KR20100098198A - Popping rice manufacture device - Google Patents

Abstract

PURPOSE: An apparatus for manufacturing puffed rice is provided to prevent an expansive spring from being bent or broken even when an upper mold is strongly pressed and to improve durability of a product by preventing the separation of a rotating chain. CONSTITUTION: An apparatus for manufacturing puffed rice comprises: a main body(1) including a work table(12), a plurality of main body frames(11), and a support plate(14); a controller(2) which is installed on the outer side of the main body frames and includes a heater switch(21), a motor switch(22), and a heater controller(23); a driving unit which includes a drive motor and a sprocket wheel connected to a drive shaft of the drive motor; raising and lowering unit(4) unit including an operation lever(41), a raising and lowering module(43), a support frame(44), a projection(45a), and an expansive spring(46); a support bracket which is installed on the lower end of the main body frame; and a grain supply unit(8) including a hopper, a supply pipe, and a grain control unit.

Description

Popping rice manufacture device

The present invention relates to a sprinkler manufacturing apparatus, and more particularly, an expansion spring for repositioning a lift module when pressing the upper mold onto a lower mold by pressing force of a lifting means of the grain input to the lower mold of the sprinkler. It is separated into a plurality of right, right, up and down, and the chain which is rotated by the driving force of the driving motor is supported by the support bracket so that the lifting module can be lifted up and down. The present invention relates to a fry splash manufacturing apparatus that can improve the stability of the product and the convenience of work.

As is well known, frying is fried by heating and molding various grains, such as rice or corn, and has been provided to consumers in various forms. In recent years, frying is mainly made of carbohydrates, so it is safe to eat even if eaten a little as a diet food. It is in the spotlight.

Such a frying apparatus makes a frying confectionery by supplying various grains and heating them to a certain temperature, that is, when a certain amount of grains are put into a closed mold and heated, water vapor expands inside the grains, thereby rapidly increasing the pressure in the mold. Opening a closed mold in the process reduces the pressure, which is produced by the principle that the grain expands more than several times.

1 to 6, the conventional apparatus for producing splashing water 100 is largely provided in the main body frame 120 and the main body frame 120, and includes a drive motor 131 having the reducer 311 and the A drive unit 130 including first and second drive shafts 132 and 133 to receive power from the drive motor 131, first and second actuating cams 140 and 150 provided on the first drive shaft 132, An operation unit 160 connected to the first operation cam 140 to operate the seesaw, an upper mold 170 connected to the operation unit 160 to move up and down, and provided with a heating means, the upper mold 170. Lower mold 180 is installed directly below the heating means is provided, the grain supply unit 190, the second operation cam 150, which is connected to the first drive shaft 132 by power and discharges a predetermined amount of grain. A grain transfer unit 200 connected to the grain supply unit 190 to transfer the grains supplied to the grain supply unit 190 to the lower mold 180, the main body p The frame 120 includes a control box 128 for controlling the driving of each component.

Referring to the conventional hot dip manufacturing apparatus configured as described above in detail, as shown in Figs. 1 and 2, the main body frame 120 is provided with an installation space by installing a set of side frames 121, A front plate, a rear cover and an upper cover (not shown) are fixedly installed through the side frame 121, and a support plate 126 on which an upper mold 170 is installed on the front surface of the main body frame 120. A work table 125 on which the lower mold 180 is installed is provided, and a control box 128 is installed on one side of the main frame 120.

In addition, in the installation space formed by the side frame 121, each component, for example, the driving unit 130, the first and second operating cams 140 and 150, and the operation unit as shown in FIGS. 3 and 4. 160, the grain supply unit 190 and the grain transfer unit 200 is installed.

3 and 4, the driving unit 130 transmits the rotational force provided from the driving motor 131 having the reduction gear 311 to the first and second driving shafts 132 and 133. To this end, the shaft (not shown) of the reduction gear 311 and the first driving shaft 132 axially couple the sprocket wheel W to connect the chain C, and the first driving shaft ( The second driving shaft 133 located at the front lower portion of the 132 moves the lower mold 180 in the up and down direction, and the second driving shaft 133 is connected to the first driving shaft 132 and the chain C to provide rotational force. The first and second actuating cams 140 and 150 are mounted on the first driving shaft 132 by a key coupling method, respectively.

