CN115144540B - Chemical component detection device for alkali-activated cementing material and application method of chemical component detection device - Google Patents

Abstract

The invention relates to the field of material detection and discloses a chemical component detection device of alkali-activated cementing materials and a use method thereof.

Description

Chemical component detection device for alkali-activated cementing material and application method of chemical component detection device

Technical Field

The invention relates to the field of material detection, in particular to a chemical component detection device of alkali-activated cementing materials and a use method thereof.

Background

Alkali-activated gelling materials, also known as "chemically activated gelling materials". Hydraulic binders are produced using the catalytic principle of alkali-activators (caustic, alkali-containing silicate, aluminate). Including alkali-slag cements, geopolymers, or earth-poly cements, and the like. The method mainly comprises the steps of calcining natural minerals or industrial waste residues (such as metakaolin, slag, fly ash, silica fume, steel slag and the like) and alkali-exciting agents of aluminosilicate containing with a certain quenching heat history. Fast setting and hardening, high strength and high temperature resistance. The method is used for engineering such as civil construction, nuclear and solid waste fixation, high strength, sealing, high-temperature environment and the like.

Before the alkali-activated cementing material is used, the chemical components of the alkali-activated cementing material are detected, the specific contents of different chemical components are known to better utilize the alkali-activated cementing material, most of the existing alkali-activated cementing material chemical component detection devices have simple structures, and the environment is polluted in the detection process without considering that some alkali-activated cementing materials contain industrial pollutants.

Disclosure of Invention

In order to solve the defects in the background art, the invention aims to provide a chemical component detection device of alkali-activated cementing materials and a use method thereof.

The aim of the invention can be achieved by the following technical scheme:

the chemical component detection device of the alkali-activated cementing material comprises a support frame, wherein a scanning detection device is arranged on the support frame, a screening device is arranged on one side close to the scanning detection device, a dissolution mixing device is arranged on the other side close to the scanning detection device, and a second conveying device is arranged on the side of the dissolution mixing device;

the support frame comprises a support plate, a control console is arranged on the support plate, a first fixing plate and a second fixing plate are arranged on the side of the control console, a third fixing plate is arranged on the second fixing plate, a fourth fixing plate is arranged on the side of the first fixing plate and the side of the second fixing plate, a sliding groove is formed in the upper portion of the fourth fixing plate, and four fifth fixing plates distributed in an array are arranged on the side of the fourth fixing plate;

the scanning detection device comprises two symmetrically distributed fixing frames, the two fixing frames are fixed on a supporting plate, a group of supporting rods which are distributed in an array are fixedly connected between the two fixing frames, two symmetrically distributed first conveying rollers are arranged above the supporting rods, two ends of each first conveying roller are respectively connected with the upper parts of the fixing frames in a rotating mode, first conveying belts are sleeved on the surfaces of the two first conveying rollers, partition plates which are distributed in an array are arranged on the first conveying belts, detection equipment is arranged above the first conveying belts and fixed on the tops of the fixing frames, first motors are fixedly installed on the fixing frames positioned on one side, and output shafts of the first motors penetrate through the fixing frames and are fixedly connected with one of the first conveying rollers;

the second conveying device comprises a main conveying mechanism, a sliding mechanism is arranged below the main conveying mechanism, and an auxiliary conveying mechanism is arranged on the side of the sliding mechanism.

Further, the control console comprises a supporting table, the supporting table is arranged above the supporting plate, a controller is arranged above the supporting table, a control button is arranged on the side of the controller, and a display screen is arranged above the control button.

Further, sieving mechanism includes the fixed station, and the fixed station top is equipped with two mounting panels of symmetric distribution, is fixed with the second motor on the mounting panel of keeping away from mount one side, and the output shaft of second motor runs through the mounting panel and is fixed with first ball, and the slip is provided with the liftout pole on the first ball, two slide bars of symmetric distribution are installed to the both sides of fixed station, and the both sides of liftout pole are equipped with symmetric distribution's supporting lug, supporting lug and slide bar sliding connection.

