KR100996537B1 - A treadle type of food waste treatment apparatus - Google Patents

Abstract

PURPOSE: A food processing apparatus using power generated according to rolled by foot is provided to prevent a defective motor due to compressing the food waste by using power generated according to rolling the foot. CONSTITUTION: A food processing apparatus using power generated according to rolled by foot includes a step part rolling over the foot, a grinding part(140) which grinds the food waste by rotating a gear and screw and a dehydration part(150) which dehydrates the food waste while the power of the step part transmitted and rotating the dewatering box. The step part includes an elastic body connected to one side tie bar in which the first acceleration is expanded as one side of the stage. One side of a connection bar and the first acceleration are connected to a crank.

Description

A Treadle Type of Food Waste Treatment Apparatus}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a garbage disposal apparatus, and more particularly, to a garbage disposal apparatus for disposing garbage using a power generated by rolling a foot.

Conventionally developed food waste disposal system was installed in the kitchen sink, and the food waste discharged from the sink was treated through grinding, dehydration and drying processes, and the power required for the operation of the food waste disposal system was driven by a motor.

Accordingly, when a power failure occurs, not only the food waste disposal apparatus can not be operated but also the electric power cost due to the operation is consumed, and noise due to driving of the motor is generated.

The present invention has been made to solve the problems of the prior art as described above, and it is an object of the present invention to provide a stepped food garbage disposer configured to crush, dewater and squeeze food garbage using power generated along a cloud Its purpose is to.

According to another aspect of the present invention, there is provided a stepped food garbage disposer comprising: a tread portion for treading a foot; a crushing portion for crushing the food garbage while feeding gears and screws while receiving power from the tread portion; It is characterized in that it comprises a dehydration unit for rotating the dehydration container to receive power to dehydrate the food waste introduced into the dehydration container, and a receiving unit for storing the food waste dewatered and discharged from the dehydration container.

In addition, according to a preferred embodiment of the present invention, the stepping portion includes a footrest that is inclined, an elastic body supporting one side so that the footplate is inclined, and a connection bar extending to the left and right of the footrest.

Further, according to a preferred embodiment of the present invention, a first acceleration part is connected to one side connection bar extending to one side of the scaffold, and the first acceleration part transmits the power generated from the scaffold to the crushing part.

In addition, according to a preferred embodiment of the present invention, the one side connecting bar and the first acceleration part are connected by a crank, and the first acceleration part is rotatably mounted through the grinding part and the dehydration part.

In addition, according to a preferred embodiment of the present invention, a second acceleration portion is connected to the other connection bar extending to the other side of the scaffold, the second acceleration portion transfers the power generated in the scaffold to the dewatering portion.

In addition, according to a preferred embodiment of the present invention, the other connection bar and the second acceleration portion is connected to the crank, the dehydration portion of the dehydration portion is connected to the second acceleration portion by the power transmitted through the second acceleration portion The dehydration bucket rotates.

According to a preferred embodiment of the present invention, the rotational speed of the second accelerating portion is faster than the rotational speed of the first accelerating portion.

According to a preferred embodiment of the present invention, the body of the food garbage disposer is provided with an input unit for inputting food waste, and food waste is transferred to the first rotation shaft so that the food waste injected through the inlet is transferred to the crusher A first screw is formed, gears for cutting and grinding are mounted on a first rotary shaft corresponding to the grinding unit, and a second rotary shaft parallel to the first rotary shaft is rotatably mounted on the grinding unit. Gears are mounted on the second rotation shaft to mesh with the gears of the first rotation shaft to rotate.

In addition, according to a preferred embodiment of the present invention, the dehydration unit is equipped with a dehydration barrel which is connected to the second acceleration portion and rotates, the dehydration cylinder is smaller in the inner diameter toward the opposite side of the crushing portion is located, the The first rotary shaft is mounted to the first rotary shaft corresponding to the dehydration unit in a state where the first rotary shaft is located through the dehydration container, and compresses and transports the food waste dewatered from the dehydration container to the outside of the dehydration container.

According to a preferred embodiment of the present invention, a frame is formed inside the food waste so as to be positioned below the crushing portion, and a hole is formed in the frame.

In addition, according to a preferred embodiment of the present invention, a semicircular disc is symmetrically positioned at the loading port to close the loading port, and the disc is supported by a spring. When a weight greater than the elastic force of the spring is applied to the disc, The inlet is opened and the inlet is closed while being restored by elastic force when the weight applied is removed.

Further, according to a preferred embodiment of the present invention, the gears are saw blade gears or helical gears.

