KR0156698B1 - Food waste handler - Google Patents

Abstract

The present invention relates to a food waste processor that compresses and dehydrates crushed food waste to reduce food waste and sanitarily treats food waste. In the food waste processor, dehydration is performed by decompressing and dehydrating food waste to compress and dehydrate food waste. Means 60, power generating means 70 for generating power to operate the dewatering means 60, and sensing means 80 for detecting the rotational speed and direction of rotation of the power generating means 70; It is characterized in that, because it is configured in this way, it is easy to handle the food waste by reducing the weight and volume of the food waste by increasing the dehydration degree to prevent the corruption of food waste.

Description

Food waste handler

1 is a longitudinal sectional view showing a conventional food waste processor.

Figure 2 is a longitudinal sectional view showing a food waste processor according to an embodiment of the present invention.

FIG. 3 is a perspective view of the dehydrating container, the compression plate and the discharge plate of FIG.

4 is a cross-sectional view taken along the line A-A in FIG.

5 is a perspective view showing the first sensing means and the second sensing means of FIG.

6 to 8 are diagrams showing the operating state of the food waste according to one embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

41: main body 51: recovery container

53, 55: guide tube 57: valve means

59: drain pipe 60: dewatering means

61: outer cylinder 63: dehydration container

65: compression plate 67: discharge plate

677: discharge wing 68: electric screw member

69: drive shaft member 70: power generating means

71: first motor 73: second motor

80: detection means 81,91: mounting rotating plate

83,93: Optical sensor 85,95: Mounting member

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a food waste processor, and more particularly, to a food waste processor that compresses and dehydrates crushed food waste to reduce food waste and sanitarily treats it.

Conventionally, in the food waste processor, as shown in FIG. 1, the mounting table 3 is mounted on the left side of the base body 1 by the fastening means 5, and the power is applied to the mounting table 3. As shown in FIG. The motor 7 which generate | occur | produces is arrange | positioned, The grinding | pulverization blade 9 is provided in the motor shaft which protruded above the said motor 7 so that food waste may be crushed. In addition, the upper side of the mounting table (3) is provided with a crushing body (11) forming a pulverization space 111 by a fastening means (not shown), so that food waste is put into the upper part of the crushing body (11). An inlet 13 is formed, and the inlet 13 is provided with a lid 14 so as to be openable and open so that the food waste during the grinding process does not splash out, and the bottom of the inner circumferential surface of the crushing body 11 is disposed of The fixed blade 15 is disposed to face the grinding blade 9 so as to increase the degree of grinding.

On the right side of the base body 1, dehydration means 30 for dewatering from the ground food debris is disposed, and the dewatering means 30 between the dewatering means 30 and the mounting table 3 is dewatered. A guide tube 17 for guiding the grounded food waste to be supplied to is disposed. One end of the guide tube 17 is connected to the upper portion of the outer peripheral surface of the mount (3) and the other end of the guide tube 17 is connected to the lower portion of the dehydration means (30).

The dewatering means 30 is an outer cylinder 31, a transfer screw member 33 for conveying the crushed food waste upwards by receiving the power of the motor 7, and disposed inside the outer cylinder 31 and the It consists of a dehydration tank 35 in which a plurality of outflow holes are formed so that water contained in the food dregs is discharged in the radial direction of the transfer screw member 33 while the food dregs are conveyed upward by the feed screw members 33. .

On the upper side of the transfer screw member 33, the discharge blade 21 for applying a moving force to the dehydrated food dregs to discharge the dehydrated food dregs through the guide tube 19 while passing through the dehydrating layer 35. The discharge container 23 which collect | recovers the said dehydrated food waste is arrange | positioned at the exit of the said guide pipe 19.

On the other hand, a pulley and a belt 25 are disposed in the base body 1 so as to transmit the power of the motor 7 to the dewatering means 30.

In the conventional food waste processor configured as described above, after the user opens the lid 14, the food waste containing water is introduced into the pulverization space 111 through the inlet 13, and then the lid 14 is closed and illustrated. If the operation switch not shown is turned on, power is applied to the motor 7 via an electric wire (not shown), and the motor 7 rotates. By the rotational force of the said motor 7, the grinding blade 9 arrange | positioned at the motor shaft of the motor 7 rotates at high speed. The rotating grinding blade 9 finely crushes the food waste in the grinding space 111 together with the fixed blade 15 fixed to the inner circumferential surface of the grinding body 11.