Further, dissolve mixing arrangement includes the mixing box, and the both sides outer wall of mixing box is equipped with symmetrical distribution's dwang, and two dwang rotate with first fixed plate and second fixed plate respectively and be connected, and the mixing box top is opened there is the feed inlet, is equipped with the case lid on the feed inlet, and mixing box bottom is equipped with the outlet pipe, and mixing box top outer wall is fixed with the third motor, and the output shaft of third motor runs through mixing box top outer wall connection and has the rotation connector, rotates the puddler that the connector below was equipped with array distribution, the bottom of mixing box is equipped with the heater, heater and outlet pipe intercommunication, and the both sides inner wall of mixing box is fixed with symmetrical distribution's ultrasonic oscillator respectively, and the side of second fixed plate is equipped with swing mechanism.

Further, swing mechanism includes the fourth motor, and the fourth motor is fixed on the fourth fixed plate, and the output shaft fixedly connected with dwang of fourth motor, one side of dwang are equipped with the swinging arms, the dwang side is equipped with the swinging arms, and one side of swinging arms is equipped with the swinging block, opens on the swinging block has the swinging groove, and the opposite side of swinging arms is equipped with the connecting rod, and the connecting rod runs through second fixed plate fixedly connected with dwang.

Further, the main conveying mechanism comprises a conveying frame, a fifth motor is arranged on the outer wall of one side of the conveying frame, two second conveying rollers distributed in an array are rotatably connected to the inner walls of two sides of the conveying frame, an output shaft of the fifth motor penetrates through the outer wall of the conveying frame and is fixedly connected with the second conveying rollers, a second conveying belt is sleeved on the second conveying rollers, a supporting block is arranged at one end of the conveying frame, and the supporting block is slidably arranged in the sliding groove.

Further, the sliding mechanism comprises two sliding support frames distributed in an array mode, the sliding support frames are fixed on the supporting plate, a sixth motor is arranged on the sliding support frames located on one side, an output shaft of the sixth motor penetrates through the sliding support frames to be fixedly connected with a second ball screw, two ends of the second ball screw are rotatably connected with the sliding support frames, sliding blocks are arranged on the second ball screw, and the sliding blocks are fixedly connected with the bottoms of the conveying frames.

Further, the auxiliary conveying mechanism comprises two rotating shafts and a seventh motor which are symmetrically distributed, three third conveying rollers which are distributed in an array are arranged on each rotating shaft, a third conveying roller is arranged between every two fifth fixing plates, and a third conveying belt is sleeved on the two third conveying rollers between every two fifth fixing plates.

Further, the rotating shaft penetrates through the fifth fixing plate and is in rotating connection with the fifth fixing plate, the seventh motor is fixed on the fifth fixing plate at the outermost side, and an output shaft of the seventh motor penetrates through the fifth fixing plate and is fixedly connected with the rotating shaft.

A method for using a chemical composition detection device for alkali-activated gelling materials, comprising the chemical composition detection device for alkali-activated gelling materials according to any one of claims 1-9, characterized in that the method comprises the following steps:

step one: the alkali-activated cementing material is screened out by the cooperation of a scanning detection device and a screening device, and the alkali-activated cementing material without pollutants is screened out;

step two: adding the alkali-activated cementing material without pollutants into a dissolving and mixing device to prepare a solution, and then filling the solution into a container for sealing;

step three: setting the rotation speed, the rotation direction and the running interval of the fifth motor, the sixth motor and the seventh motor through a control console;

step four: conveying the alkali-activated cementing material mixed solution to different detection procedures through a second conveying device;

step five: and detecting the contents of various chemical components in the alkali-activated cementing material mixed solution through different detection procedures.

The invention has the beneficial effects that:

1. the invention is provided with a scanning detection device and a screening device, wherein the scanning detection device is provided with detection equipment for detecting the conveyed alkali-activated cementing material, when the alkali-activated cementing material with pollutants on the surface is detected, the alkali-activated cementing material with the pollutants is ejected out of the equipment through the screening device, the conveyed alkali-activated cementing material is screened, and the quality of the alkali-activated cementing material conveyed to the next station is ensured.

