CN216943613U

CN216943613U - Automatic production equipment for crushed ice bags

Info

Publication number: CN216943613U
Application number: CN202220714520.9U
Authority: CN
Inventors: 杨宗斌
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-03-30
Filing date: 2022-03-30
Publication date: 2022-07-12
Anticipated expiration: 2032-03-30

Abstract

The utility model discloses an automatic production device of crushed ice bags, comprising: an ice crusher; the feeding port of the conveying mechanism is communicated with the discharging port of the ice crusher; the feed inlet of the material distribution mechanism is communicated with the discharge outlet of the conveying mechanism; the feeding port of the weighing mechanism is communicated with the discharge port of the material distribution mechanism; automatic packaging machine, its pan feeding pipe with the discharge gate intercommunication of weighing machine structure, just the pan feeding pipe endotheca is equipped with first film, the inner wall of pan feeding pipe has still coated a teflon. The utility model realizes the high-efficiency production of the crushed ice bag, effectively prevents the crushed ice from melting and bonding in the manufacturing process, and has the beneficial effects of improving the processing efficiency and ensuring the processing quality.

Description

Automatic production equipment for crushed ice bags

Technical Field

The utility model relates to ice bag production equipment, in particular to automatic production equipment for crushed ice bags.

Background

The crushed ice bag plays a role in refrigerating and preserving vegetables, fruits, foods and other easily-changing products, perishable products, biological agents and all products needing refrigerating and transporting, prevents the vegetables, the fruits, the beer, the beverage, the foods and the like from going bad, and refrigerates and preserves the vegetables, the fruits, the beer, the beverages, the foods and the like for a long time or a short time in places without a cold source. The crushed ice bag is an ice bag made by crushing large ice blocks, and is mainly used for products needing refrigerated transportation, and the crushed ice bag is transported away along with the products during transportation and cannot be recycled for reuse, so that the use requirement is high.

In the prior art, crushed ice bags are produced. Due to the temperature difference between the crushed ice and the outside, the crushed ice is often melted and adhered to production equipment, so that the production efficiency is influenced, and the quality of the final finished crushed ice bag is also influenced. In severe cases, the bonding into a whole results in damage to the production equipment.

Therefore, the automatic production equipment for the crushed ice bags, which can realize efficient production of the crushed ice bags, effectively prevent the crushed ice from melting and bonding in the manufacturing process, and has the advantages of improving the processing efficiency and ensuring the processing quality, is particularly important.

SUMMERY OF THE UTILITY MODEL

An object of the present invention is to solve at least the above problems and/or disadvantages and to provide at least the advantages described hereinafter.

To achieve these objects and other advantages and in accordance with the purpose of the utility model, there is provided an automatic crushed ice bag manufacturing apparatus, comprising:

an ice crusher;

the feeding port of the conveying mechanism is communicated with the discharging port of the ice crusher;

the feed inlet of the material distribution mechanism is communicated with the discharge outlet of the conveying mechanism;

the feeding port of the weighing mechanism is communicated with the discharging port of the material distributing mechanism;

automatic packaging machine, its pan feeding pipe with the discharge gate intercommunication of weighing machine structure, just the pan feeding intraductal cover is equipped with first film, the inner wall of pan feeding pipe has still coated first teflon.

Preferably, wherein the conveying mechanism comprises:

the feeding port of the variable-frequency spiral feeding machine is positioned below the discharging port of the ice crusher, and the discharging port of the variable-frequency spiral feeding machine is positioned above the conveying mechanism;

the first temperature insulation sleeve is fixedly connected to the outer side of the conveying pipeline of the variable-frequency spiral feeding machine;

the diversion bag is fixedly connected to the discharge port of the spiral feeding machine;

and the triangular supports are used for supporting and are fixedly connected with the conveying pipeline of the variable-frequency spiral feeding machine.

Preferably, the material distributing mechanism comprises:

a support;

the material distribution hopper is fixedly connected to the middle position of the top end of the support, a plurality of second vibrators are symmetrically and fixedly connected to the outer side of the material distribution hopper, and a first plastic plate is fixedly connected to the material distribution hopper along the inner wall;

and one end of the blanking device is communicated with the discharge hole of the material distributing hopper, and the other end of the blanking device is communicated with the feeding hole of the weighing mechanism.

