CN114703027A - Large-scale electrical heating wine making equipment based on intelligence control by temperature change - Google Patents

Abstract

The invention discloses large-scale electric heating wine brewing equipment based on intelligent temperature control, which comprises a liquid storage tank, a temperature control unit and a temperature control unit, wherein the liquid storage tank is used for storing wine liquid; the end part of the liquid guide pipe is connected with the liquid storage chamber; the storage tank is connected with the other end of the liquid guide pipe; the heating execution mechanism is arranged in the material storage tank, the vinasse in the evaporation cavity can be pushed to move from the bottom layer to the surface layer by the turnover part so as to enable the vinasse to flow to increase the gap between deposits, and during the specific implementation of the heating execution mechanism, the evaporation part can intermittently guide hot steam to enter the storage cavity so as to push the turnover part to linearly reciprocate along the storage cavity; and the overturning component pushes the vinasse in the evaporation cavity to move from the bottom layer to the surface layer when being pushed to rise by the hot steam and quickly descends when the hot steam does not enter the storage cavity any more so as to push the hot steam in the storage cavity to flow for a circle along the evaporation cavity and then be discharged.

Description

Large-scale electrical heating wine making equipment based on intelligence control by temperature change

Technical Field

The invention relates to the technical field of brewing equipment, in particular to large-scale electric heating brewing equipment based on intelligent temperature control.

Background

At present, the existing wine brewing equipment generally distills and brews wine by directly heating vinasse, so that steam and the vinasse are difficult to contact with each other, and the taste of brewed wine is influenced. Meanwhile, if the water content of the vinasse is too much, the vinasse is influenced on the quality of the wine and must be poured out, so that serious waste is caused. Therefore, if the water vapor is not in direct contact with the vinasse in the process of brewing the wine, the water cannot be mixed in the wine, the more mellow wine is brewed, the cost is saved, and the production efficiency is improved. However, the invention has the following defects: the vinasse close to the steam pipeline has higher temperature, the vinasse far away from the steam pipeline has lower temperature, the vinasse is heated unevenly due to large high-low temperature difference, and the vinasse is not mixed sufficiently, so that the quality and the taste of brewed wine are influenced during the distillation of the vinasse.

To solve the problem, there are various solutions for cold protection in the prior art, for example, patent document No. 201611015551.1, which discloses a brewing apparatus with heating function, which heats distiller's grains by hot air flow into a steam pipeline, so that the high-temperature steam pipeline heats the distiller's grains, avoids direct contact between water vapor and distiller's grains, and further, the wine is not mixed with water, and thus, more mellow wine is brewed; 2. hot water discharged from the condensing device enters the steam pipe to be changed into hot steam, and the hot steam enters the steam pipe and the exhaust pipe to enable the first hose and the second hose to move up and down, so that the heated vinasse in the sealed tank body is stirred, the heated vinasse is uniformly mixed without temperature difference and heated uniformly, and the quality and the taste of brewed wine are improved; 3. when the second valve is opened, hot steam exhausted from the second hose enters the steam tank through the exhaust pipe, and can be recycled, so that reasonable optimization and reutilization of resources are realized.

However, the above operation has limitations in terms of the accumulation of thick fermented glutinous rice, for example, during the distillation of fermented glutinous rice, the evaporation efficiency of the central area of fermented glutinous rice is low due to the accumulation of liquid in the central area of the thick fermented glutinous rice, and although there is a technical means for stirring the fermented glutinous rice accumulated together in the prior art, the operation mostly only temporarily loosens the accumulated fermented glutinous rice, and once the accumulation time is long, the phenomenon that the accumulated liquid accumulates to block the vent hole occurs.

Therefore, the electric heating wine brewing equipment in the prior art cannot solve the problem that steam is difficult to discharge in the center area of the thick fermented glutinous rice.

Disclosure of Invention

The invention aims to provide large-scale electric heating wine brewing equipment based on intelligent temperature control, and the large-scale electric heating wine brewing equipment is used for solving the technical problem that steam is difficult to discharge in a thick fermented glutinous rice center area in the prior art.

