CN111266040A - Reprocessing real-time detection prevents sediment device based on textile auxiliary material - Google Patents

Abstract

The invention provides a textile auxiliary material reprocessing real-time detection anti-sedimentation device, relates to the field of mixed anti-sedimentation devices, and solves the problems that the sedimentation state cannot be automatically detected, automatic diversified mixing is carried out to realize the anti-sedimentation of textile auxiliary materials, and the detachment and the cleaning of a diversified mixed structure are not convenient enough; the sample is convenient inadequately, and can not carry out the dismantlement of sample structure and the problem of maintaining at the hybrid process. A reprocessing real-time detection anti-sedimentation device based on textile auxiliary materials comprises a barrel body; six gas mixing structures are inserted in the top end surface of the barrel body in an annular array shape. When the sedimentation gravity reaches 0.5N/kg, the gravity sensor sends an electric signal to the microprocessor, the microprocessor sends a signal to the timer and the servo motor at the same time, the servo motor drives the rotating shaft to rotate at the moment, the timer starts timing for 3min, the timer sends a signal to the microprocessor to control the servo motor to stop rotating after 3min, and the steps are repeated so as to realize real-time sedimentation prevention.

Description

Reprocessing real-time detection prevents sediment device based on textile auxiliary material

Technical Field

The invention belongs to the technical field of mixed anti-precipitation devices, and particularly relates to a textile auxiliary material-based reprocessing real-time detection anti-precipitation device.

Background

In the process of stirring and mixing the textile auxiliary materials, the precipitation phenomenon is easy to generate due to low particle fusion welding degree. Based on the above, the mixing process of the textile auxiliary materials at present has the following defects: one is that the degree of automation is low, the precipitation state cannot be automatically detected, automatic diversified mixing is carried out to realize the precipitation prevention of the textile auxiliary, and the disassembly and the cleaning of a diversified mixing structure are not convenient enough; moreover, the sampling is not convenient enough, and the disassembly and maintenance of the sampling structure cannot be carried out in the mixing process.

Therefore, in view of the above, research and improvement are made for the existing structure and defects, and a real-time detection anti-settling device based on reprocessing of textile auxiliary materials is provided, so as to achieve the purpose of higher practical value.

Disclosure of Invention

In order to solve the technical problems, the invention provides a real-time detection anti-precipitation device based on reprocessing of textile auxiliary materials, which aims to solve the problems that the existing device has low automation degree, cannot automatically detect precipitation state, carries out automatic diversified mixing to realize anti-precipitation of the textile auxiliary, and is inconvenient to disassemble and clean a diversified mixed structure; moreover, the sample is convenient inadequately, and can not carry out the dismantlement of sample structure and the problem of maintaining in the mixing process.

The invention relates to a textile auxiliary material-based reprocessing real-time detection anti-precipitation device, which is realized by the following specific technical means:

a reprocessing real-time detection anti-sedimentation device based on textile auxiliary materials comprises a barrel body; six gas mixing structures are inserted into the top end surface of the barrel body in an annular array shape, and a servo motor is installed on the barrel body; an observation sampling structure is inserted on the barrel body, and a gravity sensor is arranged in the observation sampling structure; the observation sampling structure also comprises a connecting pipe, the connecting pipe is inserted on the barrel body through a quick connector, and the head end of the connecting pipe is contacted with the baffle; the head end of the connecting pipe is of an inclined structure, and when the connecting pipe and the quick connector are pushed to finish quick locking, the baffle is in an open state under the pushing of the connecting pipe, so that the baffle can be automatically opened and closed by inserting and pulling out the connecting pipe; the observation sampling structure further comprises a glass tube, a sampling hole A, a protective tube and a sampling hole B, wherein the glass tube is connected with the connecting tube, and the sampling hole A is formed in the glass tube; the protective pipe is sleeved on the glass pipe, a strip-shaped hole for observing the mixing condition is formed in the protective pipe, and a sampling hole B is formed in the protective pipe; when the protective tube is rotated to a certain degree, the sampling hole A and the sampling hole B are overlapped, and the protective tube forms a protective and sampling combined structure of the glass tube; the control box is fixedly connected with the upper end of the bolt, and a microprocessor and a timer are arranged in the control box.

