CN115636123B - Ice taking metering control device for ice slurry conveying system - Google Patents

Abstract

The invention discloses an ice taking metering control device for an ice slurry conveying system, which comprises an equipment frame and an ice making mechanism, wherein a shell cover is fixedly arranged on the outer side of the equipment frame, an annular frame is fixedly arranged on the inner side of the shell cover, a discharge opening and a feed inlet are formed at the side end of the annular frame, an opening matched with ice slurry output is formed in the side wall of a sliding connection pipe, and a component for controlling the sliding connection pipe to vertically move is arranged above the annular frame. According to the invention, firstly, the elastic sheet provides an outward pressing force for the arc-shaped frame to realize the weighing of the weight of the ice slurry in the metering chamber, and the rotatable baffle disc is matched for quantitatively taking the ice slurry, so that the fresh-keeping effect of the taken ice slurry on foods and the fresh-keeping time are kept uniform, and secondly, after the bracket shields the outside of the distance sensor, the position of the metering chamber is automatically switched, and the batch automatic taking of the quantitative ice slurry is realized through the design of the linkage structure, so that the operation and the use of workers are facilitated while the taking efficiency of the ice slurry is ensured.

Description

Ice taking metering control device for ice slurry conveying system

Technical Field

The invention relates to the technical field of ice slurry machine taking, in particular to an ice taking metering control device for an ice slurry conveying system.

Background

The ice slurry machine is used for preparing flowing water into flowing ice water mixture, and the prepared ice slurry is widely applied to the fields of aquatic product fresh-keeping, central air conditioning cold accumulation, industrial cooling and the like.

After the ice making operation of the ice slurry machine is finished, if a worker needs to take a certain amount of ice slurry in batches for packaging along with fresh-keeping products, the taking of the ice slurry is generally realized by adopting a pumping and discharging mode, and in order to realize the quantitative taking of the ice slurry, the worker often selects to set and control the opening and closing time of the output channel valve, and the quantitative metering control mode has the following problems: firstly, as the degree of freedom of the water after forming the ice slurry is larger, the components of the ice slurry which is taken out by a pumping mode in unit time are difficult to be kept uniform, so that the fresh-keeping effect of the ice slurry put into use on food and the fresh-keeping time are difficult to be kept uniform; secondly, in order to improve the efficiency of quantitatively taking ice slurry in batches, the mode of directly replacing the containing containers can be adopted for taking ice slurry in two adjacent batches, when the containing containers are switched by adopting the electric control conveying equipment, the opening and closing time of the conveying equipment and the channel valve is required to be adjusted by a worker, so that after the container finishes taking ice slurry, the next group of containers are rapidly switched to the outlet of the ice slurry under the conveying of the conveying equipment, if the quantitative taking of the ice slurry is determined according to the opening and closing time of the channel valve, the switching and conveying time of the container is required to be adjusted again after the quantitative discharging time of the ice slurry is adjusted each time by the worker, and inconvenience is brought to the operation of the worker.

In view of the above drawbacks, it is desirable to provide an ice pick-up metering control device for an ice slurry delivery system.

Disclosure of Invention

The invention aims at: in order to solve the above problems, an ice taking metering control device for an ice slurry conveying system is provided.

In order to achieve the above purpose, the present invention adopts the following technical scheme: the ice taking metering control device for the ice slurry conveying system comprises an equipment frame and an ice making mechanism arranged on the equipment frame, wherein a shell cover is fixedly arranged on the outer side of the equipment frame through a support column, an annular frame is fixedly arranged on the inner side of the shell cover, and a discharge opening and a feed opening which are matched with the ice slurry to go in and out are formed at the side end of the annular frame;

the inner side of the annular frame is rotationally connected with a baffle disc, the side end of the baffle disc is fixedly provided with a shaft sleeve penetrating into the annular frame, the outer end of the shaft sleeve is fixedly provided with three partition plates which are distributed in an annular mode, three metering chambers are formed in the annular frame under the partition of the partition plates, and the equipment frame is provided with a component for quantitatively rotating the metering chambers;

