JP2791834B2 - Continuous decompression frying method and apparatus - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a continuous vacuum frying method and apparatus for continuously frying raw materials under reduced pressure.

[0002]

2. Description of the Related Art Conventionally, as a vacuum fryer, Japanese Patent Application Laid-Open No. Sho 62-262954 discloses a method in which a raw material is supplied into oil by a screw and the raw material is transported by a screw conveyor in a reduced pressure oil. Is disclosed. In addition, the present applicant has disclosed a continuous type depressurizing fryer as disclosed in Japanese Patent Application No. 1-188014 and Japanese Patent Application No. 1-18801.
No. 5, Japanese Patent Application No. 1-188016, Japanese Patent Application No. 1-2460
No. 09 has filed a patent application.

[0003]

However, the conventional continuous vacuum fryer and the vacuum fry method performed by the continuous vacuum fryer have a problem that the efficiency of heat supply to the raw material by the heating oil is low. is there.

That is, according to the above-mentioned conventional continuous decompression fryer, the heated oil flows substantially along the conveying direction of the raw material conveying path, while the raw material to be fried is diffused substantially near the oil surface. . As a result, the heating oil flowing below the transport path is hardly used for frying of the raw material, and the efficiency of heat supply to the raw material by the heating oil is reduced.

[0005]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems of the conventional continuous decompression frying apparatus, and moves the oil in the oil with the opening of the net conveyor facing downward so that the moisture in the raw material is reduced. The raw material does not float to the surface of the heating oil in the room with buoyancy as steam, and the heating oil flows vertically from the upper part to the lower part in the raw material conveying path in the heating oil at right angles to the raw material conveying path, It is an object of the present invention to provide a continuous decompression fryer that prevents a raw material from floating and adhering to a net conveyor and peels off the adhering raw material. The present invention also provides a feed path in heated oil,
The supplied heating oil flows and is discharged in a direction perpendicular to the raw material conveying path, and almost all of the heating oil comes into contact with the raw material diffused substantially over the entire oil surface. It is an object of the present invention to provide a continuous reduced-pressure frying apparatus which is capable of performing uniform frying of a raw material with good efficiency of heat supply to the raw material by heated oil.

The present invention relates to a continuous reduced pressure fry method for performing a frying process in heated oil under reduced pressure by transferring the raw material by a net conveyor along a raw material transfer path provided in a reduced pressure fry chamber. The endless belt is provided with a plurality of substantially outwardly extending partitioning nets forming a plurality of outwardly opening partitioning chambers, such that the opening of the partitioning chambers is in the heating oil in the conveying path portion facing downward. The raw material is held and transported in the compartment of the placed net conveyor,
A continuous decompression fry method characterized by flowing heated oil from above to below a conveying path so as to be substantially orthogonal to the conveying path.

[0007] The present invention also provides a continuous vacuum fry apparatus for performing frying in heated oil under reduced pressure by transporting the raw material by a net conveyor along a raw material transport path provided in a reduced pressure fry chamber, On a net-shaped endless belt, a net conveyor formed by providing a plurality of substantially outwardly extending partition nets forming a plurality of outwardly opened partition chambers,
Arranged so that the opening of the compartment is in the oil in the conveying path portion facing downward, a plurality of heating oil supply ports are provided along the conveying path above the conveying path, and the heating oil from the heating oil supply port is provided. A continuous pressure-reducing fryer characterized in that an oil discharge port is provided at a position below a transport path corresponding to supply.

[0008]

According to the present invention, since the opening of the net conveyor moves downward and moves in the oil, the water in the raw material becomes water vapor and the raw material floats up to the surface of the heating oil in the room with buoyancy. In addition, since the heating oil flows vertically from the upper side to the lower side perpendicular to the raw material conveying path in the raw material conveying path in the heating oil, the raw material is prevented from floating and adhering to the net conveyor. In addition, it has an effect of peeling off the attached raw material. According to the present invention, further, in the raw material transport path in the heated oil, the supplied heated oil flows and is discharged in a direction perpendicular to the raw material transport path, so that most of the heated oil almost completely fills the oil surface. Contact with the diffused raw material, where heat is exchanged, it is quickly discharged, the efficiency of heat supply to the raw material by the heating oil is improved, and uniform frying of the raw material can be performed. Has an effect that can be.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. As shown in FIG. 1, the continuous-type decompression fryer includes a decompression fry chamber 1 and a decompression fry chamber 1 for performing decompression fry processing.
A raw material supply device 3 for supplying a raw material to the raw material supply device 2 and a product cooling chamber 4 for cooling the reduced-pressure fried products.