Further, the barrel body comprises a barrel cover, a rotating shaft and a poke rod, the barrel body comprises a barrel cover fixedly connected with the top of the barrel cover through a bolt, and the barrel cover is rotatably connected with the rotating shaft; the rotating shaft is provided with stirring teeth and is fixedly connected with a poke rod through a bolt; the gas mixing structure comprises an air inlet pipe and a rubber balloon, the air inlet pipe is of a cylindrical tubular structure, the rubber balloon is installed at the top of the air inlet pipe, and when the poke rod rotates and is in contact with the rubber balloon, the poke rod is in an extrusion state of the rubber balloon.

Furthermore, the air inlet pipe comprises air outlet grooves, and six air outlet grooves are formed in the air inlet pipe in an annular array shape; the gas mixing structure also comprises six cleaning brushes, and the six cleaning brushes are welded on the inner wall of the barrel body in a rectangular array shape through connecting iron; the cleaning brush is sleeved inside the air inlet pipe and is close to the upper position, the connecting iron on the cleaning brush is matched with the width of the air outlet groove, and the cleaning brush forms a pull-out type cleaning structure of the air inlet pipe.

Furthermore, the intake pipe still includes connecting slot, intake pipe bottom face is located every the open end in groove of giving vent to anger has all seted up one connecting slot, just connecting slot is the V-arrangement structure.

Furthermore, the observation sampling structure comprises an inserting seat and a baffle plate, the inserting seat is welded on the inner wall of the barrel body, and the baffle plate is elastically connected in the inserting seat in a sliding manner through a sliding rod and an elastic piece; the bottom end face of the baffle is of an inclined structure, and the baffle is in a closed state when the elastic piece is elastically stretched.

Further, the microprocessor, the servo motor, the gravity sensor and the timer are electrically connected, when the precipitation gravity reaches 0.5N/kg, the gravity sensor sends an electric signal to the microprocessor, the microprocessor sends a signal to the timer and the servo motor at the same time, the servo motor drives the rotating shaft to rotate at the moment, the timer starts timing for 3min, and after 3min, the timer sends a signal to the microprocessor to control the servo motor to stop rotating.

Compared with the prior art, the invention has the following beneficial effects:

this device can realize that the periodic stirring of real-time detection mixes, has guaranteed mixed effect on the basis of saving the electric power cost, specifically as follows: when the sedimentation gravity reaches 0.5N/kg, the gravity sensor sends an electric signal to the microprocessor, the microprocessor sends a signal to the timer and the servo motor at the same time, the servo motor drives the rotating shaft to rotate at the moment, the timer starts timing for 3min, the timer sends a signal to the microprocessor to control the servo motor to stop rotating after 3min, and the steps are repeated so as to realize real-time sedimentation prevention.

Improved mixed structure, can realize gaseous supplementary the mixture through improving the back, and the installation of gaseous supplementary mixed structure is convenient with clean, specifically as follows: firstly, when the poke rod rotates and is in contact with the rubber balloon, the poke rod is in a squeezing state of the rubber balloon, so that gas can be discharged through the gas inlet pipe to be mixed with the gas; secondly, because of the pull-out type cleaning structure of the air inlet pipe is formed by the cleaning brush, the cleaning brush can automatically clean the air outlet groove when the air inlet pipe is upwards drawn out.

Through the arrangement of the observation sampling structure, the head end of the connecting pipe is of an inclined structure, and when the connecting pipe and the quick connector are pushed to finish quick locking, the baffle is in an open state under the pushing of the connecting pipe, so that the baffle can be automatically opened and closed through the insertion and the extraction of the connecting pipe; fourthly, because of the sampling hole A and the sampling hole B overlap after the protective tube degree is rotated, and the protective tube constitutes the protection and the sampling combined structure of the glass tube.

Drawings

Fig. 1 is a schematic axial view of the present invention.

Fig. 2 is a partial sectional structural schematic view of the present invention.

