CN116135749B - Food additive monoglyceride production line sampling detection device - Google Patents

Abstract

The utility model relates to the technical field of product detection, in particular to a sampling detection device for a food additive monoglyceride production line, which comprises a conveying mechanism, a feeding mechanism and a shifting mechanism, wherein the conveying mechanism comprises a conveying platform, a conveying belt and a plurality of conveying rollers which are equidistantly arranged in the conveying platform along the length direction of the conveying platform, one side of the conveying platform is connected with a sampling detection conveying platform communicated with the conveying platform, the feeding mechanism is arranged on one side of the conveying platform, one side of the feeding mechanism is also provided with a control terminal, the shifting mechanism comprises four shifting rods which are equal in length and coaxially rotate, the shifting rods are positioned below the conveying rollers, and one side of one shifting rod is also connected with a driven wheel. Compared with the prior art, the sampling frequency of the product can be changed according to the sampling result, and the phenomenon that the product put in midway collides with the product on the original conveying line can be avoided.

Description

Food additive monoglyceride production line sampling detection device

Technical Field

The utility model relates to the technical field of product detection, in particular to a sampling detection device for a food additive monoglyceride production line.

Background

Monoglycerides, i.e., fatty acid monoglycerides, are an important class of nonionic surfactants. It contains a lipophilic long-chain alkyl group and two hydrophilic hydroxyl groups, so that it has good surface activity, and can be used as emulsifying agent in the fields of food, cosmetics and medicine, etc..

Both the chinese patent of publication No. CN110542743a and the chinese patent of publication No. CN216449186U disclose a sampling detection device for a food additive production line, and both of them are designed to solve the technical problem of manual intervention in the sampling detection process, but in addition, care should be taken in the sampling detection process because the sampling detection has randomness, all the problems may not necessarily be found, but if the problems are found in the sampling process, whether the sampling frequency needs to be widened to detect whether the problems exist in a large batch.

In addition, the production line of monoglyceride as a food additive includes a series of operations such as quantifying, filling, weighing, adjusting and conveying, and generally, the packaging of monoglyceride is packaged in bags and then conveyed to a subsequent detection station by a conveyor belt device, however, during the conveying process, some bagged monoglyceride is vertical, some of the bagged monoglyceride lies horizontally, which is unfavorable for the subsequent production process, and after sampling detection, the monoglyceride may collide with the subsequently conveyed monoglyceride when the monoglyceride is replaced on the conveying line, so that it is also needed to solve the problem.

Therefore, it is necessary to provide a sampling and detecting device for a food additive monoglyceride production line to solve the above-mentioned technical problems.

Disclosure of Invention

The utility model aims to provide a sampling detection device for a food additive monoglyceride production line, which aims to solve the problems in the background technology.

In order to solve the technical problems, the utility model provides the following technical scheme:

the sampling detection device comprises a conveying mechanism, a feeding mechanism and a shifting mechanism, wherein the conveying mechanism comprises a conveying platform, a conveying belt and a plurality of conveying rollers which are equidistantly arranged in the conveying platform along the length direction of the conveying platform, one side of the conveying platform is connected with a sampling detection conveying platform communicated with the conveying platform, the feeding mechanism is arranged on one side of the conveying platform, and one side of the feeding mechanism is also provided with a control terminal;

the conveying mechanism comprises four conveying rods which are equal in length and coaxially rotate, the conveying rods are located below the conveying rollers, one side of each conveying rod is further connected with a driven wheel, a transmission box is mounted on the bottom wall of the conveying platform below the conveying mechanism, driving wheels and output wheels are arranged in the transmission box, the driving wheels are connected with the output wheels through first crawler belts, the driving wheels are further connected with the driven wheels through second crawler belts, a plurality of adjusting plates are arranged on the output wheels, one side of each adjusting plate is provided with a driving assembly in the output wheel, the first crawler belt is mounted on each adjusting plate, and one side of the output wheels is further provided with a movable auxiliary component along the inner wall of one side of the transmission box.

In one embodiment, the feeding mechanism is a round table, a plurality of placement areas are formed above the feeding mechanism, a pushing plate is arranged in each placement area, and one side of the pushing plate is connected with a linear motor.