2. The invention is provided with the dissolution mixing device, the dissolution mixing device is internally provided with the ultrasonic oscillator and the stirring rod to stir and mix the screened alkali-activated cementing materials, and the dissolution mixing device is also provided with the swinging mechanism which can drive the mixing box to swing, so that the mixing is more thorough, manual cleaning by workers is not needed, and a large amount of manpower is saved.

3. The invention is provided with the second conveying device which is provided with the main conveying mechanism and the auxiliary conveying mechanism, and can simultaneously convey the cleaned alkali-activated cementing material mixed solution to a plurality of detection stations to detect the contents of various chemical components in the alkali-activated cementing material mixed solution, thereby improving the detection efficiency.

Drawings

The invention is further described below with reference to the accompanying drawings.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the structure of the support frame of the present invention;

FIG. 3 is a schematic diagram of a scanning detection apparatus according to the present invention;

FIG. 4 is a schematic diagram of a screening apparatus according to the present invention;

FIG. 5 is a top view of the screening apparatus of the present invention;

FIG. 6 is a schematic view of a dissolution mixing apparatus according to the present invention;

FIG. 7 is a cross-sectional view of a mixing tank of the present invention;

FIG. 8 is a schematic diagram of the swing mechanism of the present invention;

FIG. 9 is a schematic view of a second conveyor apparatus according to the present invention;

FIG. 10 is a schematic view of a sliding mechanism according to the present invention;

fig. 11 is a schematic view of the structure of the auxiliary conveying mechanism of the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be understood that the terms "open," "upper," "lower," "thickness," "top," "middle," "length," "inner," "peripheral," and the like indicate orientation or positional relationships, merely for convenience in describing the present invention and to simplify the description, and do not indicate or imply that the components or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention.

As shown in fig. 1, a chemical component detection device for alkali-activated cementing materials comprises a support frame 1, wherein a scanning detection device 2 is arranged on the support frame 1, a screening device 3 is arranged on one side close to the scanning detection device 2, a dissolution mixing device 4 is arranged on the other side close to the scanning detection device 2, and a second conveying device 5 is arranged on the side of the dissolution mixing device 4.

As shown in fig. 2, the supporting frame 1 includes a supporting plate 11, a console 12 is disposed on the supporting plate 11, a first fixing plate 13 and a second fixing plate 14 are disposed on a side of the console 12, a third fixing plate 15 is disposed on the second fixing plate 14, a fourth fixing plate 16 is disposed on a side of the first fixing plate 13 and a side of the second fixing plate 14, a sliding groove 17 is disposed above the fourth fixing plate 16, and four fifth fixing plates 18 distributed in an array are disposed on a side of the fourth fixing plate 16.

The console 12 includes a supporting table 121, the supporting table 121 is disposed above the supporting plate 11, a controller 122 is disposed above the supporting table 121, a control button 123 is disposed beside the controller 122, and a display screen 124 is disposed above the control button 123.

As shown in fig. 3, the scanning detection device 2 includes two symmetrically distributed fixing frames 21, the two fixing frames 21 are fixed on the supporting plate 11, a group of supporting rods 22 which are distributed in an array are fixedly connected between the two fixing frames 21, two symmetrically distributed first conveying rollers 23 are arranged above the supporting rods 22, two ends of each first conveying roller 23 are respectively rotationally connected with the upper parts of the fixing frames 21, a first conveying belt 24 is sleeved on the surfaces of the two first conveying rollers 23, a partition plate 25 which is distributed in an array is arranged on the first conveying belt 24, detection equipment 26 is arranged above the first conveying belt 24, the detection equipment 26 is fixed at the top of the fixing frame 21, a first motor 27 is fixedly mounted on the fixing frame 21 positioned at one side, and an output shaft of the first motor 27 penetrates through the fixing frame 21 and is fixedly connected with one of the first conveying rollers 23.

