JP2024026222A - Fine article removal device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fine article removal device which separates and removes fine articles contained in a liquid by automatic operation and removes the liquid adhering to the fine articles and recovers the fine articles to enable unmanned operation.

SOLUTION: A fine article removal device includes: a cylinder housing part 20 which houses fine articles to which a liquid is adhered; a screw shaft 30 which is disposed in an axial direction within the cylinder housing part and discharges the fine articles through rotation; and driving means 40 which rotationally drives the screw shaft. The liquid adhering to the fine articles is removed through rotation of the screw shaft and the fine articles from which the liquid is removed are discharged from the cylinder housing part.

SELECTED DRAWING: Figure 12

COPYRIGHT: (C)2024,JPO&INPIT

Description

The present invention relates to a fine particle removal device that separates fine particles such as fine powdery waste contained in a liquid, removes liquid adhering to the fine particles, and recovers the fine particles.

For example, in a machining device, cutting is performed while supplying a cutting fluid from a supply tank, and the cutting fluid contains cutting waste in the form of fine powder. The cutting fluid containing this fine powder cutting waste is supplied to a filter device, the cutting waste is removed by the filter device, and the cutting fluid is returned to the supply tank (for example, Patent Document 1).

As such filter devices, for example, there are those that remove cutting debris using a filter membrane or those that remove cutting debris by precipitation, but both of these devices remove fine powdery cutting debris that is contained in large quantities in the cutting fluid using a small device. There are problems such as the inability to reliably remove it in a short period of time.

In addition, the filter membrane may become clogged, and if it becomes clogged, the filter device must first be disassembled and the filter membrane must be cleaned. This cleaning work and replacement work occur when the product becomes unusable. Further, when filter membranes are used repeatedly, their filtration accuracy deteriorates and they become easily clogged, so most filter membranes are disposable filter membranes, which pose problems such as high costs.

Japanese Patent Application Publication No. 2001-137743

In this way, in a fine particle removal system, if the cutting debris is removed using a filter membrane, cleaning or replacing the filter membrane is required, and unmanned automatic operation removes fine powder particles contained in the liquid. It was difficult to separate the fine particles and remove the liquid adhering to the fine particles to recover the fine particles.

This invention was made in view of the above circumstances, and by automatically separating and removing fine particles contained in liquid, removing liquid adhering to fine particles, and recovering fine particles, unmanned operation is possible. The purpose is to provide a fine particle removal device that enables operation.

In order to solve the above problems and achieve the objects, the present invention was constructed as follows.

The invention according to claim 1 includes:
A centrifugal separator that separates and precipitates the fine particles contained in a liquid using centrifugal force, or a fine particle removal device that connects to a sedimentation unit that collects the separated fine particles, removes the liquid that adheres to the fine particles, and discharges the fine particles. is a device,
a cylindrical storage section that stores fine objects to which liquid is attached;
a screw shaft that is disposed in the axial direction inside the cylindrical housing part and discharges the fine particles by rotation;
a driving means for rotationally driving the screw shaft,
removing the liquid adhering to the fine particles by rotating the screw shaft;
The fine matter removing device is characterized in that the fine matter from which the liquid has been removed is discharged from the cylindrical storage portion.

The invention according to claim 2 is
A constriction part is provided on the discharge side of the cylindrical storage part,
Covering the constriction part with a stopper,
Always biasing the stopper in the closing direction by a biasing means,
2. The device for removing fine particles according to claim 1, wherein the stopper is pushed by the fine particles discharged from the cylindrical accommodating portion, and the constriction portion can be opened and closed.

The invention according to claim 3 is
Connecting a discharge cylinder to the discharge side of the cylindrical housing part,
The discharge tube has a discharge opening that opens upward from the cylindrical housing part,
2. The fine matter removing device according to claim 1, wherein the fine matter removed from the cylindrical storage portion is configured to be able to be discharged from a discharge opening of the discharge tube.