In one embodiment, the upper side both sides of conveyer belt all are provided with spacing, one side of spacing is provided with the baffle, the baffle pass through the hub connection rotate set up in between the inner wall of conveying platform, just the baffle is located all the time the outside of spacing, the below of spacing is in install the adjustment mechanism who is connected with it on conveying platform's the diapire.

In one embodiment, the adjustment mechanism comprises a fixed frame, two sliding rods and a movable rod of a U-shaped structure, a rotating piece is arranged in the middle of the fixed frame in a rotating mode, two ends of the rotating piece are connected with connecting handles through shafts, the two sliding rods are symmetrically distributed on two sides of the rotating piece and are arranged in a sliding mode along the inner wall of the fixed frame, the other end of each connecting handle is connected with the sliding rod located on the same side through a shaft, and the movable rod located on the same side is fixed with the sliding rod through welding.

In one embodiment, a feeding hole and a discharging hole are formed in one side wall of the conveying platform, the feeding hole and the discharging hole are respectively located at two ends of the sampling inspection conveying platform, an infrared sensor group is further embedded in the sampling inspection conveying platform at a position close to the discharging hole, and the infrared sensor group comprises an infrared emitter and an infrared receiver.

In one embodiment, the notch is formed in the opposite position of the discharge hole on the conveying platform, a baffle is elastically arranged on the side wall of the conveying platform on one side of the notch, an adjusting plate is further arranged on the conveying platform, a first sliding bolt is embedded in the middle of one end of the adjusting plate, a first rotating handle is arranged on one side of the first sliding bolt and is arranged in a sliding mode along the length direction of the first rotating handle, the first rotating handle is rotatably arranged on one side of the conveying platform through shaft connection, a second rotating handle is rotatably arranged in the side wall of the other side of the conveying platform, an electric push rod is further arranged in the second rotating handle, and the output end of the first electric push rod is connected to the adjusting plate.

In one embodiment, when the adjusting plate is parallel to the length direction of the conveying platform, the baffle is located at the highest position, when the adjusting plate is perpendicular to the length direction of the conveying platform, the baffle is located at the lowest position, and the baffle can be in abutting contact with one side surface of the adjusting plate.

In one embodiment, the shifting mechanism further comprises two fixing plates and a penetrating shaft, the fixing plates are fixed between the side walls of the conveying platform through screws, the penetrating shaft penetrates through the four shifting rods and is adhered to the four shifting rods into a whole, one end of the penetrating shaft rotates in one fixing plate, and the driven wheel is mounted on the other end of the penetrating shaft.

In one embodiment, the auxiliary moving component comprises a sliding block and a second electric push rod, a groove is formed in the inner wall of one side of the transmission case, the sliding block slides between the inner walls of the groove, the second electric push rod is also installed in the transmission case, the output end of the second electric push rod is fixedly bonded with the side wall of the sliding block, a first rotating motor is installed on one side of the sliding block through a screw, the end part of an output shaft of the first rotating motor is fixedly connected with the side wall of the output wheel, a rotating shaft is arranged in the output wheel in a rotating mode, and a second rotating motor connected with the rotating shaft is fixedly arranged on the side wall of the other side of the output wheel through a screw.

In one embodiment, the driving assembly comprises a driving handle, a linkage handle and a connecting shaft, wherein the driving handle, the linkage handle and the connecting shaft are arranged in equal quantity with the adjusting piece, one end of the driving handle is fixedly welded on the outer surface of the rotating shaft, one end of the connecting shaft is fixedly welded on the side wall of the adjusting piece, the connecting shaft is fixedly connected with the output wheel through electromagnetic adsorption, one end of the linkage handle is movably arranged with the other end of the connecting shaft through shaft connection, and a sliding bolt II is embedded on the other end of the linkage handle and slides between the inner walls of the driving handle.

Compared with the prior art, the utility model has the following beneficial effects:

1. in the utility model, the shifting mechanism is arranged below the conveying roller, and the rotation rate of the driving wheel is controlled by utilizing the change of the transmission ratio between the output wheel and the driving wheel, so that the shifting mechanism connected with the driven wheel can change the frequency of shifting the upper sampling detection conveying platform of the monoglyceride, thereby improving the sampling frequency and expanding the sampling range.