The first actuating cam 140 is a semi-circular plate-shaped body, at least two straight sections are formed in a predetermined outer circumferential surface, and the second actuating cam 150 is formed in a disc shape, and only a part of the outer circumferential surface thereof is cut out to operate. 151 is provided.

The operation unit 160 is composed of a lever 161 and a guide bar 163, the lever 161 is rotatably coupled to the central axis 127 provided in the body frame 120.

At this time, the guide bar 163 is rotated through a central rotation shaft (not shown), one end of which is connected to the lever 161, the other end of the roller in close contact with the outer peripheral surface of the first operation cam 140 ( 631) is installed.

Accordingly, the actuating unit 160 has a guide bar 163 connected to the first actuating cam 140 to operate the lever 161 and the lever 161 is centered around the central axis 127. It works in the form.

As shown in FIG. 3, the grain supply unit 190 includes a hopper 191 for storing grain and a discharge module (not shown) in which the hopper 191 is installed. The support plate 126 is installed, which horizontally inserts a circular supply rod 921 having a discharge hole 922 perforated under the discharge portion of the hopper 191, and ends one end of the circular supply rod 921. Connected to the first drive shaft 132 and the chain (C) to operate the circular supply rod 921 is rotated intermittently to discharge a predetermined amount of grain through the discharge hole 922, the circular supply rod ( A discharge port 923 is formed in the lower portion of the 921 to discharge the grain to the tribute transfer unit 200.

Meanwhile, as shown in FIG. 5, the grain transfer unit 200 receives grain from the grain discharging position A of the grain supply unit 190 and feeds the grain to the lower mold position B. FIG. And a drive module 112 for driving the feeder 111.

The feeder 111 is a supply plate 113 for seating the grain discharged from the grain supply unit 190 on its upper surface, and is installed on the upper surface of the supply plate 113 is seated on the supply plate 113 It is composed of a supply ring 114 is provided with a plurality of supply pieces 141 to prevent the grains from being separated, the supply plate 113 and the supply ring 114 is the central portion of the main body frame 120 It is rotatably coupled to the support plate 126 of.

As shown in FIGS. 5 and 6, the driving module 112 includes first and second operating levers 115 and 116 connected to the second operating cam 150, and the first and second operating levers 115. , The link actuators 117 and 117 'and the link actuators 117 and 117' respectively connecting the supply plate 113 and the supply ring 114 to the first and second operating levers 115, respectively. And a pair of actuating springs 118 and 118 'installed correspondingly in opposite directions connected to 116, the first and second actuating levers 115 and 116 having one end connected to the main body frame 120. It is rotatably installed, the central portion is provided with rollers (510, 610) in close contact with the outer circumferential surface of the second operation cam 150, the other end of the link actuator (117, 117 ') and the operating spring (118, 118 'is connected, and the position where the rollers 510 and 610 of the first and second operating levers 115 and 116 are in close contact with the second operating cam 150 is the roller of the first operating lever 115. Roll 510 of the second actuating lever 116 Position the feed plate 113 and the feed ring 114 to the lower mold 180, and then the feed plate 113 is preferentially moved to position the feed plate 113 in front of the roller 610. The grain seated on the feed ring 114 is configured to be supplied to the lower mold 180, and the supply plate 113 and the supply ring 114 supply the grain to the lower mold 180. The pulling force of each of the working springs 118 and 118 'is returned to the grain discharging position of the grain supply unit 190 to repeat the above-described operation.

As shown in FIG. 4, the upper mold 170 is connected to the lever 161 of the operation unit 160 to move up and down, and the upper mold 170 and the lever 161 are the link pieces 171. And the elevating module 172 is connected via a medium.

The link piece 171 is rotatably connected to the other end of the lever 161, and the link piece 171 and the lifting module (171) are installed in the lifting module 172 with an upper mold 170 installed therein. 172 is rotatably connected to implement the lifting operation of the upper mold (170).