In order to solve the technical problems, the invention specifically provides the following technical scheme:

large-scale electrical heating wine brewing equipment based on intelligent temperature control comprises

The liquid storage tank is used for storing wine liquid;

the end part of the liquid guide pipe is connected with the liquid storage chamber;

the storage tank is connected with the other end of the liquid guide pipe;

the heating actuating mechanism is arranged in the material storage tank;

the intelligent temperature control system is connected to the material storage tank and is used for adjusting the temperature in the material storage tank in real time so that the temperature of each part in the material storage tank is within a set range;

wherein the heating actuator comprises an evaporation component, a turnover component and a guide component;

the evaporation part is connected inside the material storage tank, a feeding port and a storage cavity are arranged on the evaporation part, an evaporation cavity for storing vinasse is arranged in the evaporation part, the axial leads of the evaporation cavity, the feeding port and the storage cavity are positioned on the same straight line, the turnover part is connected in the evaporation cavity, and the guide part is arranged at the feeding port of the evaporation part;

the evaporation part can intermittently guide hot steam into the storage cavity to push the overturning part to linearly reciprocate along the storage cavity;

the turnover part can push the vinasse in the evaporation cavity to move from the bottom layer to the surface layer when being pushed to rise by hot steam and quickly descend when the hot steam does not enter the storage cavity any more so as to push the hot steam in the storage cavity to flow along the evaporation cavity for a circle and then be discharged;

the guide component can guide the steam generated after evaporation of the vinasse in the evaporation cavity to converge towards the pipe orifice of the liquid guide pipe; the liquid guide pipe can condense vapor evaporated from the vinasse and guide the condensed vapor to enter the liquid storage tank.

As a preferable aspect of the present invention, the evaporation component includes a fixed cylinder installed on an inner side wall of the liquid storage tank, the evaporation cavity, the input port, and the storage cavity are respectively and correspondingly arranged at the top, the middle, and the bottom of the fixed cylinder in the vertical direction, the fixed cylinder is provided with a heating flow channel, one end of the heating flow channel is communicated with a side wall of the bottom end of the storage cavity, and the other end of the heating flow channel extends to an outer surface of the liquid storage tank:

the overturning part comprises a push-up bag sleeve and a pneumatic column, the push-up bag sleeve is hermetically connected with the edge of the top of the storage cavity, the pneumatic column is slidably connected in the storage cavity, one end of the pneumatic column is connected with the center of the push-up bag sleeve, the bottom end of the storage cavity is provided with a one-way blocking sheet connected with the end part of the heating flow channel, and the one-way blocking sheet is used for blocking and limiting gas in the storage cavity from entering the heating flow channel; the pneumatic column can take the one-way blocking sheet to slide away from the heating flow channel in the process of being pushed to rise to the top end of the storage cavity by the gas filled in the storage cavity so as to release the limitation on the heating flow channel.

As a preferable scheme of the invention, a pull-back spring connected with the other end of the pneumatic column is arranged in the storage cavity;

the push-up capsule cover is installed a pair of spacer piece in the one side that is close to depositing a chamber top edge, and this is right the spacer piece can be when push-up capsule cover is pulled into depositing a intracavity the top of piece chamber is deposited in order to prevent that the lees from pouring into and depositing a chamber.

In a preferred embodiment of the present invention, the guide member includes a guide sleeve provided at the inlet and connected to the fixed cylinder, and a restriction block is provided inside the guide sleeve, and the restriction block is capable of restricting a maximum lift stroke of the pneumatic column.

As a preferable scheme of the invention, an unfolding net ring is arranged on the inner side wall of the fixed cylinder, a flow loop is arranged between the inner side wall of the fixed cylinder and the unfolding net ring, an air guide column connected with the unfolding net ring is arranged on the inner side wall of the fixed cylinder, and a guide strip is arranged on one side surface of the unfolding net ring and can guide the vinasse on the surface of the unfolding net ring to slide into the flow loop in an inclined trend so as to prevent the vinasse from aggregating into lumps in the sliding process.

As a preferable scheme of the invention, the surface of the push-up bag sleeve is provided with a plurality of inclined lead-in grooves, the inclined lead-in grooves are respectively arranged in pairs and are symmetrical with respect to the pneumatic column, and the inclined lead-in grooves can be driven by the pneumatic column to lift up along with the push-up bag sleeve and can slide vinasse to the surface of the spreading net ring in the lifting process;

the pneumatic support is characterized in that an installation cavity is formed in the inner wall of the top end of the storage cavity, a pressure applying spring is installed in the installation cavity, a pressure applying column is installed at one end, far away from the installation cavity, of the pressure applying spring, and the pressure applying column can push and push the push capsule sleeve to be tightly attached to the pneumatic column in the process of pushing the capsule sleeve to enter the storage cavity.

