CN211994321U - Organic garbage crushing device - Google Patents

Abstract

The utility model discloses an organic garbage crushing device, which comprises a crushing bin provided with a left feed inlet and a right feed inlet; a left extrusion cylinder is arranged above the left feed port, a left extrusion piston is arranged inside the left extrusion cylinder, and a left lower gate valve is arranged between the left extrusion cylinder and the left feed port; a left hopper is arranged above the left extrusion cylinder, and a left upper gate valve is arranged between the left extrusion cylinder and the left hopper; a right extrusion cylinder is arranged above the right feeding hole, a right extrusion piston is arranged inside the right extrusion cylinder, and a right lower gate valve is arranged between the right extrusion cylinder and the right feeding hole; a right hopper is arranged above the right extrusion cylinder, and a right upper gate valve is arranged between the right extrusion cylinder and the right hopper; the left extrusion piston and the right extrusion piston are driven by a first bidirectional cylinder; the valve plates of the left lower gate valve and the right lower gate valve are driven by a second bidirectional cylinder; and valve plates of the left upper gate valve and the right upper gate valve are driven by a third bidirectional cylinder. The utility model discloses organic rubbish breaker, it can extrude dehydration and breakage to organic rubbish.

Description

Organic garbage crushing device

Technical Field

The utility model relates to an organic rubbish breaker.

Background

The organic garbage is waste containing organic matter components in household garbage, the organic garbage needs to be subjected to biochemical treatment, the organic garbage needs to be crushed before the biochemical treatment, and in many cases, the organic garbage needs to be dehydrated.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an organic rubbish breaker, it can extrude dehydration and breakage to organic rubbish.

In order to achieve the purpose, the technical scheme of the utility model is to design an organic garbage crushing device, which comprises a crushing bin, wherein the top end of the crushing bin is provided with a feeding hole, the bottom end of the crushing bin is provided with a feeding hole, and the inside of the crushing bin is provided with a crushing mechanism;

the feed inlets comprise a left feed inlet and a right feed inlet;

a horizontally arranged left extrusion cylinder is arranged above the left feed inlet and is arranged along the left-right direction; the left end of the left extrusion cylinder is sealed by a left water filtering plate, and a plurality of water filtering through holes are uniformly distributed on the left water filtering plate; a left extrusion piston is arranged in the left extrusion cylinder and is in sliding fit with the left extrusion cylinder; the bottom of the left extrusion cylinder is communicated with the left feed inlet, and a horizontally arranged left lower gate valve is arranged between the left extrusion cylinder and the left feed inlet; a left hopper is arranged above the left extrusion cylinder, the top of the left extrusion cylinder is communicated with the bottom end of the left hopper, and a horizontally arranged left upper gate valve is arranged between the left extrusion cylinder and the left hopper;

a horizontally arranged right extrusion cylinder is arranged above the right feeding hole and is arranged along the left-right direction; the right end of the right extrusion cylinder is sealed by a right water filtering plate, and a plurality of water filtering through holes are uniformly distributed on the right water filtering plate; a right extrusion piston is arranged in the right extrusion cylinder and is in sliding fit with the right extrusion cylinder; the bottom of the right extrusion cylinder is communicated with the right feed inlet, and a horizontally arranged right lower gate valve is arranged between the right extrusion cylinder and the right feed inlet; a right hopper is arranged above the right extrusion cylinder, the top of the right extrusion cylinder is communicated with the bottom end of the right hopper, and a horizontally arranged right upper gate valve is arranged between the right extrusion cylinder and the right hopper;

the left extrusion cylinder and the right extrusion cylinder share the axis, the left extrusion piston and the right extrusion piston are driven by a first bidirectional cylinder, the first bidirectional cylinder is arranged along the left and right direction, a left piston rod of the first bidirectional cylinder is connected with the left extrusion piston, and a right piston rod of the first bidirectional cylinder is connected with the right extrusion piston;

the valve plates of the left lower gate valve and the right lower gate valve are driven by a second bidirectional cylinder, the second bidirectional cylinder is arranged along the left-right direction, a left piston rod of the second bidirectional cylinder is connected with the valve plate of the left lower gate valve, and a right piston rod of the second bidirectional cylinder is connected with the valve plate of the right lower gate valve;