Fig. 3 is an enlarged schematic view of the structure at a of the present invention.

Fig. 4 is an enlarged schematic view of the invention at B.

FIG. 5 is a schematic view of a cross-sectional enlarged structure of the gas mixing structure of the present invention.

Fig. 6 is an enlarged view of the structure of fig. 5C according to the present invention.

FIG. 7 is an enlarged schematic axial view of the observation sampling structure of the present invention.

Fig. 8 is an enlarged view of fig. 7D according to the present invention.

Fig. 9 is a schematic diagram of the system structure of the invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a barrel body; 101. a barrel cover; 102. a rotating shaft; 103. a poke rod; 2. a gas mixing structure; 201. an air inlet pipe; 20101. an air outlet groove; 20102. a connecting clamping groove; 202. a rubber balloon; 203. a cleaning brush; 3. a servo motor; 4. observing the sampling structure; 401. a socket; 402. a baffle plate; 403. a connecting pipe; 404. a glass tube; 40401. sampling hole A; 405. a protective tube; 40501. a sampling hole B; 5. a control box; 6. a microprocessor; 7. a gravity sensor; 8. a timer.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 9:

the invention provides a reprocessing real-time detection anti-precipitation device based on textile auxiliary materials, which comprises a barrel body 1; six gas mixing structures 2 are inserted into the top end surface of the barrel body 1 in an annular array shape, and a servo motor 3 is installed on the barrel body 1; an observation sampling structure 4 is inserted on the barrel body 1, and a gravity sensor 7 is arranged in the observation sampling structure 4; referring to fig. 3 and 7, the observation sampling structure 4 further includes a connection pipe 403, the connection pipe 403 is inserted into the barrel 1 through a quick coupling, and a head end of the connection pipe 403 contacts the baffle 402; the head end of the connecting pipe 403 is an inclined structure, and when the connecting pipe 403 and the quick coupling are pushed to complete quick locking, the baffle 402 is in an open state under the pushing of the connecting pipe 403, so that the baffle 402 can be automatically opened and closed by plugging and pulling out the connecting pipe 403; referring to fig. 7, the observation and sampling structure 4 further includes a glass tube 404, a sampling hole a40401, a protection tube 405, and a sampling hole B40501, the glass tube 404 is connected to the connection tube 403, and the glass tube 404 is provided with a sampling hole a 40401; the protective tube 405 is sleeved on the glass tube 404, a strip-shaped hole for observing the mixing condition is formed in the protective tube 405, and a sampling hole B40501 is formed in the protective tube 405; when the protective tube is rotated by 40590 degrees, the sampling hole A40401 and the sampling hole B40501 are overlapped, and the protective tube 405 forms a protective and sampling combined structure of the glass tube 404; the upper part is fixedly connected with a control box 5 through a bolt, and a microprocessor 6 and a timer 8 are arranged in the control box 5. Microprocessor model: 80C51 is a general type; the timer model: li phoenix; the gravity sensor model: QS/QS-A.

Referring to fig. 2 and 4, the barrel body 1 comprises a barrel cover 101, a rotating shaft 102 and a poke rod 103, the barrel body 1 comprises a barrel cover 101 fixedly connected with the top of the barrel cover 101 through bolts, and the rotating shaft 102 is rotatably connected to the barrel cover 101; the rotating shaft 102 is provided with stirring teeth, and the rotating shaft 102 is also fixedly connected with a poke rod 103 through a bolt; the gas mixing structure 2 comprises a gas inlet pipe 201 and a rubber balloon 202, the gas inlet pipe 201 is of a cylindrical tubular structure, the rubber balloon 202 is mounted at the top of the gas inlet pipe 201, when the poke rod 103 rotates and is in contact with the rubber balloon 202, the poke rod is in a squeezing state of the rubber balloon 202, and therefore gas can be discharged through the gas inlet pipe 201 to be mixed.