As a preferable scheme of the invention, the surface of one side of the push-lift balloon sleeve, which is close to the pressure application column, is connected with an air guide tube, a shaping balloon strip is installed at a position of the side wall of the air guide tube, which corresponds to the inclined introduction groove, the shaping balloon strip can be embedded into the inclined introduction groove to shape the inclined introduction groove, an expansion balloon is installed at one end of the air guide tube, which is far away from the pneumatic column, the side wall of the expansion balloon is connected with the packing sheet, and the compressed push-lift balloon sleeve can push the gas in the shaping balloon strip to enter the expansion balloon along the air guide tube in the process of compressing the push-lift balloon sleeve so as to expand the expansion balloon to expand the self volume.

As a preferred scheme of the invention, a sliding groove is formed in the position of the inner side wall of the storage cavity corresponding to the heating flow channel, and the one-way blocking sheet is arranged in the sliding groove;

the side wall of the pneumatic column is provided with a concave embedded groove, and the concave embedded groove can clamp the one-way blocking sheet and drive the one-way blocking sheet to slide along the sliding groove in a reciprocating mode in the moving process of the pneumatic column.

As a preferred scheme of the invention, an air guide passage is arranged in the spreading net ring, one end of the air guide passage is communicated with the heating flow passage through an air guide column, and a telescopic bag column is arranged on the inner wall of the other end of the air guide passage;

the air guide channel can guide air in the heating flow channel to enter the telescopic bag column.

In a preferred aspect of the present invention, the width of the inclined introduction groove provided in the push-up bag cover near the top edge of the storage chamber is not smaller than the width of the inclined introduction groove provided in the push-up bag cover near the pneumatic column.

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

the invention can push the vinasse in the evaporation cavity to move from the bottom layer to the surface layer through the turnover part so as to enable the vinasse to flow to increase the gap between deposits, and when the device is implemented, the evaporation part can intermittently guide hot steam to enter the storage cavity so as to push the turnover part to linearly reciprocate along the storage cavity; the turnover component pushes vinasse in the evaporation cavity to move from the bottom layer to the surface layer when being pushed to rise by hot steam and quickly descends when the hot steam does not enter the storage cavity any more so as to push the hot steam in the storage cavity to flow for a circle along the evaporation cavity and then be discharged; then the guide part can guide the steam generated after the vinasse in the evaporation cavity is evaporated to converge towards the pipe orifice of the liquid guide pipe; then the liquid guide pipe can condense the vapor evaporated from the vinasse and guide the condensed vapor into the liquid storage tank.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

FIG. 1 is a schematic view of the overall structure of a static pneumatic column according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of the overall structure of the pneumatic column of the embodiment of the present invention when the pneumatic column moves up to the maximum stroke;

fig. 3 is a schematic structural diagram of a fixed cylinder in the embodiment of the invention.

The reference numerals in the drawings denote the following, respectively:

1-a liquid storage tank; 2-a catheter; 3-storage tank; 4-a heating actuator; 5-a guide member; 6-an evaporation part; 7-a flipping member;

61-a fixed cylinder; 62-an evaporation cavity; 63-throwing in port; 64-a storage cavity; 65-heating the flow channel; 66-a pull back spring;

611-unfolding the net ring; 612-flow loop; 613-gas-conducting column; 614-guide strip; 615-air guide channel; 616-a bellows column;

641-mounting cavity; 642-pressing a spring; 643-a pressure applying column; 644-sliding groove;

71-pushing and lifting the capsule sleeve; 72-a pneumatic column; 73-one-way barrier sheet; 74-a septum; 711-inclined introduction groove; 712-shaping the balloon strips; 713-ballooning balloon; 714-airway tube;

51-a guide sleeve; 52-limiting block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in figure 1, the invention provides a large-scale electric heating wine brewing device based on intelligent temperature control, which comprises