the valve plates of the left upper gate valve and the right upper gate valve are driven by a third bidirectional cylinder, the third bidirectional cylinder is arranged along the left-right direction, a left piston rod of the third bidirectional cylinder is connected with the valve plate of the left upper gate valve, and a right piston rod of the third bidirectional cylinder is connected with the valve plate of the right upper gate valve;

a material storage box is arranged above the left hopper and the right hopper, the top end of the material storage box is open, and the bottom end of the material storage box is provided with a left blanking port and a right blanking port; the left blanking port is communicated with the top end of the left hopper, and the right blanking port is communicated with the top end of the right hopper.

Preferably, the top of the crushing bin is also provided with an annular liquid collecting groove, and the bottom of the annular liquid collecting groove is externally connected with a liquid discharge pipe.

Preferably, the left feed inlet and the right feed inlet are symmetrically arranged.

Preferably, the left extrusion cylinder and the right extrusion cylinder are symmetrically arranged.

Preferably, the left extrusion piston and the right extrusion piston are symmetrically arranged.

Preferably, the left lower gate valve and the right lower gate valve are symmetrically arranged.

Preferably, the left upper gate valve and the right upper gate valve are symmetrically arranged.

Preferably, the left piston rod of the first bidirectional cylinder and the right piston rod of the first bidirectional cylinder are symmetrically arranged.

Preferably, the left piston rod of the second bidirectional cylinder and the right piston rod of the second bidirectional cylinder are symmetrically arranged.

Preferably, a left piston rod of the third bidirectional cylinder and a right piston rod of the third bidirectional cylinder are symmetrically arranged.

Preferably, the left hopper and the right hopper are symmetrically arranged.

The utility model has the advantages and the beneficial effects that: provided is an organic garbage crushing device which can perform extrusion dehydration and crushing on organic garbage.

The storage box is used for storing organic garbage to be crushed, and the organic garbage in the storage box can fall into the left hopper and the right hopper.

The left upper gate valve is used for controlling the left hopper to output organic garbage to the left extrusion cylinder, and when the left upper gate valve is opened, part of the organic garbage in the left hopper can fall into the left extrusion cylinder; when the left upper gate valve is closed, the organic garbage in the left hopper cannot fall into the left extrusion cylinder; the right upper flashboard valve is used for controlling the right hopper to output the organic garbage to the right extrusion cylinder, and when the right upper flashboard valve is opened, the organic garbage in the right hopper can partially fall into the right extrusion cylinder; when the upper right gate valve is closed, the organic garbage in the right hopper cannot fall into the right extrusion cylinder; the third bidirectional cylinder drives the left upper gate valve and the right upper gate valve to be opened and closed alternately, namely when the left upper gate valve is opened, the right upper gate valve is closed; when the upper left gate valve is closed, the upper right gate valve is opened.

The left extrusion piston is used for extruding the organic garbage in the left extrusion cylinder leftwards (the organic garbage is extruded with liquid to achieve a certain dehydration effect), and the extruded liquid is output by the water filtering through holes on the left water filtering plate and falls into the annular liquid collecting tank; the right extrusion piston is used for extruding the organic garbage in the right extrusion cylinder rightwards (the organic garbage is extruded with liquid to achieve a certain dehydration effect), and the extruded liquid is output by the water filtering through holes on the right water filtering plate and falls into the annular liquid collecting tank; the first bidirectional cylinder drives the left extrusion piston and the right extrusion piston to alternately extrude, namely, when the left extrusion piston extrudes leftwards, the right extrusion piston retracts leftwards; when the left extrusion piston retracts rightwards, the right extrusion piston extrudes rightwards.