The invention according to claim 4 includes:
A centrifugal separator that separates and precipitates the fine particles contained in a liquid using centrifugal force, or a fine particle removal device that connects to a sedimentation unit that collects the separated fine particles, removes the liquid that adheres to the fine particles, and discharges the fine particles. is a device,
a screw shaft that discharges the fine particles by rotation;
a laterally disposed fine object removing section including a driving means for rotationally driving the screw shaft;
a cylindrical storage section that stores fine objects to which liquid is attached;
a screw shaft that is disposed in the axial direction inside the cylindrical housing part and discharges the fine particles by rotation;
a driving means for rotationally driving the screw shaft, and an obliquely arranged fine object removing section,
By driving the horizontally arranged fine object removing section and driving the obliquely arranged fine object removing section,
Sending fines from the horizontally arranged fines removing section to the obliquely arranged fines removing section,
The fine matter removing device is characterized in that the liquid is removed from the obliquely arranged fine matter removing section and the fine matter is discharged.

The invention according to claim 5 includes:
The obliquely arranged fine matter removing section is
Equipped with a fine matter discharge rail that discharges fine matter from which liquid has been removed.
5. The fine matter removing device according to claim 4, wherein the fine matter discharge rail has a configuration in which the position of the discharge port can be changed.

The invention according to claim 6 includes:
The screw axis direction of the obliquely arranged fine matter removing section is
6. The fine matter removing device according to claim 4, wherein the fine matter removing device is configured such that the angle of the horizontally arranged fine matter removing section can be varied using the center of the screw shaft as a fulcrum.

With the above configuration, the present invention has the following effects.

In the invention as claimed in claims 1 to 6, the microorganism is connected to a centrifugal separator that separates and precipitates fine particles contained in a liquid by centrifugal force, or a sedimentation section that collects separated fine particles, and adheres to the fine particles. A fine matter removal device that removes liquid and discharges fine matter can separate and remove fine matter contained in the liquid, remove liquid adhering to the fine matter, and recover the fine matter.

1 is a diagram showing a fine object removal system according to a first embodiment; FIG. FIG. 3 is a diagram showing a fine object removal system according to a second embodiment. FIG. 7 is a diagram showing a fine object removal system according to a third embodiment. FIG. 7 is a diagram showing a fine matter removal system according to a fourth embodiment. It is a figure showing the fine matter removal system of Embodiment 5. FIG. 2 is a diagram illustrating a fine object amount detection device. It is a principle diagram explaining the detection of the amount of fine particles. It is a figure which shows the case where the amount of fine objects is not detected. It is a figure which shows the case where the amount of minute objects is detected. FIG. 3 is a flow diagram showing detection of the amount of fine particles. It is a figure which shows the fine object amount detection apparatus of another form. FIG. 3 is a cross-sectional view of the fine matter removing device. FIG. 3 is a diagram showing a state in which fine particles are removed. It is a figure which shows the fine object removal apparatus of another form. It is a figure which shows the fine object removal apparatus of another form. FIG. 3 is a front view showing the fine matter removing device. FIG. 2 is a plan view showing a fine object removing device. FIG. 2 is a perspective view showing a fine object removing device. FIG. 6 is a diagram showing a configuration in which the position of the discharge port can be changed. It is a figure which shows the structure which can change an angle using the center of a screw shaft as a fulcrum.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a fine matter removing system and a fine matter removing apparatus of the present invention will be described in detail based on the drawings, but the present invention is not limited to these embodiments.

The fine matter removal system of this invention can be used to recover fine materials such as raw materials for pharmaceuticals, chemicals, foods, and beverages, as well as cutting powder and other fine materials from automobiles, machine tools, and processing industries. It is used for filtration of circulating water and wastewater from processing, etc., for removing fine particles such as impurities from semiconductors and biotechnology, and for removing fine particles such as foreign substances from washing water and solvents. Widely used for separating and removing substances.

(Embodiment 1)
This first embodiment is shown in FIG. FIG. 1 is a diagram showing a fine particle removal system.