three axially distributed rotating rings are rotationally embedded in the shaft sleeve, a baffle is fixedly arranged at the side end of each rotating ring through a connecting frame penetrating through the shaft sleeve, and a groove matched with the connecting frame to move is formed in the shaft sleeve;

the inner side of the baffle disc is connected with three arc-shaped frames corresponding to the baffle plates in a sliding manner, a boss is fixedly arranged at the inner end of the baffle disc, a spring sheet for acting on the arc-shaped frames is abutted to the side end of the boss, the baffle plates control the arc-shaped frames to move radially along the baffle disc through a transmission part, and a part for limiting the movable range of the arc-shaped frames is arranged on the equipment frame;

the ice making device comprises an ice making mechanism, a discharging pipe is arranged at the bottom of the ice making mechanism, a sliding connection pipe which can extend into a feeding port is slidably embedded in the discharging pipe, an opening matched with ice slurry output is formed in the side wall of the sliding connection pipe, and a component for controlling the sliding connection pipe to vertically move is arranged above the annular frame.

Preferably, the transmission part comprises a butt joint block fixedly arranged at the outer end of the arc-shaped frame, a supporting rod penetrating through the baffle disc to act on the butt joint block is fixedly arranged at the side end of the baffle plate, an arc-shaped groove matched with the supporting rod to slide is formed in the baffle disc in a penetrating mode, and a sector-shaped piece for shielding the arc-shaped groove is fixedly arranged on the baffle plate.

Preferably, the component for quantitatively rotating the metering chamber comprises a bracket fixedly arranged at one end of the arc-shaped frame, which is away from the butt joint block, a boss is fixedly arranged at the inner end of the baffle disc, and a distance sensor for sensing the position of the bracket is arranged on the boss.

Preferably, the inner end of the bracket is fixedly provided with a cross rod, the outer end of the equipment rack is fixedly provided with a baffle ring for limiting the radial movement of the cross rod through the tripod, and the inner end of the baffle ring is provided with a strip-shaped support opening matched with the cross rod to slide and separate.

Preferably, the part limiting the movable range of the arc-shaped frame comprises a shell cover rotatably connected to the inner side of the baffle disc, three abutting blocks serving as abutting blocks are fixedly arranged on the inner wall of the shell cover, a circular groove penetrating through the shell cover in cooperation with three cross bars is formed in the shell cover, and a component controlling the shell cover to rotate is arranged on the equipment frame.

Preferably, the component for controlling the rotation of the shell cover is a gear rotatably connected to the outer end of the equipment rack, and a toothed ring meshed with the gear is fixedly arranged at the inner end of the shell cover.

Preferably, two motors are installed at the outer end of the equipment rack, one motor controls the gear to rotate, and the other motor controls the baffle disc to rotate through the rotating shaft.

Preferably, the component for controlling the vertical movement of the sliding connection pipe comprises a frame plate fixedly arranged at the side end of the sliding connection pipe, a transverse plate is sleeved on the outer side of the blanking pipe in a sliding mode, a vertical rod is fixedly arranged between the transverse plate and the frame plate, a triangular block is fixedly arranged at the bottom of the transverse plate, and a notch matched with the triangular block in a buckling mode is formed in the outer edge of the blocking disc.

In summary, due to the adoption of the technical scheme, the beneficial effects of the invention are as follows:

1. in this application, after the baffle received the pressure of ice thick liquid weight, branch will be through the effect butt joint piece for the arc frame slides to the axle center department of fender dish, and the shell fragment provides outside oppression power for the arc frame, realizes its measurement to the ice thick liquid weight in the measurement cavity, shields the outside of back to distance sensor when the support, accomplishes the ration to the ice thick liquid and gets, thereby makes its effect and fresh-keeping time to food keep unifying.

2. In this application, the support is shielding the outside of back to distance sensor, and the controller that meets with distance sensor electrical property will control two motors synchronous operation simultaneously, realizes the automatic switch over to measurement cavity position, and when next notch was up along with the rotation of fender dish, measurement cavity was also rotated in place, continued to accept ice slurry, through the design of this interlock structure, realized the batch automatic access to quantitative ice slurry, when the guarantee ice slurry is accepted and is used in the operation of staff of being convenient for.