The left lower gate valve is used for controlling the left extrusion cylinder to output organic garbage to the crushing bin, and when the left lower gate valve is closed, the organic garbage in the left extrusion cylinder cannot fall into the crushing bin; when the left lower flashboard valve is opened, the organic garbage in the left extrusion cylinder can fall into the crushing bin; the right lower gate valve is used for controlling the right extrusion cylinder to output the organic garbage to the crushing bin, and when the right lower gate valve is closed, the organic garbage in the right extrusion cylinder cannot fall into the crushing bin; when the right lower flashboard valve is opened, the organic garbage in the right extrusion cylinder can fall into the crushing bin; the second bidirectional cylinder drives the left lower gate valve and the right lower gate valve to be opened and closed alternately, namely when the left lower gate valve is opened, the right lower gate valve is closed; when the left lower flashboard valve is closed, the right lower flashboard valve is opened.

The lower left gate valve, the upper left gate valve and the left extrusion piston are matched with each other, and the matching process is as follows: A1) closing the left lower flashboard valve and opening the left upper flashboard valve; A2) the left extrusion piston extrudes leftwards until the left extrusion piston completes the leftward stroke; A3) closing the left upper flashboard valve, and opening the left lower flashboard valve; A4) the left extrusion piston retracts rightwards until the left extrusion piston completes the rightward stroke; A5) repeat steps a 1) through a 4).

The lower right gate valve, the upper right gate valve and the right extrusion piston are mutually matched, and the matching process is as follows: A1) closing the right lower gate valve and opening the right upper gate valve; A2) the right extrusion piston extrudes rightwards until the right extrusion piston completes the rightwards stroke; A3) the right upper flashboard valve is closed, and the right lower flashboard valve is opened; A4) the right extrusion piston retracts rightwards until the right extrusion piston completes the rightward stroke; A5) repeat steps a 1) through a 4).

The organic garbage in the left extruding cylinder and the right extruding cylinder falls into the crushing bin after being extruded and dehydrated, and is further crushed by a crushing mechanism in the crushing bin.

The utility model provides a left side extrusion piston and right side extrusion piston can extrude in turn, can improve work efficiency.

Drawings

Fig. 1 is a schematic diagram of the present invention.

Detailed Description

The following description will further describe embodiments of the present invention with reference to the accompanying drawings and examples. The following examples are only for illustrating the technical solutions of the present invention more clearly, and the protection scope of the present invention is not limited thereby.

The utility model discloses the technical scheme who specifically implements is:

as shown in fig. 1, an organic garbage crushing device comprises a crushing bin 1, wherein a feeding hole is formed in the top end of the crushing bin 1, a feeding hole is formed in the bottom end of the crushing bin 1, and a crushing mechanism is arranged inside the crushing bin 1;

the feed inlets comprise a left feed inlet and a right feed inlet;

a horizontally arranged left extrusion cylinder 2 is arranged above the left feed inlet, and the left extrusion cylinder 2 is arranged along the left-right direction; the left end of the left extrusion cylinder 2 is sealed by a left water filtering plate 21, and a plurality of water filtering through holes are uniformly distributed on the left water filtering plate 21; a left extrusion piston 22 is arranged inside the left extrusion cylinder 2, and the left extrusion piston 22 is in sliding fit with the left extrusion cylinder 2; the bottom of the left extrusion cylinder 2 is communicated with the left feed inlet, and a horizontally arranged left lower gate valve 41 is arranged between the left extrusion cylinder 2 and the left feed inlet; a left hopper 51 is arranged above the left extrusion cylinder 2, the top of the left extrusion cylinder 2 is communicated with the bottom end of the left hopper 51, and a horizontally arranged left upper gate valve 61 is arranged between the left extrusion cylinder 2 and the left hopper 51;

a horizontally arranged right extrusion cylinder 3 is arranged above the right feeding hole, and the right extrusion cylinder 3 is arranged along the left-right direction; the right end of the right extrusion cylinder 3 is sealed by a right water filtering plate 31, and a plurality of water filtering through holes are uniformly distributed on the right water filtering plate 31; a right extrusion piston 32 is arranged inside the right extrusion cylinder 3, and the right extrusion piston 32 is in sliding fit with the right extrusion cylinder 3; the bottom of the right extrusion cylinder 3 is communicated with the right feed inlet, and a horizontally arranged right lower gate valve 42 is arranged between the right extrusion cylinder 3 and the right feed inlet; a right hopper 52 is arranged above the right extrusion cylinder 3, the top of the right extrusion cylinder 3 is communicated with the bottom end of the right hopper 52, and a horizontally arranged right upper gate valve 62 is arranged between the right extrusion cylinder 3 and the right hopper 52;