The liquid storage tank 1 is used for storing wine liquid;

a liquid guide pipe 2, wherein the end part of the liquid guide pipe 2 is connected with the liquid storage chamber;

the storage tank 3 is connected with the other end of the liquid guide pipe 2;

the heating actuator 4 is arranged in the material storage tank 3;

the intelligent temperature control system is connected in the material storage tank 3 and is used for adjusting the temperature in the material storage tank 3 in real time so that the temperature of each part in the material storage tank 3 is in a set range;

wherein, the heating actuator 4 comprises an evaporation component 6, a turnover component 7 and a guide component 5;

the evaporation part 6 is connected inside the material storage tank 3, the evaporation part 6 is provided with a feeding port 63 and a storage cavity 64, the evaporation part 6 is internally provided with an evaporation cavity 62 for storing vinasse, the axial lines of the evaporation cavity 62, the feeding port 63 and the storage cavity 64 are positioned on the same straight line, the overturning part 7 is connected inside the evaporation cavity 62, and the guide part 5 is arranged at the feeding port 63 of the evaporation part 6;

the evaporation component 6 can intermittently guide hot steam into the storage cavity 64 to push the overturning component 7 to linearly reciprocate along the storage cavity 64;

the overturning part 7 can push the vinasse in the evaporation cavity 62 to move from the bottom layer to the surface layer when being pushed to rise by the hot steam and quickly descend when the hot steam does not enter the storage cavity 64 any more so as to push the hot steam in the storage cavity 64 to flow along the evaporation cavity 62 for one circle and then be discharged;

the guide part 5 can guide the steam evaporated from the vinasse in the evaporation cavity 62 to converge towards the pipe orifice of the liquid guide pipe 2; the liquid guide pipe 2 can condense the vapor evaporated from the vinasse and guide the condensed vapor into the liquid storage tank 1.

The invention can push the vinasse in the evaporation cavity 62 to move from the bottom layer to the surface layer by the turnover part 7, so that the vinasse flows to increase the clearance between deposits, and in the specific implementation, the evaporation part 6 intermittently guides hot steam into the storage cavity 64 to push the turnover part 7 to linearly reciprocate along the storage cavity 64; the overturning component 7 pushes the vinasse in the evaporation cavity 62 to move from the bottom layer to the surface layer when being pushed to rise by the hot steam and rapidly descends when the hot steam does not enter the storage cavity 64 any more so as to push the hot steam in the storage cavity 64 to flow along the evaporation cavity 62 for one circle and then be discharged; then the guide part 5 can guide the vapor evaporated from the vinasse in the evaporation cavity 62 to converge towards the nozzle of the liquid guide pipe 2; then the liquid guide pipe 2 condenses the vapor evaporated from the distiller's grains and guides the condensed vapor into the liquid storage tank 1.

In this embodiment, the intelligent temperature control system is used for controlling the temperature in the storage tank 3, and the specific structure thereof has various structures, where a temperature controller and an electromagnetic valve can be selected, the temperature controller is used for detecting the temperature in the storage tank 3, once the detected temperature is greater than a set temperature range, the electromagnetic valve can be used for controlling the hot steam not to enter the storage cavity 64, and if the detected temperature is smaller than the set temperature range, the hot steam is controlled to continuously enter the storage cavity 64 until the detected temperature is within the set temperature range.

As shown in fig. 1 and fig. 2, the evaporation component 6 includes a fixed cylinder 61 installed on the inner side wall of the liquid storage tank 1, the evaporation cavity 62, the input port 63 and the storage cavity 64 are respectively and correspondingly arranged on the top, the middle and the bottom of the fixed cylinder 61 in the vertical direction, the fixed cylinder 61 is provided with a heating flow channel 65, one end of the heating flow channel 65 is communicated with the bottom end side wall of the storage cavity 64, and the other end of the heating flow channel 65 extends to the outer surface of the liquid storage tank 1:

the overturning part 7 comprises a push-up bag sleeve 71 and a pneumatic column 72 which are hermetically connected with the top edge of the storage cavity 64, the pneumatic column 72 is slidably connected in the storage cavity 64, one end of the pneumatic column 72 is connected with the central position of the push-up bag sleeve 71, the bottom end of the storage cavity 64 is provided with a one-way blocking sheet 73 connected with the end part of the heating flow channel 65, and the one-way blocking sheet 73 is used for blocking and limiting gas in the storage cavity 64 from entering the heating flow channel 65; the pneumatic column 72 can slide away from the heating channel 65 with the one-way blocking piece 73 to release the restriction of the heating channel 65 during the process of being pushed up to the top of the storage chamber 64 by the gas filled in the storage chamber 64.