Referring to fig. 5, the air inlet pipe 201 includes air outlet grooves 20101, and six air outlet grooves 20101 are formed in the air inlet pipe 201 in an annular array; the gas mixing structure 2 further comprises six cleaning brushes 203, the six cleaning brushes 203 are arranged, and the six cleaning brushes 203 are welded on the inner wall of the barrel body 1 in a rectangular array shape through connecting iron; the cleaning brush 203 is sleeved inside the air inlet pipe 201 and is close to the upper position, the connecting iron on the cleaning brush 203 is matched with the width of the air outlet groove 20101, the cleaning brush 203 forms a pull-out type cleaning structure of the air inlet pipe 201, and therefore the cleaning brush 203 can automatically clean the air outlet groove 20101 when the air inlet pipe 201 is pulled out upwards.

Referring to fig. 6, the air inlet pipe 201 further includes a connecting slot 20102, the bottom end surface of the air inlet pipe 201 is provided with a connecting slot 20102 at the opening end of each air outlet groove 20101, and the connecting slot 20102 is of a V-shaped structure, so that smoothness of insertion between the air outlet grooves 20101 and connecting irons on the cleaning brush 203 can be improved.

Referring to fig. 3, the observation sampling structure 4 includes a socket 401 and a baffle 402, the socket 401 is welded on the inner wall of the barrel 1, and the baffle 402 is elastically connected in the socket 401 through a sliding rod and an elastic member; the bottom end face of the flap 402 is of a sloped configuration and the flap 402 is in a closed position when the resilient member is resiliently extended.

Referring to fig. 9, the microprocessor 6, the servo motor 3, the gravity sensor 7 and the timer 8 are electrically connected, when the precipitation gravity reaches 0.5N/kg, the gravity sensor 7 sends an electric signal to the microprocessor 6, at this time, the microprocessor 6 sends a signal to the timer 8 and the servo motor 3 at the same time, at this time, the servo motor 3 drives the rotating shaft 102 to rotate, the timer 8 starts to time for 3min, and after 3min, the timer 8 sends a signal to the microprocessor 6, and the microprocessor 6 controls the servo motor 3 to stop rotating.

The specific use mode and function of the embodiment are as follows:

when the device is used, when the precipitation gravity reaches 0.5N/kg, the gravity sensor 7 sends an electric signal to the microprocessor 6, the microprocessor 6 sends a signal to the timer 8 and the servo motor 3 at the same time, the servo motor 3 drives the rotating shaft 102 to rotate at the moment, the timer 8 starts to time for 3min, after 3min, the timer 8 sends a signal to the microprocessor 6, the microprocessor 6 controls the servo motor 3 to stop rotating, and the steps are repeated so as to realize real-time precipitation prevention;

during the use process, firstly, when the poke rod 103 rotates and contacts with the rubber balloon 202, the rubber balloon 202 is in a squeezing state, so that the gas can be discharged through the gas inlet pipe 201 to be mixed with the gas; secondly, the cleaning brush 203 forms a drawing type cleaning structure of the air inlet pipe 201, so that the cleaning brush 203 can automatically clean the air outlet groove 20101 when the air inlet pipe 201 is drawn upwards; thirdly, because the head end of the connecting pipe 403 is an inclined structure, and when the connecting pipe 403 and the quick coupling are pushed to complete quick locking, the baffle 402 is in an open state under the pushing of the connecting pipe 403, so that the baffle 402 can be automatically opened and closed by plugging and pulling out the connecting pipe 403; fourthly, because of the sampling hole A40401 and the sampling hole B40501 overlap after rotating the protective tube 40590 degree, and the protective tube 405 constitutes the protection and the sampling combined structure of the glass tube 404.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (6)