Drawings

Fig. 1 shows a perspective view of a metering control device provided according to an embodiment of the present invention;

FIG. 2 shows a schematic view of the internal structure of a toroidal cage provided in accordance with an embodiment of the present invention;

FIG. 3 shows a schematic view of the back structure of a housing provided in accordance with an embodiment of the present invention;

FIG. 4 shows a structural exploded front view of a metering control device provided in accordance with an embodiment of the present invention;

fig. 5 shows a structural exploded side view of a metering control device provided in accordance with an embodiment of the present invention.

Legend description:

1. an equipment rack; 2. a cover; 3. an annular frame; 301. a feed inlet; 302. a discharge port; 4. a shaft sleeve; 401. a groove; 5. a rotating ring; 501. a connecting frame; 6. a partition plate; 7. a baffle; 8. a fan-shaped sheet; 9. a baffle disc; 901. a notch; 902. an arc-shaped groove; 10. a support rod; 11. a boss; 1101. a distance sensor; 12. an arc-shaped frame; 13. a bracket; 14. a cross bar; 15. a spring plate; 16. a butt joint block; 17. a rotating shaft; 18. a housing; 1801. a circular groove; 19. an abutment block; 20. a toothed ring; 21. a gear; 22. a motor; 23. a tripod; 24. a baffle ring; 2401. a strip-shaped support opening; 25. an ice making mechanism; 26. discharging pipes; 27. a cross plate; 28. triangular blocks; 29. a slip joint pipe; 30. a frame plate; 31. and a vertical rod.

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.

Referring to fig. 1-5, the present invention provides a technical solution: an ice taking metering control device for an ice slurry conveying system comprises an equipment frame 1 and an ice making mechanism 25 arranged on the equipment frame 1, wherein a shell cover 2 is fixedly arranged on the outer side of the equipment frame 1 through a support column, an annular frame 3 is fixedly arranged on the inner side of the shell cover 2, and a discharge opening 302 and a feed opening 301 which are matched with the ice slurry to go in and out are formed at the side end of the annular frame 3; the prepared ice slurry enters the annular frame 3 through the feed inlet 301, and is discharged outwards through the discharge outlet 302 after being metered.

The inner side of the annular frame 3 is rotationally connected with a baffle disc 9, a shaft sleeve 4 penetrating into the annular frame 3 is fixedly arranged at the side end of the baffle disc 9, three partition boards 6 distributed in an annular mode are fixedly arranged at the outer end of the shaft sleeve 4, three metering chambers are formed in the annular frame 3 under the partition of the partition boards 6, and a component for quantitatively rotating the metering chambers is arranged on the equipment frame 1; when the ice slurry in the metering chamber reaches the rated weight, the position of the metering chamber for loading the ice slurry is switched along with the rotation of the baffle disc 9, so that the opening of the metering chamber is opposite to the discharge opening 302, and the quantitative ice slurry is discharged and collected.

Three axially distributed rotating rings 5 are rotationally embedded in the shaft sleeve 4, a baffle 7 is fixedly arranged at the side end of each rotating ring 5 through a connecting frame 501 penetrating through the shaft sleeve 4, and a groove 401 matched with the connecting frame 501 to move is formed in the shaft sleeve 4; when the ice slurry, after passing into the metering chamber, the weight borne by the baffle 7 increases, which will have a tendency to deflect downwards, the collar 5 will then rotate along the sleeve 4.

The inner side of the baffle disc 9 is connected with three arc-shaped frames 12 corresponding to the baffle disc 7 in a sliding manner, a boss 11 is fixedly arranged at the inner end of the baffle disc 9, a spring piece 15 which acts on the arc-shaped frames 12 is abutted to the side end of the boss 11, the baffle disc 7 controls the arc-shaped frames 12 to move radially along the baffle disc 9 through a transmission part, and a part for limiting the movable range of the arc-shaped frames 12 is arranged on the equipment frame 1; when the baffle 7 deflects downwards and rotates, the baffle will press the arc-shaped frame 12 to slide towards the axis direction of the baffle disc 9 through the transmission part; the elastic sheet 15 always provides an outward pressing force for the arc-shaped frame 12 to realize the measurement of the weight of the ice slurry in the metering chamber, and when the arc-shaped frame 12 slides to a corresponding position, the baffle disc 9 rotates to switch the position of the metering chamber.