The fine matter removal system 10 of this embodiment includes an apparatus 100 that performs processing or processing using a liquid, a storage tank 101 that stores the liquid used for processing or processing, and a liquid that is transferred from the storage tank 101 to the apparatus 100. It includes a circulation path 102 for supplying the liquid and returning it from the device 100 to the storage tank 101 for circulation, and circulates the liquid by driving the pump 103.

The circulation path 102 includes a centrifugal separator 110 that separates and precipitates fine particles contained in a liquid by centrifugal force, and a fine particle removal device 120 that removes liquid adhering to the precipitated fine particles and discharges the fine particles. , is provided.

The centrifugal separator 110 has a well-known configuration, and uses centrifugal force to separate fine matter from a liquid containing fine matter, and the separated fine matter settles and accumulates in the settling section 111 . In this embodiment, the settling section 111 is constituted by a cup molded from resin, metal, or the like.

The control device 113 includes a fine matter amount detection device 112 that detects the amount of fine matter accumulated by sedimentation, and a control device 113 that drives the fine matter removal device 120 based on the detected amount of fine matter. The fine matter removing device 120 is driven based on the amount of fine matter accumulated in the fine matter removal device 111 . The fine substance amount detection device 112 is configured to be provided in the sedimentation section 111.

A second automatic valve 114a is provided on the inlet side of the settling section 111, and a third automatic valve 114b is provided on the outlet side, each of which is controlled by a controller 113. During normal operation, the second automatic valve 114a is opened and the third automatic valve 114b is closed, and the separated fines settle and accumulate in the settling section 111. When the amount of fine particles accumulated in the settling section 111 reaches a predetermined amount, the second automatic valve 114a is closed, the third automatic valve 114b is opened, and the fine particles accumulated in the settling section 111 are discharged.

The fine matter amount detection device 112 detects the amount of fine matter accumulated in the settling section 111, and the control device 113 detects the amount of fine matter detected from the fine matter amount detection device 112.
The second automatic valve 114a is closed, the third automatic valve 114b is opened, the fine particles accumulated in the settling section 111 are sent to the fine particle removal device 120, and the fine particle removal device 120 is driven to adhere to the precipitated fine particles. The liquid is removed and the fine matter is discharged, the fine matter is collected in the collection container 61, and the removed liquid is returned to the storage tank 101.

In this embodiment, the circulation path 102 includes a centrifugal separator 110 that separates and precipitates fine particles contained in a liquid by centrifugal force, and a centrifugal separator 110 that removes liquid adhering to the precipitated fine particles and discharges the fine particles. A fine matter removing device 120 is provided, the fine matter amount detecting device 112 detects the amount of fine matter accumulated in the settling section 111, and the control device 113 detects the fine matter removing device 120 based on the amount of fine matter detected from the fine matter amount detecting device 112. The automatic operation separates and removes the fine particles contained in the liquid and removes the liquid that adheres to the fine particles. Collecting fine particles enables unmanned operation.

In this embodiment, the second automatic valve 114a is provided on the inlet side of the settling section 111, and is closed when sending the fine matter accumulated in the settling section 111 to the fine matter removing device 120. Fine matter may be stored in the sedimentation section 111 and sent to the fine matter removal device 120 without providing the valve 114a. The types of the second automatic valve 114a and the third automatic valve 114b are not particularly limited.

(Embodiment 2)
This second embodiment is shown in FIG. FIG. 2 is a diagram showing a fine particle removal system.

In the fine matter removal system 10 of this embodiment, the same components as in Embodiment 1 are given the same reference numerals, and the description thereof will be omitted. The fine matter removal system 10 of this embodiment includes:
A plurality of two fine object removing devices 120 are connected in series. The fine matter removing device 120 on the upstream side is connected to the centrifugal separator 110, and the fine matter removing device 120 on the downstream side is connected to the storage tank 101.

The upstream fine matter removal device 120 and the downstream fine matter removal device 120 are equipped with a fine matter amount detection device 112, and the fine matter amount detection device 112 detects the amount of fine matter accumulated in the fine matter removal device 120 and outputs a detection signal. is sent to the control device 113.