As shown in fig. 4 and 5, the screening device 3 includes a fixed table 31, two mounting plates 32 symmetrically distributed are disposed above the fixed table 31, a second motor 33 is fixed on the mounting plate 32 far away from one side of the fixed frame 21, an output shaft of the second motor 33 penetrates through the mounting plate 32 to be fixed with a first ball screw 34, a material ejection rod 35 is slidably disposed on the first ball screw 34, two sliding rods 36 symmetrically distributed are mounted on two sides of the fixed table 31, supporting lugs 37 symmetrically distributed are disposed on two sides of the material ejection rod 35, and the supporting lugs 37 are slidably connected with the sliding rods 39.

When the device is used, the alkali-activated cementing material is placed between the two partition plates 25, the first motor 27 is operated to drive the first conveying roller 23 to rotate, alkali-activated cementing material starts to be conveyed, after the alkali-activated cementing material is detected by the detecting equipment 26, if the material contains pollutants, the result is fed back to the control console 12, the control console 12 controls the first motor 27 to convey the alkali-activated cementing material to the corresponding position of the screening device 3 through the controller 122, then the operation of the first motor 27 is stopped, the control console 12 controls the operation of the second motor 33 through the controller 122, the operation of the second motor 33 drives the first ball screw 34 to rotate, so that the ejector rod 35 is driven to slide along the sliding rod 39, and the alkali-activated cementing material containing the pollutants is ejected out of the equipment, and then the controller 122 controls the first motor 27 to continue to operate.

As shown in fig. 6 and 7, the dissolution mixing device 4 includes a mixing box 41, two side outer walls of the mixing box 41 are provided with symmetrically distributed rotating rods 42, two rotating rods 42 are respectively connected with a first fixing plate 13 and a second fixing plate 14 in a rotating way, a feeding port 43 is formed in the top of the mixing box 41, a box cover is arranged on the feeding port 43, a water outlet pipe 44 is arranged at the bottom of the mixing box 41, a third motor 45 is fixed on the outer wall of the top of the mixing box 41, an output shaft of the third motor 45 penetrates through the outer wall of the top of the mixing box 41 and is connected with a rotating connector 46, an array distributed stirring rod 47 is arranged below the rotating connector 46, a heater 48 is arranged at the bottom of the mixing box 41 and is communicated with the water outlet pipe 44, symmetrically distributed ultrasonic oscillators 49 are respectively fixed on two side inner walls of the mixing box 41, and a swinging mechanism 6 is arranged at the side of the second fixing plate 14.

As shown in fig. 8, the swing mechanism 6 includes a fourth motor 61, the fourth motor 61 is fixed on the fourth fixed plate 16, an output shaft of the fourth motor 61 is fixedly connected with a rotating plate 62, one side of the rotating plate 62 is provided with a swing rod 63, a side of the rotating plate 62 is provided with a swing plate 64, one side of the swing plate 64 is provided with a swing block 65, a swing groove 66 is formed in the swing block 65, the other side of the swing plate 64 is provided with a connecting rod 67, and the connecting rod 67 penetrates through the second fixed plate 14 and is fixedly connected with the rotating rod 42.

When the device is used, the screened alkali-activated cementing material is put into the mixing box 41 from the feed inlet, then the liquid is injected, the box cover is closed, the third motor 45, the ultrasonic oscillator 49 and the fourth motor 61 are respectively opened by using the control button 123, the third motor 45 operates to drive the rotary connector 46 to rotate, so that the stirring rod 47 is driven to rotate in the water box to stir the alkali-activated cementing material, meanwhile, the ultrasonic oscillator 49 is used for stirring and mixing the alkali-activated cementing material in a deeper layer based on alternating shock waves and cavitation generated by ultrasonic frequency vibration in the liquid, the fourth motor 61 rotates to drive the rotary plate 62 to rotate, so that the swinging rod 63 is driven to slide along the swinging groove 66, so that the swinging plate 64 is driven to swing up and down, the mixing box 41 is driven to swing through the connecting rod 67, the mixed alkali-activated cementing material in the mixing box 41 is thoroughly mixed, the water outlet pipe 44 is opened, and the mixed solution in the mixing box 41 is discharged into the container through the water outlet pipe 44 after the mixing is completed.