A blanking pipe 26 is arranged at the bottom of the ice making mechanism 25, a total valve is arranged in the blanking pipe 26, and when the valve is closed, the blanking function cannot be realized; a sliding connection pipe 29 which can extend into the feeding port 301 is slidably embedded in the discharging pipe 26, an opening matched with ice slurry output is formed in the side wall of the sliding connection pipe 29, and a component for controlling the sliding connection pipe 29 to move vertically is arranged above the annular frame 3; the ice making mechanism 25 sends ice slurry into the sliding connection pipe 29 through the blanking pipe 26, and finally the ice slurry is input into the metering chamber through the feed inlet 301, and when the feed inlet 301 moves upwards, the opening of the ice slurry is covered by the inner wall of the blanking pipe 26, so that the ice slurry channel is cut off.

Specifically, as shown in fig. 5, the transmission component comprises a butt joint block 16 fixedly arranged at the outer end of the arc-shaped frame 12, a supporting rod 10 penetrating through a baffle disc 9 and acting on the butt joint block 16 is fixedly arranged at the side end of the baffle 7, an arc-shaped groove 902 matched with the supporting rod 10 to slide is formed in the baffle disc 9 in a penetrating manner, and a sector-shaped piece 8 for shielding the arc-shaped groove 902 is fixedly arranged on the baffle 7;

when the baffle 7 is under the pressure of the weight of ice slurry, the support rod 10 fixed with the baffle will act on the butt joint block 16, so that the arc-shaped frame 12 slides towards the axle center of the baffle disc 9; the butt joint block 16 is a triangular prism, and the end face of the butt joint block 16, which is attached to the support rod 10, is in an arc surface structure and extends in a direction away from the axle center of the baffle disc 9.

Specifically, as shown in fig. 3-5, the component for quantitatively rotating the metering chamber comprises a bracket 13 fixedly arranged at one end of the arc-shaped frame 12, which is far away from the butt joint block 16, a boss 11 is fixedly arranged at the inner end of the baffle disc 9, and a distance sensor 1101 for sensing the position of the bracket 13 is arranged on the boss 11; the bracket 13 moves along with the arc-shaped bracket 12 until the bracket shields the outer side of the distance sensor 1101, at the moment, a controller electrically connected with the distance sensor 1101 controls the two motors 22 to synchronously operate, and the rotating shaft 17 drives the baffle disc 9 to rotate, so that the position of the metering chamber is switched; the distance sensor 1101 employs an existing photosensor; the controller is triggered to send an instruction when any one of the light sensors is shielded by the bracket 13.

The inner end of the bracket 13 is fixedly provided with a cross rod 14, the outer end of the equipment rack 1 is fixedly provided with a baffle ring 24 for limiting the radial movement of the cross rod 14 through a tripod 23, and the inner end of the baffle ring 24 is provided with a strip-shaped support 2401 matched with the cross rod 14 to slide and separate;

along with the rotation of the metering chamber filled with ice slurry, the opening of the metering chamber is opposite to the discharge opening 302, the accurately metered ice slurry is output outwards through the discharge opening 302, the weight borne by the corresponding baffle 7 is reduced, but at the moment, the position of the arc-shaped frame 12 is not changed due to the limitation of the baffle ring 24 on the cross rod 14, the bracket 13 always shields the sensing opening of the distance sensor 1101 until the cross rod 14 passes through the strip-shaped support opening 2401, the arc-shaped frame 12 drives the bracket 13 to release the shielding of the distance sensor 1101 under the action of the elastic sheet 15, the controller controls the motor 22 to stop running, and meanwhile, the cross rod 14 is embedded into the strip-shaped support opening 2401, so that the rapid braking of the baffle disc 9 is realized, the rotating angle of the baffle disc is prevented from being excessively large, and the next group of ice slurry is not favorable for being picked up.