1. The utility model provides a reprocessing real-time detection prevents deposiing device based on textile auxiliary material which characterized in that: comprises a barrel body (1); six gas mixing structures (2) are inserted into the top end surface of the barrel body (1) in an annular array shape, and a servo motor (3) is installed on the barrel body (1); an observation sampling structure (4) is inserted on the barrel body (1), and a gravity sensor (7) is arranged in the observation sampling structure (4); the observation sampling structure (4) further comprises a connecting pipe (403), the connecting pipe (403) is inserted into the barrel body (1) through a quick connector, and the head end of the connecting pipe (403) is in contact with the baffle (402); the head end of the connecting pipe (403) is of an inclined structure, and when the connecting pipe (403) and the quick connector are pushed to finish quick locking, the baffle (402) is in an open state under the pushing of the connecting pipe (403); the observation sampling structure (4) further comprises a glass tube (404), a sampling hole A (40401), a protective tube (405) and a sampling hole B (40501), the glass tube (404) is connected with the connecting tube (403), and the sampling hole A (40401) is formed in the glass tube (404); the protective tube (405) is sleeved on the glass tube (404), a strip-shaped hole for observing the mixed condition is formed in the protective tube (405), and a sampling hole B (40501) is formed in the protective tube (405); when the protective tube (405) is rotated for 90 degrees, the sampling hole A (40401) and the sampling hole B (40501) are overlapped, and the protective tube (405) forms a protective and sampling combined structure of the glass tube (404); go up through bolt fixedly connected with control box (5), and be provided with microprocessor (6) and time-recorder (8) in control box (5).

2. The textile auxiliary material-based reprocessing real-time detection anti-precipitation device according to claim 1, wherein: the barrel body (1) comprises a barrel cover (101), a rotating shaft (102) and a poke rod (103), the barrel cover (101) is fixedly connected to the top of the barrel cover (101) through a bolt, and the rotating shaft (102) is rotatably connected to the barrel cover (101); the rotating shaft (102) is provided with stirring teeth, and the rotating shaft (102) is also fixedly connected with a poke rod (103) through a bolt; gas hybrid structure (2) include intake pipe (201) and rubber balloon (202), intake pipe (201) are the cylinder tubular structure, and rubber balloon (202) are installed at intake pipe (201) top, work as poker rod (103) rotate and when contacting with rubber balloon (202), be the extrusion state of rubber balloon (202) this moment.

3. The textile auxiliary material-based reprocessing real-time detection anti-precipitation device according to claim 2, wherein: the air inlet pipe (201) comprises air outlet grooves (20101), and six air outlet grooves (20101) are formed in the air inlet pipe (201) in an annular array shape; the gas mixing structure (2) further comprises six cleaning brushes (203), and the six cleaning brushes (203) are welded on the inner wall of the barrel body (1) in a rectangular array shape through connecting iron; the cleaning brush (203) is sleeved inside the air inlet pipe (201) and is close to the upper position, the connecting iron on the cleaning brush (203) is matched with the width of the air outlet groove (20101), and the cleaning brush (203) forms a pull-out cleaning structure of the air inlet pipe (201).

4. The textile auxiliary material-based reprocessing real-time detection anti-precipitation device according to claim 2, wherein: the air inlet pipe (201) further comprises a connecting clamping groove (20102), one connecting clamping groove (20102) is formed in the bottom end face of the air inlet pipe (201) and located at the opening end of each air outlet groove (20101), and the connecting clamping groove (20102) is of a V-shaped structure.

5. The textile auxiliary material-based reprocessing real-time detection anti-precipitation device according to claim 1, wherein: the observation sampling structure (4) comprises a plug socket (401) and a baffle (402), the plug socket (401) is welded on the inner wall of the barrel body (1), and the baffle (402) is elastically connected in the plug socket (401) in a sliding manner through a sliding rod and an elastic piece; the bottom end face of the baffle plate (402) is of a tilting structure, and the baffle plate (402) is in a closed state when the elastic member is elastically stretched.

6. The textile auxiliary material-based reprocessing real-time detection anti-precipitation device according to claim 1, wherein: microprocessor (6), servo motor (3), gravity inductor (7) all link to each other with time-recorder (8) electrical property, gravity inductor (7) send the signal of telecommunication to microprocessor (6) when depositing gravity and reaching 0.5N kg, microprocessor (6) send signal to time-recorder (8) and servo motor (3) simultaneously this moment, servo motor (3) drive pivot (102) and rotate this moment, and time-recorder (8) begin timing 3min, 3min back time-recorder (8) send signal to microprocessor (6) control servo motor (3) stall.

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