JP2014138944A - Compression packing device and controlling method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a compression packing device capable of easily removing jam of waste in a hopper.SOLUTION: The compression packing device includes a damper member 30 disposed so as to oscillate in a hopper 20, a first waste detecting sensor 71 for detecting retention of waste near a supply port 10, a second waste detecting sensor 72 for detecting retention of the waste in the hopper 20, and a control device 70 for oscillating the damper member 30 when the first waste detecting sensor 71 does not detect the waste and the second waste detecting sensor 72 detects the waste. When the waste is caught by the damper member 30 in the hopper 20 to generate the jam of the waste, the waste caught by the damper member 30 is made to fall by oscillating the damper member 30 with the control device 70, and the jam of the waste in the hopper 20 can be easily removed.

Description

  The present invention relates to a compression packing apparatus for compressing and packing recyclable waste materials such as corrugated cardboard, newspapers and magazines, and plastic bottles, and a control method thereof.

  2. Description of the Related Art Conventionally, a ram cutting type structure as shown in FIG. 4 is known as a compression packing device (see, for example, Patent Document 1). This type of compression packing apparatus is configured such that a moving compression block 40 called a ram reciprocates linearly within the compression chamber 11. Waste material such as waste paper is fed into a waste material feeding cylinder called a hopper 20 from a charging port (not shown) formed in the upper portion thereof, falls inside the hopper 20 and is opened on the upper surface of the compression chamber 11. It is supplied from the (inlet part) into the compression chamber 11. Subsequently, the moving compression block 40 moves forward and transports the waste material forward while compressing the waste material in the compression chamber 11.

  In the front of the compression chamber 11, the compressed waste materials are arranged as a compressed lump. Each time the next waste material is compressed and transferred, it is sequentially pushed forward. Thus, the compressed lump of the waste material arranged in front of the compression packing apparatus is bundled by a wire called a number line and discharged from the compression packing apparatus.

  Here, the overall length of the plurality of compressed lumps bound by the wires is more convenient for the subsequent transport operation, regardless of the type of waste material to be supplied. Therefore, in the conventional compression packing apparatus, the number of compressed lumps to be bundled together is appropriately changed according to the type of waste material to be supplied, or the starting position of the moving compression block 40 is set in the middle of the supply port 10. By disposing at the position, the supply port 10 is closed by the upper surface of the movable compression block 40 by an arbitrary area, so that the amount of waste material supplied from the supply port 10 can be adjusted. As a result, even if waste materials having different densities such as corrugated cardboard and newspaper are supplied, the compressed lump of waste materials can be bundled together in a substantially constant length unit.

  However, as described above, when the starting position of the moving compression block 40 is disposed at an intermediate position of the supply port 10 and the supply port 10 is partially blocked by the upper surface of the moving compression block 40, the waste material that has dropped in the hopper 20 However, it accumulates on the upper surface of the moving compression block 40 that closes the supply port 10 and stays in the hopper 20. For this reason, the waste material cannot be smoothly introduced into the opening portion of the supply port 10, and clogging of the waste material may occur frequently in the hopper 20.

Therefore, in the conventional apparatus disclosed in Patent Document 2, a guide plate (reference numeral 3 in FIG. 2 and reference numeral 21 in FIG. 3 in the same document) is provided in the hopper, and the waste material put in the hopper is used as the guide plate. The structure which makes it slide along the surface of this and guide | induces to the opening part of a supply port (connection port) is added.
However, even if this type of prior art is added, the horizontal cross-sectional area through which the waste material passes in the hopper is reduced by the guide plate, and there is a possibility that the waste material will be clogged there. Once the waste material is clogged in the hopper, the operation of the compression packing device is stopped, and the complicated work of manually removing the waste material clogged in the hopper is required. There was a risk of it.

JP 2004-74343 A Japanese Patent No. 4207186

  The present invention has been made in view of the above-described circumstances, and an object thereof is to make it possible to easily remove clogging of waste materials in a hopper.