the left extrusion cylinder 2 and the right extrusion cylinder 3 are coaxial, the left extrusion piston 22 and the right extrusion piston 32 are driven by a first bidirectional cylinder 71, the first bidirectional cylinder 71 is arranged along the left-right direction, a left piston rod of the first bidirectional cylinder 71 is connected with the left extrusion piston 22, and a right piston rod of the first bidirectional cylinder 71 is connected with the right extrusion piston 32;

the valve plates of the left lower gate valve 41 and the right lower gate valve 42 are driven by a second bidirectional cylinder 72, the second bidirectional cylinder 72 is arranged along the left-right direction, a left piston rod of the second bidirectional cylinder 72 is connected with the valve plate of the left lower gate valve 41, and a right piston rod of the second bidirectional cylinder 72 is connected with the valve plate of the right lower gate valve 42;

the valve plates of the left upper gate valve 61 and the right upper gate valve 62 are driven by a third bidirectional cylinder 73, the third bidirectional cylinder 73 is arranged along the left-right direction, a left piston rod of the third bidirectional cylinder 73 is connected with the valve plate of the left upper gate valve 61, and a right piston rod of the third bidirectional cylinder 73 is connected with the valve plate of the right upper gate valve 62;

a material storage box 8 is arranged above the left hopper 51 and the right hopper 52, the top end of the material storage box 8 is open, and the bottom end of the material storage box 8 is provided with a left blanking port and a right blanking port; the left blanking port is communicated with the top end of the left hopper 51, and the right blanking port is communicated with the top end of the right hopper 52.

The top of the crushing bin 1 is also provided with an annular liquid collecting groove 9, and the bottom of the annular liquid collecting groove 9 is externally connected with a liquid discharge pipe 91.

The left feed inlet and the right feed inlet are symmetrically arranged.

The left extrusion cylinder 2 and the right extrusion cylinder 3 are symmetrically arranged.

The left extrusion piston 22 and the right extrusion piston 32 are symmetrically arranged.

The left lower gate valve 41 and the right lower gate valve 42 are symmetrically arranged.

The left upper gate valve 61 and the right upper gate valve 62 are symmetrically arranged.

The left piston rod of the first bidirectional cylinder 71 is arranged symmetrically to the right piston rod of the first bidirectional cylinder 71.

The left piston rod of the second bidirectional cylinder 72 is arranged symmetrically to the right piston rod of the second bidirectional cylinder 72.

The left piston rod of the third bidirectional cylinder 73 is arranged symmetrically to the right piston rod of the third bidirectional cylinder 73.

The left hopper 51 and the right hopper 52 are symmetrically arranged.

The utility model discloses organic rubbish breaker, it can extrude dehydration and breakage to organic rubbish.

The storage bin 8 is used for storing organic garbage to be crushed, and the organic garbage in the storage bin 8 can fall into the left hopper 51 and the right hopper 52.

The left upper gate valve 61 is used for controlling the left hopper 51 to output organic garbage to the left extrusion cylinder 2, and when the left upper gate valve 61 is opened, part of the organic garbage in the left hopper 51 can fall into the left extrusion cylinder 2; when the upper left gate valve 61 is closed, the organic garbage in the left hopper 51 can not fall into the left extrusion cylinder 2; the right upper gate valve 62 is used for controlling the right hopper 52 to output organic garbage to the right extrusion cylinder 3, and when the right upper gate valve 62 is opened, the organic garbage in the right hopper 52 can partially fall into the right extrusion cylinder 3; when the upper right gate valve 62 is closed, the organic garbage in the right hopper 52 can not fall into the right extrusion cylinder 3; the third bidirectional cylinder 73 drives the left upper gate valve 61 and the right upper gate valve 62 to be opened and closed alternately, namely when the left upper gate valve 61 is opened, the right upper gate valve 62 is closed; when the upper left gate valve 61 is closed, the upper right gate valve 62 is opened.

