CN210203189U - Low-temperature vacuum hydraulic impregnation device - Google Patents

Abstract

The utility model discloses a low temperature vacuum hydraulic pressure steeping device, including the installation base, there is four equidistance first supporting legs that distribute at the top of installation base through bolted connection, and there is the steeping jar body at the top of first supporting leg through bolted connection, there is sealed lid at the top of the steeping jar body through bolted connection, and the outer wall welding of the steeping jar body has the cooling storehouse, there is temperature sensor inner wall bottom of the steeping jar body through bolted connection, there are four equidistance third supporting legs that distribute at the top middle part of installation base through bolted connection, and there is mounting platform at the top of third supporting leg through bolted connection. The utility model discloses in, through being provided with sealed lid, hydraulic cylinder, piston sleeve, promote the handle, when carrying out the flooding, the hydraulic cylinder that the sealed installation of covering drives the piston sleeve and pushes down, can exert pressure to the sugar liquid, has increased the infiltration effect of sugar liquid and fruit base.

Description

Low-temperature vacuum hydraulic impregnation device

Technical Field

The utility model relates to a technical field is made to the preserved fruit, especially relates to a low temperature vacuum hydraulic pressure steeping device.

Background

Preserved fruit, also called sweetmeat, is a food prepared by pickling fruits and vegetables such as peach, apricot, plum, jujube or wax gourd, ginger and the like with sugar or honey. In addition to being eaten directly as snacks or snacks, the confection can also be used as a snack to be placed on cakes, biscuits and the like. The preserved fruit is invented by a Imperial meal room in the Ming dynasty. Beijing and Taiwan in China are used for producing heavy towns from preserved fruits.

The fruit blanks are processed by a vacuum liquid phase impregnation method, and sugar liquid impregnation can be carried out on the fruit blanks. Under normal pressure, because air exists in the pores inside the fruit blanks, the filling rate of the sugar liquid to the fruit blanks is not ideal, and particularly when the viscosity of the sugar liquid is high, the effect is not good, but the traditional gas pressurizing device is complex in structure, complex in operation and very inconvenient to operate.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the defects existing in the prior art and providing a low-temperature vacuum hydraulic impregnation device.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a low-temperature vacuum hydraulic impregnation device comprises an installation base, wherein the top of the installation base is connected with four first supporting legs which are distributed equidistantly through bolts, the top of each first supporting leg is connected with an impregnation tank body through a bolt, the top of the impregnation tank body is connected with a sealing cover through a bolt, the outer wall of the impregnation tank body is welded with a cooling bin, the bottom of the inner wall of the impregnation tank body is connected with a temperature sensor through a bolt, the middle part of the top of the installation base is connected with four third supporting legs which are distributed equidistantly through bolts, the top of each third supporting leg is connected with an installation platform through a bolt, the top of the installation platform is connected with a buffer bottle through a bolt, one side of the top of the installation platform is connected with a vacuum pump through a bolt, the top of the vacuum pump is connected with an exhaust pipe through a, the top welding of exhaust tube has the breathing pipe, the top of cushion flask has first gas-supply pipe through flange joint, and threaded connection has the manometer at the top of first gas-supply pipe, first gas-supply pipe passes through flange joint with the flooding jar body, the outer wall of the flooding jar body has the treater through bolted connection, there is the refrigerator at the top middle part of installation base through bolted connection.

Preferably, the first air delivery pipe, the air exhaust pipe and the outer wall of the air suction pipe are connected with an air control valve through threads.

Preferably, the other side of the top of the mounting base is connected with three second supporting legs which are distributed at equal intervals through bolts, and the tops of the second supporting legs are connected with the same sugar solution tank through bolts.

Preferably, the top welding of sugar solution jar has the feed liquor pipe, and the bottom welding of sugar solution jar has the transfer line, the transfer line passes through flange joint with the flooding jar body, and the outer wall of transfer line has control valve through threaded connection.

Preferably, the refrigerator is connected with the cooling bin through a pipeline, and the top and the bottom of the outer wall of the cooling bin are respectively welded with a liquid inlet pipe and a liquid outlet pipe.