In order to achieve the above object, the compression packing device of the present invention includes a compression chamber in which a supply port for supplying waste material to be compressed and packed opens on the upper surface,
A hopper extending in the vertical direction, having a waste material inlet formed above, and having a lower end opening communicating with the supply port;
A movable compression block that is capable of reciprocating in the compression chamber in the front-rear direction, and transferring the waste material supplied from the supply port forward while being compressed in the compression chamber;
An inclined surface is provided in the hopper so as to be swingable and guides the waste material to the opening portion of the supply port above the moving compression block when the movement compression block starts moving from a position where the supply port is partially blocked. A damper member to be formed;
A first waste material detection sensor for detecting the retention of waste material near the supply port;
A second waste material detection sensor for detecting the retention of waste material in the hopper;
Control means for swinging the damper member when the first waste material detection sensor does not detect the waste material and the second waste material detection sensor detects the waste material;
It is provided with.

  According to the present invention having the above-described configuration, when the waste material is caught in the damper member in the hopper and the waste material is clogged, the damper member is swung to apply an external force to the stuck waste material, The horizontal cross-sectional area through which the waste material passes can be increased. With such an operation, the waste material caught on the damper member can be dropped, and the clogging of the waste material in the hopper can be easily removed.

Here, the damper member is formed in a plate shape, the upper end edge is swingable around the horizontal axis, and receives the waste material put into the hopper and slides down toward the opening portion of the supply port. It is preferable that the surface is provided with a dispersion wall that disperses the waste material to be slid down from the central region in the hopper toward the both side regions.
By providing such a dispersion wall, waste materials that tend to accumulate in the central region in the compression chamber can be distributed and supplied to the regions on both sides. Thereby, the compression of the waste material can be made uniform in the entire region, and it becomes possible to form a block-shaped integrated compressed mass that is less likely to collapse.

In addition, the compression packing apparatus of the present invention has a function of opening and closing a part of the opening surface of the supply port from the front end to the rear and pushing the waste material overflowing from the supply port into the compression chamber due to the closing operation. An open / close compression lid;
A moving cutting blade provided at the front upper edge of the moving compression block;
A first fixed cutting blade provided at a front edge portion of the supply port in the compression chamber;
A second fixed cutting blade provided at the edge of the open / close compression lid corresponding to the front edge of the open supply port in a state where the open / close compression lid closes a partial region of the supply port;
It is good also as a structure provided with.

According to such a configuration, a part of the waste material overflowing from the supply port can be appropriately compressed by the open / close compression lid and pushed into the compression chamber. Thereafter, with the forward movement of the moving compression block, the remaining waste material overflowing from the supply port is cut by the shearing action of the moving cutting blade and the second fixed cutting blade, and the waste material in the compression chamber is removed with the pressing force of the moving compression block. It moves forward while compressing.
In this way, by pushing a part of the waste material overflowing from the supply port into the compression chamber using the open / close compression lid, the cutting distance of the waste material by the moving cutting blade and the fixed cutting blade is shortened, so the power required for the cutting Is small. In addition, since the waste material pushed into the compression chamber by the open / close compression lid has a high density in the compression chamber, the compression efficiency in the compression chamber is improved.

  On the other hand, some waste materials are easy to cut and do not require the use of an open / close compression lid. In that case, without using the open / close compression lid, the waste material overflowing from the supply port is cut by the shearing action of the moving cutting blade and the first fixed cutting blade as the moving compression block advances, and the moving compression block The waste material in the compression chamber can be transported forward while being compressed with a pressing force.

  Here, it is preferable that the opening / closing compression lid is configured to linearly move from obliquely above the supply port to close a part of the supply port. With this configuration, compared to a rotary opening / closing lid with a hinge at the center, the linear drive force can be changed to a waste material compression force with a simple structure, so a large compression ratio can be achieved with low power. Can be obtained.

  Moreover, the control method of the compression packaging apparatus according to the present invention is a method of swinging the damper member when the first waste material detection sensor does not detect the waste material and the second waste material detection sensor detects the waste material. Here, the detection of the waste material by the second waste material detection sensor is not a temporary detection that the waste material simply passes through the detection region by the second waste material detection sensor, but the waste material is constant in the detection region by the second waste material detection sensor. It means the detection of waste material in a situation where it stays continuously for more than an hour.

  As described above, according to the present invention, the waste material caught on the damper member can be dropped and the clogging of the waste material in the hopper can be easily removed by simply swinging the damper member. .