2. According to the utility model, the adjusting plate is arranged at one side of the outlet of the sampling inspection conveying platform, and is controlled to be switched and adjusted in the horizontal direction and the vertical direction by utilizing the cooperation of the first rotating handle, the second rotating handle and the first sliding bolt, when the adjusting plate is positioned in the horizontal direction, the placing state of the monoglyceride packaging bag on the conveying line can be adjusted to be uniformly and horizontally laid, and when the adjusting plate is positioned in the vertical direction, the monoglyceride packaging bag on the conveying line can be blocked, so that the problems of collision with sampling inspection samples sent out from the sampling inspection conveying platform and the like are prevented.

Drawings

Technical solutions and other advantageous effects of the present application will be made apparent from the following detailed description of specific embodiments of the present application with reference to the accompanying drawings.

In the drawings:

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

FIG. 2 is a schematic front view of FIG. 1;

FIG. 3 is a schematic top view of FIG. 1;

FIG. 4 is a schematic bottom view of FIG. 1;

FIG. 5 is a schematic view of a transfer roll connection of the present utility model;

FIG. 6 is a schematic illustration of the connection between the adjustment plate, first and second handles of the present utility model;

FIG. 7 is a schematic diagram of the connection of the second handle to the first electric putter of the present utility model;

FIG. 8 is a schematic illustration of the installation of the indexing mechanism of the present utility model;

FIG. 9 is a schematic illustration of the connections between the present utility model's indexing mechanism, driven wheel, drive wheel and output wheel;

FIG. 10 is a schematic view of the installation of the drive wheel, output wheel and slider of the present utility model;

fig. 11 is a schematic view of the tab adjustment of the present utility model.

In the figure:

1. a control terminal;

2. round bench; 21. a push plate;

3. a conveying platform; 31. a conveyor belt; 32. a limit bar; 33. a spot check conveying platform; 331. an infrared sensor group; 34. a baffle; 35. a guide groove; 36. a conveying roller; 37. a guide plate;

4. a movable rod;

5. a fixed frame; 51. a rotating member; 52. a slide bar; 53. a connecting handle;

6. an adjusting plate; 61. a rotating handle I; 611. a movable groove; 612. a sliding bolt I; 62. a second rotating handle; 621. an electric push rod I;

7. a shifting rod; 71. a fixing plate; 72. a through shaft; 73. driven wheel;

8. a transmission case; 81. a driving wheel; 82. an output wheel; 821. a regulating piece; 822. a rotation shaft; 823. a drive handle; 824. a linkage handle; 825. a connecting shaft; 826. a shaft sleeve; 827. a built-in power supply; 828. a sliding bolt II; 83. a slide block; 84. an electric push rod II; 85. a groove.

Detailed Description

The following disclosure provides many different embodiments or examples for implementing different structures of the present application. In order to simplify the disclosure of the present application, the components and arrangements of specific examples are described below. Of course, they are merely examples and are not intended to limit the present application. Furthermore, the present application may repeat reference numerals and/or letters in the various examples, which are for the purpose of brevity and clarity, and which do not in themselves indicate the relationship between the various embodiments and/or arrangements discussed. In addition, the present application provides examples of various specific processes and materials, but one of ordinary skill in the art may recognize the application of other processes and/or the use of other materials.

In embodiment 1, please refer to fig. 1-5 and fig. 8-11, the present utility model provides the following technical solutions: the utility model provides a food additive monoglyceride production line sampling detection device, includes conveying mechanism, feeding mechanism and thumb feed mechanism, and conveying mechanism includes conveying platform 3, is provided with conveyer belt 31 and a plurality of equidistant conveying roller 36 that set up along its length direction in the conveying platform 3, is connected with the hold-in range between the adjacent conveying roller 36, and wherein, the driving motor of conveying roller 36 is not shown;

the feeding mechanism is a round table 2, which is arranged on one side of a conveying platform 3, one side of the feeding mechanism is also provided with a control terminal 1, the control terminal 1 is connected with the feeding mechanism, the conveying mechanism and a spot check conveying platform 33 through electric wires, so that the control operation on the three and upper parts of the feeding mechanism can be realized on the control terminal 1, a rotary table is rotatably arranged on the top of the round table 2, a partition plate is fixed on the rotary table through screws, the upper area of the rotary table is divided into a plurality of placement areas, a push plate 21 is arranged in each placement area, one side of the push plate 21 is connected with a linear motor, the linear motor is fixed on the side wall of the partition plate through screws, and a rotary motor IV connected with the rotary table is arranged at the bottom of the round table 2 through bolts;

