CN216337528U - Feeding device for grain soaking barrel - Google Patents

Abstract

The utility model discloses a feeding device for a grain soaking barrel, which comprises: the discharge port of the feeding pipe is communicated with the mixing device; the water outlet of the water inlet pipe is communicated with the mixing device; the mixing device is provided with a cavity structure, the material conveyed by the feeding pipe and the hot water conveyed by the water inlet pipe are mixed in the cavity structure of the mixing device, and the cavity structure of the mixing device is also communicated with the discharging pipe; the discharging pipe, the mixed feed inlet switch-on mixing arrangement's of discharging pipe cavity structure, the mixed discharge gate switch-on of discharging pipe steep the grain bucket. According to the utility model, the materials and the hot water are firstly mixed in the mixing device and then discharged into the grain soaking barrel, so that the hot water and the materials can be fully mixed again, and the water temperature is uniformly distributed up and down, thereby solving the problem of non-uniform temperature during grain soaking. Meanwhile, the cover plate structure designed by the utility model also solves the technical problem that the pipe wall is mildewed and smelly.

Description

Feeding device for grain soaking barrel

Technical Field

The utility model relates to the technical field of wine brewing, in particular to a feeding device for a grain soaking barrel.

Background

In the brewing process of the white spirit, grains for brewing wine generally need to be soaked in grains, and the grains can absorb moisture when being soaked in the grains, so that the grains are easy to steam and penetrate through the heart in the subsequent cooking process, the gelatinization is good, and most of tannin contained in sorghum is removed in water during the grain soaking process, thereby being beneficial to saccharification and fermentation. Meanwhile, the ash and sand sundries in the grains can be removed after soaking the grains, so that the raw materials are cleaner. When the grain soaking operation is carried out, water is generally required to be enough, the water temperature after grain is added and stirred is kept between 70 ℃ and 74 ℃, the grain soaking time is 6-10 hours, and the water soaking temperature is above 90 ℃.

In the grain soaking process, generally, grains are conveyed to the upper part of a grain soaking barrel through a conveyor, then fall into the grain soaking barrel through a corresponding blanking pipe, and hot water is conveyed to the grain soaking barrel through a pipeline. At present, the grain soaking modes are the following three modes: firstly, water is firstly added to grains, namely when grains are soaked, hot water is firstly discharged into a grain soaking barrel, and then grains are poured in, so that the upper and lower water temperatures in the grain soaking barrel are consistent, the grains are heated uniformly, and the water absorption is uniform; secondly, firstly, discharging grains into a grain soaking barrel and then pouring hot water into the grain soaking barrel when the grains are soaked in water; and thirdly, simultaneously discharging grains and hot water into the grain soaking barrel through the feed pipe and the water inlet pipe respectively, so that the grains and the hot water are simultaneously mixed in the grain soaking barrel. For the first mode, hot water heat is absorbed by grains after the grains enter the water surface, and the hot water heat on the upper layer is absorbed when all the grains fall into the water from top to bottom, so that the temperature difference between the water and the water is large, and the grain soaking effect is influenced. To the second mode, hot water gets into behind the grain layer surface course and is absorbed hot water heat by grain, and the temperature is lower when leading to hot water to fall into the bottom to produce great difference in temperature from top to bottom, influenced the grain effect of steeping. For the third mode, this mode causes the material to wet inhomogeneous easily, leads to some materials not yet by hot water wet soak just to be buried in the material heap, and in continuous reinforced in-process, this kind of problem is more outstanding, even solve through the mode of stirring, nevertheless the material that is wetted afterwards and soaked and the material that is wetted and soaked earlier have great difference in temperature and weight difference (the water absorption volume difference leads to), finally also can lead to the temperature to produce great difference in temperature from top to bottom. Therefore, the three methods adopted at present have the problem of uneven temperature during grain soaking, and finally cause low grain soaking quality.

In addition, when steeping grain, when grain gets into the grain bucket through the inlet pipe, dust impurity in the grain can the adhesion on the pipe wall, upwards scurries into in the inlet pipe at the hot water steam that grain in-process bubble grain water produced, can produce the muddy thing that has the stickness and the adhesion on the pipe wall after steam and the dust of adhesion on the pipe wall fuse, and in certain time, the muddy thing of adhesion takes place the microbial reaction under the aerobic environment and leads to the pipe wall to go mildy, smelly to influence food safety.