As shown in FIG. 2, the raw material supply device 3 has a raw material stock tank 31, and a conveyor 32 for transferring the raw material disposed below the raw material stock tank 31. The raw material discharged from the lower end of the raw material stock tank 31 is transferred from the conveyor 32 to the terminal portion 33, from which the raw material is dropped and supplied to the lower raw material input device 2.

As shown in FIG. 2, the raw material charging device 2 further includes a raw material hopper 21 provided below the end portion 33 of the conveyor 32 for receiving a raw material, and a rotating hopper provided below the raw material hopper 21. It has a valve 22 and a horizontal tube portion 23 provided below the rotary valve 22 for receiving a raw material supplied from the rotary valve 22.

The rotary valve 22 has a valve body 25. The valve body 25 is provided with depressions 24a and 24b that do not allow the upstream side (normal pressure state) and the downstream side (decompression state) of the raw material charging device 2 to communicate with each other. . Recesses 24a, 2
4b collectively drops a fixed amount of raw materials supplied in a conveyed manner by the conveyor 32 onto the horizontal tube portion 23.

The horizontal pipe section 23 communicates with the vacuum fry chamber 1. A loading bar 26 that reciprocates inside the horizontal tube portion 23 is incorporated in the horizontal tube portion 23. The loading bar 26 is attached to a hydraulic cylinder 27 serving as a driving source, and a pushing surface 28 at a tip portion of the loading bar 26 is closer to the front side than the drop position of the raw material from the rotary valve 22 by the hydraulic cylinder 27 (the hydraulic cylinder 27 side). Is moved back and forth until it reaches the inlet 10 of the decompression fry chamber.

The raw material supplied through the hopper 21 is supplied to the recess 24 a or 24 a provided in the valve body 25.
b. Thereafter, the valve body 25 is turned over, and the raw material that has been in the recess 24 a or 24 b is dropped into the horizontal pipe portion 23. In this case, the recesses 24a and 24b do not communicate between the upstream side of the raw material charging device 2, that is, the hopper side (normal pressure state) and the downstream side, that is, the horizontal pipe section side (depressurized state). The raw material can be supplied while maintaining the reduced pressure.

Subsequently, the loading bar 2 is moved to a position where the pushing surface 28 at the tip reaches the loading port 10 of the decompression fry chamber 1.
6 is moved, and the raw material is charged into the reduced pressure fry chamber 1.

The number of recesses provided in the valve body 25 can be increased to three or more by reducing the angular dimension of the hopper 21 and the inlet (falling port) in the rotation direction of the valve body 25. .

The decompression fry chamber 1 has a net conveyor 42 for transporting raw materials and a leak valve 41. As shown in FIG. 3, the net conveyor 42 includes a net-shaped endless belt 5.
0 is provided with a plurality of partition nets 52 extending substantially outward. The width of the decompression fry chamber 1 in the direction orthogonal to the transport direction of the net conveyor 42 is substantially equal to the width of the endless belt 50 and the division net 52. Accordingly, a plurality of compartments 54 that open outward are formed in the net conveyor 42, and the raw materials are charged therein. The inclination angle of the division net 52 with respect to the endless belt 50 will be described later.

As shown in FIG. 4, the net conveyor 42 is guided by three guide pulleys 60, 61 and 62 and is driven intermittently by a drive pulley 64.
The transport path of the net conveyor 42 has a substantially parallelogram shape when viewed from the side, and the portion corresponding to the bottom surface is in the oil, and the raw material input from the raw material input device 2 is fried here. . The net conveyor 42 is, for example, 10
It moves intermittently by the width in the transport direction of the net conveyor 42 in the compartment 54 at a rate of once every second to 10 minutes.