Specifically, as shown in fig. 3-5, the means for limiting the movement range of the arc-shaped frame 12 includes a housing 18 rotatably connected to the inner side of the baffle disc 9, three abutment blocks 19 serving as abutment blocks 16 are fixedly arranged on the inner wall of the housing 18, a circular groove 1801 penetrating through in cooperation with the three cross bars 14 is formed in the housing 18, and a component for controlling the rotation of the housing 18 is arranged on the equipment frame 1; the component for controlling the shell 18 to rotate is a gear 21 rotatably connected to the outer end of the equipment rack 1, and a toothed ring 20 meshed with the gear 21 is fixedly arranged at the inner end of the shell 18; two motors 22 are arranged at the outer end of the equipment rack 1, wherein one motor 22 controls a gear 21 to rotate, and the other motor 22 controls a baffle disc 9 to rotate through a rotating shaft 17; starting a motor 22 to control the gear 21 to rotate, so that the toothed ring 20 meshed with the gear 21 drives the shell cover 18 to rotate, and the shell cover 18 acts on the butt block 16 through the butt block 19 in the rotating process to adjust the distance between the bracket 13 and the sensing port of the distance sensor 1101, thereby achieving the purpose of adjusting the receiving of the quantitative ice slurry by the metering chamber; when the position of the metering chamber is switched by the rotation of the baffle disc 9, the two motors 22 should be kept running synchronously, so that the housing 18 and the baffle disc 9 keep rotating synchronously, eliminating the influence between the abutment block 19 and the abutment block 16.

Specifically, as shown in fig. 1-4, the means for controlling the sliding connection pipe 29 to move vertically comprises a frame plate 30 fixedly arranged at the side end of the sliding connection pipe 29, a transverse plate 27 is sleeved on the outer side of the blanking pipe 26 in a sliding manner, a vertical rod 31 is fixedly arranged between the transverse plate 27 and the frame plate 30, a triangular block 28 is fixedly arranged at the bottom of the transverse plate 27, and a notch 901 for being buckled by the triangular block 28 is formed at the outer edge of the baffle plate 9; when the sliding connection pipe 29 feeds ice slurry into the metering chamber, the triangular block 28 is embedded in the notch 901, after the metering chamber is filled with a certain amount of ice slurry, the notch 901 presses the triangular block 28 upwards through the inclined wall end of the notch along with the rotation of the baffle disc 9, so that the transverse plate 27 drives the sliding connection pipe 29 to move upwards, and the opening of the sliding connection pipe 29 is closed, thereby avoiding the waste of the ice slurry caused by continuous outflow of the ice slurry in the switching process of the chamber; when the next notch 901 is upwards along with the rotation of the baffle disc 9, the triangular block 28 falls into the notch 901 again, and at the moment, the metering chamber is also rotated in place to receive ice slurry, and the batch quick receiving of quantitative ice slurry is realized through the design of the linkage structure, so that the metering receiving efficiency of ice slurry is improved.

The previous description of the embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (5)

1. The ice taking metering control device for the ice slurry conveying system comprises an equipment frame (1) and an ice making mechanism (25) arranged on the equipment frame (1), and is characterized in that a shell cover (2) is fixedly arranged on the outer side of the equipment frame (1) through a support column, an annular frame (3) is fixedly arranged on the inner side of the shell cover (2), and a discharge opening (302) and a feed opening (301) which are matched with ice slurry to go in and out are formed at the side end of the annular frame (3);

the inner side of the annular frame (3) is rotationally connected with a baffle disc (9), a shaft sleeve (4) penetrating into the annular frame (3) is fixedly arranged at the side end of the baffle disc (9), three annular-distributed partition plates (6) are fixedly arranged at the outer end of the shaft sleeve (4), three metering chambers are formed in the annular frame (3) under the partition of the partition plates (6), and a component for quantitatively rotating the metering chambers is arranged on the equipment frame (1);

three axially distributed rotating rings (5) are rotationally embedded in the shaft sleeve (4), a baffle (7) is fixedly arranged at the side end of each rotating ring (5) through a connecting frame (501) penetrating through the shaft sleeve (4), and a groove (401) matched with the connecting frame (501) to move is formed in the shaft sleeve (4);