the sampling inspection conveying platform 33 communicated with the conveying platform 3 is connected to one side of the conveying platform 3, the sampling inspection conveying platform 33 is arranged in an arc structure, a conveying belt is arranged on the sampling inspection conveying platform 33, a driving motor of the conveying belt is not shown, a feeding hole and a discharging hole are formed in the side wall of one side of the conveying platform 3, the feeding hole and the discharging hole are respectively arranged at two ends of the sampling inspection conveying platform 33, a product is fed into the sampling inspection conveying platform 33 from the feeding hole by a shifting mechanism during sampling inspection, then a sampling inspection person takes off the product from the sampling inspection conveying platform 33 for inspection, the product is returned to the sampling inspection conveying platform 33 after the inspection is finished, and finally is fed back to the conveying platform 3 from the discharging hole, an infrared sensor group 331 is embedded in the sampling inspection conveying platform 33 at a position close to the discharging hole, the infrared sensor group 331 comprises an infrared emitter and an infrared receiver, when the product passes through the middle area of the infrared sensor group 331, the signal of the product is interrupted, and at the moment, the adjusting plate 6 starts to adjust the position, otherwise, the adjusting plate 6 is not changed and is always arranged at the horizontal position;

the shifting mechanism comprises four shifting rods 7 which are equal in length and coaxially rotate, two fixing plates 71 and a penetrating shaft 72, wherein the shifting rods 7 are positioned below the conveying rollers 36, the four shifting rods 7 are respectively moved in gaps between the two adjacent conveying rollers 36 (as shown in fig. 3), the fixing plates 71 are fixed between the side walls of the conveying platform 3 through screws, the penetrating shaft 72 penetrates through the four shifting rods 7 and is adhered to the four shifting rods into a whole, one end of the penetrating shaft 72 rotates in one fixing plate 71, a driven wheel 73 is arranged on the other end of the penetrating shaft 72, the penetrating shaft 72 is driven to rotate by the rotation of the driven wheel 73, and the shifting rods 7 are synchronously driven to rotate and adjust within a 90-degree range;

the lower part of the shifting mechanism is provided with a transmission box 8 on the bottom wall of the conveying platform 3 through screws, the transmission box 8 is internally provided with a driving wheel 81 and an output wheel 82, the driving wheel 81 and the output wheel 82 are connected and arranged through a crawler, the crawler I is arranged on an adjusting plate 821, the driving wheel 81 is also connected and arranged with the driven wheel 73 through a crawler II, the output wheel 82 is provided with a plurality of adjusting plates 821, the actual output diameter of the output wheel 82 is changed through the position change of the adjusting plates 821, the transmission ratio between the output wheel 82 and the driving wheel 81 is changed, one side of the adjusting plates 821 is provided with a driving component in the output wheel 82, the driving component comprises a driving handle 823 which is arranged in the same amount as the adjusting plates 821, a linkage handle 824 and a connecting shaft 825 made of iron, one end of the driving handle 823 is fixedly welded on the outer surface of the rotating shaft 822, one end of the connecting shaft 825 is fixedly welded with the side wall of the adjusting plates 821, the connecting shaft 825 is fixed with the output wheel 82 through electromagnetic adsorption, a plurality of through holes are formed in the output wheel 82, a shaft sleeve 826 made of silicon steel sheets is fixedly embedded in the through holes, the connecting shaft 825 penetrates through the shaft sleeve 826 to be movably arranged, three built-in power supplies 827 are arranged on the inner wall of the output wheel 82, each built-in power supply 827 is respectively connected with the shaft sleeve 826 on two sides of the connecting shaft 825 through wires, the built-in power supply 827 is started through the control terminal 1 and then the shaft sleeve 826 is electrified, so that strong suction is generated to attract the iron connecting shaft 825, the fixing of the adjusting plate 821 is realized, one end of the linkage handle 824 is movably arranged with the other end of the connecting shaft 825 through shaft connection, a sliding bolt II 828 is embedded on the other end of the linkage handle 824, a sliding hole is formed in the driving handle 823, and the sliding bolt II 828 slides between the inner walls of the sliding hole;