The left extrusion piston 22 is used for extruding the organic garbage in the left extrusion cylinder 2 leftwards (the organic garbage is extruded with liquid to achieve a certain dehydration effect), and the extruded liquid is output from the water filtering through holes on the left water filtering plate 21 and falls into the annular liquid collecting tank 9; the right extrusion piston 32 is used for extruding the organic garbage in the right extrusion cylinder 3 rightwards (the organic garbage is extruded with liquid to achieve a certain dehydration effect), and the extruded liquid is output through the water filtering through holes on the right water filtering plate 31 and falls into the annular liquid collecting tank 9; the first bidirectional cylinder 71 drives the left extrusion piston 22 and the right extrusion piston 32 to alternately extrude, namely when the left extrusion piston 22 extrudes leftwards, the right extrusion piston 32 retracts leftwards; when the left pressing piston 22 is retracted rightward, the right pressing piston 32 is pressed rightward.

The left lower gate valve 41 is used for controlling the left extrusion cylinder 2 to output organic garbage to the crushing bin 1, and when the left lower gate valve 41 is closed, the organic garbage in the left extrusion cylinder 2 cannot fall into the crushing bin 1; when the left lower gate valve 41 is opened, the organic garbage in the left extrusion cylinder 2 can fall into the crushing bin 1; the right lower gate valve 42 is used for controlling the right extrusion cylinder 3 to output organic garbage to the crushing bin 1, and when the right lower gate valve 42 is closed, the organic garbage in the right extrusion cylinder 3 cannot fall into the crushing bin 1; when the right lower gate valve 42 is opened, the organic garbage in the right extrusion cylinder 3 can fall into the crushing bin 1; the second bidirectional cylinder 72 drives the left lower gate valve 41 and the right lower gate valve 42 to be opened and closed alternately, namely when the left lower gate valve 41 is opened, the right lower gate valve 42 is closed; when the left lower gate valve 41 is closed, the right lower gate valve 42 is opened.

The left lower gate valve 41, the left upper gate valve 61 and the left extrusion piston 22 are mutually matched, and the matching process is as follows: A1) closing the left lower gate valve 41 and opening the left upper gate valve 61; A2) the left extrusion piston 22 extrudes leftward until the left extrusion piston 22 completes a leftward stroke; A3) closing the left upper gate valve 61 and opening the left lower gate valve 41; A4) the left extrusion piston 22 retracts rightward until the left extrusion piston 22 completes a rightward stroke; A5) repeat steps a 1) through a 4).

The lower right gate valve 42, the upper right gate valve 62 and the right extrusion piston 32 are mutually matched, and the matching process is as follows: A1) the right lower gate valve 42 is closed and the right upper gate valve 62 is opened; A2) the right pressing piston 32 presses rightward until the right pressing piston 32 completes a rightward stroke; A3) the right upper gate valve 62 is closed and the right lower gate valve 42 is opened; A4) the right squeeze piston 32 retracts to the right until the right squeeze piston 32 completes its rightward stroke; A5) repeat steps a 1) through a 4).

The organic garbage in the left extruding cylinder 2 and the right extruding cylinder 3 falls into the crushing bin 1 after being extruded and dehydrated, and is further crushed by a crushing mechanism in the crushing bin 1.

The utility model provides a left extrusion piston 22 and right extrusion piston 32 can extrude alternately, can improve work efficiency.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the technical principle of the present invention, and these improvements and decorations should also be regarded as the protection scope of the present invention.