The finely ground food waste falls into the lower side of the grinding blade 9 through a space formed between the grinding blade 9 and the fixed blade 15, and then dewatering means 30 through the guide tube 17. Flows into the lower portion of the feed screw member 33. The crushed food waste flows naturally because it contains water.

On the other hand, the rotational force of the motor (7) is transmitted to the feed screw member 33 via the electric gear, pulley and valve 25 from the motor shaft protruding downward of the motor (7) and the feed screw member 33 rotates in a constant direction. When the conveying screw member 33 is rotated, the food waste introduced into the lower portion of the conveying screw member 33 is moved to the upper portion of the conveying screw member 33 by riding the screw bone of the conveying screw member 33. The water contained in the food waste during the movement of the food waste to the upper side is disadvantageous from the food waste through the outlet hole of the dehydration container 35 and then the space formed between the dehydration container 35 and the outer cylinder 31. Down to the bottom. This water is drained through a drain not shown.

The food waste dehydrated while passing through the dehydration container 35 is subjected to the movement force by the discharge blade 21 that rotates as the feed screw member 33 is rotated to the recovery container 23 through the guide tube 19. Gather.

The user checks that the food waste put into the grinding space 111 through the monitoring window (not shown) disposed on the outer circumferential surface of the grinding body 11 is crushed and completely falls to the lower side of the grinding blade 9, and then a predetermined time elapses. Then, when the operation switch (not shown) is turned off, the power supply to the motor 7 is stopped and the food waste processor stops operating.

Then, when a predetermined amount of dehydrated food waste is filled in the collecting container 23, after separating the collecting container 23 from the guide tube 19, the collecting container 23 is empty and the guide tube 19 is removed. Reattach or attach a new container to the guide tube (19).

By the way, in the conventional food waste processing apparatus comprised in this way, since the food waste containing water is dehydrated simply through the outflow hole of the dehydration container 35 in the middle of being raised by the feed screw member 33, dehydration from food waste is carried out. Did not go right. Therefore, the food waste collected in the collecting container 23 as well as the food waste remaining in the transfer screw member 33 and the guide tube 19 when the food waste processor is not in operation are decayed after a certain period of time, giving off a bad smell and an unsanitary environment. There was a problem with making.

Therefore, the present invention has been made to solve the problems described above, the object of the present invention is to dehydrate the food waste by dehydration, thereby increasing the dehydration to prevent the corruption of food waste and at the same time the weight and volume of food waste To reduce food waste handlers.

Food waste processor according to the present invention made to achieve the above object in the food waste processor, dehydration means for compressing and dehydrating food waste to compress and dehydrate food waste, and generates power to operate the dewatering means It characterized in that the power generating means, and the sensing means for detecting the rotational speed and the rotation direction of the power generating means.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In addition, the same code | symbol is attached | subjected about the part same as the part shown in FIG. 1, and the overlapping description is abbreviate | omitted.

As shown in FIG. 2, the motor mounting stand 43 is disposed on the left side of the main body 41, and the motor mounting stand 43 is placed in the grinding space 111 of the grinding body 11 above the motor mounting stand 43. A crushing motor 45 for generating power to crush the food waste is disposed, and on the right side of the crushing motor 45, a dehydration means 60 compresses the crushed food waste and dehydrates the food waste. It is.

Further, a power generating means 70 for generating power to operate the dewatering means 60 is disposed outside the dewatering means 60, and the power generating means outside the power generating means 70. Detecting means 80 for detecting the rotational speed and the rotational direction of the 70 is disposed.

In addition, the right side of the dewatering means 60 is provided with a collecting container 51 for collecting dehydrated food waste while passing through the dehydrating means 60, and an opening 511 formed at an upper end of the collecting container 51. ) Is in contact with one end of the guide pipe 53 for guiding the food waste to recover the dehydrated food waste into the collecting container 51. The other end of the guide tube 53 is in communication with one side of the dewatering means (60).