one side of the output wheel 82 is further provided with a movement auxiliary component along one side inner wall of the transmission case 8, the movement auxiliary component comprises a sliding block 83 and a second electric push rod 84, a groove 85 is formed in one side inner wall of the transmission case 8, the sliding block 83 slides between the inner walls of the groove 85, the second electric push rod 84 is also installed in the transmission case 8, the output end of the second electric push rod is fixedly adhered to the side wall of the sliding block 83, one side of the sliding block 83 is provided with a first rotating motor through a screw, the end part of an output shaft of the first rotating motor is fixed with the side wall of the output wheel 82, a rotating shaft 822 is arranged in the output wheel 82 in a rotating mode, and a second rotating motor connected with the rotating shaft 822 is fixed on the other side wall of the output wheel 82 through a screw.

In this embodiment, a torsion spring is mounted on the shaft rotating between the guide plate 37 and the conveying platform 3, so that the guide plate can automatically reset, but the rotation direction of the guide plate 37 is always positioned in the conveying platform 3 and cannot be turned to the outside; the angle of each rotation of the rotating motor is (360/the number of the placement areas) degrees, and after each rotation of the angle, the central axis of the placement area is collinear with the central axis of the conveying platform 3 along the length of the conveying platform, and the conveying platform can be suspended for 3 seconds; the diameter of the driving wheel 81 is equal to that of the driven wheel 73, and the effective output diameter of the output wheel 82 is always larger than that of the driving wheel 81;

working principle: the staff places the packaged products in the placing area one by one, the push plate 21 pushes the products onto the conveying belt 31 after rotating the rotary table, the products are conveyed onto the conveying roller 36 along the conveying belt 31, under normal conditions, the products are always conveyed forward along the conveying roller 36, in the process of sampling inspection, some of the conveyed products are pushed onto the sampling inspection conveying platform 33 by the shifting mechanism for sampling inspection, after sampling inspection, the staff repacks the sampling inspected products and returns the products to the sampling inspection conveying platform 33, so that the products are conveyed back onto the conveying platform 3 from the discharge hole and are conveyed forward along with the conveying roller 36;

during spot inspection, the shifting mechanism swings back and forth by 90 degrees and rotates to the vertical position from the horizontal position, so that a product is pushed onto the spot inspection conveying platform 33 and then is reset to the horizontal position, and the circulating action is specifically as follows: the rotary motor drives the output wheel 82 to rotate, so that the driving wheel 81 is synchronously driven to rotate through the first crawler belt, the driving wheel 81 synchronously drives the driven wheel 73 to rotate and adjust under the action of the second crawler belt, and then the driving wheel 81 drives the shifting mechanism to swing and rotate, under the condition that normal spot inspection is free of problems, the regulating piece 821 is positioned at the position closest to the outer surface of the output wheel 82 (namely, the regulating piece 821 is contacted with the output wheel 82), at the moment, the rotating speeds of the driving wheel 81 and the driven wheel 73 are equal and are the minimum rotating speeds, namely, the shifting frequency of the shifting mechanism is the minimum, when the spot inspection is problematic, the spot inspection range needs to be enlarged, namely, the position of the regulating piece 821 needs to be adjusted to the position farthest from the outer surface of the output wheel 82, at the moment, the rotating speeds of the driving wheel 81 and the driven wheel 73 are the maximum, namely, the shifting frequency of the shifting mechanism is the highest, and therefore more products can be inspected in a unit time;

the adjustment process of the adjusting piece 821 is specifically as follows: the rotating motor I is suspended, the output wheel 82 stops rotating, the power supply of the built-in power supply 827 is cut off, suction does not exist between the shaft sleeve 826 and the connecting shaft 825 any more, then the rotating motor II is started, the rotating shaft 822 rotates along with the rotating shaft, the driving handle 823 rotates synchronously, when the driving handle 823 rotates, the sliding bolt II 828 slides along the inner wall of the sliding hole and drives the linkage handle 824 to move, the connecting shaft 825 is controlled to do linear motion in the length direction of the connecting shaft and drive the adjusting piece 821 to move, when the sliding bolt II 828 slides to the innermost end of the sliding hole (namely the position closest to the rotating shaft 822), the central axes of the driving handle 823, the linkage handle 824 and the connecting shaft 825 at this time are all collinear, the distance between the adjusting piece 821 and the output wheel 82 is the farthest, otherwise, when the sliding bolt II 828 slides to the outermost end of the sliding hole (namely the position farthest from the rotating shaft 822), the adjusting piece 821 contacts with the outer surface of the output wheel 82 at this time; in addition, when the adjusting piece 821 adjusts the position, the second electric push rod 84 also synchronously starts the position of the adjusting slide block 83, and when the adjusting piece 821 moves to the side far away from the output wheel 82, the output shaft of the second electric push rod 84 stretches out to the longest speed, the slide block 83 moves to one end of the groove 85 (as shown in fig. 10), otherwise, the second electric push rod 84 drives the slide block 83 to move to the other end of the groove 85, so as to match with the change of the transmission ratio of the first crawler belt, and avoid the falling of the first crawler belt.