The control device 113 drives the upstream fine matter removal device 120 based on the detection signal from the fine matter amount detection device 112 disposed in the upstream fine matter removal device 120.
The liquid adhering to the precipitated fines is removed and the fines are discharged, the fines are collected in the collection container 61, and the removed liquid is sent to the fines removing device 120 on the downstream side.

The control device 113 drives the downstream fine matter removing device 120 based on the detection signal from the fine matter amount detecting device 112 disposed in the downstream fine matter removing device 120.
The liquid adhering to the precipitated fines is removed and the fines are discharged, the fines are collected in the collection container 61, and the removed liquid is returned to the storage tank 101.

(Embodiment 3)
This third embodiment is shown in FIG. FIG. 3 is a diagram showing a fine object removal system.

In the fine matter removal system 10 of this embodiment, the same components as in Embodiment 1 are given the same reference numerals, and the description thereof will be omitted. The fine matter removal system 10 of this embodiment has a path leading to the device 100 via the first automatic valve 114c, a second automatic valve 114a, and the centrifugal separator 110 in order on the upstream side of the sedimentation section 111. The downstream side of the settling section 111 includes a path leading to the fine matter removing device 120 via the third automatic valve 114b.

Under the control of the control device 113, in normal operation, the first automatic valve 114c is closed, the second automatic valve 114a is opened, and the third automatic valve 114b is closed to accumulate fine substances in the sedimentation section 111. The amount of fine particles accumulated in the sedimentation section 111 is detected by the fine particle amount detection device 112, and the control device 113 performs control based on the detected amount of fine particles, and the discharge operation is performed by closing the second automatic valve 114a and The automatic valve 114b is opened to discharge the fine particles accumulated in the sedimentation section 111, and at that time, the first automatic valve 114c is opened to wash the sedimentation section 111 and the third automatic valve 114b to remove the fine particles that cannot be discharged. It is discharged to the material removal device 120. When returning to normal operation, the first automatic valve 114c is closed, the second automatic valve 114a is opened, and the third automatic valve 114b is closed to collect fine particles in the settling section 111. The types of the first automatic valve 114c, the second automatic valve 114a, and the third automatic valve 114b are not particularly limited.

In the fine matter removal system 10 of this embodiment, by performing normal operation, discharge operation, and return to normal operation, only the accumulated amount of fine matter can be detected and discharged, regardless of the flow rate per minute. This makes it possible to automate the process by minimizing the amount of waste liquid.

(Embodiment 4)
This fourth embodiment is shown in FIG. FIG. 4 is a diagram showing a fine object removal system.

In the fine matter removal system 10 of this embodiment, the same components as in Embodiment 1 are given the same reference numerals, and the description thereof will be omitted. The fine matter removal system 10 of this embodiment includes an introduction passage 140 that leads precipitated fine matter to the fine matter removal device 120, and the introduction passage 140 is configured to communicate with the centrifugal separator 110 via an automatic valve 141. be.

In normal operation, the automatic valve 141 is opened, and the separated fines settle and are introduced into the fines removal device 120 via the introduction passage 140. The introduction passage 140 is equipped with a fine matter amount detection device 112, and the fine matter amount detection device 112 detects the amount of fine matter accumulated in the introduction passage 140. The control device 113 closes the automatic valve 141 based on the amount of fine particles detected by the fine particle amount detection device 112, drives the fine particle removing device 120, removes the liquid adhering to the precipitated fine particles, and discharges the fine particles. .

(Embodiment 5)
This fifth embodiment is shown in FIG. FIG. 5 is a diagram showing a fine object removal system.

In the fine matter removal system 10 of this embodiment, the same components as in Embodiment 1 are given the same reference numerals, and the description thereof will be omitted. The fine matter removal system 10 of this embodiment includes:
It includes an introduction passage 140 that guides precipitated fines to the fines removing device 120, and the introduction passage 140 is configured to communicate with the centrifugal separator 110 via an automatic valve 141a.

The fine matter removal system 10 of this embodiment has a path leading to the device 100 via the first automatic valve 114c, a second automatic valve 114a, and the centrifugal separator 110 in sequence on the upstream side of the introduction passage 140. The downstream side of the introduction passage 140 includes a path leading to the fine matter removal device 120.