At this time, the lifting module 172 is installed to pass through the support plate 126 provided on the upper portion of the work table 125, as shown in Figure 2, one side and the other side of the lifting module 172 An elastic spring 721 supported by the support plate 126 is installed to perform compression and expansion during the lifting operation of the module 172.

The upper mold 170 is a heating rod 176 is inserted into the heating means is installed to perform a heat generating action, the lower mold 180 is movable in the vertical direction directly below the upper mold 170, specifically The second driving shaft 133 is positioned below the lower mold 180 and is movable up and down by the cam 331 mounted on the second driving shaft 133.

The lower mold 180 is drilled into a set of heater rod insertion holes for inserting the heater rod 184, which is a heating means, in the same manner as the upper mold 170 described above, and a chamber into which grain is injected (top). Not included).

The control box 228 is installed on the side frame 121 of the body frame 120, which is provided with various control buttons for controlling the driving of the above-described components, as well as the upper and lower molds 170 , A display window for displaying a temperature of 180) and a counter for displaying the number of jobs may be provided, and thus the operator may set a desired environmental condition through various control buttons.

However, the conventional hot dip manufacturing apparatus 100 having the above configuration has the support plate so that the lifting module 172 may perform a compression and expansion operation during the lifting operation according to the operation of the operation unit 160. Since the elastic spring 721 supported by 126 is formed long on each side, one by one up and down, the upper mold 170 is strongly pressed against the lower mold 180 by the operation of the operation unit 160. The elastic spring 721 may be bent or broken by pressure to cause damage such that durability is significantly reduced.

In addition, as described above, as the operation unit 160 is moved up and down by the rotation of the operation cams 140 and 150, the operation unit 160 is moved up and down while rotating by the drive of the driving motor 131 by the pressure. Since the chain C is separated from the sprocket wheel W, the operation of the device is interrupted, causing a failure of the sputtering apparatus and at the same time, the workability is deteriorated.

In addition, in the conventional boil-off manufacturing apparatus, as the driving shafts 132 and 133 rotate in accordance with the driving of the driving motor 131, the operation unit 160 is moved up and down. There is a problem in that the quality of the product is lowered, such that the taste can be reduced by not being able to accurately match the conditions of the different grains, such as the amount of grain or the dry state because it is added constantly.

Therefore, the present invention has been made in order to solve the above problems, even if the upper mold is strongly pressed by the operation of the lifting unit, the expansion spring is not bent or broken, as well as the chain connected to the sprocket wheel by the support bracket to rotate The purpose is to improve the durability of the product does not deviate.

In addition, the present invention can easily adjust the lifting pressure of the lifting module with the control lever and the amount of grain fed into the supply pipe through the hopper can be easily adjusted by a simple operation of the grain control unit, such as the amount of grain or dry state It is an object of the present invention to provide a frying apparatus for producing frying, which can be precisely made in accordance with the conditions of the present invention so as to produce delicious and high-quality frying.

The present invention for achieving the above object is formed in the main body frame on both sides, the controller is installed on the outer side of one main body frame, and electrically grounded with the controller on the lower rear portion of the main body frame in accordance with the operation signal of the controller A drive motor to drive is installed and is connected to the drive shaft of the drive motor to form an operation lever for driving the seesaw according to the driving of the drive motor, and connected to the operation lever to move the upper mold upward and downward. A lifting module is formed to move up and down so as to move to, and a plurality of expansion springs are respectively formed up and down by connecting rods to elastically move the lifting module on both sides of the lifting module, and the other main body Prevents the chain from being disconnected from the sprocket wheel at the bottom of the outer side of the frame. It is to provide a sputtering manufacturing apparatus characterized in that the support bracket is fixed to.

As described above, the present invention is formed by dividing the expansion spring into upper and lower plural on both sides when the expansion spring elastically moves the elevating module to be moved up and down by the operation of the operation cam. It can maximize the stability of the product by minimizing the impact on the product, and can adjust the pressure of the lifting module to manufacture the best taste of the hot-frying product. It has an effect.