Preferably, wherein the blanking device comprises:

the two variable-frequency spiral blanking machines are fixedly connected to the top of the bracket, and a feeding port of each spiral blanking machine is respectively communicated with a discharging port of the distributing hopper;

and the two second heat insulation sleeves are fixedly connected with the outer wall of the conveying pipeline of each variable-frequency spiral blanking machine respectively.

Preferably, wherein the weighing mechanism comprises:

the first connecting plate is fixedly connected to the middle of the bracket;

the two weighing sensors are respectively and symmetrically fixedly connected to the top end of the first connecting plate;

the discharge port of each weighing hopper is arranged at the top end of each weighing sensor and is fixedly connected with the discharge port of each blanking device, the discharge port of each weighing hopper is hinged with a separation blade, each separation blade is in transmission connection with each weighing hopper, and the inner wall of each weighing hopper is coated with second teflon;

the U-shaped guide plate is fixedly connected to one side of the connecting plate in an inclined manner, an inlet of the U-shaped guide plate is communicated with discharge ports of the two weighing hoppers, an outlet of the U-shaped guide plate is communicated with the feeding pipe, and the inner wall of the U-shaped guide plate is coated with third Teflon;

the two first vibrators are fixedly connected with the weighing hoppers respectively;

the two second thin films are respectively sleeved in the weighing hoppers;

and the third film is sleeved on the inner side of the U-shaped guide plate.

Preferably, the manner of transmission connection between each baffle plate and each weighing hopper is as follows: the bottom of each separation blade is fixedly connected with a connecting ring, each weighing hopper is fixedly connected with a connecting rod, each connecting rod is fixedly connected with a servo motor, a transmission shaft of each servo motor is fixedly connected with a torsion bar, the bottom of each torsion bar is sleeved in each connecting ring, and each servo motor is connected with each weighing sensor in a control mode through a weighing controller.

Preferably, wherein the blanking device comprises:

the variable-frequency conveyor is fixedly connected to the middle position of the top of the support, and a discharge port of the variable-frequency conveyor is positioned above a feed port of each weighing hopper;

the two first baffle plates are fixedly connected to two sides of the discharge hole of the distributing hopper respectively, and the bottom end of each first baffle plate is close to the top end of the variable frequency conveyor respectively;

one side of the L-shaped partition plate is fixedly connected with the material distributing hopper, one side of the bottom end of the L-shaped partition plate is close to the top end of the variable frequency conveyor, and the other side of the bottom end of the L-shaped partition plate is positioned in the middle of the two weighing hoppers;

and the flow limiting device is used for controlling the flow of the crushed ice and is arranged between the two first baffles.

Preferably, wherein the flow limiting device comprises:

the two partition plates are fixedly connected with the material distribution hopper, are respectively positioned in the middle of the L-shaped partition plate and the first baffle plates, and the bottom end of each partition plate is close to the top end of the variable frequency conveyor;

the two second baffle plates are respectively hinged between the partition plates and the first baffle plates, and the bottom ends of the second baffle plates are close to the top end of the variable frequency conveyor;

the two third baffle plates are respectively hinged between each baffle plate and the L-shaped baffle plate, and the bottom end of each third baffle plate is close to the top end of the variable frequency conveyor;

the two ends of the hinged rod are fixedly connected with the tail ends of the first baffles respectively;

the top ends of the two first cylinders are respectively hinged with the hinge rod, and the transmission shaft of each first cylinder is respectively hinged with each second baffle;

the top ends of the two second cylinders are respectively hinged with the hinge rod, and the transmission shaft of each second cylinder is respectively hinged with each third baffle.

Preferably, a second plastic plate for preventing crushed ice from being bonded is fixedly connected to the inner wall of the bin of the ice crusher, and a third vibrator is fixedly connected to the outer side of the bin.

Preferably, the first film is any one of a first polyethylene film, a first polypropylene film, a first polyvinyl chloride film and a first polyester film; the second film is any one of a second polyethylene film, a second polypropylene film, a second polyvinyl chloride film and a second polyester film; the third film is any one of a third polyethylene film, a third polypropylene film, a third polyvinyl chloride film and a third polyester film.

The utility model at least comprises the following beneficial effects:

firstly, the utility model realizes the high-efficiency production of the crushed ice bag, effectively prevents the crushed ice from melting and bonding in the manufacturing process, and has the beneficial effects of improving the processing efficiency and ensuring the processing quality.