SUMMERY OF THE UTILITY MODEL

The utility model aims to: aiming at the existing problems, the utility model provides a feeding device for a grain soaking barrel, which is characterized in that materials and hot water are mixed in a mixing device for the first time, the materials and the hot water can be quickly and fully wetted by mixing the materials for the first time under the action of the conveying force of the materials and the conveying force of the hot water, and then the materials and the hot water can be fully mixed again after being discharged into the grain soaking barrel, and the water temperature is uniformly distributed up and down at the moment, so that the problem of non-uniform temperature during grain soaking is solved.

The technical scheme adopted by the utility model is as follows: a kind of grain soaking barrel uses the feed arrangement, it includes:

the feeding pipe is used for conveying materials, a feeding hole of the feeding pipe is communicated with the material conveying device, and a discharging hole of the feeding pipe is communicated with the mixing device;

the water inlet pipe is used for conveying hot water, a water inlet of the water inlet pipe is communicated with the hot water conveying device, and a water outlet of the water inlet pipe is communicated with the mixing device;

the mixing device is used for mixing materials and hot water, the mixing device is provided with a cavity structure, the materials conveyed by the feeding pipe and the hot water conveyed by the water inlet pipe are mixed in the cavity structure of the mixing device, and the cavity structure of the mixing device is also communicated with the discharging pipe;

the discharging pipe is used for discharging mixed materials in the mixing device into the grain soaking barrel, a mixed feeding hole of the discharging pipe is communicated with the cavity structure of the mixing device, and a mixed discharging hole of the discharging pipe is communicated with the grain soaking barrel.

Because the setting of above-mentioned structure, when carrying out the operation of steeping grain, carry material and hot water respectively through inlet pipe and inlet tube, material and hot water realize mixing in mixing arrangement, then in discharging the grain bucket of steeping through the discharging pipe, realized from this that material and water get into simultaneously and steep the grain bucket, this feeding mode can make to steep the grain bucket when carrying out the operation of steeping grain, the difference in temperature of temperature is very little, and then solved traditional inhomogeneous problem of temperature when steeping grain, the degree of soaking and the uniformity of temperature that make the material are better, avoided appearing because of the not high problem that influences the wine quality of grain quality of steeping.

In the utility model, in order to solve the problem of mildewing and smelling of the pipe wall, a cover plate is arranged at the mixed discharge port of the discharge pipe and is used for opening or/and closing the mixed discharge port of the discharge pipe. Prevent through the apron that the vapor in the grain bucket of steeping from scurrying into in the discharging tube, solve the moldy, smelly problem of pipe wall from this.

In order to reduce the use cost of the cover plate and ensure the working reliability of the cover plate, the cover plate is movably connected with the discharge pipe, covers the mixed discharge hole of the discharge pipe under the action of the self gravity of the cover plate, and is separated from the mixed discharge hole of the discharge pipe under the action of impact of materials in the discharge pipe. The cover plate of the utility model realizes the automatic opening and closing functions under the action of the self gravity and the impact force of materials, has simple structure and strong working reliability, and has the use cost obviously lower than that of a manual operation and automatic control (such as electric valve control).

Furthermore, in order to better realize the cover plate of the utility model, the discharge pipe is bent to form a certain radian, so that the included angle between the pipe axis at the mixed discharge port of the discharge pipe and the gravity line of the cover plate is 30-150 degrees.

Preferably, the included angle between the tube axis at the mixing discharge port of the discharge tube and the gravity line of the cover plate is 45-90 degrees. In this contained angle within range, the mixing material in the discharging tube can all be arranged to the greatest extent, can not have remaining material to stay in the discharging tube, but also can reduce the flow that steam scurried into in the discharging tube in a large number, has further avoided steam to scurry into intraductally and make and close moldy smelly problem.

In the utility model, in order to filter hot water and facilitate later installation and maintenance, a filter screen is arranged in the cavity structure of the mixing device and is used for filtering hot water.

Preferably, the filter screen has a cylindrical structure, the end openings of the filter screen correspond to the discharge port of the feed pipe and the mixing feed port of the discharge pipe respectively, and the side surface of the filter screen corresponds to the water outlet of the water inlet pipe.

In the utility model, in order to wash the feeding pipe, a spray cleaning head is arranged in the feeding pipe and is used for cleaning the feeding pipe.

The utility model also comprises a grain soaking method, wherein the material and the hot water are simultaneously discharged into the grain soaking barrel through the feeding device, and then the grain soaking operation is carried out. The method can solve the problem of non-uniform temperature during traditional grain soaking, and improve grain soaking quality.