As shown in FIG. 2, the trajectory of the end portion of the partitioning net 52 is
It is preferable that the first and second extruding surfaces 28 substantially coincide with each other. Thus, the tip end of the partitioning net 52 after scraping the raw material can scrape the pushing surface 28 of the throwing bar 26, and effectively prevent the raw material from adhering to the pushing surface 28.

As a means for preventing the material from adhering near the inlet, an oil supply port 502 for showering and pouring oil in the vicinity of the pushing surface 28 in the reduced pressure fry chamber 1 can be provided. Further, by providing an oil supply port 504 for flowing oil in a wall portion above the input port 10 of the reduced-pressure fry chamber 1, it is possible to drain off the raw material attached near the input port 10.

Further, as shown in FIG. 5, the endless belt 50 of the net conveyor 42 has a height of 40 to 6 with respect to the horizontal above the discharge slope 106 of the decompression fry chamber 1.
It runs at an angle of 0 ° in parallel.

In this state, the endless belt 50 is fixed by the fixing member 108 such that the angle formed with respect to the horizontal line H, that is, the discharge inclination angle α of the division net is 40 to 100 °, preferably 80 to 90 °. Attached to

The first half of the raw material transfer path of the vacuum fry chamber 1,
That is, above the raw material input side of the bottom portion of the parallelogram-shaped transport path of the net conveyor 42, FIGS.
As shown in the figure, a large number of oil supply units 500 for supplying oil at a predetermined temperature in a shower state are provided.

As a result, in the initial stage of the reduced pressure frying process, a predetermined amount of oil having a sufficient calorific value for the raw material can be supplied to the raw material. Further, the raw materials adhered to the endless belt 50 in the initial stage of the reduced pressure frying process can be removed.

Each of the oil supply units 500 has an oil amount adjusting valve (not shown), and
Of the raw material transport path in the transport direction, that is, the raw material compartment 5
It is configured such that the supply amount of oil per hour can be controlled according to the reduced-pressure frying time of the raw material in 4. Therefore, it is possible to efficiently supply a desired amount of heat to the raw material in the raw material compartment 54 according to the reduced-pressure frying time.

An oil outlet 107 composed of a number of small holes is provided on the bottom surface of the reduced pressure fry chamber 1 at a position substantially below each of the oil supply units 500. As a result, the oil poured down like a shower from above flows almost vertically from the oil level to the bottom surface of the decompression fry chamber 1. As a result, most of the oil comes into contact with the raw material that is substantially diffused over the entire oil surface, and it is possible to effectively prevent frying unevenness and supply the calorie of the oil to the raw material without waste. And the heat supply efficiency, that is, the reduced-pressure frying processing efficiency is improved.

As shown in FIG. 1, the oil that has flowed out of the oil extraction unit 107 is provided with a first oil lubrication pump 601, a strainer 602, and a centrifugal separator 60 for removing water from the oil.
3. The oil is supplied to the oil supply unit 500 again through the oil circulation path 600 having the oil storage tank 604 and the second oil circulation pump 605.

In the oil circulation path 600, first, raw materials and the like are removed from the oil by the strainer 602. Next, the oil is sent to a centrifugal separator 603 for removing moisture in the oil, and subjected to centrifugal separation. As a result, the oil and the water scattered in the oil are separated into an oil layer and a water layer, respectively, the water layer portion is discharged, and the water scattered in the oil is sufficiently removed.

As shown in FIG. 6, the oil storage tank 604 is connected to the oil circulation path 600 through pressure cutoff valves 610 and 611.
Is in communication with The oil storage tank 604 is in communication with the first vacuum pump 701. Thereby, for example, when cleaning the inside of the decompression fry chamber 1, the pressure shutoff valves 610, 61
1 is closed, and air remaining in the oil storage tank is sufficiently removed by the first vacuum pump 701, so that oxidation of the stored oil can be effectively prevented.

Further, a jacket 711 is provided on the wall of the oil storage tank 604, and a sheath heater 712 is provided inside the jacket, for heating the oil to a required temperature. Further, an agitator 713 is provided in the oil storage tank 604 to make the temperature of the oil uniform.