Secondly, the two second temperature insulation sleeves arranged in the utility model are used for isolating the external temperature difference of the conveying pipeline of each spiral blanking machine, so that crushed ice is prevented from being adhered in the conveying pipeline after being thawed in the conveying process, and the processing efficiency is improved, and the processing quality is guaranteed.

Thirdly, the two second films are arranged in the weighing hopper to prevent crushed ice from melting and being adhered in the weighing hopper during weighing. The third film of establishing through the inboard cover of U-shaped guide plate prevents that the garrulous ice after weighing from melting to freeze the bonding in transportation process, has the advantage that ensures production quality, promotes production efficiency.

Fourthly, the plurality of vibrators arranged in the ice discharging device guarantee that crushed ice in the material distribution hopper can be discharged continuously, and the crushed ice is prevented from being frozen and bonded in the material distribution hopper through the arranged Teflon plates.

Additional advantages, objects, and features of the utility model will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the utility model.

Description of the drawings:

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural diagram of the conveying mechanism of the present invention.

Fig. 3 is a schematic structural diagram of the material distributing mechanism of the present invention.

Fig. 4 is a schematic structural diagram of the weighing mechanism of the present invention.

Fig. 5 is a schematic view of the connection of the baffle plate of the present invention.

Fig. 6 is a schematic structural diagram of another embodiment of the present invention.

Fig. 7 is a schematic structural diagram of a material distributing mechanism in another embodiment of the utility model.

Fig. 8 is a front view of a feed mechanism in another example of the utility model.

Fig. 9 is a schematic view of the structure of the distribution hopper of the present invention.

Fig. 10 is a schematic view of the ice crusher of the present invention.

The specific implementation mode is as follows:

the present invention is further described in detail below with reference to the attached drawings so that those skilled in the art can implement the utility model by referring to the description text.

It will be understood that terms such as "having," "including," and "comprising," as used herein, do not preclude the presence or addition of one or more other elements or groups thereof.

It is to be understood that in the description of the present invention, the terms indicating orientation or positional relationship are based on the orientation or positional relationship shown in the drawings, and are used only for convenience in describing the present invention and for simplification of the description, and do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" 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, unless otherwise specifically stated or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are used broadly, and for example, "connected" may be a fixed connection, a detachable connection, or an integral connection, a mechanical connection, an electrical connection, a direct connection, an indirect connection via an intermediate medium, or a communication between two elements, and those skilled in the art will understand the specific meaning of the terms in the present invention specifically.

Further, in the present invention, unless otherwise explicitly specified or limited, a first feature "on" or "under" a second feature may be directly contacted with the first and second features, or indirectly contacted with the first and second features through an intermediate. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

Fig. 1 shows an implementation form of the present invention, which includes:

an ice crusher 1;

the feeding port of the conveying mechanism 2 is communicated with the discharging port of the ice crusher 1;

the feed inlet of the material distribution mechanism 3 is communicated with the discharge outlet of the conveying mechanism 2;

the feeding port of the weighing mechanism 4 is communicated with the discharging port of the material distributing mechanism 3;

automatic packaging machine 5, its pan feeding pipe 51 with the discharge gate intercommunication of weighing machine 4, just pan feeding pipe 51 endotheca is equipped with first film, the inner wall of pan feeding pipe 51 has still coated first teflon.

The working principle is as follows: during the process of making, ice blocks are placed into the ice crusher 1 to be made into crushed ice, the crushed ice enters the feeding hole of the conveying mechanism 2 from the discharging hole of the ice crusher 1, the crushed ice enters the material distributing mechanism 3 through the conveying mechanism 2, the crushed ice is distributed by the material distributing mechanism 3 and then enters the weighing mechanism 4 through the material distributing mechanism 3 to be weighed, when the weighing mechanism 4 weighs the crushed ice to reach the specified weight, the crushed ice enters the automatic packaging machine 5 through the weighing mechanism 4 to be packaged, and the crushed ice bag is made. Through the first film that pan feeding pipe 51 endotheca was established, prevent that the trash ice from melting and freezing the inner wall that bonds at pan feeding pipe 51 to the isolated outside temperature of first teflon through pan feeding pipe 51's inner wall coating prevents that the trash ice from melting, prevents that the trash ice from melting and bonding at the inner wall of pan feeding pipe 51 after the first film is broken, guarantee ice crusher normal operating. In this kind of technical scheme, realize the high-efficient production of trash ice bag to effectively prevent that the trash ice from melting in the manufacturing process and freezing the bonding, have the beneficial effect who promotes machining efficiency, guarantee processing effect.