In addition, the present invention is to install a support bracket to support the chain in the main frame so that the chain is rotated in accordance with the drive of the drive motor does not deviate from the strong impact of the elevating module to achieve a stable operation of the splashing apparatus. It can be effective.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 7 shows a perspective view of the splatter manufacturing apparatus according to the present invention, Figure 8 is a perspective view showing the internal structure of the splatter manufacturing apparatus according to the present invention, Figure 9 shows the internal structure of the splatter manufacturing apparatus according to the present invention. 1 is a front view, Figure 10 is a side view of the side frying apparatus according to the present invention, Figure 11 is a side perspective view of the frying apparatus according to the present invention, Figure 12 is a grain supply according to the present invention Figure 13 is a perspective view showing a grain control unit of the means, Figure 13 is a front view of the grain control unit of the grain supply means according to the present invention, Figure 14a is a through hole formed in the control plate of the grain control unit according to the present invention and the inside of the supply pipe Figure 14b is a cross-sectional view showing the state of communication as possible, Figure 14b is a through hole formed in the throttle plate sliding the throttle plate of the grain control unit according to the present invention and the supply and the inside are partially crossed A usage example showing the lean state.

The frying apparatus according to the present invention comprises a main body 1, a controller 2, a driving means 3, a lifting means 4, and a grain supply means 8.

The main body 1 has a work table 12 on which a bottom mold 13 is installed on a bottom surface thereof, and a plurality of main body frames 11 are spaced apart on both sides of the work table 12. The support plate 14 is fixed to the lower inner surface of the main body frame 11.

Meanwhile, the front cover 15, the rear cover 16, and the upper cover 17 are formed on the front, rear, and top surfaces of the main body frame 11.

The controller 2 is installed on one side of the main body frame 11, a heater switch 21 is formed to turn on / off the heater, and the drive means 3 is turned on / off. The motor switch 22 is formed so that the heater switch 23 is formed to control the temperature of the heater.

The drive means 3 is a drive motor 31 is installed in the main body frame 11 and the power is connected to the controller 2 to operate in accordance with the on / off operation of the motor switch 22, the drive motor The sprocket wheel 34 which is connected to the drive shaft 32 of the 31 by the chain 33 and rotates according to the drive of the drive motor is formed.

The elevating means 4 is connected to the operation cam (not shown) provided on the drive shaft 32 is formed with an operating lever 41 which is operated by the seesaw according to the rotation of the sprocket wheel 34, the operating lever An elevating module 43 connected to the connecting member 42 to move up and down is formed to penetrate the support plate 14, and the lower end of the elevating module 43, that is, the lower support plate 14. In accordance with the elevating operation of the elevating module 43, the support frame 44 provided with the upper mold 37 is formed to move in the up and down direction to be in close contact with the lower mold 13.

On the other hand, the lower mold 13 and the upper mold 47 is provided with a heater (not shown) in which high heat is generated by the operation of the heater switch 21.

The control lever 5 is formed at the upper end of the operation lever 41 to adjust the pressure at which the elevating module 43 is elevated.

In addition, a plurality of connecting rods 45 are formed on both sides of the support frame 44 by penetrating the support plate 14, but protruding jaws 45a are formed at the central portions of the connecting rods 45, respectively. A plurality of expansion springs 46 are formed on the outer surface of the connecting rod 45, respectively.

At this time, each of the expansion spring 46 is to be installed by dividing the upper and lower plural by the projection jaw (45a) of the connecting rod (45).

A ball bearing 6 is formed between the operation lever 41 and the elevating module 43 of the elevating means 4 so that the elevating module 43 can operate smoothly.

Meanwhile, a support bracket 7 is installed at one lower end of one main body frame 11 of the main body 1 so as to prevent the chain 33 connected to the sprocket wheel 34 from being separated.

The grain supply means 8 is formed with a hopper 81 to be penetrated through the upper cover 17, the lower mold 13 is connected to the hopper 81, the grain is introduced into the hopper 81 A supply pipe 82 is formed so as to be fed into the container.

In addition, the supply pipe 82 is formed with a grain control unit 83 to adjust the amount of grain.