The dehydration means 60 flows into the outer cylinder 61, the dehydration barrel 63 disposed inside the outer cylinder 61 at regular intervals from the inner circumferential surface of the outer cylinder 61, and the dehydration cylinder 63. Compression plate 65 disposed so as to move up and down from the bottom in the dehydration container 63 and to compress the food waste introduced into the dehydration container (63) to compress the food waste and the dehydration container ( A discharge plate 67 disposed to be movable upward and downward from an upper portion of the upper portion 63, an electric screw member 68 electrically coupled to the compression plate 65 to drive the compression plate 65, and the discharge plate; It consists of a drive shaft member (69) slide-coupled to the discharge plate (67) so as to drive the guide (67) at the same time.

In the above description, the food waste crushed by the grinding blade 9 and the fixed blade 15 flows into the dehydration container 63 in the middle of the left side (outer peripheral surface) of the outer cylinder 61 and the dehydration container 63. Inlets 611 and 631 are formed, respectively, and the inlet 611 communicates with a guide tube 55 for guiding the crushed food waste into the dehydration container 63. In addition, the inlet 611 is provided with a valve means 57 controlled by a control means (not shown) to block or distribute the food waste flowing into the dehydration container 63 from the guide tube 55.

In addition, outlets 613 and 633 are formed at upper portions of the right side (outer circumferential surface) of the outer cylinder 61 and the dehydration container 63 so that the dehydrated food waste is discharged to the guide tube 53. In addition, the lower portion of the right side (outer circumferential surface) of the outer cylinder 61 is formed with a drain hole 615 communicated with the drain pipe 59 so that water separated from the food waste is drained.

3 and 4, a plurality of outlet holes 635 are formed on the circumferential surface of the dehydration container 63 so that water contained in the food waste flows out of the dehydration container 63. Is formed, and a protrusion 637 is formed in the longitudinal direction of the dehydration container 63 to guide the compression plate 65 at a predetermined portion of the inner circumferential surface of the dehydration container 63, and the dehydration container 63 is formed. On the inner circumferential surface of the upper portion of the discharge plate 67 is formed an electric female screw portion 639 to move up and down along the screw groove.

In the central portion of the compression plate 65, the electric female screw hole 651 is formed so that the electric screw member 68 is coupled with the electric screw to penetrate therethrough. A concave and convex portion 653 is formed to be unevenly coupled to the protrusion 637 so that the compression plate 65 moves up and down along the protrusion 637 of the 63.

A through hole 671 is formed in the central portion of the discharge plate 67 so that the drive shaft member 69 slides and penetrates, and a concave inlet portion 673 is formed at a constant portion of the inner circumferential surface of the through hole 671. On the outer circumferential surface of the discharge plate 67, an electric male screw part 675 which is electrically screwed to the electric female screw part 639 of the dehydration container 63 is formed, and a bottom of the discharge plate 67 is formed. A plurality of discharge wings 677 are formed to discharge the dehydrated food waste to the guide tube 53.

In addition, as shown in Figure 2, the outer circumferential surface of the drive shaft member 69 is fitted into the concave inlet portion 673 of the discharge plate 67 to guide the discharge plate 67 to move up and down ( 691 is formed in the longitudinal direction of the drive shaft member 69.

In addition, an opening is formed on the right side of the main body 41 to allow the recovery container 51 to enter and exit the inside of the main body 41, and the recovery container 51 is moved on the right side of the recovery container 51. Handle 513 is formed to facilitate.

The power generating means 70 drives the compression plate 65 of the dewatering means 60 to generate power to compress the crushed food waste, and the ship of the dewatering means 60. The second motor 73 generates power to drive the press 67 and simultaneously discharge the crushed food waste.

The first motor 71 and the second motor 73 are control motors, such as a stepping motor or a servo motor, in which a rotation amount can be controlled by control means (not shown).

In addition, the first motor 71 is disposed on the bottom surface of the outer cylinder 61 of the dewatering means 60 by fixing means (not shown), so that the first motor 71 motor shaft is connected by an unshown connecting means. It is connected to the electric screw member 68 of the dewatering means 60, the second motor 73 is disposed on the upper end surface of the outer cylinder 61 of the dewatering means 60 by a fixing means (not shown) The motor shaft of the second motor 73 is connected to the drive shaft member 69 of the dewatering means 60 by connecting means (not shown).