It is a front sectional view showing typically the composition of the compression packing device concerning the embodiment of the present invention. It is a figure which expands and shows the structure of a damper member, (a) is a top view, (b) is a front view. It is a block diagram which shows the control apparatus of the compression packing apparatus which concerns on embodiment of this invention. It is front sectional drawing which shows the structure of the conventional compression packing apparatus.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a front sectional view schematically showing a configuration of a compression packaging device according to an embodiment of the present invention.
As shown in the figure, the compression packing device of the present embodiment extends in the front-rear direction, and has a compression chamber 11 having a waste material supply port 10 opened in a part of the upper surface, and extends in the vertical direction. A hopper 20 in which a port (not shown) is formed and whose lower end opening communicates with the supply port 10, a damper member 30 swingably provided in the hopper 20, and a reciprocating movement in the compression chamber 11 in the front-rear direction A movable compression block 40, an open / close compression lid 50 that opens and closes a partial region of the supply port 10, and a binding machine 60 that bundles a plurality of compressed waste lumps together with a wire are provided.

  The compression chamber 11 forms a space in which a hollow portion having a square cross section extends in the front-rear direction. The supply port 10 is formed by cutting out the vicinity of the rear end portion of the ceiling wall forming the compression chamber 11 into a square shape. As described above, the supply port 10 communicates with the lower end opening of the hopper 20 provided above the supply port 10.

From a charging port (not shown) formed above the hopper 20, waste material conveyed by a charging conveyor (not shown) is charged. And a waste material is supplied in the compression chamber 11 through the supply port 10 by natural fall.
The waste material to be packaged is recyclable waste such as waste paper such as newspapers, magazines and cardboard, and plastic bottles.

The moving compression block 40 reciprocates in the front-rear direction in the compression chamber 11 under the driving force of a driving cylinder (not shown). The front surface of the moving compression block 40 is a flat surface having the same rectangular shape as the cross section of the compression chamber 11 and has a slightly smaller area than the cross section, so that friction does not occur between the inner wall of the compression chamber 11. The gap is formed. The moving compression block 40 has a strength that can sufficiently withstand the pressure to compress the waste material supplied into the compression chamber 11 into a lump.
The moving compression block 40 is movable from the rear side of the rear end edge of the supply port 10 in the compression chamber 11 through the region where the supply port 10 is formed and further forward.

FIG. 2 is an enlarged view showing the configuration of the damper member.
In the present embodiment, the damper member 30 is formed of a square plate-shaped metal member as shown in the figure, and the upper end edge 30a is swingably attached to the inner wall of the hopper 20 via a hinge 31. . The hinge 31 serving as a rotation axis is provided along the horizontal axis. The flat damper member 30 can swing in an arbitrary angle range from an attitude parallel to the inner wall 20a of the hopper 20 to an attitude inclined at an arbitrary angle with respect to the inner wall 20a.
The damper member 30 swings with a driving force of a driving motor (not shown), and the driving motor is controlled by a control device 70 described later (see FIG. 3). In this specification, such a drive motor is included in the damper member 30 and its control operation and the like will be described.

  The damper member 30 is disposed so as to cover the upper side of the moving compression block 40 when the moving compression block 40 starts moving from a position where the supply port 10 is partially closed as described later. An inclined surface is formed that guides the waste material that has fallen upward to the opening portion of the supply port 10 in the compression chamber 11.

  Further, the damper member 30 is formed with a dispersion wall 32 protruding on the surface that receives the waste material put into the hopper 20 and slides down toward the opening portion of the supply port 10. The dispersion wall 32 is provided in a substantially central portion of the surface of the damper member 30, and is formed in a mountain shape having a triangular cross section extending in the vertical direction. Further, the dispersive wall 32 has a shape in which the mountain-shaped ridge line gradually increases in height from the longitudinal center portion of the damper member 30 toward the lower end edge, and thereby the waste material that slides down on the surface of the damper member 30 is formed. It becomes possible to disperse from the central region in the hopper 20 toward the two side regions.

The open / close compression lid 50 is configured to penetrate through the inner wall of the hopper 20 provided above the supply port 10 and linearly move to the supply port 10 obliquely from above, thereby closing a partial region of the supply port 10. The open / close compression lid 50 reciprocates linearly upon receiving a driving force from a driving cylinder (not shown). The bottom surface 50 a of the open / close compression lid 50 is set at an angle so as to be arranged on the same plane as the supply port 10, and this bottom surface 50 a is a partial region (hereinafter referred to as “backward”) from the front end of the opening surface of the supply port 10. Open / close area). The width of the open / close region can be arbitrarily set, but the shape is set to a rectangular shape having the same width as the rectangular supply port 10 and an arbitrary length from the front end.
As shown in FIG. 1, the open / close compression lid 50 is preferably retracted from the hollow portion of the hopper 20 where the waste material falls by setting the standby position to the outside of the inner wall of the hopper 20. The open / close compression lid 50 passes through the hollow portion of the hopper 20 from the standby position and closes the open / close region of the supply port 10. At the same time, the open / close compression lid 50 presses the waste material overflowing upward from the open / close region and pushes it into the compression chamber 11.