As shown in FIG. 1, a plurality of the oil storage tanks 604 are provided. Thus, the oil in the vacuum fry chamber 1 can be easily changed depending on the type of the raw material, and the smell of the raw material can be effectively prevented from being transferred to the oil and the smell being transferred to another raw material.

Next, the decompression fry chamber 1 has a vacuum unit 8 for exhausting air and water vapor generated from the raw material from within the decompression fry chamber 1 to reduce the pressure in the decompression fry chamber 1. Maintain the vacuum required for frying.
As shown in FIG. 1, the vacuum unit 8 basically includes a cold trap 801 and a second vacuum pump 802.

A cold trap 801 for bringing a gas into contact with a bottom warm wall surface to condense and remove water in the gas is shown in FIG.
As shown in the figure, the water storage tank 820 has a drainage pipe 813 provided with pressure cutoff valves 811 and 812 on the upstream and downstream sides of the water storage tank 820, respectively. The temperature of the trap surface 830 is maintained at -20 to 20 ° C, preferably 0 to 10 ° C, by circulating a constant temperature refrigerant inside. In addition, it is desirable that the water storage tank 820 be provided with a pressure adjusting pipe (not shown) that communicates with the outside via a leak valve and a pressure shutoff valve, in that the water can be smoothly discharged. Further, it is desirable that the water storage tank 820 be kept at a predetermined temperature or lower by, for example, covering with a heat insulating material or providing a pipe for circulating a refrigerant. Thereby, it is possible to effectively prevent the water accumulated in the water storage tank 820 from being heated and turned into steam again.

According to the cold trap 801, the pressure cutoff valve 811 provided on the upstream side of the water storage tank 820
And open the pressure cutoff valve 8 provided on the downstream side of the water storage tank.
Close 12. As a result, a large amount of water vapor generated in the decompression fry chamber 1 is trapped in a water state (liquid state) on the trapping surface 830 and accumulates in the water storage tank 820 through the upstream side of the drainage pipe 813. After a predetermined time, after closing the pressure shut-off valve 811, the pressure shut-off valve of the pressure adjusting pipe is opened, and after the inside of the water storage tank is returned to normal pressure, the pressure shut-off valve 812 on the downstream side of the water storage tank is opened.
The water stored in the water storage tank 820 is discharged through a drainage pipe 813. When discharging the water, the vacuum fry chamber 1
And the outside are not communicated with each other, so that the water vapor can be continuously removed while maintaining the inside of the decompression fry chamber 1 in a decompressed state.

Further, it is preferable to provide a flow regulating valve 840 between the cold trap 8 and the reduced pressure fry chamber 1.
This is because, for example, when the amount of water vapor generated inside the reduced pressure fry chamber 1 is small, such as when a small amount of raw material is processed due to variation in the amount of input, the degree of reduced pressure inside the reduced pressure fry chamber 1 becomes too good. This lowers the freezing point of the water,
As a result, there is a possibility that water vapor cannot be trapped in the state of water. In order to prevent this, it is useful to prevent the inside of the decompression fry chamber 1 from becoming better than a predetermined decompression degree, and the flow control valve 840 is the simplest and desirable as a means for that.

The unloading slope 106 of the decompression fry chamber 1
As shown in FIG. 1 and FIG. 5, a discharge port 110 is provided at the upper terminal end. The discharge port 110 communicates with the product cooling chamber 4 via a shutoff valve 900. After the decompression fry processing is completed, the decompression fried product transferred to the upper part of the carry-out slope 106 by the partition net 52 falls from the discharge port 110. When the decompressed fried product accumulates in a predetermined amount or more, the shutoff valve 900 is opened and the product is put into the product cooling chamber 4.

The product cooling chamber 4 is provided with a cooling mechanism 401, and after closing the shutoff valve 900, cools the supplied reduced pressure fried product to a predetermined temperature.

A pressure shutoff valve 4 is provided below the product cooling chamber 4.
A product stock tank 5 is provided via 20.
The product stock tank 5 has a carry-out port 501,
The outlet 501 is constituted by a pressure cutoff valve.