In the above solution, the conveying mechanism 2 includes:

a feeding port of the variable-frequency spiral feeding machine 21 is positioned below a discharging port of the ice crusher 1, and a discharging port of the variable-frequency spiral feeding machine is positioned above the conveying mechanism 3;

the first temperature insulation sleeve is fixedly connected to the outer side of the conveying pipeline of the variable-frequency spiral feeding machine 21;

the diversion bag 22 is fixedly connected to the discharge port of the spiral feeding machine 21;

and the triangular supports 23 are used for supporting and are fixedly connected with the conveying pipeline of the variable-frequency spiral feeding machine 21.

The working principle is as follows: at conveying mechanism 2 at the in-process of carrying the trash ice, prevent through the mode of frequency conversion spiral material loading machine 21 spiral material loading that the trash ice from skidding in transportation process to through the conveying speed of frequency conversion adjustment material loading, thereby the guarantee carries the effect. Through the first temperature-isolating sleeve of fixed connection in the pipeline outside of frequency conversion spiral feeding machine 21, isolated external difference in temperature prevents that the trash ice from melting and freezing the bonding in transportation process, influences the transport effect to prevent through water conservancy diversion bag 22 that the trash ice from carrying out the time sputtering, cause the wasting of resources. The conveying pipeline of the variable-frequency spiral feeding machine 21 is fixedly supported by a plurality of triangular supports 23, so that the variable-frequency spiral feeding machine is prevented from inclining and collapsing in the operation process. The mode has the advantages of guaranteeing the conveying effect and the heat insulation effect.

In the above scheme, the material distribution mechanism 3 includes:

a bracket 31;

the material distribution hopper 32 is fixedly connected to the middle position of the top end of the bracket 31, a plurality of second vibrators 321 are symmetrically and fixedly connected to the outer side of the material distribution hopper 32, and a first plastic plate 322 is fixedly connected to the material distribution hopper 32 along the inner wall;

and one end of the blanking device 6 is communicated with the discharge hole of the material distribution hopper 32, and the other end of the blanking device is communicated with the feeding hole of the weighing mechanism 4.

The working principle is as follows: after the crushed ice is conveyed to the distributing mechanism 3 by the conveying mechanism 2, the crushed ice is stored in the distributing hopper 32, the crushed ice in the distributing hopper 32 can be continuously discharged through the plurality of second vibrators 321, and the crushed ice is prevented from being frozen and bonded in the distributing hopper through the arranged first plastic plate 322. The crushed ice conveyed out from the material dividing hopper 32 is divided by the blanking device 6, and the crushed ice is conveyed to the weighing mechanism 4 in order by the blanking device 6 to be weighed. This has the advantage of ensuring production quality.

In the above scheme, the blanking device 6 includes:

the two variable-frequency spiral blanking machines 61 are fixedly connected to the top of the bracket 31, and the feeding port of each spiral blanking machine 61 is respectively communicated with the discharging port of the distributing hopper 32;

and the two second heat insulation sleeves are fixedly connected with the outer wall of the conveying pipeline of each variable-frequency spiral blanking machine 61 respectively.

The working principle is as follows: after crushed ice is conveyed into the distributing hopper 32 through the conveying mechanism 2, the two variable-frequency spiral blanking machines 61 are started one by one, the crushed ice is conveyed to the weighing mechanism 4 to be weighed in a spiral blanking mode in an alternating mode, and the load of the single variable-frequency spiral blanking machine 61 is reduced. And the blanking speed of each variable frequency spiral blanking machine 61 can be adjusted according to the weight requirement of the crushed ice bag, so that the aim of rapidness and accuracy is fulfilled, and the crushed ice is prevented from being placed in the distribution hopper 32 for a long time and being frozen and then being coagulated into blocks. Through two second heat insulation covers that set up, isolated each frequency conversion spiral blanking machine 61's the pipeline external temperature difference prevents that the trash ice from melting in transportation process and freezing the back and bonding in pipeline. The mode has the advantages of improving the processing efficiency and guaranteeing the processing quality.