  A moving cutting blade 41 is provided at the upper end edge of the front portion of the moving compression block 40. In addition, the open / close compression lid 50 is provided with a second fixed cutting blade 51 at the edge of the open / close compression lid 50 corresponding to the front edge of the supply port 10 that is open when the open / close region of the supply port 10 is closed. is there. As the moving compression block 40 moves forward, the movable cutting blade 41 and the second fixed cutting blade 51 cooperate to cut the waste material overflowing upward from the supply port 10.

  A first fixed cutting blade 12 is provided at the front edge portion of the supply port 10 in the compression chamber 11. As already described, some waste materials are easy to cut and do not require the use of the open / close compression lid 50. In that case, without using the open / close compression lid 50, the moving cutting blade 41 and the first fixed cutting blade 12 cooperate with each other as the moving compression block 40 advances, and overflows upward from the supply port 10. Cut the waste material.

  The bundling machine 60 winds a metal wire, called a number wire, around a compressed lump of waste material that has been sequentially compressed and transferred forward in the compression chamber 11 by the moving compression block 40 on a horizontal plane. Has the function of binding. That is, in the front region of the compression chamber 11, a plurality of waste materials that are compressed into a compacted mass are in contact with each other, and the wire is placed from one side surface to the front surface with respect to the compressed mass of the plurality of waste materials. Rotate and bind around the other side and back side. Bundling with wires is performed simultaneously at a plurality of locations at regular intervals in the vertical direction.

FIG. 3 is a block diagram showing a control device of the compression packing apparatus according to the present embodiment.
The operation of the waste material charging conveyor 80, the moving compression block 40, the damper member 30, the open / close compression lid 50, and the binding machine 60 is controlled by the control device 70. The control device 70 is configured by, for example, a computer in which a control program for the compression packing device is incorporated. The device control conditions are input from an input device 73 such as a touch panel connected to the control device 70.
In addition, the control device 70 inputs detection signals from the first waste material detection sensor 71 and the second waste material detection sensor 72, respectively. The first waste material detection sensor 71 detects the retention of waste material in the vicinity of the supply port 10 of the compression chamber 11. Further, the second waste material detection sensor 72 detects the retention of the waste material at a preset height position in the hopper 20 (a position higher than the damper member 30).

Next, a method for controlling the compression packing apparatus according to the present embodiment will be described.
Control conditions corresponding to the type of waste material and the like are input in advance from the input device 73. The control conditions include, for example, the start start position of the moving compression block 40, the swing position of the damper member 30, the presence / absence of use of the open / close compression lid 50, and the like.

Based on these control conditions, first, the moving compression block 40 is arranged at the start start position, the damper member 30 swings to cover the upper side of the moving compression block 40, and the opening of the supply port 10 in the compression chamber 11. Placed in a position to guide the waste material to the part.
When operating with all the supply ports 10 of the compression chamber 11 opened, as shown by the solid line in FIG. 1, the front end surface of the moving compression block 40 is positioned below the rear end edge of the supply port 10 or below. Is also stopped at the rear position (left direction in the figure). At this time, the damper member 30 is disposed at a position where it is suspended so as to be parallel to the inner surface of the hopper 20.

  Next, the agitating member (not shown) in the hopper 20 is operated, and the waste material loading conveyor (not shown) is driven to feed the waste material from the charging port (not shown) of the hopper 20. . The waste material thrown into the hopper 20 is stirred by a stirring member (not shown), falls inside the hopper 20, and is supplied from the supply port 10 into the compression chamber 11. At this time, if the damper member 30 is disposed at a position inclined with respect to the inner side surface of the hopper 20, the waste material slides down along the surface of the damper member 30, and the center of the hopper 20 in the hopper 20 by the action of the dispersion wall 32. Disperse the waste material from the area toward both sides.