The grain control unit 83 is connected to the control knob 84 is installed on the outer surface of the main body frame 11, the control knob 84 is moved forward and backward according to the rotation operation of the control knob 84 It is connected to the operating member 85 and the operating member 85 by a hinge 87 to the control plate 86 to be slid before and after in the supply pipe 82 in accordance with the movement of the operating member (85). Is formed.

In addition, the control plate 86 is formed with a through hole 86a penetrating the supply pipe 82 so that the grain introduced into the supply pipe 82 may fall into the lower mold 13.

Looking at the operating state according to the present invention made of a configuration as described above are as follows.

First, when the grain is introduced into the hopper 81, the grain is dropped into the supply pipe 82 and becomes a standby state, and with the heater switch 21 of the controller 2 turned on, the upper and lower portions are turned on. A heater (not shown) installed in the molds 47 and 13 is heated and the motor switch 22 is turned on to drive the driving motor 31.

As the drive motor 31 is driven, the drive shaft 32 and the sprocket wheel 34 rotate, and the chain 33 connected to the sprocket wheel 34 rotates and the drive shaft 32 is driven together with the drive. Since the operation lever 41 is located at the bottom dead center through the seesaw movement along the outer circumferential surface of the operation cam (not shown), the upper mold 47 is lifted and the grain is supplied to the lower mold 13 through the supply pipe 82. It will be done.

At this time, by operating the grain control unit 83 to adjust the amount of grain flowing into the supply pipe 82 when the control knob 84 is rotated as shown in the accompanying drawings, Figure 14a and 14b The operating member 85 connected to the adjusting knob 84 is moved forward and backward by the rotation of the adjusting knob 84 and with the hinge 85 on the operating member 85 as the operating member 85 moves. Control panel 86 is connected to the slide before and after the variable opening and closing area of the through-hole (86a) connected to the supply pipe 82 is to be able to adjust the amount of grain flowing into the supply pipe (82). .

When the grain is supplied to the lower mold 13, the operating lever 41 is positioned at the top dead center through a seesaw movement along the outer circumferential surface of the actuating cam by the driving of the driving motor 31. As the elevating module 43 connected to the connecting member 42 descends, the upper mold 47 presses the lower mold 13.

Accordingly, the heaters built in the upper and lower molds 47 and 13 apply heat and pressure to the grains in the upper and lower molds 47 and 13.

In addition, the actuating lever 41 moving along the actuating cam descends at a predetermined interval while passing through a straight section of the actuating cam, and then the actuating lever 41 passes the end point of the actuating cam. Is rapidly lowered, in conjunction with the operation of the operation lever 41, the elevating module 43 is rapidly rising in accordance with the expansion force of the expansion spring 46 while the upper mold 47 is to be quickly released from the lower mold (13) Will be.

Thus, the grain of the lower mold 13 is expanded several times or more, so that the frying is completed.

The control lever 5 is installed above the connecting member 42 of the elevating means 4, so that the elevating pressure of the elevating module 43 is increased by the driving of the driving means 3. By adjusting the upper and lower molds (47, 13) can be easily adjusted to the state that the grain is pressed and fried to be able to produce the best taste crispy fried.

On the other hand, when the elevating module 43 of the elevating means (4) is quickly raised in the upward direction by the expansion force of the expansion spring 46, the expansion spring 46 is a plurality of upper and lower, respectively on both sides Since it is formed by dividing to minimize the impact applied to the expansion spring 46 in the strong pressure of the elevating means (4) it is possible to prevent the malfunction of the elevating means (4) and damage to the device.

And, since the support bracket (7) for supporting the chain 33 is installed on the outer surface of the main body frame 11, the elevating module 43 of the elevating means (4) in accordance with the drive of the drive motor (31). When the elevating operation is carried out at a rigid pressure, the chain 33, which is connected to the sprocket wheel 34 and rotates, is operated stably without being separated from the strong impact of the elevating means 4.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

Figure 1 is a perspective view showing the structure of the sputtering apparatus according to the prior art.

Figure 2 is a front view showing the structure of the fry splashing apparatus shown in FIG.

Figure 3 is a side schematic view showing a power transmission structure of the splatter manufacturing apparatus shown in FIG.