In addition, according to a preferred embodiment of the present invention, the receiving portion includes a hopper located at a lower portion of the outlet of the dewatering vessel, and a housing located below the hopper.

In addition, according to a preferred embodiment of the present invention, the upper part of the hopper is equipped with a ventilator.

As described above, the foot stepped food waste disposal apparatus of the present invention is advantageous in that the foot waste can be crushed, dehydrated, and compressed by discharging the food waste using the power generated along the clouds, so that there is no power consumption, have.

In addition, the stepping food waste treatment device of the present invention has an advantage that almost no failure occurs because the motor is not configured and can be used semi-permanently.

FIGS. 1A and 1B are a front view and a front sectional view showing a pedestrian-type food garbage disposer according to the present invention,
2 is a schematic view showing a gear configuration of the first acceleration unit shown in FIG.
3 is a schematic view showing a gear configuration of the second acceleration unit illustrated in FIG. 1.
Figure 4 is a side view showing a crank connecting the step portion and the gear shown in FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a footing food waste disposal apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic view showing a gear configuration of a first accelerating portion shown in Fig. 1, Fig. 3 is a schematic view showing a gear configuration of the first accelerating portion shown in Fig. 1 It is a schematic diagram which shows the gear structure of the 2nd acceleration part shown in the figure. And Figure 4 is a side view showing a crank connecting the step portion and the gear shown in FIG.

1A and 1B, a footing type food waste disposal apparatus 100 includes a step portion 110 for generating a foot power by a user, a food waste disposing unit 110 for inserting food waste 1 into a main body 101 of the food waste disposal apparatus 100, A transferring part 130 for transferring the food waste 1 introduced through the inlet 120 and a crushing part for cutting and crushing the food waste 1 transferred by the transferring part 130, And a squeezing unit 160 for squeezing and discharging the dehydrated food waste 1. The food waste 1 may be disposed in the vicinity of the food waste 1, And a power transmitting portion 170 for transmitting the power of the step portion 110 to the first rotating shaft 191 which rotates for conveying, crushing, dewatering and pressing.

The following describes the stepping food waste processor configured as described above.

The garbage disposer 100 is provided with a tread portion 110 at the bottom center of the main body 101. A loading port 120 is formed at the upper right portion of the main body 101 and a treated food garbage receiving portion 180) is formed.

The pedestal 111 is hinged to the front end of the foot 111 and is fixed to the body 101 and the pedestal 113 And an elastic body for supporting the foot plate 111 such that the foot plate 111 is inclined. Here, the elastic body is a torsion spring 117, but may alternatively be configured as a leaf spring and a coil spring, and when the user presses on the footrest 111, the footrest 111 is downwardly centered on a hinged front end. The torsion spring 117 is compressed while going down. When the force applied at this time is removed, the foot plate 111 is revolved upwardly by the elastic force of the torsion spring 117.

The foot bar 111 is connected to the connecting bars (119L, 119R) to the left and right, respectively, and the left connection bar (119L) extending to the left is connected to the first acceleration portion 171, which is a power transmission unit, extending to the right The second acceleration part 172 is connected to the right connection bar 119R.

Here, the first acceleration part 171 has an acceleration rate relatively smaller than the rotational speed of the second acceleration part 172, so that the user is connected to the second acceleration part 172 as compared with the number of times the user steps on the footrest 111. The number of revolutions of the gear is greater than the number of revolutions of the final gear connected to the first acceleration unit 171. The rotation speed of the dewatering unit 150 connected to the second acceleration unit 172 is faster than the rotation speed of the first rotation axis 191 connected to the first acceleration unit 171.

The lower end of the crank 175 is connected to the end of the left connection bar 119L and the first gear 179a of the first acceleration portion 171 is connected to the upper end of the crank 175. [ Here, the first accelerator 171 and the second accelerator 172 accelerate each other by connecting four gears 179a, 179b, 179c, and 179d, respectively, as shown in FIGS. 2 and 3. The accelerator 171 is engaged with the small gear of the first gear 179a and the second gear 179b, the large gear of the second gear 179b and the large gear of the third gear 179c mesh with each other, and the third gear 179c The small gear and the fourth gear 179d mesh with each other.

In the second acceleration part 172, the small gear of the first gear 179a and the second gear 179b meshes with each other, the large gear of the second gear 179b and the small gear of the third gear 179c mesh with each other, and the third gear ( The large gear of 179c and the fourth gear 179d mesh with each other.

Here, the first acceleration portion 171 is connected to the first gear 179a, the second gear 179b and the third gear 179c at an accelerating gear ratio, while the third gear 179c and the fourth gear 179d are connected at a reduction gear ratio Connected.