As shown in FIGS. 2 and 5, the sensing means 80 is mounted to the rotary shafts 81 and 91 mounted on one end of the motor shaft of the first motor 71 and one end of the motor shaft of the second motor 73, respectively. ) And a predetermined distance from the mounting rotary plates 81 and 91 so as to sense a rotational direction and the number of rotations of the mounting rotary plates 81 and 91 rotated according to the rotation of the motor shaft and transmit a signal to a control means (not shown). Exposed optical sensors 83 and 93 and mounting members 85 and 95 fixed to the inner wall of the main body 41 by fastening means (not shown) for disposing the optical sensors 83 and 93, respectively.

Concave portions 811 and 911 and convex portions 813 and 913 are formed at edges of the mounting rotary plates 81 and 91 to generate pulse signals by the optical sensors 83 and 93 as the mounting rotary plates 81 and 91 rotate. Are alternately formed, and the optical sensors 83 and 93 are electrically connected to control means, not shown, by wires, not shown.

The operation and effects of the food waste processor according to the present invention configured as described above will be described below.

As shown in FIG. 2, the inlet 611 which is opened and closed by the valve means 57 is opened, the discharge plate 67 is moved to the upper side in the dehydration container 63, and the compression plate 65 is dehydrated. In the state moved to the lower side in), the grinding motor 45 is operated to guide the finely crushed food waste by the grinding blade (9) and the fixed blade (15) fixed to the inner peripheral surface of the grinding body (11) When a certain amount is accumulated on the upper surface of the compression plate 65 in the dehydration container 63 through the pipe 55, the signal sensed by the sensing means (not shown) is transmitted to the control means (not shown). Next, the first motor 45 stops operating in accordance with the information embedded in the control means receiving the detection signal, and the valve means 57 is operated to close the inlet 611.

Next, as shown in FIG. 6, when the second motor 73 is operated by the control of the control means, and the drive shaft member 69 connected to the motor shaft of the second motor 73 rotates in a constant direction. , Discharge plate 67 moves downward within the length of drive shaft member 69. That is, the discharge plate 67 and the drive shaft member 69 is only rotated by the inlet portion 673 and the projecting portion (691) can be a linear movement, the electric screw coupled to the inner peripheral surface of the dehydration tube (63) The discharge plate 67 is moved while rotating along the screw groove. At this time, since the mounting rotary plate 91 mounted on the motor shaft protruding upward of the second motor 73 also rotates, an optical sensor for detecting the recess 911 and the convex portion 913 of the mounting rotary plate 91. The pulse signal generated by the 93 is transmitted to a control means (not shown), the second motor 73 is controlled by the control means, and the discharge plate 67 in accordance with the rotation speed of the second motor 73. Stop at the position past the outlets 613 and 633.

Natural dehydration is performed from the food waste accumulated on the compression plate 65 while the second motor 73 is in operation. That is, the water contained in the food waste is separated from the food waste through the outlet hole 635 of the dehydration container 63 while descending by gravity, and the separated water passes through the drain pipe 615 through the drain pipe 59. It is discharged to the outside.

After the second motor 73 is stopped, the first motor 71 is operated by the control of a control means (not shown), and the electric screw member 68 connected to the motor shaft of the first motor 71 is fixed. In the direction of rotation, the compression plate 65 moves upward within the length of the transmission screw member 68. That is, the compression plate 65 and the dehydration tube 63 are not rotated with each other by the concave indentation part 653 formed in the compression plate 65 and the protrusion 637 formed in the dehydration tube 63. Therefore, the compression plate 65 coupled to the outer peripheral surface of the electric screw member 68 is moved along the screw groove. At this time, since the mounting rotary plate 81 mounted on the motor shaft protruding downward of the first motor 71 also rotates, an optical sensor for detecting the recess 811 and the convex portion 813 of the mounting rotary plate 81. The pulse signal generated by the 83 is transmitted to a control means (not shown), the first motor 71 is controlled by the control means, and the compression plate 65 according to the rotation speed of the first motor 71. ) Rises to a fixed position. Therefore, the food waste between the discharge plate 67 and the compression plate 65 is compressed as the compression plate 65 is raised, the water contained in the food waste through the outlet hole 635 of the dehydration container Separated from the food waste, the separated water is discharged to the outside through the drain pipe 615 through the drain pipe (615).