When the waste material accumulates in the compression chamber 11 and overflows from the supply port 10, the first waste material detection sensor 71 detects the waste material. This detection signal is output to the control device 70. Thereafter, the waste material is accumulated, and when the second waste material detection sensor 72 detects the waste material, a detection signal is output to the control device 70.
When the control device 70 sequentially receives detection signals from the first waste material detection sensor 71 and the second waste material detection sensor 72, the control device 70 stops the waste material input conveyor (not shown) to stop the input of the waste material.

  Subsequently, when using the opening / closing compression lid 50, the opening / closing compression lid 50 is operated to press the waste material overflowing upward from the opening / closing area of the supply port 10 and into the compression chamber 11, Close the open / close area. Thereafter, the moving compression block 40 is driven to compress the waste material supplied into the compression chamber 11. After repeating a series of these operations a preset number of times, the binding machine is driven to bundle a plurality of waste compacts together with wires.

When the waste material is caught by the damper member 30 and clogged in the hopper 20, the second waste material detection sensor 72 detects the waste material and outputs a detection signal to the control device 70 before the first waste material detection sensor 71 detects the waste material. To do. When the control device 70 does not input the detection signal from the first waste material detection sensor 71 and inputs only the detection signal from the second waste material detection sensor 72, the control device 70 is clogged with waste material in the hopper 20. And the damper member 30 is swung.
Here, the control device 70 excludes temporary detection in which the waste material simply passes through the detection area of the second waste material detection sensor 72, and the waste material is continuously detected in the detection area of the second waste material detection sensor 72 for a certain period of time. It is determined that the waste material is clogged in the hopper 20.
By swinging the damper member 30 in this manner, an external force can be applied to the hooked waste material, or the horizontal cross-sectional area through which the waste material passes in the hopper 20 can be expanded. By this operation, the waste material caught on the damper member 30 falls, and the clogging of the waste material in the hopper 20 is removed with a high probability.

  It should be noted that the present invention is not limited to the above-described embodiment, and various modifications and applications can be made within the scope of the invention described in the claims.

10: supply port, 11: compression chamber, 12: first fixed cutting blade, 20: hopper, 30: damper member, 32: dispersion wall, 40: moving compression block, 41: moving cutting blade, 50: open / close compression lid, 51: second fixed cutting blade, 60: binding machine, 70: control device, 71: first waste material detection sensor, 72: second waste material detection sensor, 73: input device, 80: input conveyor

Claims (5)

A compression chamber in which a supply port for supplying waste material to be compressed is opened on the upper surface;
A hopper extending in the vertical direction, having a waste material inlet formed above, and having a lower end opening communicating with the supply port;
A movable compression block that is capable of reciprocating in the front-rear direction in the compression chamber, and that transports the waste material supplied from the supply port to the front while being compressed in the compression chamber;
When the movable compression block starts to move from a position where the supply port is partially closed, the waste material is disposed above the movable compression block to the opening portion of the supply port. A damper member that forms an inclined surface for guiding;
A first waste material detection sensor for detecting the retention of waste material in the vicinity of the supply port;
A second waste material detection sensor for detecting the retention of waste material in the hopper;
Control means for swinging the damper member when the first waste material detection sensor does not detect waste material and the second waste material detection sensor detects waste material;
A compression packing apparatus comprising: The damper member is formed in a plate shape, and an upper end edge thereof is swingable about a horizontal axis, and receives the waste material thrown into the hopper and slides down toward an opening portion of the supply port. 2. The compression packing apparatus according to claim 1, wherein a dispersion wall is provided on the surface to disperse the waste material to be slid down from a central region in the hopper toward both side regions. An open / close compression lid having a function of opening and closing a part of the opening surface of the supply port from the front end toward the rear and pushing the waste material overflowing from the supply port into the compression chamber with a closing operation;
A moving cutting blade provided at the front upper edge of the moving compression block;
A first fixed cutting blade provided at a front edge portion of the supply port in the compression chamber;
A second fixed cutting blade provided at an edge of the open / close compression lid corresponding to the front end edge of the supply port opened in a state where the open / close compression lid closes a partial region of the supply port;
The compression packing apparatus according to claim 1 or 2, further comprising: 4. The compression packing apparatus according to claim 3, wherein the opening / closing compression lid is configured to linearly move from obliquely above the supply port to close a part of the supply port. A method for controlling a compression packaging device according to claim 1,
A control method for a compression packing device, wherein the damper member is swung when the first waste material detection sensor does not detect waste material and the second waste material detection sensor detects waste material.

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