Under the control of the control device 113, in normal operation, the first automatic valve 114c is closed, the second automatic valve 114a is opened, and fine particles are accumulated in the introduction passage 140. The amount of fine particles accumulated in the introduction passage 140 is detected by the fine particle amount detection device 112, and the control device 113 performs control based on the detected amount of fine particles. The introduction of the removing device 120 is driven to discharge the fine particles accumulated in the passage 140, and at this time, the first automatic valve 114c is opened to clean the introduction passage 140 and discharge the fine particles that cannot be discharged to the fine particle removing device 120. . Returning to normal operation is configured to close the first automatic valve 114c, open the second automatic valve 114a, and collect fine particles in the introduction passage 140.

(fine object detection device)
[Configuration of form 1]
The fine object amount detection device is configured as shown in FIGS. 6 to 11. FIG. 6 is a diagram explaining a fine object amount detection device, FIG. 7 is a principle diagram explaining the detection of a fine object amount, FIG. 8 is a diagram showing a case where no fine object amount is detected, and FIG. 9 is a diagram showing a case where a fine object amount is detected. , FIG. 10 is a flowchart showing the detection of the amount of fine particles, and FIG. 11 is a diagram showing another form of the fine particle amount detection device.

This fine substance amount detection device 112 is a device that detects the amount of fine substances accumulated in the sedimentation part 111, and is a device that detects the amount of fine substances accumulated in the sedimentation part 111. Detecting means 112b for detecting the amount of accumulated fine particles.

The ultrasonic sensor 112a is held on the outer surface of the precipitation part 111 by a coupling material 112c, and is attached to a predetermined position with a mounting jig 112d. The position where this ultrasonic sensor 112a is attached is the position where the amount of fine particles accumulated in the sedimentation section 111 is detected. A discharge passage 150 communicates with the bottom of the settling section 111 .

The detection means 112b determines that the amount of fine particles is less than the specified value when the output from the ultrasonic sensor 112a is equal to or higher than the threshold value, and determines that the amount of fine particles is less than the specified value when the output from the ultrasonic sensor 112a is less than the threshold value. It is judged that this is the above.

(Detection principle)
The ultrasonic sensor 112a of this embodiment is configured to detect the presence or absence of an object by transmitting ultrasonic waves toward the object using a transmitter 112a1 and receiving the reflected waves using a receiver 112a2.

In this embodiment, a reflection type is used, and as shown in FIG. 7(a), the side wall of the precipitation part 111 causes mouth reflection, inner wall reflection, and outer wall reflection. For example, a method may be used in which only reflected waves from objects existing within a detection distance range set by a distance adjustment volume or the like are detected.

As shown in FIG. 7B, when only the cutting fluid or no cutting fluid is collected inside the settling portion 111, the output due to reflection from the inner wall of the ultrasonic sensor 112a is large. As shown in FIG. 7(c), when the fine particles contained in the cutting fluid are separated and removed and the fine particles accumulate inside the settling section 111, the output due to reflection from the inner wall of the ultrasonic sensor 112a becomes fine. It is attenuated by objects and becomes smaller.

(Detection of minute amount)
Detection of the amount of fine objects by the fine object amount detection device 112 of this embodiment will be explained based on FIGS. 8 to 10. In the minute object detection device 112 of this embodiment, an ultrasonic sensor 112a is connected to a detection means 112b by a cable.

Detection of the amount of minute objects is started (FIG. 10(a)), and the ultrasonic sensor 112a transmits ultrasonic waves and receives the reflected waves (FIGS. 10(b) and (c)). The detection means 112b judges the signal received by the ultrasonic sensor 112a (FIG. 10(d)), and determines that if the output from the ultrasonic sensor 112a, that is, the received voltage is above the threshold value, the amount of fine particles is below the specified value ( In FIG. 8(b)), when the received voltage is below the threshold value, it is determined that the amount of fine particles is above the specified value (FIG. 9(b)).