After a certain time has elapsed, when dehydration is completely performed from food waste, the second motor 73 rotates in the opposite direction and is controlled by a control means (not shown) as shown in FIG. 71 continues to rotate so that the discharge plate 67 and the compression plate 65 is raised to remove dehydrated food waste between the discharge plate 67 and the compression plate 65 of the discharge ports 613 and 633. Located at the height, the first motor 71 and the second motor 73 is stopped.

Next, as shown in FIG. 8, in the state in which the compression plate 65 is stopped by the control of a control means (not shown), the second motor 73 in the direction in which the discharge plate 67 descends. Is rotated so that when the drive shaft member 69 fixed to the motor shaft of the second motor 73 is rotated, the discharge plate 67 slide-bonded to the drive shaft member 69 is a screw of the dehydration tube 63 Lower as you rotate along the groove. At this time, the food waste is discharged to the guide tube 53 through the discharge holes 613 and 633 by the discharge wing 677 formed on the bottom of the discharge plate 67.

The discharge plate 67, which is lowered by a certain distance by the control of a control unit (not shown), is lifted by the rotation in the opposite direction of the second motor 73, and the compression plate 65 is the first motor 71. The inlet 611 of the outer cylinder 61 is opened by the valve means 57, and becomes the initial state as shown in FIG.

When the dehydrated food waste is collected in the collecting container 51 through the guide tube 53, and a predetermined amount of food waste is filled in the collecting container 51, the food waste processing unit stops the operation of the food waste processing unit 51. After holding the handle 513, the collection container 51 is pulled out of the main body 41, the collection container 51 is emptied, and the collection container 51 is inserted into the main body 41 again.

As described above, the food waste processor according to the present invention provides a dehydration means for compressing and dehydrating food waste, thereby increasing the degree of dehydration, preventing the corruption of food waste, making the environment sanitary, and improving the weight and volume of food waste. It is very easy to handle food waste by reducing it.

Claims (5)

Dehydration means (60) for compressing and dehydrating food waste to compress and dehydrate food waste in the food waste processor, power generating means (70) for generating power to operate the dewatering means (60), and the power Food waste processor, characterized in that consisting of a detection means for detecting the number of revolutions and the rotation direction of the generating means (80). According to claim 1, The dewatering means 60 is the outer cylinder 61, the dehydration container 63 disposed inside the outer cylinder 61 at regular intervals from the inner circumferential surface of the outer cylinder 61, and the dewatering A compression plate 65 disposed so as to be movable up and down from the lower portion of the dehydration container 63 to compress the food waste introduced into the container 63, and simultaneously compressing the food waste introduced into the dewatering container 63; A discharge plate 67 disposed so as to be movable upward and downward from the upper portion of the dehydration container 63 to be discharged, and an electric screw member 68 coupled to the compression plate 65 to drive the compression plate 65; And a drive shaft member (69) coupled to the discharge plate (67) to guide the discharge plate (67) at the same time. The food waste processor according to claim 2, wherein a plurality of discharge wings (677) are formed on the bottom of the discharge plate (67) to discharge the dehydrated food waste. According to claim 1, wherein the power generating means 70 is driven by driving the compression plate 65 of the dewatering means 60, the first motor 71 for generating power to compress the crushed food waste, and the dewatering And a second motor (73) for generating power to simultaneously drive the discharge plate (67) of the means (60) to compress the crushed food waste and to discharge it. The method of claim 1, wherein the sensing means 80 is mounted to the motor shaft of the first motor 71 and the motor shaft of the second motor 73, respectively, and the mounting rotating plate (81,91) Optical sensors (83, 93) for generating a signal by detecting the rotational direction and the number of revolutions of the mounting rotating plate (81, 91) rotated in accordance with the rotation, respectively, and the mounting member (11, 93) is disposed Food waste processor, characterized in that consisting of (85,95).