In order to complete the layer turning of the vinasse, in the specific implementation, the external hot steam injection device is required to intermittently inject hot steam into the storage cavity 64 (a timing valve can be optionally installed on a pipeline for injecting the heat evidence to control the intermittent injection of the steam), that is, as shown in fig. 1, the hot steam is injected from a through hole at the left side of the bottom of the storage cavity 64, then, the pressure in the storage cavity 64 gradually increases and pushes the pneumatic column 72 in the storage cavity 64 to rise, and the pneumatic column 72 pushes the push-up bag sleeve 71 to slide out of the storage cavity 64 when rising, and the specific structure is that the storage cavity 64 is slid and changed from the state shown in fig. 1 to the state shown in fig. 2.

During the raising of the pneumatic column 72 to the state shown in fig. 2, the distiller's grains (which are thrown into the evaporation chamber 62 in advance) at the bottom of the evaporation chamber 62 are pushed to move upward, and when the pneumatic column 72 is raised to the state shown in fig. 2, the pneumatic column 72 carries the one-way blocking piece 73 to slide away from the heating flow channel 65 to release the restriction of the heating flow channel 65, so that the steam can enter the heating flow channel 65.

In this embodiment, the aperture of the heating channel 65 can be made smaller to increase the evaporation efficiency, so as to limit the flow speed of the steam.

As shown in fig. 1 and 2, a pull-back spring 66 connected to the other end of the pneumatic column 72 is installed in the storage chamber 64;

the push-up bladder sleeve 71 is fitted with a pair of packing pieces 74 on a side near the top edge of the storage chamber 64, the pair of packing pieces 74 being capable of packing the top of the storage chamber 64 to prevent the reverse flow of the wine lees into the storage chamber 64 when the push-up bladder sleeve 71 is pulled into the storage chamber 64.

In order to prevent the steam from flowing slowly due to the small diameter of the heating channel 65, the gas can be assisted to enter the heating channel 65 by the pull-back spring 66.

As pneumatic column 72 rises, pneumatic column 72 will pull-back spring 66 to extend, and once pneumatic column 72 slides with one-way blocker 73, pull-back spring 66 will pull pneumatic column 72 to slide into storage chamber 64, during which pneumatic column 72 will increase the flow rate of steam into heating channel 65.

When the push-up bag cover 71 is sufficiently slid into the storage cavity 64 by the downwardly sliding pneumatic column 72, the packing pieces 74 will assume the state shown in fig. 1, that is, the pair of packing pieces 74 will pack the top of the storage cavity 64 to prevent the vinasse from flowing back into the storage cavity 64 when the push-up bag cover 71 is pulled into the storage cavity 64.

As shown in fig. 1 and 2, the guide member 5 includes a guide sleeve 51 provided at the inlet 63 and connected to the fixed cylinder 61, the guide sleeve 51 guides the vapor into the liquid guide tube 2, and a restricting piece 52 is provided inside the guide sleeve 51, and the restricting piece 52 can restrict the maximum lift stroke of the air column 72.

As shown in fig. 1 and 2, the inner side wall of the fixed cylinder 61 is provided with an expanded mesh ring 611, a flow loop 612 is arranged between the inner side wall of the fixed cylinder 61 and the expanded mesh ring 611, the inner side wall of the fixed cylinder 61 is provided with an air guide column 613 connected with the expanded mesh ring 611, one side surface of the expanded mesh ring 611 is provided with a guide strip 614, and the guide strip 614 can guide the vinasse on the surface of the expanded mesh ring 611 to slide into the flow loop 612 with an inclined trend so as to prevent the vinasse from being agglomerated in the sliding process (that is, the guide strip 614 is obliquely arranged on the surface of the expanded mesh ring 611).

In order to prevent the flowing vinasse from aggregating to form lumps in the flowing process, the vinasse on the surface of the spreading-out net ring 611 can be guided by the inclined guide bars 614 arranged on the surface of the spreading-out net ring 611 to slide into the flowing loop 612 in an inclined trend so as to prevent the vinasse from aggregating to lumps in the sliding process.

Under the condition of layer turning, the vinasse in the center of the bottom is driven to rise, and the vinasses on the two sides can gradually slide down under the influence of gravity to fill up the vacancy in the bottom.

As shown in fig. 1, 2 and 3, the surface of the push-up bag cover 71 is provided with a plurality of inclined introduction grooves 711, the inclined introduction grooves 711 are respectively arranged in pairs and symmetrically with respect to the pneumatic column 72, and the inclined introduction grooves 711 can be driven by the pneumatic column 72 to lift up along with the push-up bag cover 71 and slide the vinasse to the surface of the spreading net ring 611 in the lifting process (i.e. represent the protruding state of the inclined introduction grooves 711);

an installation cavity 641 is formed in the inner wall of the top end of the storage cavity 64, a pressure applying spring 642 is installed in the installation cavity 641, a pressure applying column 643 is installed at one end, far away from the installation cavity 641, of the pressure applying spring 642, and the pressure applying column 643 can push the push-up bag sleeve 71 to cling to the pneumatic column 72 in the process that the push-up bag sleeve 71 enters the storage cavity 64.