In the above solution, the weighing mechanism 4 includes:

a first connecting plate 41 fixedly connected to a middle portion of the bracket 31;

two weighing sensors 42, which are respectively and symmetrically fixedly connected to the top end of the first connecting plate 41;

the discharge port is arranged on two weighing hoppers 43 on one side of the bottom, the weighing hoppers are respectively and fixedly connected to the top ends of the weighing sensors 42, the feed port of each weighing hopper 43 is respectively communicated with the discharge port of each blanking device 6, the discharge port of each weighing hopper 43 is hinged with a baffle plate 45, each baffle plate 45 is respectively in transmission connection with each weighing hopper 43, and the inner wall of each weighing hopper 43 is coated with second teflon;

the U-shaped guide plate 44 is fixedly connected to one side of the connecting plate 41 in an inclined manner, the inlet of the U-shaped guide plate 41 is communicated with the discharge ports of the two weighing hoppers 43, the outlet of the U-shaped guide plate 41 is communicated with the feeding pipe 51, and the inner wall of the U-shaped guide plate 41 is coated with third teflon;

two first vibrators 431 fixedly connected to the weighing hoppers 43, respectively;

two second films respectively sleeved in the weighing hoppers 43;

a third film that fits over the inside of the U-shaped deflector 44.

The working principle is as follows: broken ice divides the material back by unloader 6, pours into two hopper 43 of weighing into in proper order respectively and weighs, and the discharge gate that hopper 43 of weighing will be weighed to separation blade 45 during weighing seals the broken ice and prevents that the broken ice from flowing, weighs the broken ice that pours into through weighing sensor 42 and reaches when appointed weight, separation blade 45 opens the discharge gate that hopper 43 of weighing through being connected with the transmission of hopper 43 of weighing, and the first vibrator 431 that corresponds simultaneously starts, drives hopper 43 of weighing and carries out the vibration unloading. A certain weight of crushed ice is injected into the automatic packaging machine 5 through the U-shaped guide plate 44 to be made into crushed ice bags with specified specifications. After the weighing hopper 43 is completely blanked, the baffle 45 is reset to close the discharge port of the weighing hopper 43, and the corresponding first vibrator 431 is closed. The two weighing hoppers 43 alternately weigh the crushed ice respectively conveyed by the blanking device 6, and then alternately convey the crushed ice with certain weight to the automatic packaging machine 5 through the U-shaped guide plate 44 to manufacture crushed ice bags with specified specifications. And the crushed ice is prevented from melting and being adhered in the weighing hoppers when weighing by respectively sleeving the two second films in the weighing hoppers 43. Through the second teflon that the inner wall of weighing hopper 43 all coated, isolated outside temperature prevents that the trash ice from melting, prevents simultaneously that the trash ice from melting and bonding at the inner wall of pan feeding pipe 51 after the second film is broken. The third film is sleeved on the inner side of the U-shaped guide plate 44, so that the crushed ice after weighing is prevented from being thawed and bonded in the conveying process. Through the third teflon that the inner wall of U-shaped guide plate 44 all coated, isolated outside temperature prevents that the trash ice from melting, prevents simultaneously that the trash ice from melting and bonding on U-shaped guide plate 44 after the third film is broken. The mode has the advantages of ensuring the production quality and improving the production efficiency.

In the above scheme, the manner of the transmission connection between each baffle 45 and each weighing hopper 43 is as follows: the bottom of each blocking piece 45 is fixedly connected with a connecting ring 48, each weighing hopper 43 is fixedly connected with a connecting rod 46, each connecting rod 46 is fixedly connected with a servo motor 47, a transmission shaft of each servo motor 47 is fixedly connected with a torsion bar 49, the bottom of each torsion bar 49 is respectively sleeved in each connecting ring 48, and each servo motor 47 is in control connection with each weighing sensor 42 through a weighing controller.

The working principle is as follows: the weight of the crushed ice in the weighing hopper 43 is weighed by the load cell 42 to reach a specified weight, and a start signal is transmitted to the servo motor 47 through the weighing controller. The servo motor 47 is started to drive the torsion bar 49 to rotate a certain angle, so that the torsion bar 49 drives the baffle 45 to rotate through the connecting ring 48, the discharge port of the weighing hopper 43 is opened, and a certain weight of crushed ice in the weighing hopper 43 is injected onto the U-shaped guide plate 44 through the discharge port. After the crushed ice in the weighing hopper 43 is discharged, when the weighing value of the weighing sensor 42 returns to zero, the servo motor 47 is transmitted by the weighing controller again, the servo motor 47 performs rotary reset, the baffle plate 45 is driven by the torsion bar 49 to seal the discharge hole of the weighing hopper 43, and the weighing hopper 43 performs charging and weighing again. The adoption of the mode has the advantage of guaranteeing the weighing effect.