Figure 4 is a side view for explaining the interior of the sputtering apparatus shown in FIG.

Figure 5 is a plan view showing a grain transfer unit of the fry fried manufacturing apparatus according to the prior art.

Figure 6 is a side view showing a grain transfer unit of the conventional frying machine.

Figure 7 is a perspective view of the splatter manufacturing apparatus according to the present invention.

Figure 8 is a perspective view showing the internal structure of the sputtering apparatus according to the present invention.

Figure 9 is a front view showing the internal structure of the fry splash manufacturing apparatus according to the present invention.

Figure 10 is an exemplary side view of the fry splashing apparatus according to the present invention.

Figure 11 is a side perspective view of the sputtering apparatus according to the present invention.

12 is a perspective view showing a grain control unit of the grain supply means according to the present invention.

Figure 13 is a front view of the grain control unit of the grain supply means according to the present invention.

Figure 14a is a cross-sectional view illustrating a state in which the through-hole formed in the control plate of the grain control unit according to the present invention communicated with the inside of the supply pipe as much as possible.

Figure 14b is an exemplary view showing a state in which the through-hole and the supply and the inside of the control plate of the grain control unit according to the present invention is partially slid to the sliding control plate sliding.

<Description of the symbols for the main parts of the drawings>

1: body 2: controller

3: driving means 4: lifting and lowering means

5: control lever 6: ball bearing

7: support bracket 8: grain supply means

11 body frame 12 work table

13: lower mold 14: support plate

21: heater switch 22: motor switch

23: heater control unit 31: drive motor

32: drive shaft 33: chain

34: sprocket wheel 41: operating lever

42: connecting member 43: lifting module

44: support frame 45: connecting rod

45a: protruding jaw 46: expansion spring

47: upper mold 81: hopper

82: supply pipe 83: grain control unit

84: adjusting knob 85: operating member

86: control panel 86a: through hole

87: hinge

Claims (3)

A work table having a lower mold installed on a bottom surface thereof, a main body having a plurality of main body frames spaced apart from each other on both sides of the work table, and having a support plate fixed to an inner bottom of the main body frame; A controller installed at an outer side of the main body frame and having a heater switch, a motor switch, and a heater control unit configured to adjust a temperature of the heater to turn the heater on / off; A drive motor is installed in the main body frame and connected to the controller and is operated according to the on / off operation of the motor switch. The sprocket wheel is connected to the drive shaft of the drive motor by a chain and rotates according to the drive motor. Drive means formed; The operation lever is connected to the operation cam provided on the drive shaft is formed to operate the seesaw according to the rotation of the sprocket wheel, the elevating module is connected to the operation lever is connected to the operation lever to move up and down is formed through the support plate And a support frame provided with an upper mold installed at a lower end of the elevating module, i.e., under the support plate, to be moved upward and downward according to the elevating operation of the elevating module to be in close contact with the lower mold. There is a plurality of connecting rods are formed by penetrating through the support plate, the projection jaw is formed in the center of each of the connecting rod is formed by the projection jaw formed on the outer surface of each connecting rod divided by a plurality of upper and lower expansion spring is formed and; A support bracket installed at a lower end of one main body frame of the main body to prevent separation of the chain connected to the sprocket wheel; A hopper is formed to penetrate the upper cover formed on the main body, and a supply pipe is formed to be connected to the hopper so that the grain fed into the hopper can be fed into the lower mold. Grain supply means is formed so that the grain control unit; Scooping apparatus characterized in that the formed. The method of claim 1, In the upper end of the operating lever, the apparatus for manufacturing splashing, characterized in that the control lever is formed to form a ball bearing so that the pressure control and the lifting module can be operated to increase and lower the lifting module; The method of claim 1, The grain control unit is a control knob which is installed on the outer surface of the main body frame, an operating member connected to the control knob to move the front and rear according to the rotation operation of the control knob, the hinge is connected to the operating member It is formed as a control plate which is slid before and after in the supply pipe in accordance with the movement of the member, wherein the control plate is characterized in that the through-hole is formed so that the penetrating through the supply pipe and the grain introduced into the supply pipe fall into the lower mold Device.

Images