On the other hand, since the second acceleration part 172 is connected to the fourth gear 179d from the first gear 179a at an accelerator gear ratio, the first acceleration part 171 and the second acceleration part 172 are the same four types. The fourth gear 179d of the second acceleration portion 172 rotates at a higher speed than the fourth gear 179d of the first acceleration portion 171 according to the gear ratio.

In the first accelerator 171, the first gear 179a and the left connection bar 119L are connected to each other by a crank 175. Here, it is preferable that the crank 175 has a shape in which the first gear 179a of the first acceleration portion 171 is connected with a predetermined radius of curvature. As such, one side of the crank 175 that transmits power is more effective in transmitting the force as it is curved. Techniques for constructing one side of the crank 175 with a curved structure for efficiency of force transmission are also disclosed in the prior art, so that a detailed description thereof will be omitted.

The first gear 179a of the second acceleration portion 172 and the right connection bar 119R are connected to each other by a crank 175.

The first rotation shaft 191 is fixed to the center of the fourth gear 179d of the first acceleration unit 171, and the first rotation shaft 191 is rotatable by a plurality of bearings 193. The crushing unit 140, the dewatering unit 150, and the crushing unit 160 in the longitudinal direction of the conveying unit 130.

The fourth gear 179d of the second accelerator 172 is a gear formed around the dewatering drum 151 of the dewatering unit 150 and receives the power of the third gear 179c. Accordingly, the dewatering drum 151 is rotated by the second accelerator 172, and the spinning speed of the dewatering drum 151 is faster than the rotating speed of the first rotating shaft 191. Here, the dewatering cylinder 151 is also supported by a bearing or the like so as to freely rotate by the fourth gear 179d of the second acceleration portion 172. [

On the other hand, a first screw 131 having a long pitch is mounted on a portion of the first rotating shaft 191 corresponding to the transfer unit 130. The food garbage (1), which is separated from the upper part by a long lead having a long pitch, is pushed by the first screw (131) and transferred to the crushing part (140).

The saw blade gear 141 and the helical gear 143 are mounted on the first rotary shaft 191 corresponding to the crusher 140. In addition, the second rotary shaft 192 which rotates idle is rotatably mounted to the main body 101 at a portion corresponding to the crushing unit 140, and the saw blade gear 141 of the first rotary shaft 191 is mounted on the second rotary shaft 192. And a helical gear 143 and a relative sawtooth gear 141 which rotate in engagement with the helical gear 143 are mounted.

The food waste 1 transported to the crushing unit 140 along the first screw 131 of the transporting unit 130 is cut while passing through the sawing gear 141 of the crushing unit 140, It breaks down through the fields. The finely crushed food garbage 1 exits the crushing unit 140 along the helical gear 143 and falls into the dewatering tank 151 of the dewatering unit 150.

On the other hand, the dehydration container 151 is rotated at a higher speed than the first rotary shaft 191 by the second acceleration unit 172, the food waste (1) dropped to the dehydration container 151 is rotated along the dehydration container (151) While dehydrating the water contained in the food waste (1). The food waste 1 rotating along the dewatering container 151 moves to the pressing part 160 along the second screw 162 mounted on the first rotating shaft 191. [

The crimping unit 160 is a rear end of the dewatering container 151, and the diameter thereof gradually decreases toward the rear end of the dewatering container 151, and also has an outer diameter of the second screw 162 corresponding to the crimping unit 160. Becomes smaller. Therefore, the tip portion of the dewatering container 151 has a wide inner diameter and the food waste 1 dehydrates smoothly along the dewatering container 151 as the dewatering container 151 rotates at high speed, but along the second screw 162. The inner diameter of the dewatering container 151 becomes smaller toward the crimping portion 160 which is the rear end of the dewatering container 151 so that the food garbage 1 is compressed before being discharged from the discharge port 152 of the dewatering container 151, The garbage 1 is discharged in a compressed state and falls into the storage unit 180.

A hopper 181 is mounted below the outlet 152 of the dehydration container 151, and a storage box 183 for storing the dehydrated food waste 1 is located at the bottom of the hopper 181. Therefore, the dehydrated food waste (1) discharged from the dehydration container (151) is stored in the storage box (183) through the hopper (181).

On the other hand, an upper portion of the hopper 181 is provided with a ventilating barrel 185 so that fresh air is maintained in a portion where the hopper 181 and the housing 183 are located.

In the conveying unit 130 and the crushing unit 140 configured as described above, a frame 103 supporting the food waste 1 is mounted in the main body 101 at the lower portion of the first rotating shaft 191, and the frame 103. The wastewater generated in the food garbage 1 is separated through the hole 105 under the frame 103 and separated.