In another example, the blanking device 6 includes:

the variable-frequency conveyor 62 is fixedly connected to the middle position of the top of the bracket 31, and a discharge hole of the variable-frequency conveyor 62 is positioned above a feed hole of each weighing hopper 43;

the two first baffle plates 63 are fixedly connected to two sides of the discharge hole of the distributing hopper 32 respectively, and the bottom end of each first baffle plate 63 is close to the top end of the variable frequency conveyor 62 respectively;

one side of an L-shaped partition plate 64 for distributing crushed ice is fixedly connected with the distributing hopper 32, one side of the bottom end of the L-shaped partition plate 64 is close to the top end of the variable frequency conveyor 62, and the other side of the bottom end of the L-shaped partition plate 64 is positioned in the middle of the two weighing hoppers 43;

and a flow restriction device for controlling the flow of crushed ice, which is disposed between the two first baffles 63.

The working principle is as follows: in the blanking process, crushed ice stored in the sub-hopper 32 is injected onto the variable frequency conveyor 62 through the discharge hole of the sub-hopper 32, and the conveying speed of the variable frequency conveyor 62 is adjusted according to the weight requirement of the crushed ice bag, so as to achieve the purpose of rapidness and accuracy. The crushed ice is prevented from running off from both sides of the inverter conveyor 62 by the two first baffles 63. The crushed ice is divided by the L-shaped partition plate 64, and the guided crushed ice can be respectively injected into the two weighing hoppers 43. And then the crushed ice is controlled to be respectively injected into the two weighing hoppers 43 for weighing according to the sequence through the current limiting device. The method has the advantages of guaranteeing the production quality and the weighing effect.

In another example, the current limiting device includes:

the two partition plates 65 are used for shunting the crushed ice again and fixedly connected with the distributing hopper 32, each partition plate 65 is respectively positioned in the middle of the L-shaped partition plate 64 and each first baffle plate 63, and the bottom end of each partition plate 65 is close to the top end of the variable frequency conveyor 62;

two second baffles 66 respectively hinged between each partition plate 65 and each first baffle 63, and the bottom end of each second baffle 66 is close to the top end of the variable-frequency conveyor 62;

two third baffles 67 respectively hinged between each partition 65 and the L-shaped partition 64, wherein the bottom end of each third baffle 67 is close to the top end of the variable frequency conveyor 62;

a hinge rod 631 having both ends fixedly connected to the ends of the first blocking plates 63, respectively;

two first cylinders 68, the top ends of which are hinged with the hinge rods 631, and the transmission shaft of each first cylinder 68 is hinged with each second baffle 66;

the top ends of the two second cylinders 69 are hinged to the hinge rods 631, and the transmission shaft of each second cylinder 69 is hinged to each third baffle 67.

The working principle is as follows: in the blanking process, the transmission rods of the first air cylinder 68 and the second air cylinder 69 on one side of the L-shaped partition plate 64 retract to drive the corresponding second baffle 66 and the corresponding third baffle 67 to open, and crushed ice can be injected into the corresponding weighing hopper 43 through the conveying of the variable-frequency conveyor 62. When the transmission rods of the first air cylinder 68 and the second air cylinder 69 on one side of the L-shaped partition plate 64 are retracted, the transmission rods of the first air cylinder 68 and the second air cylinder 69 on the other side of the L-shaped partition plate 64 are extended, and the corresponding second baffle plate 66 and the corresponding third baffle plate 67 are in a closed state, so that crushed ice is prevented from being injected into the other weighing hopper 43. When the crushed ice in the corresponding bearing hopper 43 is about to reach the designated weight, the transmission rod of the first air cylinder 68 on one side of the L-shaped partition plate 64 extends out to drive the corresponding second baffle plate 66 to close, so that the flow limitation is performed on the crushed ice to ensure the weighing precision. When the crushed ice in the bearing hopper 43 reaches the designated weight, the transmission rod of the second air cylinder 69 on one side of the L-shaped partition plate 64 extends out to drive the corresponding third baffle 67 to be closed, and meanwhile, the transmission rods of the first air cylinder 68 and the second air cylinder 69 on the other side of the L-shaped partition plate 64 retract, so that the crushed ice is guided to be injected into the other weighing hopper 43 for weighing through the conveying of the variable-frequency conveyor 62, and the weighing is sequentially circulated. The method has the advantages of ensuring the production quality and improving the weighing precision.