Preferably, the processor is electrically connected with the vacuum pump and an external switch of the refrigerator through conducting wires, the processor is electrically connected with the temperature sensor through a signal wire, and the processor is electrically connected with an external power supply through a power transmission wire.

Preferably, the top of the sealing cover is connected with a hydraulic oil cylinder through a flange, the bottom of a piston rod of the hydraulic oil cylinder is connected with a piston sleeve through a bolt, two sides of the top of the sealing cover are connected with lifting handles through bolts, the hydraulic oil cylinder is connected with an external hydraulic system through a pipeline, and an external switch of the hydraulic oil cylinder is electrically connected with the processor through a wire.

The utility model has the advantages that:

1. the utility model provides a low temperature vacuum hydraulic pressure steeping device, through being provided with cooling storehouse, the steeping tank body, refrigerator, temperature sensor, through feed liquor pipe to the inside refrigerant that fills in cooling storehouse, temperature sensor real-time detection steeping tank body inside temperature, through the signal line with information transfer to treater, the output of treater control refrigerator, the temperature of the internal portion of adjustable steeping tank, it is very simple and convenient.

2. The utility model provides a low temperature vacuum hydraulic pressure steeping device, through being provided with the vacuum pump, the cushion flask, the exhaust tube, first gas-supply pipe, the manometer, mounting platform, place the fruit base in the internal portion of steeping jar, processor control vacuum pump is opened, carry out the evacuation to the cushion flask, simultaneously carry out the evacuation to the internal portion of steeping jar, open control flap, can let in the steeping jar body with the sugar solution through the transfer line, the inside pressure of the first gas-supply pipe of manometer detectable, improve the flooding effect, when the flooding finishes, open the accuse gas valve on the breathing pipe, open the accuse gas valve on first gas-supply pipe and the exhaust tube simultaneously, can carry out the back pressure to the steeping jar body.

3. The utility model provides a low temperature vacuum hydraulic pressure steeping device through being provided with sealed lid, hydraulic cylinder, piston sleeve, promotes the handle, when carrying out the flooding, and the hydraulic cylinder that the sealed installation of covering drives the piston sleeve and pushes down, can exert pressure to the sugar liquid, has increased the infiltration effect of sugar liquid and fruit base.

Drawings

Fig. 1 is a schematic cross-sectional structural view of a low-temperature vacuum hydraulic impregnation apparatus provided by the present invention;

fig. 2 is a schematic front view of a low-temperature vacuum hydraulic impregnation apparatus provided by the present invention;

fig. 3 is a schematic structural diagram of a sealing cover of the low-temperature vacuum hydraulic steeping device provided by the present invention.

In the figure: the device comprises a first supporting leg 1, a temperature sensor 2, a cooling bin 3, a dipping tank 4, a piston sleeve 5, a sealing cover 6, a hydraulic oil cylinder 7, a pressure gauge 8, a first gas pipe 9, a gas suction pipe 10, a gas suction pipe 11, a sugar solution tank 12, a second supporting leg 13, a mounting base 14, a vacuum pump 15, a third supporting leg 16, a mounting platform 17, a refrigerator 18, a buffer bottle 19, a control valve 20, a lifting handle 21, a processor 22 and a transfusion tube 23.

Detailed Description

The technical solution of the present patent will be described in further detail with reference to the following embodiments.

Reference will now be made in detail to embodiments of the present patent, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present patent and are not to be construed as limiting the present patent.

In the description of this patent, it is to be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientations and positional relationships indicated in the drawings for the convenience of describing the patent and for the simplicity of description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the patent.

In the description of this patent, it is noted that unless otherwise specifically stated or limited, the terms "mounted," "connected," and "disposed" are to be construed broadly and can include, for example, fixedly connected, disposed, detachably connected, disposed, or integrally connected and disposed. The specific meaning of the above terms in this patent may be understood by those of ordinary skill in the art as appropriate.

