The second sampling port 3.2 and the third sampling port 3.3 are opened or closed.

Specifically, the sampling mechanism is used for taking out the reactant in the reaction kettle 6 for detection, the sampling mechanism comprises a sampling tube 3 and a sampling box 2, the sampling tube 3 extends into the reaction kettle 6, the sampling tube 3 is provided with a first sampling port 3.1, a second sampling port 3.2 and a third sampling port 3.3, the first sampling port 3.1, the second sampling port 3.2 and the third sampling port 3.3 are arranged at different heights of the sampling tube 3, and the first sampling port 3.1, the second sampling port 3.2 and the third sampling port 3.3 are arranged at different angles along the circumferential direction of the sampling tube 3, so when the sampling tube 3 extends into the reactant in the reaction kettle 6, the reactant can be taken out through the first sampling port 3.1, the second sampling port 3.2 and the third sampling port 3.3 and the reactant in different directions, the detection result is more accurate, the second sampling portion 3.4 is arranged at the upper part of the sampling tube 3, and the second sampling portion 3.4 can be an opening or an opening with different depths, second sample portion 3.4 sets up on 3 outside body side walls that are located reation kettle of sampling tube or on sampling box 2, be provided with second sampler 3.5 on the second sample portion 3.4, can take out the reactant in the sampling tube 3 through second sampler 3.5 and detect, be connected with sampling box 2 at the top of sampling tube 3, sampling box 2's inside is provided with the sample chamber, sample chamber and sampling tube 3 are linked together, be provided with the discharge gate simultaneously on sampling box 2, the discharge gate is linked together through feed inlet 1.2 of connecting pipe on with sampling box 1, thereby realize carrying the reactant to sampling box 1 in.

In this embodiment, the sampling box 1 may be rectangular, square or cylindrical, the number of the feeding ports 1.2 on the sampling box 1 may be one, or two or more, the feeding ports 1.2 are connected with the sampling mechanism for receiving the reactant taken out from the reaction kettle 6, the first sampling portion 1.3 is disposed on the sidewall of the sampling box 1 and is communicated with the inside of the sampling box 1, the first sampling portion 1.3 may be an opening or a channel disposed on the sidewall of the sampling box 1, the first sampler 1.4 is disposed on the first sampling portion 1.3, the reactant in the sampling box 1 can be sampled and detected by the first sampler 1.4, the first sampler 1.4 is a structure capable of taking out the reactant to be detected from the first sampling portion 1.3, and may be a sampling plate, a sampling cylinder, etc., the stirring mechanism 1.5 is disposed inside the sampling box 1, and the stirring mechanism 1.5 is used for stirring and mixing the reactant in the sampling box 1, rabbling mechanism 1.5 includes driving motor, (mixing) shaft and stirring vane, driving motor can drive the (mixing) shaft and rotate, the (mixing) shaft rotates the in-process and can drive stirring vane and rotate, thereby stir the mixture to the reactant in sampling box 1, be provided with atmospheric pressure adjustment mechanism 1.1 on the lateral wall of sampling box 1, atmospheric pressure in the adjustable sampling box 1 of atmospheric pressure adjustment mechanism 1.1, thereby make the atmospheric pressure in sampling box 1 and the reation kettle 6 suit, liquid reactant in the reation kettle 6 just can enter into sample chamber and sampling box 1 through sampling tube 3. Therefore, in the actual use process, the sampling method can be adjusted as required, when a reactant at one height needs to be sampled in the reaction kettle 6, the first sampling port 3.1 at the lowest position of the sampling tube 3 is opened, the second sampling port 3.2 and the third sampling port 3.3 are both closed, the first sampling port 3.1 is inserted into the reactant in the reaction kettle 6, the reactant is sampled from the reaction kettle 6 through the first sampling port 3.1 and the sampling tube 3, the reactant can be taken out for detection through the second sampling part 3.4 and the second sampling part 3.5, when the reactant at different heights in the reaction kettle 6 needs to be sampled, the sampling tube 3 can be inserted into the reactant, the first sampling port 3.1, the second sampling port 3.2 and the third sampling port 3.3 are sequentially opened to sample the reactant, the reactant is conveyed into the sampling box 1, and is stirred through the stirring mechanism 1.5, make the reactant misce bene of co-altitude not, taking out the reactant in the sample case 1 through first sample portion 1.3 and first sampler 1.4, so realize carrying out sample detection to the reactant of co-altitude not in reation kettle 6, increase the accuracy that detects.