In summary, due to the adoption of the technical scheme, the utility model has the beneficial effects that: according to the utility model, the materials and the hot water are mixed in the mixing device for the first time, under the action of the conveying force of the materials and the conveying force of the hot water, the materials can be quickly and fully wetted by mixing the materials and the hot water for the first time, then the materials and the hot water can be fully mixed again after being discharged into the grain soaking barrel, and the water temperature is uniformly distributed up and down, so that the problem of non-uniform temperature during grain soaking is solved. Meanwhile, the utility model designs a cover plate structure, and the technical problem that the pipe wall is moldy and smelly is solved through the cover plate structure.

Drawings

FIG. 1 is a schematic structural view of a feeding device for a grain soaking barrel according to the present invention;

FIG. 2 is a schematic view of another feeding device for a grain soaking barrel according to the present invention;

fig. 3 is a schematic structural view of a feeding device of the utility model when two grain soaking barrels are used in pair. The labels in the figure are: 1 is the feed inlet, 2 is for advancing the spray cleaning head, 3 is the inlet pipe, 4 is mixing arrangement, 401 is the cavity, 5 is the filter screen, 6 is the discharging pipe, 7 is the apron, 8 is the grain bucket of steeping, 9 is the inlet valve, 10 is the inlet tube.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings.

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

Example 1

As shown in fig. 1, a grain soaking feeding device comprises:

the feeding pipe 3 is arranged above the grain soaking barrel 8 and used for conveying materials, openings at two ends of the feeding pipe 3 respectively form a feeding port 1 and a discharging port, the feeding port 1 is communicated with the material conveying device, and the discharging port is communicated with the mixing device 4;

the mixing device 4 is arranged above the grain soaking barrel 8 and can be directly and fixedly connected to the grain soaking barrel 8, the mixing device 4 is of a cavity structure, materials and water are mixed in the cavity 401, the mixing device 4 comprises a feed pipe connector, a water inlet pipe connector and a discharge pipe connector which are respectively communicated with the cavity structure, the feed pipe connector is communicated with a discharge port of the feed pipe 3, the water inlet pipe connector is communicated with a water outlet of the water inlet pipe 10, and the discharge pipe connector is communicated with a mixing feed port of the discharge pipe 6;

the water inlet pipe 10 is arranged above the grain soaking barrel 8 and used for conveying hot water, two openings at two ends of the water inlet pipe 10 respectively form a water inlet and a water outlet, the water inlet is communicated with the hot water conveying device, and the water inlet pipe 10 is communicated with the cavity 401 of the mixing device 4 through the water outlet;

the discharging pipe 6 is arranged in the grain soaking barrel 8 and used for conveying mixed materials formed by mixing water and materials, openings at two ends of the discharging pipe 6 respectively form a mixing feeding hole and a mixing discharging hole, the discharging pipe 6 is communicated with the cavity 401 of the mixing device 4 through the mixing feeding hole, and therefore the mixed materials in the mixing device 4 are discharged into the grain soaking barrel 8 through the mixing discharging hole of the discharging pipe 6.

The operation principle of the grain soaking feeding device is as follows: when carrying out bubble grain operation, come transport material and hot water respectively through inlet pipe 3 and inlet tube 10, material and hot water realize mixing in mixing arrangement 4, then in discharging bubble grain bucket 8 through discharging pipe 6, realized from this that material and water get into simultaneously and steep grain bucket 8, this feeding mode can make bubble grain bucket 8 when carrying out bubble grain operation, the difference in temperature of temperature is very little, and then the inhomogeneous problem of temperature when having solved traditional bubble grain, the degree of soaking and the uniformity of temperature that make the material are better, the problem of having avoided influencing the wine quality because of steeping the grain quality is not high appears.

The feeding mode of this embodiment is realized the first time with material and hot water in mixing arrangement 4 and mixes, under the transport force of the transport power of material and hot water, the material just can make the material fully wet fast with the first time of hot water, then after discharging in steeping grain bucket 8, hot water can realize the intensive mixing once more with the material, and the distribution is more even about the temperature, can solve the inhomogeneous problem of temperature when steeping grain from this.

In order to better highlight the effect of the present embodiment on solving the problem of uneven temperature distribution, table 1 shows the difference between the present embodiment and the traditional grain soaking method in terms of water temperature distribution.