In the above scheme, a second plastic plate 12 for preventing crushed ice from adhering is further fixedly connected to the inner wall of the bin 11 of the ice crusher 1, and a third vibrator 13 is further fixedly connected to the outer side of the bin 11. Crushed ice in the bin 11 can be completely discharged through the third vibrator 13 arranged, and the crushed ice is prevented from being frozen and bonded in the bin 11 through the second plastic plate 12 arranged.

In the above scheme, the first film is any one of a first polyethylene film, a first polypropylene film, a first polyvinyl chloride film and a first polyester film; the second film is any one of a second polyethylene film, a second polypropylene film, a second polyvinyl chloride film and a second polyester film; the third film is any one of a third polyethylene film, a third polypropylene film, a third polyvinyl chloride film and a third polyester film. The adoption of the mode has the advantage of ensuring the anti-sticking effect of crushed ice.

While embodiments of the utility model have been described above, it is not limited to the applications set forth in the description and the embodiments, which are fully applicable in various fields of endeavor to which the utility model pertains, and further modifications may readily be made by those skilled in the art, it being understood that the utility model is not limited to the details shown and described herein without departing from the general concept defined by the appended claims and their equivalents.

Claims

1. An automatic production equipment for crushed ice bags is characterized by comprising:

an ice crusher;

2. An automatic crushed ice bag production apparatus according to claim 1, wherein said conveying mechanism comprises:

3. An automatic crushed ice bag production device according to claim 1, wherein the material distribution mechanism comprises:

a support;

4. An automatic crushed ice bag production device according to claim 3, wherein the blanking device comprises:

the two variable-frequency spiral blanking machines are fixedly connected to the top of the support, and a feeding port of each variable-frequency spiral blanking machine is respectively communicated with a discharging port of the distributing hopper;

5. An automatic crushed ice bag production apparatus according to claim 3, wherein said weighing mechanism comprises:

the first connecting plate is fixedly connected to the middle of the bracket;

the discharge port of each weighing hopper is arranged at the top end of each weighing sensor and is fixedly connected with the discharge port of the blanking device, the discharge port of each weighing hopper is respectively communicated with the discharge port of the blanking device, a separation blade is hinged to the discharge port of each weighing hopper, each separation blade is in transmission connection with each weighing hopper, and the inner wall of each weighing hopper is coated with second teflon;

the U-shaped guide plate is fixedly connected to one side of the connecting plate in an inclined manner, the inlet of the U-shaped guide plate is communicated with the discharge ports of the two weighing hoppers, the outlet of the U-shaped guide plate is communicated with the feeding pipe, and the inner wall of the U-shaped guide plate is coated with third Teflon;

the two second thin films are respectively sleeved in the weighing hoppers;

and the third film is sleeved on the inner side of the U-shaped guide plate.

6. The automatic crushed ice bag production equipment as claimed in claim 5, wherein the transmission connection mode of each baffle plate and each weighing hopper is as follows: the bottom of each separation blade is fixedly connected with a connecting ring, each weighing hopper is fixedly connected with a connecting rod, each connecting rod is fixedly connected with a servo motor, a transmission shaft of each servo motor is fixedly connected with a torsion bar, the bottom of each torsion bar is sleeved in each connecting ring, and each servo motor is connected with each weighing sensor in a control mode through a weighing controller.

7. An automatic crushed ice bag production device according to claim 5, wherein the blanking device comprises:

8. An apparatus for automatically producing crushed ice and ice bags according to claim 7, wherein the flow restricting means comprises:

9. The automatic production equipment of crushed ice bags according to claim 1, wherein a second plastic plate for preventing crushed ice from bonding is further fixedly connected to the inner wall of the bin of the ice crusher, and a third vibrator is further fixedly connected to the outer side of the bin.

10. The automatic production equipment of crushed ice bags according to claim 5, wherein the first film is any one of a first polyethylene film, a first polypropylene film, a first polyvinyl chloride film and a first polyester film; the second film is any one of a second polyethylene film, a second polypropylene film, a second polyvinyl chloride film and a second polyester film; the third film is any one of a third polyethylene film, a third polypropylene film, a third polyvinyl chloride film and a third polyester film.