As shown in fig. 9, 10 and 11, the second conveying device includes a main conveying mechanism 51, a sliding mechanism 52 is disposed below the main conveying mechanism 51, and an auxiliary conveying mechanism 53 is disposed beside the sliding mechanism 52.

The main conveying mechanism 51 comprises a conveying frame 511, a fifth motor 512 is arranged on the outer wall of one side of the conveying frame 511, two second conveying rollers 513 distributed in an array are rotatably connected to the inner walls of two sides of the conveying frame 511, the output shafts of the fifth motor 512 penetrate through the outer wall of the conveying frame 511 and are fixedly connected with the second conveying rollers 513, a second conveying belt 514 is sleeved on the second conveying rollers 513, a supporting block 515 is arranged at one end of the conveying frame 511, and the supporting block 515 is arranged in the sliding groove 17 in a sliding mode.

The sliding mechanism 52 includes two sliding support frames 521 distributed in an array, the sliding support frames 521 are fixed on the supporting plate 11, a sixth motor 522 is disposed on the sliding support frame 521 at one side, an output shaft of the sixth motor 522 penetrates through the sliding support frames 521 and is fixedly connected with a second ball screw 523, two ends of the second ball screw 523 are rotatably connected with the sliding support frames 521, a sliding block 524 is disposed on the second ball screw 523, and the sliding block 524 is fixedly connected with the bottom of the conveying frame 511.

The auxiliary conveying mechanism 53 includes two symmetrically distributed rotating shafts 531 and a seventh motor 532, the rotating shafts 531 penetrate through the fifth fixing plate 18 and are rotationally connected with the fifth fixing plate 18, the seventh motor 532 is fixed on the fifth fixing plate 18 at the outermost side, the output shaft of the seventh motor 532 penetrates through the fifth fixing plate 18 and is fixedly connected with the rotating shafts 531, three third conveying rollers 533 distributed in an array are arranged on each rotating shaft 531, a third conveying roller 533 is arranged between every two fifth fixing plates 18, and a third conveying belt 534 is sleeved on each third conveying roller 533 between every two fifth fixing plates.

In use, the controller 122 sets the rotation speed, rotation direction and operation interval of the fifth motor 512, the sixth motor 522 and the seventh motor 532, the sealed container containing the alkali-activated cementing material mixed solution is placed on the second conveying belt 514, the fifth motor 512, the sixth motor 522 and the seventh motor 532 are started, the fifth motor 512 operates to drive the second conveying roller 513 to rotate, so as to drive the second conveying belt 514 to convey the alkali-activated cementing material, the sixth motor 522 performs periodical forward and reverse rotation to drive the second ball screw 523 to forward and reverse rotation, so as to drive the sliding block 524 to slide back and forth along the second ball screw 523, so as to drive the conveying frame 511 to slide back and forth along the sliding groove 17, the seventh motor 532 operates to drive the rotation shaft 531 to rotate, the rotation shaft 531 drives all the third conveying rollers 533 to rotate, all the third conveying belts 534 are driven to convey the alkali-activated cementing material solution, and when the conveying frame 511 is aligned with one of the third conveying belts 534, the alkali-activated cementing material falls onto the third conveying belts 534 is guaranteed through the set state of the controller 122, and one alkali-activated cementing material on the third conveying belts 534 is detected to flow to the third conveying belts 534.