The test process comprises the following steps: a plurality of grain soaking barrels with the same specification are taken, and are respectively marked as a barrel No. 1, a barrel No. 2, a barrel No. 3, a barrel No. 4, a barrel No. 5 and a barrel No. 6, equivalent sorghum and hot water are simultaneously conveyed into a marking barrel at the same time, the temperature of the hot water is 85 ℃, wherein the feeding devices of the barrel No. 1 and the barrel No. 2 adopt the embodiment, the barrel No. 3 and the barrel No. 4 adopt a mode of firstly discharging the sorghum and then discharging the hot water, the barrel No. 5 and the barrel No. 6 adopt a mode of firstly discharging the hot water and then discharging the sorghum, the discharging is finished within 10min, the water level height in the marking barrels No. 6 is 1.2m, after 10min, the temperature thermometers with the height of three positions of 0m, 0.5m and 1m in each barrel are respectively measured, and a table 1 is obtained.

Table 1 example 1 and traditional grain steeping method water temperature distribution results

The temperature difference between the barrel No. 1 and the barrel No. 2 is the minimum, so that the problem of uneven temperature during grain soaking can be solved, and the technical effect obtained in the aspect of water temperature distribution during grain soaking is optimal.

Example 2

The embodiment is the same as the embodiment 1, and has a difference that a spraying cleaning head 2 is arranged in the feeding pipe 3, as shown in fig. 1, the spraying cleaning head 2 is connected with a spraying device, and the spraying cleaning head 2 and the spraying device adopt the existing spraying cleaning head and the existing spraying device, and have no special requirement as long as the spraying operation can be realized. The inlet pipe 3 can realize the washing in the inlet pipe 3 through spraying cleaning head 2, guarantees the cleanliness factor in the inlet pipe 3, avoids the wall pipe scale deposit, adhesion material and moldy, smelly problem to take place.

Example 3

The present embodiment is the same as embodiment 1, and the difference is that a cover plate 7 for opening and closing the discharging pipe is disposed at the mixed discharging port of the discharging pipe 6, as shown in fig. 1, the cover plate 7 is disposed to prevent the water vapor in the grain soaking bucket 8 from flowing into the discharging pipe 6 and other parts to cause the problem of mildewing and smelling of the pipe wall, when feeding into the grain soaking bucket 8, the cover plate 7 opens the mixed discharging port, at this time, the discharging pipe 6 is in a smooth state, when stopping feeding into the grain soaking bucket 8, the cover plate 7 closes the mixed discharging port, at this time, the discharging pipe 6 is in a closed state, and the water vapor in the grain soaking bucket 8 is difficult to enter the discharging pipe 6 through the cover plate 7.

The operation of how to open and close the cover plate 7 can be realized by manual operation or automatic control. As an improved embodiment, the cover plate 7 is rotatably connected to the discharge pipe 6, and under the normal condition, the cover plate 7 covers the mixed discharge port under the action of its own gravity, so that the discharge pipe 6 is in a closed state; when the discharging pipe 6 begins to discharge, the cover plate 7 opens the mixed discharging hole under the impact action of the mixed materials, the discharging pipe 6 is in an unblocked state, and when the discharging pipe 6 does not discharge any more, the cover plate 7 covers the mixed discharging hole under the action of self gravity. This set up mode simple structure, the power that provides is strikeed through 7 self action of gravity of apron and material realizes opening and shutting of apron 7, compares in traditional manual work and automatic control's mode, and use cost is low, and operational reliability is strong.

Further, in order to better implement the above-mentioned embodiment, the discharge pipe 6 is bent in a certain arc, so that the included angle between the pipe axis at the mixing discharge port and the gravity line of the cover plate is 30 to 150 degrees, as shown in fig. 2. This mode of setting up not only can realize the automation of apron 7 and open and close, can also avoid the mixed discharge gate of the direct impact of steam in the grain bucket 8 of steeping, and then can effectively reduce the flow that steam got into discharging pipe 6. Preferably, in order to ensure that the materials in the discharge pipe 6 completely enter the grain soaking barrel 8, the included angle between the pipe axis at the mixed discharge port and the gravity line of the cover plate 7 is preferably 45-90 degrees, the mixed materials in the discharge pipe 6 can be completely discharged within the range of the included angle, the flow rate of water vapor flowing into the discharge pipe 6 can be greatly reduced, and the problem that the closure is mildewed and smelly due to the fact that the water vapor flows into the pipe is further avoided.