In embodiment 2, referring to fig. 1 to 7, the present utility model further provides the following technical solutions: a notch is formed in a position, opposite to a discharge hole, of a conveying platform 3, two symmetrically distributed guide grooves 35 are formed in the side wall of the conveying platform 3 on one side of the notch, springs are welded to the bottom ends of the guide grooves 35, elastic blocks (not shown in the drawing) are arranged on the tops of the springs in a sliding mode between the inner walls of the guide grooves 35, the elastic blocks are fixedly welded to a baffle 34, elastic movement of the baffle 34 is controlled through elastic action of the elastic blocks by the springs, an adjusting plate 6 is further arranged on the conveying platform 3, a sliding bolt one 612 is embedded in the middle of one end of the adjusting plate 6, a rotating handle one 61 is arranged on one side of the sliding bolt one 612, a movable groove 611 is formed in the rotating handle one 61, the sliding bolt one 612 is arranged in a sliding mode along the length direction of the movable groove 611, the rotating handle one 61 is rotatably arranged on one side of the conveying platform 3 in a connecting mode, an L-shaped plate is welded on one side wall of the conveying platform 3, a rotating motor five connected with the rotating handle one 61 is arranged on the other side wall of the conveying platform 3 in a connecting mode through screws, a rotating handle two 62 are arranged in the side wall of the conveying platform 3 in a connecting mode through a connecting mode, and an electric push rod one electric push rod 621 is connected to the other side of the electric push rod 621.

In the present embodiment, when the adjusting plate 6 is parallel to the longitudinal direction of the conveying platform 3, the baffle 34 is located at the highest position, when the adjusting plate 6 is perpendicular to the longitudinal direction of the conveying platform 3, the baffle 34 is located at the lowest position, and the baffle 34 may be in abutting contact with one side surface of the adjusting plate 6.

Working principle: in the process of keeping the signal of the infrared sensor group 331 normal, the first rotating handle 61 is in the vertical direction, the output shaft of the first electric push rod 621 is in the shortest state, the adjusting plate 6 is attached to the upper surface of the conveying platform 3 in parallel as shown in fig. 1, when packaged products pass, the product packaging bag lying horizontally can pass smoothly, and the upright product packaging bag falls onto the conveying roller 36 under the resistance of the adjusting plate 6 and passes under the adjusting plate 6;

when the sample for spot check is put back onto the spot check conveying platform 33, the signal is interrupted when the sample passes through the infrared sensor group 331, and then the control terminal 1 controls the adjusting plate 6 to rotate from the horizontal position to the vertical position, and the specific process is as follows: firstly, the output shaft of the first electric push rod 621 extends to the longest to drive the adjusting plate 6 to move upwards, then the rotating motor is started five times to drive the first rotary handle 61 to rotate 90 degrees to the horizontal position and then stop, so that the adjusting plate 6 is driven to rotate to the vertical position from the horizontal position and contact with the baffle 34 below, then the first electric push rod 621 resets, the output shaft is restored to the shortest state, and the adjusting plate 6 moves to be attached to the side wall of the notch; when the infrared sensor group 331 resumes the signal docking, the adjusting plate 6 is restored to the horizontal state in the reverse process as described above.