A method of using a chemical composition detection device for alkali-activated gelling materials, the method comprising the steps of:

step one: the alkali-activated cementing material is screened out by the cooperation of a scanning detection device and a screening device, and the alkali-activated cementing material without pollutants is screened out;

step two: adding the alkali-activated cementing material without pollutants into a dissolving and mixing device to prepare a solution, and then filling the solution into a container for sealing;

step three: setting the rotation speed, the rotation direction and the running interval of the fifth motor, the sixth motor and the seventh motor through a control console;

step four: conveying the alkali-activated cementing material mixed solution to different detection procedures through a second conveying device;

step five: and detecting the contents of various chemical components in the alkali-activated cementing material mixed solution through different detection procedures.

Working principle: when the device is used, the scanning detection device 2 and the screening device 3 are matched to screen out the alkali-activated cementing material without pollutants, the dissolution mixing device 4 is used for stirring and mixing the screened alkali-activated cementing material to prepare a solution, then the solution is filled into a container for sealing, the second conveying device 5 is used for conveying the alkali-activated cementing material mixed solution to the next different working procedures, and the content of various chemical components in the alkali-activated cementing material mixed solution is detected through the different detection working procedures.

In the description of the present specification, the descriptions of the terms "one embodiment," "example," "specific example," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims.

Claims (8)

1. The chemical component detection device for the alkali-activated cementing material comprises a support frame (1), and is characterized in that a scanning detection device (2) is arranged on the support frame (1), a screening device (3) is arranged on one side close to the scanning detection device (2), a dissolution mixing device (4) is arranged on the other side close to the scanning detection device (2), and a second conveying device (5) is arranged on the side of the dissolution mixing device (4);

the support frame (1) comprises a support plate (11), a control console (12) is arranged on the support plate (11), a first fixing plate (13) and a second fixing plate (14) are arranged on the side of the control console (12), a third fixing plate (15) is arranged on the second fixing plate (14), a fourth fixing plate (16) is arranged on the side of the first fixing plate (13) and the side of the second fixing plate (14), a sliding groove (17) is formed in the upper portion of the fourth fixing plate (16), and four fifth fixing plates (18) distributed in an array are arranged on the side of the fourth fixing plate (16);

the scanning detection device (2) comprises two symmetrically distributed fixing frames (21), the two fixing frames (21) are fixed on a supporting plate (11), a group of supporting rods (22) which are distributed in an array are fixedly connected between the two fixing frames (21), two symmetrically distributed first conveying rollers (23) are arranged above the supporting rods (22), two ends of each first conveying roller (23) are respectively and rotatably connected with the upper parts of the fixing frames (21), first conveying belts (24) are sleeved on the surfaces of the two first conveying rollers (23), partition plates (25) which are distributed in an array are arranged on the first conveying belts (24), detection equipment (26) are arranged above the first conveying belts (24), the detection equipment (26) is fixed at the top of the fixing frames (21), a first motor (27) is fixedly installed on the fixing frame (21) on one side, and an output shaft of the first motor (27) penetrates through the fixing frame (21) to be fixedly connected with one of the first conveying rollers (23);

the second conveying device comprises a main conveying mechanism (51), a sliding mechanism (52) is arranged below the main conveying mechanism (51), and an auxiliary conveying mechanism (53) is arranged on the side of the sliding mechanism (52);

screening device (3) are including fixed station (31), and fixed station (31) top is equipped with two mounting panel (32) of symmetric distribution, is fixed with second motor (33) on mounting panel (32) of keeping away from mount (21) one side, and the output shaft of second motor (33) runs through mounting panel (32) and is fixed with first ball screw (34), and the slip is provided with liftout pole (35) on first ball screw (34), two slide bar (36) of symmetric distribution are installed to the both sides of fixed station (31), and the both sides of liftout pole (35) are equipped with supporting lug (37) of symmetric distribution, supporting lug (37) and slide bar (39) sliding connection.

2. The chemical component detection device for the alkali-activated cementing material according to claim 1, wherein the control console (12) comprises a supporting table (121), the supporting table (121) is arranged above the supporting plate (11), a controller (122) is arranged above the supporting table (121), a control button (123) is arranged on the side of the controller (122), and a display screen (124) is arranged above the control button (123).