In this embodiment, the adjusting member 4 is used for adjusting the sampling mechanism to realize adjustment of the sampling mode, the adjusting member 4 includes an adjusting rod 4.1, the adjusting rod 4.1 is arranged inside the sampling tube 3 in a penetrating manner, the adjusting rod 4.1 is connected with a first arc-shaped plate 4.2, a second arc-shaped plate 4.3 and a third arc-shaped plate 4.4, the first arc-shaped plate 4.2, the second arc-shaped plate 4.3 and the third arc-shaped plate 4.4 are all connected with the adjusting rod 4.1 through a connecting rod, a first annular rotary groove 3.6, a second annular rotary groove 3.7 and a third annular rotary groove 3.8 are arranged on the side wall of the sampling tube 3, the first annular rotary groove 3.6, the second annular rotary groove 3.7 and the third annular rotary groove 3.8 are arranged along the circumferential direction of the inner wall of the sampling tube 3, the first annular rotary groove 3.6, the second annular rotary groove 3.7 and the third annular rotary groove 3.8 are arranged corresponding to the first sampling port 3.1, the second sampling port 3.2 and the third sampling port 3.3.8, that is, the ends of the first sampling opening 3.1, the second sampling opening 3.2 and the third sampling opening 3.3 located inside the sampling tube 3 are just above the first annular rotary groove 3.6, the second annular rotary groove 3.7 and the third annular rotary groove 3.8, the first arc-shaped plate 4.2, the second arc-shaped plate 4.3 and the third arc-shaped plate 4.4 are respectively and rotatably arranged in the first annular rotary groove 3.6, the second annular rotary groove 3.7 and the third annular rotary groove 3.8, the first arc-shaped plate 4.2, the second arc-shaped plate 4.3 and the third arc-shaped plate 4.4 respectively open or close the first sampling opening 3.1, the second sampling opening 3.2 and the third sampling opening 3.3 along the first annular rotary groove 3.6, the second annular rotary groove 3.7 and the third annular rotary groove 3.8, respectively, the rotating plate connected with the adjusting rod 4.1 is arranged in the box 2, the driving component can be a rotating motor or a rotating driving component 4.2, the adjusting rod 4.1 can be driven by a rotating motor to rotate the rotating component, Second arc 4.3 and third arc 4.4 rotate in order to realize first sample connection 3.1, second sample connection 3.2 and third sample connection 3.3 are opened or are closed, so can realize through first sample connection 3.1, the not co-altitude's in second sample connection 3.2 and the third sample connection 3.3 to reation kettle 6 reactant take a sample, in this embodiment, can realize taking a sample the liquid reactant through sampling mechanism, can directly take a sample through sampling tube 3 to the reactant sample of thick form.

The utility model provides an epoxy reaction kettle sampling device, including sampling case 1, sampling mechanism and regulating part 4, sampling case 1 is connected with sampling mechanism in order to accept the reactant that takes out from reation kettle 6, be provided with first sample portion 1.3 and set up first sampler 1.4 on first sample portion 1.3 on the sampling case 1, sampling mechanism includes sampling tube 3 and sampling box 2, be provided with first sample connection 3.1, second sample connection 3.2 and third sample connection 3.3 that highly and orientation are all different on the sampling tube 3, regulating part 4 can be opened or closed first sample connection 3.1, second sample connection 3.2 and third sample connection 3.3, so can sample the reactant of different height and position in reation kettle 6 through first sample connection 3.1, second sample connection 3.2 and third sample connection 3.3, can mix the detection or independently detect it through first sampler 1.4 and second sampler 3.5 respectively, therefore, the accuracy of sampling detection is improved, and the condition of producing the epoxy resin in the reaction kettle 6 is effectively judged.

In this embodiment, preferably, the first annular rotary groove 3.6, the second annular rotary groove 3.7 and the third annular rotary groove 3.8 are all circumferentially arranged along the inner wall of the sampling tube 3, and the ends of the first sampling port 3.1, the second sampling port 3.2 and the third sampling port 3.3, which are located inside the sampling tube 3, are respectively in the first annular rotary groove 3.6, the second annular rotary groove 3.7 and the third annular rotary groove 3.8; so first arc 4.2, second arc 4.3 and third arc 4.4 can realize opening or closing first sample connection 3.1, second sample connection 3.2 and third sample connection 3.3 along first annular swivelling chute 3.6, second annular swivelling chute 3.7 and third annular swivelling chute 3.8 when rotating.