Example 1

Referring to fig. 1-3, a low-temperature vacuum hydraulic impregnation device comprises an installation base 14, the top of the installation base 14 is connected with four first support legs 1 which are distributed equidistantly through bolts, the top of each first support leg 1 is connected with an impregnation tank body 4 through a bolt, the top of each impregnation tank body 4 is connected with a sealing cover 6 through a bolt, the outer wall of each impregnation tank body 4 is welded with a cooling bin 3, the bottom of the inner wall of each impregnation tank body 4 is connected with a temperature sensor 2 through a bolt, the middle of the top of the installation base 14 is connected with four third support legs 16 which are distributed equidistantly through bolts, the top of each third support leg 16 is connected with an installation platform 17 through a bolt, the top of each installation platform 17 is connected with a buffer bottle 19 through a bolt, one side of the top of each installation platform 17 is connected with a vacuum pump 15 through a bolt, and extraction tube 11 and buffer bottle 19 pass through flange joint, and the welding of the top of extraction tube 11 has breathing pipe 10, and flange joint has first gas-supply pipe 9 at the top of buffer bottle 19, and threaded connection has manometer 8 at the top of first gas-supply pipe 9, and first gas-supply pipe 9 passes through flange joint with the steeping jar body 4, and the outer wall of the steeping jar body 4 has treater 22 through bolted connection, and there is refrigerator 18 through bolted connection in the middle part of the top of installation base 14.

Wherein, the outer walls of the first air pipe 9, the air exhaust pipe 11 and the air suction pipe 10 are connected with an air control valve through screw threads, the other side of the top of the mounting base 14 is connected with three second supporting legs 13 which are distributed at equal intervals through bolts, the top of the second supporting leg 13 is connected with the same sugar solution tank 12 through a bolt, the top of the sugar solution tank 12 is welded with a liquid inlet pipe, and the bottom of the sugar liquor tank 12 is welded with a transfusion tube 23, the transfusion tube 23 is connected with the dipping tank body 4 through a flange, and the outer wall of the infusion tube 23 is connected with a control valve 20 through screw threads, the refrigerator 18 is connected with the cooling bin 3 through a pipeline, the top and the bottom of the outer wall of the cooling bin 3 are respectively welded with a liquid inlet pipe and a liquid outlet pipe, the processor 22 is electrically connected with the vacuum pump 15 and an external switch of the refrigerator 18 through leads, the processor 22 is electrically connected with the temperature sensor 2 through a signal line, and the processor 22 is electrically connected with an external power supply through a power line.

Example 2

Referring to fig. 1-3, a low temperature vacuum hydraulic pressure steeping device, still include the hydraulic cylinder 7 of flange joint through the top of sealed lid 6, and there is piston cover 5 piston rod bottom of hydraulic cylinder 7 through bolted connection, there is lifting handle 21 top both sides of sealed lid 6 through bolted connection, and hydraulic cylinder 7 passes through the pipe connection with outside hydraulic system, hydraulic cylinder 7's external switch passes through wire electric connection with processor 22, when carrying out the flooding, hydraulic cylinder 7 of installation on the sealed lid 6 drives piston cover 5 and pushes down, can exert pressure to the sugar solution, the infiltration effect of sugar solution and fruit base has been increased.

The working principle is as follows: the inside of a cooling bin 3 is filled with a refrigerant through a liquid inlet pipe, the temperature sensor 2 detects the temperature inside the dipping tank body 4 in real time, information is transmitted to a processor 22 with the model of ARM9 TEMPIDE through a signal line, the processor 22 controls the output power of a refrigerator 18, the temperature inside the dipping tank body 4 can be adjusted, the fruit blank is very simple and convenient to place inside the dipping tank body 4, the processor 22 controls a vacuum pump 15 to be started, a buffer bottle 19 is vacuumized, the inside of the dipping tank body 4 is vacuumized at the same time, a control valve 20 is opened, sugar liquid can be introduced into the dipping tank body 4 through a liquid conveying pipe 23, a pressure gauge 8 can detect the pressure inside a first gas conveying pipe 9 to improve the dipping effect, when the dipping is finished, a gas control valve on a gas suction pipe 10 is opened, gas control valves on the first gas conveying pipe 9 and a suction pipe 11 are opened at the same time, the back pressure, when the fruit is soaked, the hydraulic oil cylinder 7 arranged on the sealing cover 6 drives the piston sleeve 5 to press downwards, so that pressure can be applied to the sugar liquid, and the permeation effect of the sugar liquid and the fruit blanks is improved.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (7)