Embodiment 3 referring to fig. 1-4, the present utility model further provides the following technical solutions: the utility model provides a food additive monoglyceride production line sampling detection device, the top both sides of conveyer belt 31 all are provided with spacing 32 movably, through the adjustment to the distance between two spacing 32, can control the transportation scope of product, one side of spacing 32 is provided with baffle 37, baffle 37 rotates through the hub connection and sets up between the inner wall of delivery platform 3, and baffle 37 is located the outside of spacing 32 all the time, utilize baffle 37 to carry out preliminary direction, in order to control the direction of delivery of product, the adjustment mechanism who is connected with it is installed on the diapire of delivery platform 3 to the below of spacing 32, adjustment mechanism's setting is mainly in order to control the spacing 32 synchronous adjustment of both sides;

the adjusting mechanism comprises a fixed frame 5, two sliding rods 52 and a movable rod 4 of a U-shaped structure, a rotating piece 51 is arranged in the middle of the fixed frame 5 in a rotating mode, connecting handles 53 are connected to two ends of the rotating piece 51 through shafts, the two sliding rods 52 are symmetrically distributed on two sides of the rotating piece 51 and are arranged in a sliding mode along the inner wall of the fixed frame 5, the other end of each connecting handle 53 is connected with the sliding rod 52 located on the same side through a shaft, and the movable rod 4 located on the same side is fixed with the sliding rod 52 through welding.

In the present embodiment, the rotary member 51 has a rotary motor three (not shown) mounted on the back surface thereof for driving rotation thereof, and the rotary motor three has a rotation angle of 90 degrees.

Working principle: the rotating motor III is started to drive the rotating piece 51 to rotate, so that the sliding rods 52 on two sides can synchronously and oppositely or reversely do linear motion, and further, the limiting strips 32 on two sides can synchronously and oppositely or reversely do linear motion through the connection transmission of the movable rods 4, so that the distance between the two limiting strips 32 is adjusted.

In the description of the present application, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically connected, electrically connected or can be communicated with each other; may be directly connected, may be in communication with the interior of two elements or may be in interaction with two elements. The meaning of the above terms in the present application can be understood by those of ordinary skill in the art according to the specific circumstances.

The above describes in detail the sampling detection device for the production line of the monoglyceride of the food additive provided in the embodiment of the present application, and specific examples are applied to illustrate the principles and embodiments of the present application, where the illustration of the above examples is only used to help understand the technical solution and core ideas of the present application; those of ordinary skill in the art will appreciate that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the corresponding technical solutions from the scope of the technical solutions of the embodiments of the present application.

Claims (5)

1. A food additive monoglyceride production line sampling detection device includes:

the conveying mechanism comprises a conveying platform (3), a conveying belt (31) and a plurality of conveying rollers (36) which are equidistantly arranged in the conveying platform (3) are arranged along the length direction of the conveying platform, and one side of the conveying platform (3) is connected with a sampling inspection conveying platform (33) communicated with the conveying platform;

the feeding mechanism is arranged on one side of the conveying platform (3), and one side of the feeding mechanism is also provided with a control terminal (1);

characterized by further comprising:

the conveying mechanism comprises four conveying rods (7) which are equal in length and coaxially rotate, the conveying rods (7) are located below the conveying rollers (36), one side of one conveying rod (7) is further connected with a driven wheel (73), a transmission box (8) is mounted on the bottom wall of the conveying platform (3) below the conveying mechanism, a driving wheel (81) and an output wheel (82) are arranged in the transmission box (8), the driving wheel (81) is connected with the output wheel (82) through a first crawler belt, the driving wheel (81) is further connected with the driven wheel (73) through a second crawler belt, a plurality of adjusting pieces (821) are arranged on the output wheel (82), one side of each adjusting piece (821) is provided with a driving assembly in the corresponding output wheel (82), the first crawler belt is mounted on the adjusting piece (821), and one side of the output wheel (82) is further provided with a moving auxiliary component along the inner wall of one side of the transmission box (8);

the conveying platform (3) is provided with a notch at the position opposite to the discharge hole, one side of the notch is elastically provided with a baffle plate (34) on the side wall of the conveying platform (3), the conveying platform (3) is also provided with an adjusting plate (6), one end of the adjusting plate (6) is embedded with a sliding bolt I (612), one side of the sliding bolt I (612) is provided with a rotating handle I (61) and is arranged in a sliding manner along the length direction of the rotating handle I (61), the rotating handle I (61) is rotationally arranged on one side of the conveying platform (3) through shaft connection, the side wall of the other side of the conveying platform (3) is rotationally provided with a rotating handle II (62), the rotating handle II (62) is internally provided with an electric push rod I (621), and the output end of the electric push rod I (621) is connected to the adjusting plate (6);