the inner side of the baffle disc (9) is slidably connected with three arc-shaped frames (12) corresponding to the baffle plates (7), a boss (11) is fixedly arranged at the inner end of the baffle disc (9), a spring piece (15) acting on the arc-shaped frames (12) is abutted to the side end of the boss (11), the baffle plates (7) control the arc-shaped frames (12) to move along the radial direction of the baffle disc (9) through a transmission part, and a part for limiting the movable range of the arc-shaped frames (12) is arranged on the equipment frame (1);

a blanking pipe (26) is arranged at the bottom of the ice making mechanism (25), a sliding connection pipe (29) which can extend into the feeding opening (301) is slidably embedded in the blanking pipe (26), an opening matched with ice slurry output is formed in the side wall of the sliding connection pipe (29), and a component for controlling the sliding connection pipe (29) to move vertically is arranged above the annular frame (3);

the transmission part comprises a butt joint block (16) fixedly arranged at the outer end of the arc-shaped frame (12), a supporting rod (10) penetrating through a baffle disc (9) to act on the butt joint block (16) is fixedly arranged at the side end of the baffle plate (7), an arc-shaped groove (902) matched with the supporting rod (10) to slide is formed in the baffle disc (9) in a penetrating mode, a sector piece (8) shielding the arc-shaped groove (902) is fixedly arranged on the baffle plate (7) the transmission part comprises the butt joint block (16) fixedly arranged at the outer end of the arc-shaped frame (12), the supporting rod (10) penetrating through the baffle disc (9) to act on the butt joint block (16) is fixedly arranged at the side end of the baffle plate (7), an arc-shaped groove (902) matched with the supporting rod (10) to slide is formed in the baffle disc (9) in a penetrating mode, and the sector piece (8) shielding the arc-shaped groove (902) is fixedly arranged on the baffle plate (7).

The component for quantitatively rotating the metering chamber comprises a bracket (13) fixedly arranged at one end of the arc-shaped frame (12) deviating from the butt joint block (16), a boss (11) is fixedly arranged at the inner end of the baffle disc (9), and a distance sensor (1101) for sensing the position of the bracket (13) is arranged on the boss (11);

the inner end of the bracket (13) is fixedly provided with a cross rod (14), the outer end of the equipment rack (1) is fixedly provided with a baffle ring (24) for limiting the radial movement of the cross rod (14) through a tripod (23), and the inner end of the baffle ring (24) is provided with a strip-shaped support opening (2401) matched with the cross rod (14) to slide and separate.

2. The ice taking metering control device for the ice slurry conveying system according to claim 1, wherein the means for limiting the movable range of the arc-shaped frame (12) comprises a housing (18) rotatably connected to the inner side of the baffle disc (9), three abutting blocks (19) for acting on the abutting blocks (16) are fixedly arranged on the inner wall of the housing (18), a circular groove (1801) penetrated by three cross bars (14) is formed in the housing (18), and a component for controlling the housing (18) to rotate is arranged on the equipment frame (1).

3. An ice taking metering control device for an ice slurry conveying system according to claim 2, wherein the component for controlling the rotation of the housing (18) is a gear (21) rotatably connected to the outer end of the equipment rack (1), and a toothed ring (20) meshed with the gear (21) is fixedly arranged at the inner end of the housing (18).

4. An ice-taking metering control device for an ice slurry conveying system according to claim 3, characterized in that two motors (22) are arranged at the outer end of the equipment rack (1), one motor (22) controls a gear (21) to rotate, and the other motor (22) controls a baffle disc (9) to rotate through a rotating shaft (17).

5. The ice taking metering control device for the ice slurry conveying system according to claim 1, wherein the component for controlling the sliding pipe (29) to vertically move comprises a frame plate (30) fixedly arranged at the side end of the sliding pipe (29), a transverse plate (27) is sleeved on the outer side of the discharging pipe (26) in a sliding mode, a vertical rod (31) is fixedly arranged between the transverse plate (27) and the frame plate (30), a triangular block (28) is fixedly arranged at the bottom of the transverse plate (27), and a notch (901) for being buckled by the triangular block (28) is formed at the outer edge of the baffle disc (9).

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