Claims (10)

1. The organic garbage crushing device comprises a crushing bin, wherein a feed inlet is formed in the top end of the crushing bin, a feed inlet is formed in the bottom end of the crushing bin, and a crushing mechanism is arranged inside the crushing bin; the method is characterized in that:

the feed inlets comprise a left feed inlet and a right feed inlet;

a horizontally arranged left extrusion cylinder is arranged above the left feed inlet and is arranged along the left-right direction; the left end of the left extrusion cylinder is sealed by a left water filtering plate, and a plurality of water filtering through holes are uniformly distributed on the left water filtering plate; a left extrusion piston is arranged in the left extrusion cylinder and is in sliding fit with the left extrusion cylinder; the bottom of the left extrusion cylinder is communicated with the left feed inlet, and a horizontally arranged left lower gate valve is arranged between the left extrusion cylinder and the left feed inlet; a left hopper is arranged above the left extrusion cylinder, the top of the left extrusion cylinder is communicated with the bottom end of the left hopper, and a horizontally arranged left upper gate valve is arranged between the left extrusion cylinder and the left hopper;

a horizontally arranged right extrusion cylinder is arranged above the right feeding hole and is arranged along the left-right direction; the right end of the right extrusion cylinder is sealed by a right water filtering plate, and a plurality of water filtering through holes are uniformly distributed on the right water filtering plate; a right extrusion piston is arranged in the right extrusion cylinder and is in sliding fit with the right extrusion cylinder; the bottom of the right extrusion cylinder is communicated with the right feed inlet, and a horizontally arranged right lower gate valve is arranged between the right extrusion cylinder and the right feed inlet; a right hopper is arranged above the right extrusion cylinder, the top of the right extrusion cylinder is communicated with the bottom end of the right hopper, and a horizontally arranged right upper gate valve is arranged between the right extrusion cylinder and the right hopper;

the left extrusion cylinder and the right extrusion cylinder share the axis, the left extrusion piston and the right extrusion piston are driven by a first bidirectional cylinder, the first bidirectional cylinder is arranged along the left and right direction, a left piston rod of the first bidirectional cylinder is connected with the left extrusion piston, and a right piston rod of the first bidirectional cylinder is connected with the right extrusion piston;

the valve plates of the left lower gate valve and the right lower gate valve are driven by a second bidirectional cylinder, the second bidirectional cylinder is arranged along the left-right direction, a left piston rod of the second bidirectional cylinder is connected with the valve plate of the left lower gate valve, and a right piston rod of the second bidirectional cylinder is connected with the valve plate of the right lower gate valve;

the valve plates of the left upper gate valve and the right upper gate valve are driven by a third bidirectional cylinder, the third bidirectional cylinder is arranged along the left-right direction, a left piston rod of the third bidirectional cylinder is connected with the valve plate of the left upper gate valve, and a right piston rod of the third bidirectional cylinder is connected with the valve plate of the right upper gate valve;

a material storage box is arranged above the left hopper and the right hopper, the top end of the material storage box is open, and the bottom end of the material storage box is provided with a left blanking port and a right blanking port; the left blanking port is communicated with the top end of the left hopper, and the right blanking port is communicated with the top end of the right hopper.

2. The organic garbage crushing device of claim 1, wherein the top of the crushing bin is further provided with an annular liquid collecting groove, and the bottom of the annular liquid collecting groove is externally connected with a liquid discharge pipe.

3. The organic waste crusher of claim 2, wherein the left feed opening and the right feed opening are symmetrically arranged.

4. The organic waste crusher of claim 3, wherein the left and right pressing cylinders are symmetrically arranged.

5. The organic waste crusher of claim 4, wherein the left and right crushing pistons are symmetrically arranged.

6. The organic garbage crushing device according to claim 5, wherein the left lower gate valve and the right lower gate valve are symmetrically arranged.

7. The organic garbage crushing device according to claim 6, wherein the left upper gate valve and the right upper gate valve are symmetrically arranged.

8. The organic garbage crushing device of claim 7, wherein the left piston rod of the first bidirectional cylinder is arranged symmetrically to the right piston rod of the first bidirectional cylinder.

9. The organic garbage crushing device of claim 8, wherein the piston rod on the left side of the second bidirectional cylinder is arranged symmetrically to the piston rod on the right side of the second bidirectional cylinder.

10. The organic garbage crushing device according to claim 9, wherein the piston rod on the left side of the third bidirectional cylinder is arranged symmetrically to the piston rod on the right side of the third bidirectional cylinder.

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