1. The low-temperature vacuum hydraulic impregnation device comprises an installation base (14) and is characterized in that the top of the installation base (14) is connected with four first supporting legs (1) which are distributed equidistantly through bolts, the top of each first supporting leg (1) is connected with an impregnation tank body (4) through bolts, the top of each impregnation tank body (4) is connected with a sealing cover (6) through bolts, the outer wall of each impregnation tank body (4) is welded with a cooling bin (3), the bottom of the inner wall of each impregnation tank body (4) is connected with a temperature sensor (2) through bolts, the middle of the top of the installation base (14) is connected with four third supporting legs (16) which are distributed equidistantly through bolts, the top of each third supporting leg (16) is connected with an installation platform (17) through bolts, and the top of each installation platform (17) is connected with a buffer bottle (19) through bolts, and there is vacuum pump (15) top one side of mounting platform (17) through bolted connection, there is exhaust tube (11) at the top of vacuum pump (15) through cutting ferrule connection, and exhaust tube (11) and buffer bottle (19) pass through flange joint, the top welding of exhaust tube (11) has breathing pipe (10), there is first gas-supply pipe (9) at the top of buffer bottle (19) through flange joint, and there is manometer (8) at the top of first gas-supply pipe (9) through threaded connection, flange joint is passed through with the steeping vat body (4) first gas-supply pipe (9), there is treater (22) outer wall of the steeping vat body (4) through bolted connection, there is refrigerator (18) at the top middle part of installation base (14) through bolted connection.

2. The low-temperature vacuum hydraulic impregnation device according to claim 1, wherein the first gas pipe (9) and the outer walls of the suction pipe (11) and the suction pipe (10) are connected with a gas control valve through threads.

3. A cryogenic vacuum hydraulic steeping device as claimed in claim 1 wherein the other side of the top of the mounting base (14) is bolted with three second support legs (13) which are equidistantly spaced and the top of the second support legs (13) is bolted with the same sugar solution tank (12).

4. The low-temperature vacuum hydraulic dipping device as claimed in claim 3, wherein a liquid inlet pipe is welded at the top of the sugar solution tank (12), a liquid conveying pipe (23) is welded at the bottom of the sugar solution tank (12), the liquid conveying pipe (23) is connected with the dipping tank body (4) through a flange, and the outer wall of the liquid conveying pipe (23) is connected with a control valve (20) through threads.

5. The low-temperature vacuum hydraulic impregnation device according to claim 1, wherein the refrigerator (18) is connected with the cooling bin (3) through a pipeline, and the top and the bottom of the outer wall of the cooling bin (3) are respectively welded with a liquid inlet pipe and a liquid outlet pipe.

6. A cryogenic vacuum hydraulic impregnation apparatus according to claim 1, wherein the processor (22) is electrically connected to the vacuum pump (15) and to external switches of the refrigerator (18) by means of wires, and wherein the processor (22) is electrically connected to the temperature sensor (2) by means of signal lines, and wherein the processor (22) is electrically connected to an external power source by means of power lines.

7. The low-temperature vacuum hydraulic impregnation device according to claim 1, wherein the top of the sealing cover (6) is connected with a hydraulic oil cylinder (7) through a flange, the bottom of a piston rod of the hydraulic oil cylinder (7) is connected with a piston sleeve (5) through a bolt, two sides of the top of the sealing cover (6) are connected with lifting handles (21) through bolts, the hydraulic oil cylinder (7) is connected with an external hydraulic system through a pipeline, and an external switch of the hydraulic oil cylinder (7) is electrically connected with the processor (22) through a wire.

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