Example 4

This embodiment is the same as embodiment 1 except that a filter net 5 is provided in the cavity 401 of the mixing device 4, and the filter net 5 is used for filtering hot water while preventing materials from entering the water inlet pipe 10. As shown in fig. 1 and 2, the discharge port of the water inlet pipe 10 is located above the mixing device 4, the water outlet of the water inlet pipe 10 is located on the side surface of the mixing device 4, the mixing feed port of the discharge pipe 6 is located below the mixing device 4, the filter screen 5 has a cylindrical structure, the end openings of the filter screen are respectively corresponding to the discharge port and the mixing feed port so as to avoid blocking materials, the side surface of the filter screen 5 is corresponding to the water outlet, hot water filtering is realized, and the materials are prevented from entering the water inlet pipe 10. The filtering holes of the filtering net 5 should be smaller than the grain size of the material, but should not be too small to avoid the filtering holes from being too small to cause large obstruction effect on hot water, generally, the size of the filtering holes can be selected from 20 meshes, 25 meshes, 30 meshes, 40 meshes, 50 meshes, 80 meshes, and the like.

Example 5

The embodiment is the same as the embodiment 1, and the difference is that in general, every two grain soaking barrels are arranged in pairs, as shown in fig. 3, therefore, when a feeding device is arranged, two feeding pipes 3 are correspondingly arranged, and the two feeding pipes 3 can share one feeding port 1. Correspondingly, the inlet tube 10 also corresponds to set up to two, and two inlet tubes 10 also can share a water inlet, set up inlet valve 9 on the inlet tube 10, all set up a mixing arrangement 4 on every grain bucket 8 of steeping. The grain soaking operation of the two grain soaking barrels 8 can be completed through one feeding hole and one water inlet in the arrangement mode, the structure of the equipment is simplified, and the cost of the equipment is reduced. Of course, the inlet pipe 3, the inlet pipe 10 and other components are not limited to two, and they may be respectively arranged corresponding to the grain soaking barrel 8 one by one, for example, when the grain soaking barrel 8 is 4 pairs, the inlet pipe 3 and the inlet pipe 10 are correspondingly arranged 4.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (8)

1. The utility model provides a steep grain feed arrangement for bucket which characterized in that, it includes:

the feeding pipe is used for conveying materials, a feeding hole of the feeding pipe is communicated with the material conveying device, and a discharging hole of the feeding pipe is communicated with the mixing device;

the water inlet pipe is used for conveying hot water, a water inlet of the water inlet pipe is communicated with the hot water conveying device, and a water outlet of the water inlet pipe is communicated with the mixing device;

the mixing device is used for mixing materials and hot water, the mixing device is provided with a cavity structure, the materials conveyed by the feeding pipe and the hot water conveyed by the water inlet pipe are mixed in the cavity structure of the mixing device, and the cavity structure of the mixing device is also communicated with the discharging pipe;

the discharging pipe is used for discharging mixed materials in the mixing device into the grain soaking barrel, a mixed feeding hole of the discharging pipe is communicated with the cavity structure of the mixing device, and a mixed discharging hole of the discharging pipe is communicated with the grain soaking barrel.

2. The feeding device for the grain soaking bucket according to claim 1, wherein a cover plate is arranged at the mixed discharge port of the discharge pipe, and the cover plate is used for opening or/and closing the mixed discharge port of the discharge pipe.

3. The feeding device for the grain soaking bucket according to claim 2, wherein the cover plate is movably connected with the discharge pipe, the cover plate is covered with the mixed discharge port of the discharge pipe under the action of the self gravity of the cover plate, and is separated from the mixed discharge port of the discharge pipe under the action of impact of the material in the discharge pipe.

4. The feeding device for the grain soaking bucket according to claim 3, wherein the discharging pipe is bent to form a certain radian, so that the included angle between the pipe axis at the mixed discharging port of the discharging pipe and the gravity line of the cover plate is 30-150 degrees.

5. The feeding device for the grain soaking barrel as claimed in claim 4, wherein the included angle between the tube axis at the mixing discharge port of the discharge tube and the gravity line of the cover plate is 45-90 °.

6. The feeding device for the grain soaking barrel as claimed in any one of claims 1 to 5, wherein a filter screen is arranged in the cavity structure of the mixing device, and the filter screen is used for filtering hot water.

7. The feeding device for the grain soaking barrel as claimed in claim 6, wherein the filter screen has a cylindrical structure, the end openings of the filter screen correspond to the discharge port of the feeding pipe and the mixing feed port of the discharging pipe, respectively, and the side surface of the filter screen corresponds to the water outlet of the water inlet pipe.

8. The feeding device for the grain soaking barrel as claimed in claim 7, wherein a spray cleaning head is arranged in the feeding pipe, and the spray cleaning head is used for cleaning the feeding pipe.

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