when the adjusting plate (6) is parallel to the length direction of the conveying platform (3), the baffle plate (34) is positioned at the highest position, and when the adjusting plate (6) is perpendicular to the length direction of the conveying platform (3), the baffle plate (34) is positioned at the lowest position, and the baffle plate (34) can be abutted against one side surface of the adjusting plate (6);

a feed inlet and a discharge outlet are formed in one side wall of the conveying platform (3), the feed inlet and the discharge outlet are respectively positioned at two ends of the sampling inspection conveying platform (33), an infrared sensor group (331) is embedded in the sampling inspection conveying platform (33) at a position close to the discharge outlet, and the infrared sensor group (331) comprises an infrared emitter and an infrared receiver;

the shifting mechanism further comprises two fixing plates (71) and a penetrating shaft (72), the fixing plates (71) are fixed between the side walls of the conveying platform (3) through screws, the penetrating shaft (72) penetrates through the four shifting rods (7) and is adhered with the four shifting rods into a whole, one end of the penetrating shaft rotates in one fixing plate (71), and the driven wheel (73) is arranged at the other end of the penetrating shaft (72);

the mobile auxiliary component comprises a sliding block (83) and a second electric push rod (84), a groove (85) is formed in the inner wall of one side of the transmission case (8), the sliding block (83) slides between the inner walls of the groove (85), the second electric push rod (84) is also installed in the transmission case (8) and the output end of the second electric push rod is adhered and fixed with the side wall of the sliding block (83), a first rotating motor is installed on one side of the sliding block (83) through a screw, the end part of an output shaft of the first rotating motor is fixed with the side wall of the output wheel (82), a rotating shaft (822) is arranged in the output wheel (82) in a rotating mode, and a second rotating motor connected with the rotating shaft (822) is fixed on the side wall of the other side of the output wheel (82) through a screw.

2. The sampling detection device for the food additive monoglyceride production line according to claim 1, wherein the feeding mechanism is a circular table (2), a plurality of placement areas are divided above the feeding mechanism, a push plate (21) is arranged in each placement area, and one side of the push plate (21) is connected with a linear motor.

3. The food additive monoglyceride production line sampling detection device according to claim 2, wherein a limit bar (32) is movably arranged on two sides above the conveying belt (31), a guide plate (37) is arranged on one side of the limit bar (32), the guide plate (37) is rotatably arranged between the inner walls of the conveying platform (3) through shaft connection, the guide plate (37) is always positioned on the outer side of the limit bar (32), and an adjusting mechanism connected with the limit bar (32) is arranged on the bottom wall of the conveying platform (3) below the limit bar.

4. The sampling detection device for the food additive monoglyceride production line according to claim 3, wherein the adjusting mechanism comprises a fixed frame (5), two sliding rods (52) and a movable rod (4) of a U-shaped structure, a rotating piece (51) is arranged in the middle of the fixed frame (5) in a rotating mode, connecting handles (53) are connected to two ends of the rotating piece (51) through shafts, the two sliding rods (52) are symmetrically distributed on two sides of the rotating piece (51) and are arranged in a sliding mode along the inner wall of the fixed frame (5), the other end of the connecting handle (53) is connected with the sliding rod (52) located on the same side through a shaft, and the movable rod (4) located on the same side is fixed with the sliding rod (52) through welding.

5. The device for detecting the sampling of the production line of the single glyceride of the food additive according to claim 4, wherein the driving assembly comprises a driving handle (823), a linkage handle (824) and a connecting shaft (825) which are arranged in an equal amount with the adjusting piece (821), one end of the driving handle (823) is fixedly welded on the outer surface of the rotating shaft (822), one end of the connecting shaft (825) is fixedly welded with the side wall of the adjusting piece (821), the connecting shaft (825) is fixedly connected with the output wheel (82) through electromagnetic adsorption, one end of the linkage handle (824) is movably connected with the other end of the connecting shaft (825) through a shaft, a sliding bolt II (828) is embedded on the other end of the linkage handle (824), and the sliding bolt II (828) slides between the inner walls of the driving handle (823).