3. The chemical component detection device for alkali-activated cementing materials according to claim 1, wherein the dissolution mixing device (4) comprises a mixing box (41), two side outer walls of the mixing box (41) are provided with symmetrically distributed rotating rods (42), the two rotating rods (42) are respectively connected with a first fixed plate (13) and a second fixed plate (14) in a rotating mode, a feeding hole (43) is formed in the top of the mixing box (41), a box cover is arranged on the feeding hole (43), a water outlet pipe (44) is arranged at the bottom of the mixing box (41), a third motor (45) is fixed on the outer wall of the top of the mixing box (41), an output shaft of the third motor (45) penetrates through the outer wall of the top of the mixing box (41) to be connected with a rotating connector (46), an array distributed stirring rod (47) is arranged below the rotating connector (46), a heater (48) is arranged at the bottom of the mixing box (41), the heater (48) is communicated with the water outlet pipe (44), symmetrically distributed ultrasonic oscillators (49) are respectively fixed on two side inner walls of the mixing box (41), and a swinging mechanism (6) is arranged on the side of the second fixed plate (14).

4. A chemical component detection device for alkali-activated cementing materials according to claim 3, wherein the swinging mechanism (6) comprises a fourth motor (61), the fourth motor (61) is fixed on a fourth fixed plate (16), an output shaft of the fourth motor (61) is fixedly connected with a rotating plate (62), one side of the rotating plate (62) is provided with a swinging rod (63), the side of the rotating plate (62) is provided with a swinging plate (64), one side of the swinging plate (64) is provided with a swinging block (65), a swinging groove (66) is formed in the swinging block (65), the other side of the swinging plate (64) is provided with a connecting rod (67), and the connecting rod (67) penetrates through the second fixed plate (14) and is fixedly connected with a rotating rod (42).

5. The chemical component detection device for the alkali-activated cementing material according to claim 1, wherein the main conveying mechanism (51) comprises a conveying frame (511), a fifth motor (512) is arranged on the outer wall of one side of the conveying frame (511), two second conveying rollers (513) distributed in an array are rotatably connected to the inner walls of two sides of the conveying frame (511), an output shaft of the fifth motor (512) penetrates through the outer wall of the conveying frame (511) and is fixedly connected with the second conveying rollers (513), a second conveying belt (514) is sleeved on the second conveying rollers (513), a supporting block (515) is arranged at one end of the conveying frame (511), and the supporting block (515) is slidably arranged in the sliding groove (17).

6. The chemical component detection device for the alkali-activated cementing material according to claim 1, wherein the sliding mechanism (52) comprises two sliding support frames (521) distributed in an array, the sliding support frames (521) are fixed on the supporting plate (11), a sixth motor (522) is arranged on the sliding support frame (521) positioned at one side, an output shaft of the sixth motor (522) penetrates through the sliding support frames (521) and is fixedly connected with a second ball screw (523), two ends of the second ball screw (523) are rotatably connected with the sliding support frames (521), sliding blocks (524) are arranged on the second ball screw (523), and the sliding blocks (524) are fixedly connected with the bottom of the conveying frame (511).

7. The chemical component detection device for the alkali-activated cementing material according to claim 1, wherein the auxiliary conveying mechanism (53) comprises two rotating shafts (531) and a seventh motor (532) which are symmetrically distributed, three third conveying rollers (533) which are distributed in an array are arranged on each rotating shaft (531), one third conveying roller (533) is arranged between every two fifth fixing plates (18), and a third conveying belt (534) is sleeved on each of the two third conveying rollers (533) between every two fifth fixing plates.

8. The chemical component detection device for alkali-activated gelling material according to claim 7, wherein the rotating shaft (531) penetrates through the fifth fixing plate (18) and is rotatably connected with the fifth fixing plate (18), the seventh motor (532) is fixed on the outermost fifth fixing plate (18), and the output shaft of the seventh motor (532) penetrates through the fifth fixing plate (18) and is fixedly connected with the rotating shaft (531).

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