In order to further push the lees to slide down from both sides, when the push-up bag sleeve 71 is lifted, the part of the push-up bag sleeve 71 in the area of the inclined guide groove 711 is lifted by the pneumatic column 72 along with the whole push-up bag sleeve 71 and slides the lees to the surface of the spreading net ring 611 during lifting, that is, the lees flow is assisted by pushing the lees from the side through the part of the push-up bag sleeve 71 in the area of the inclined guide groove 711.

As shown in fig. 1, 2 and 3, an air duct 711 is connected to a surface of the push-up bag cover 71 on a side close to the pressure applying column 643, a shaping bag strip 712 is installed at a position of a side wall of the air duct 711 corresponding to the inclined introduction groove 711, the shaping bag strip 712 can be embedded into the inclined introduction groove 711 to shape the inclined introduction groove 711, an expansion bag 713 is installed at one end of the air duct 711 far from the pneumatic column 72, the side wall of the expansion bag 713 is connected to the packing sheet 74, and the push-up bag cover 71 pressed in the process of pressing the push-up bag cover 71 pushes air in the shaping bag strip 712 to enter the expansion bag 713 along the air duct 711 so as to expand the expansion bag 713.

In order to prevent the portion of the push-up bag cover 71 in the region of the inclined introduction groove 711 from being pressed flat by the distiller's grains, the portion of the push-up bag cover 71 in the region of the inclined introduction groove 711 is shaped by the shaping bag strip 712, that is, the strength of the portion of the push-up bag cover 71 in the region of the inclined introduction groove 711 is increased.

However, when the lees move to the bottom, the lees is likely to press on the ballooning bag 713, so that part of the lees is not moved sufficiently, when the push-up bag sleeve 71 is driven by the downward-sliding pneumatic column 72 to slide into the storage cavity 64 sufficiently, the pressing column 643 presses and pushes the push-up bag sleeve 71 against the pneumatic column 72 in the process of pushing the push-up bag sleeve 71 into the storage cavity 64, at this time, the shaping bag strip 712 is also compressed, so that the gas in the shaping bag strip 712 enters the ballooning bag 713 along the air duct 711, that is, the pressed push-up bag sleeve 71 pushes the gas in the shaping bag strip 712 into the ballooning bag 713 along the air duct 711 in the process of pushing the push-up bag sleeve 71, so that the ballooning bag 713 expands in its own volume, and then the accumulated lees move toward the upper rope area of the push-up bag sleeve 71.

As shown in fig. 1 and fig. 2, a sliding groove 644 is formed in a position of the inner side wall of the storage cavity 64 corresponding to the heating flow channel 65, and the one-way blocking sheet 73 is arranged in the sliding groove 644;

the side wall of the pneumatic column 72 is provided with a concave embedding groove 721, and the concave embedding groove 721 can clamp the one-way blocking sheet 73 and can drive the one-way blocking sheet 73 to slide along the sliding groove 644 in a reciprocating manner in the moving process of the pneumatic column 72.

In this embodiment, the width dimension of the sliding groove 644 is not smaller than the width dimension of the one-way blocking sheet 73, so that the one-way blocking sheet 73 does not return automatically.

As shown in fig. 2, when the pneumatic column 72 rises to a certain height, the one-way blocking plate 73 is driven to slide along the sliding groove 644 and rise, when the pneumatic column 72 descends, the one-way blocking plate 73 is pushed to reset, and when the one-way blocking plate 73 slides along the sliding groove 644 and rises, the gas in the storage cavity 64 enters the heating channel 65.

As shown in fig. 1, 3 and 3, an air guide duct 615 is arranged in the expanded mesh ring 611, one end of the air guide duct 615 is communicated with the heating channel 65 through an air guide column 613, and a bellows column 616 is arranged on the inner wall of the other end of the air guide duct 615;

the air guide tube 615 can guide the air in the heating channel 65 into the bellows column 616.

The gas in the heating flow channel 65 can enter the air guide channel 615 and gradually fill the bellows column 616, so that the evaporation efficiency of the lees is higher due to more gaps.