Further, the product stock tank 5 is connected to the first vacuum pump 701. Then, the decompressed product cooled to the predetermined temperature in the product cooling chamber 4 is dropped into the stock tank 5 by opening the pressure shutoff valve 420.

Next, after closing the pressure shut-off valve 420, the outlet 501 is opened to take out the reduced pressure fried product. After the removal, the outlet 501 is closed, and then the pressure of the product stock tank 5 is reduced again by the first vacuum pump 701 to the same reduced pressure as the reduced pressure fry chamber 1.

In another embodiment, in addition to the constitution of the above-described embodiment, a retainer having a measuring device is provided between the terminal end of the conveyor of the raw material supply device and the hopper of the raw material charging device. Means for calculating the oil supply amount to each oil supply unit according to the position of the raw material transport path of the measured raw material, that is, the reduced-pressure frying time of the measured raw material, based on the measured measurement value, and This is a continuous pressure-reducing fryer provided with means for controlling the amount of oil supply to each oil supply unit based on the amount of supply.

According to this continuous-type decompression fryer, even when the input amount of raw materials is not constant, the amount of heat required for frying can always be supplied without excess or shortage, and a sufficiently porous fried product can be obtained. it can.

In still another embodiment, instead of the rotary valve of the above-described embodiment, an airtight valve and a pressure shutoff valve arranged in the conveying path of the pushing device are provided.

[Brief description of the drawings]

FIG. 1 is an overall explanatory diagram of an embodiment of the present invention.

FIG. 2 is an explanatory diagram of a raw material supply device.

FIG. 3 is a perspective view of a net conveyor.

FIG. 4 is an enlarged explanatory view of a decompression fry chamber.

FIG. 5 is an enlarged explanatory view near the discharge port of the decompression fry chamber.

FIG. 6 is a perspective view in which an oil storage tank is partially cut away.

FIG. 7 is a perspective view of a cold trap.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 decompression fry chamber 2 raw material feeding device 3 raw material supply device 4 product cooling chamber 10 input port 21 raw material hopper 22 rotation valve 24 a, 24 b recess 26 charging bar 28 extrusion surface 31 raw material stock tank 32 conveyor 42 net conveyor 52 section net 107 oil flow Outlet 400 Cooling mechanism 500 Oil supply section 600 Oil circulation path 604 Oil storage tank 801 Cold trap 820 Water storage tank

Claims (6)

(57) [Claims] 1. A raw material transfer path provided in a reduced pressure fry chamber.
The raw material is transported on a net conveyor along
Continuous decompression fan that performs frying in heated oil under reduced pressure.
In the lie method, a plurality of compartments opened outward are formed on a net-like endless belt.
Providing a plurality of substantially outwardly extending partition nets to be formed;
In the transport path where the opening of the compartment is downward,
The above section of the net conveyor arranged to be in hot oil
A continuous depressurized frying method, characterized in that a raw material is held and transported in a chamber, and heated oil is caused to flow from above to below the transport path so as to be substantially orthogonal to the transport path. 2. A raw material transfer path provided in a reduced pressure fry chamber.
The raw material is transported on a net conveyor along
Continuous decompression fan that performs frying in heated oil under reduced pressure.
In the lie apparatus, a plurality of compartments opened outward are formed on a net-like endless belt.
Providing a plurality of substantially outwardly extending partition nets to be formed
With the opening of the compartment facing downward.
A plurality of heating oil supply ports are provided along the conveyance path above the conveyance path, and a plurality of heating oil supply ports are provided below the conveyance path corresponding to the heating oil supply from the heating oil supply port. A continuous pressure-reducing fryer, characterized in that an oil discharge port is provided at the position (1). 3. The heating oil supply port is a small hole.
Continuous decompression fry equipment. 4. The continuous vacuum fryer according to claim 2, wherein said heating oil supply port is a shower nozzle. 5. The continuous decompression fryer according to claim 2, wherein said oil discharge port is a slit extending along a conveying path. 6. The continuous vacuum fryer according to claim 2, wherein said oil outlet is a small hole.