And the inlet 120 is equipped with an automatic switch 121 so as to prevent the odor flow back. Automatic switch 121 is a pair of semi-circular disk 123 is mounted to the inlet 120, the disk 123 is maintained in a horizontal state to close the inlet 120 by a spring, the disk 123 When the weight of the food waste 1 that is separated from the food waste 1 is larger than the elastic force of the spring, the two discs 123 of the semicircular shape are turned downward to open the inlet 120. When the food waste 1 is dropped by the feeder 130, The two disks 123 of the shape close the inlet 120 while being restored to a horizontal state by the elastic force.

In this way, the inlet 120 is always kept closed and opened only when the food waste 1 is input, thereby preventing the odor generated by the food waste 1 from flowing back.

1: food waste 100: food waste processor
101: main body 103: frame
105: hole 110:
111: footstool 113: pedestal
115: elastic body 117: torsion spring
119L: Left connection bar 119R: Right connection bar
120: inlet 121: automatic switch
123: Disk 130:
131: first screw 140: grinding unit
141: saw blade 143: helical gear
150: Dewatering unit 151: Dewatering tank
160: crimping portion 162: second screw
170: power transmission unit 171: first acceleration unit
172: second acceleration unit 175: crank
179a to 179d: gear
180: storage part 181: hopper
183: storage box 185: ventilator
191: first axis of rotation 192: second axis of rotation
193: Bearings

Claims (14)

Stepping portion 110 to roll,
A crushing unit 140 for crushing the food waste 1 while transferring the gears 141 and 143 and the screws 131 and 162 while receiving power from the crushing unit 110,
A dewatering unit 150 for receiving the power of the dredging unit 110 and rotating the dewatering tank 151 and dewatering the food wastes 1 introduced into the dewatering tank 151,
And a storage unit (180) for storing the food waste (1) dewatered and discharged from the dehydration tank (150)
Wherein the stepping portion includes an inclined foot plate, an elastic body for supporting one side of the foot plate so as to be inclined, and a connecting bar extending to the left side and the right side of the foot plate,
A first acceleration part is connected to one side connection bar extending to one side of the scaffold, and the first acceleration part transmits the power generated from the scaffold to the crushing part.
Wherein the first connecting part and the first accelerating part are connected by a crank, and the first rotating part is rotatably mounted on the first accelerating part through the crushing part and the dewatering part,
A second acceleration part is connected to the other connection bar extending to the other side of the scaffold, and the second acceleration part transmits the power generated from the scaffold to the dewatering part,
Wherein the second connection portion and the second acceleration portion are connected to each other by a crank and the dehydration conduit of the dehydration portion is connected to the second acceleration portion and the dehydration conduit is rotated by the power transmitted through the second acceleration portion. Garbage processor. delete delete delete delete delete The method of claim 1,
Wherein the rotation speed of the second accelerating portion is faster than the rotation speed of the first accelerating portion. The method of claim 1,
The main body of the food waste processor is provided with an inlet for injecting food waste, and a first screw for transporting food waste is formed in the first rotary shaft so that the food waste introduced through the inlet is transferred to the crushing unit. And a second rotation shaft which is parallel to the first rotation shaft is rotatably mounted on the first rotation shaft and gears are mounted on the second rotation shaft, Food waste processor characterized in that the rotation of the gear mesh with the rotating shaft. The method of claim 1,
The dehydration unit is equipped with a dehydration barrel that is connected to the second acceleration portion to rotate,
The inner diameter of the dehydrating tub becomes smaller toward the opposite side of the side where the pulverizing portion is located,
And a second screw is mounted on the first rotation shaft corresponding to the dewatering unit in a state where the first rotation shaft is passed through the dewatering tank so that the food wastewater dehydrated in the dewatering tank is pressed and conveyed out of the dewatering tank Food garbage disposal. The method of claim 1,
The food waste processor of the food waste is formed so that the frame is located under the crushing unit, the frame is a food waste processor, characterized in that the hole is formed. The method of claim 8,
The semicircular disk is symmetrically positioned at the loading port to close the loading port. The disk is supported by a spring. When the weight of the disk is greater than the elastic force of the spring, the loading port is opened and the applied weight is removed And the inlet is closed while being restored by elastic force. The method of claim 8,
Wherein the gears are sawtooth gears or helical gears. 10. The method of claim 9,
The housing part food waste processor, characterized in that it comprises a hopper located below the outlet of the dehydration container, and a storage box located below the hopper. The method of claim 13,
The food waste processing unit, characterized in that the upper part of the hopper is equipped with a ventilator.

Images