The width of the inclined lead-in groove 711 provided in the push-up bag cover 71 near the top edge of the storage cavity 64 is not smaller than the width of the inclined lead-in groove 711 provided in the push-up bag cover 71 near the pneumatic column 72, so that the vinasse near the top edge of the storage cavity 64 can be sufficiently pushed without being pushed.

The above embodiments are only exemplary embodiments of the present application, and are not intended to limit the present application, and the protection scope of the present application is defined by the claims. Various modifications and equivalents may be made to the disclosure by those skilled in the art within the spirit and scope of the disclosure, and such modifications and equivalents should also be considered as falling within the scope of the disclosure.

Claims (10)

1. The utility model provides a large-scale electrical heating making wine equipment based on intelligence control by temperature change which characterized in that: comprises that

The liquid storage tank (1) is used for storing wine liquid;

a liquid guide pipe (2), wherein the end part of the liquid guide pipe (2) is connected with the liquid storage chamber;

the storage tank (3), the storage tank (3) is connected with the other end of the liquid guide pipe (2);

the heating execution mechanism (4) is arranged in the material storage tank (3);

the intelligent temperature control system is connected in the material storage tank (3) and is used for adjusting the temperature in the material storage tank (3) in real time so that the temperature of each part in the material storage tank (3) is in a set range;

wherein the heating actuator (4) comprises an evaporation component (6), a turnover component (7) and a guide component (5);

the evaporation component (6) is connected to the inside of the material storage tank (3), a feeding port (63) and a storage cavity (64) are formed in the evaporation component (6), an evaporation cavity (62) for storing vinasse is arranged in the evaporation component (6), the axial lines of the evaporation cavity (62), the feeding port (63) and the storage cavity (64) are on the same straight line, the overturning component (7) is connected to the inside of the evaporation cavity (62), and the guide component (5) is arranged at the feeding port (63) of the evaporation component (6);

the evaporation component (6) can intermittently guide hot steam into the storage cavity (64) to push the overturning component (7) to linearly reciprocate along the storage cavity (64);

the overturning component (7) can push vinasse in the evaporation cavity (62) to move from the bottom layer to the surface layer when being pushed to rise by hot steam and quickly descend when the hot steam does not enter the storage cavity (64) any more so as to push the hot steam in the storage cavity (64) to flow along the evaporation cavity (62) for one circle and then be discharged;

the guide part (5) can guide steam generated after evaporation of vinasse in the evaporation cavity (62) to converge towards the pipe opening of the liquid guide pipe (2); the liquid guide pipe (2) can condense vapor evaporated from the vinasse and guide the condensed vapor to enter the liquid storage tank (1).

2. The large-scale electric heating wine brewing equipment based on intelligent temperature control as claimed in claim 1, wherein: evaporation parts (6) are including installing fixed cylinder (61) of depositing fluid reservoir (1) inside wall, evaporation chamber (62), input mouth (63) and deposit a chamber (64) and correspond the top, middle part and the bottom that sets up in fixed cylinder (61) vertical side respectively, be provided with heating runner (65) on fixed cylinder (61), the one end of heating runner (65) with deposit the bottom lateral wall intercommunication in a chamber (64), the other end of heating runner (65) extends to and deposits fluid reservoir (1) surface:

the overturning component (7) comprises a push-lifting bag sleeve (71) and a pneumatic column (72) which are hermetically connected to the top edge of the storage cavity (64), the pneumatic column (72) is connected in the storage cavity (64) in a sliding manner, one end of the pneumatic column (72) is connected with the center of the push-lifting bag sleeve (71), a one-way blocking sheet (73) connected with the end part of the heating flow channel (65) is arranged at the bottom end of the storage cavity (64), and the one-way blocking sheet (73) is used for blocking and limiting gas in the storage cavity (64) from entering the heating flow channel (65); the pneumatic column (72) can slide away from the heating flow channel (65) with the one-way blocking sheet (73) in the process of being pushed to rise to the top end of the storage cavity (64) by the gas filled in the storage cavity (64) so as to release the restriction on the heating flow channel (65).

3. The large-scale electric heating wine brewing equipment based on intelligent temperature control as claimed in claim 2, wherein: a pull-back spring (66) connected with the other end of the pneumatic column (72) is arranged in the storage cavity (64);

the push-up capsule sleeve (71) is provided with a pair of sealing sheets (74) at one side close to the top edge of the storage cavity (64), and the pair of sealing sheets (74) can seal the top of the storage cavity (64) to prevent the vinasse from pouring into the storage cavity (64) when the push-up capsule sleeve (71) is pulled into the storage cavity (64).