In this embodiment, optionally, the circumferential lengths of the first arc-shaped plate 4.2, the second arc-shaped plate 4.3 and the third arc-shaped plate 4.4 are all different, the circumferential length of the second arc-shaped plate 4.3 is greater than or equal to twice the circumferential length of the first arc-shaped plate 4.2, and the circumferential length of the third arc-shaped plate 4.4 is greater than or equal to twice the circumferential length of the second arc-shaped plate 4.3; the circumferential lengths of the first arc-shaped plate 4.2, the second arc-shaped plate 4.3 and the third arc-shaped plate 4.4 are provided with a plurality of types, which is one of the setting modes, the first sampling port 3.1 is positioned at the lowest part of the sampling tube 3, the third sampling port 3.3 is positioned at the highest part of the sampling tube 3, the second sampling port 3.2 is positioned between the first sampling port 3.1 and the third sampling port 3.3, the length of the second arc-shaped plate 4.3 is more than or equal to twice of the length of the first arc-shaped plate 4.2, the circumferential length of the third arc-shaped plate 4.4 is more than or equal to twice of the circumferential length of the second arc-shaped plate 4.3, so when the first sampling port 3.1 is opened through the first arc-shaped plate 4.2, the second sampling port 3.2 and the third sampling port 3.3 are not opened, and when the second sampling port 3.2 is opened, the third sampling port 3.3 is not opened, and when the third sampling port 3.3 is opened, the first sampling port and the second sampling port 3.1 are both opened.

In this embodiment, preferably, the rotary driving member includes a circular driving plate, the circular driving plate is connected to the upper end of the adjusting rod 4.1, and the circular driving plate is connected with a driving button; the rotatable setting of circular drive plate can drive circular drive plate through drive button and rotate on the roof of sampling box 2 to make and adjust pole 4.1 and rotate, drive first arc 4.2, second arc 4.3 and third arc 4.4 and rotate, realize opening or closing first sample connection 3.1, second sample connection 3.2 and third sample connection 3.3.

In this embodiment, preferably, a top plate of the sampling box 2 is provided with a rotation mark, and the rotation mark is matched with the circumferential lengths of the first arc-shaped plate 4.2, the second arc-shaped plate 4.3 and the third arc-shaped plate 4.4; the rotation marks and encircles the setting of drive button, and drive button rotates to mark position department like this, just can know first sample connection 3.1, second sample connection 3.2 and third sample connection 3.3 in the sampling tube 3 and be open mode or closed state.

In the embodiment, the sampling device preferably further comprises a water storage tank 5, wherein a water outlet is formed in the water storage tank 5 and is communicated with the sampling tank 1 and the sampling pipe 3 through a connecting water pipe; water is stored in the water storage tank 5, and the water output value sampling box 1 or the sampling tube 3 in the water storage tank 5 can be cleaned by the water outlet, so that the sampling box 1 or the sampling tube 3 is prevented from being cleaned, and the residue sampled last time is prevented from remaining in the sampling box 1 or the sampling tube 3, so that the influence on next sampling detection is caused.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the present invention. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the invention.

Claims

1. The utility model provides an epoxy reation kettle sampling device which characterized in that includes:

2. The epoxy reactor sampling device of claim 1, wherein the first annular rotary groove, the second annular rotary groove and the third annular rotary groove are all circumferentially arranged along the inner wall of the sampling tube, and the ends of the first sampling port, the second sampling port and the third sampling port located inside the sampling tube are respectively located in the first annular rotary groove, the second annular rotary groove and the third annular rotary groove.

3. The epoxy resin reaction kettle sampling device of claim 1, wherein the first arc-shaped plate, the second arc-shaped plate and the third arc-shaped plate are different in circumferential length, the circumferential length of the second arc-shaped plate is greater than or equal to twice the circumferential length of the first arc-shaped plate, and the circumferential length of the third arc-shaped plate is greater than or equal to twice the circumferential length of the second arc-shaped plate.

4. The epoxy reactor sampling device of claim 3, wherein the rotary drive comprises a circular drive plate, the circular drive plate is connected to the upper end of the adjustment stem, and a drive button is connected to the circular drive plate.

5. The epoxy resin reaction kettle sampling device of claim 4, wherein a top plate of the sampling box is provided with a rotation mark, and the rotation mark is matched with the circumferential lengths of the first arc-shaped plate, the second arc-shaped plate and the third arc-shaped plate.

6. The epoxy resin reaction kettle sampling device of claim 1, further comprising a water storage tank, wherein a water outlet is arranged on the water storage tank, and the water outlet is communicated with the sampling tank and the sampling pipe through a connecting water pipe.