4. The large-scale electric heating wine brewing equipment based on intelligent temperature control as claimed in claim 2, wherein: the guide member (5) comprises a guide sleeve (51) which is arranged at the input port (63) and is connected with the fixed cylinder (61), a limiting block (52) is arranged on the inner side of the guide sleeve (51), and the limiting block (52) can limit the maximum lifting stroke of the pneumatic column (72).

5. The large-scale electric heating wine brewing equipment based on intelligent temperature control as claimed in claim 2, wherein: the inside wall of solid fixed cylinder (61) is provided with and spreads out net ring (611), gu fixed cylinder (61) inside wall with it flows circuit (612) to spread out to be provided with between net ring (611), gu fixed cylinder (61) inside wall is equipped with air guide column (613) of being connected with spreading out net ring (611), a side surface that spreads out net ring (611) is provided with guide strip (614), guide strip (614) can guide the lees that spread out net ring (611) surface to slide into flow circuit (612) with the trend of slope in order to prevent that lees from gathering into a mass at the slip process.

6. The large-scale electric heating wine brewing equipment based on intelligent temperature control as claimed in claim 5, wherein: the surface of the push-up bag sleeve (71) is provided with a plurality of inclined leading-in grooves (711), the inclined leading-in grooves (711) are respectively arranged pairwise and symmetrically relative to the pneumatic column (72), and the inclined leading-in grooves (711) can be driven by the pneumatic column (72) to lift up along with the push-up bag sleeve (71) and slide vinasse to the surface of the spreading net ring (611) in the lifting process;

an installation cavity (641) is formed in the inner wall of the top end of the storage cavity (64), a pressure applying spring (642) is installed in the installation cavity (641), a pressure applying column (643) is installed at one end, far away from the installation cavity (641), of the pressure applying spring (642), and the pressure applying column (643) can extrude and push the push and lift bag sleeve (71) to be attached to the pneumatic column (72) in the process that the push and lift bag sleeve (71) enters the storage cavity (64).

7. The large-scale electric heating wine brewing equipment based on intelligent temperature control as claimed in claim 6, wherein: the surface of one side, close to the pressure applying column (643), of the push-lift bag sleeve (71) is connected with an air guide tube (714), a shaping bag strip (712) is installed at a position, corresponding to the inclined guide groove (711), of the side wall of the air guide tube (714), the shaping bag strip (712) can be embedded into the inclined guide groove (711) to shape the inclined guide groove (711), an expansion bag (713) is installed at one end, far away from the pneumatic column (72), of the air guide tube (714), the side wall of the expansion bag (713) is connected with the isolation piece (74), and the push-lift bag sleeve (71) pressed in the process that the push-lift bag sleeve (71) is pressed can push air in the shaping bag strip (712) to enter the expansion bag (713) along the air guide tube (714) so that the expansion bag (713) expands in volume.

8. The large-scale electric heating wine brewing equipment based on intelligent temperature control as claimed in claim 6, wherein: a sliding groove (644) is formed in the position, corresponding to the heating flow channel (65), of the inner side wall of the storage cavity (64), and the one-way blocking sheet (73) is arranged in the sliding groove (644);

the side wall of the pneumatic column (72) is provided with a concave embedding groove (721), and the concave embedding groove (721) can clamp the one-way blocking sheet (73) and drive the one-way blocking sheet (73) to slide along the sliding groove (644) in a reciprocating mode in the moving process of the pneumatic column (72).

9. The large-scale electric heating wine brewing equipment based on intelligent temperature control as claimed in claim 5, wherein: an air guide channel (615) is arranged in the spreading net ring (611), one end of the air guide channel (615) is communicated with the heating flow channel (65) through an air guide column (613), and a telescopic bag column (616) is installed on the inner wall of the other end of the air guide channel (615); the air guide channel (615) can guide the gas in the heating flow channel (65) to enter the telescopic bag column (616).

10. The large-scale electric heating wine brewing equipment based on intelligent temperature control as claimed in claim 6, wherein: the width of an inclined lead-in groove (711) arranged on the edge of the push-lift bag sleeve (71) close to the top of the storage cavity (64) is not less than the width of an inclined lead-in groove (711) arranged on the push-lift bag sleeve (71) close to the pneumatic column (72).

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