If it is determined that the amount of fine particles is below the specified value, a normal display is performed (FIG. 10(e)), and for example, a blue lamp is turned on. If it is determined that the amount of fine particles is equal to or greater than the specified value, a detection signal is output (FIG. 10(f)) and the process ends (FIG. 10(g)).

[Configuration of form 2]
The fine substance amount detection device 112 of this embodiment uses a transmission type ultrasonic sensor 112a provided on the outer surface of the settling section 111, as shown in FIG. This transmission type has a configuration in which the transmitter 112a1 transmits ultrasonic waves toward the object, and the transmitted waves are received by the wave receiver 112a2 to detect the presence or absence of the object. The wave transmitter 112a1 and the wave receiver 112a2 are held by a coupling material 112c on the outer surface of the settling portion 111 at opposing positions, and are attached to a predetermined position using a mounting jig. The position where this ultrasonic sensor 112a is attached is the position where the amount of fine particles accumulated in the sedimentation section 111 is detected.

The detection means 112b determines that the amount of fine particles is less than the specified value when the output from the ultrasonic sensor 112a is equal to or higher than the threshold value, and determines that the amount of fine particles is less than the specified value when the output from the ultrasonic sensor 112a is less than the threshold value. It is judged that this is the above.

In this embodiment, as shown in FIG. 11(b), when only the cutting fluid or no cutting fluid is collected inside the settling section 111, the output of the ultrasonic sensor 112a is is large. When the fine particles contained in the cutting fluid are separated and removed and the fine particles accumulate inside the settling section 111, the output of the ultrasonic sensor 112a is attenuated by the fine particles and becomes smaller.

(Fine object removal device)
[Configuration of form 1]
The fine particle removal device of this embodiment will be explained based on FIGS. 12 and 13. FIG. 12 is a sectional view of the fine matter removing device, and FIG. 13 is a diagram showing a state in which fine matter is removed.

The fine matter removing device 120 of this embodiment includes a cylindrical storage section 20 that accommodates fine matter to which settling liquid has adhered, and a screw that is disposed in the axial direction inside the cylindrical housing section 20 and discharges the fine matter by rotation. This configuration includes a shaft 30 and a driving means 40 that rotationally drives the screw shaft 30.

The cylindrical housing portion 20 has an introduction opening 21 formed above the center thereof, and an introduction pipe 22 is connected to the introduction opening 21 . A centrifugal separator 50 is connected to the cylindrical housing part 20 via an introduction pipe 22. The fine particles to which the liquid has adhered are accommodated inside the cylindrical accommodating portion 20 through the introduction opening 21 .

The screw shaft 30 has a screw 31 , and the screw 31 is formed to correspond to the length of the cylindrical housing portion 20 . The driving means 40 is constituted by a motor 41 , and an output shaft 42 of the motor 41 is connected to the input shaft portion 32 of the screw shaft 30 via a connecting member 43 .

A motor 41 is attached to the rear end of the cylindrical housing portion 20 via a mounting body 23 , and the input shaft portion 32 of the screw shaft 30 is pivotally supported by the mounting body 23 via a bearing 24 .

A constriction part 27 is provided on the discharge side of the cylindrical accommodating part 20, and the constriction part 27 is covered with a stopper 70. The stopper 70 includes a stopper part 71 having a spherical surface that comes into contact with the opening of the constriction part 27, a support shaft part 72 to which the stopper part 71 is fixed, and a support tube 73 that supports the support shaft part 72. The support tube 73 is supported by a holder 74, and the holder 74 is attached to a support body 76 fixed to the constriction portion 27 with attachment bolts 75.

The stopper portion 71 is fixed to a receiving portion 72a of the support shaft portion 72, and a spring 78 constituting the biasing means 77 is arranged between the receiving portion 72a and the flange portion 73a of the support tube 73. The spring 78 biases the surface of the stopper portion 71 via the receiving portion 72a of the support shaft portion 72 so that the surface of the stopper portion 71 always comes into contact with the opening of the throttle portion 27. In this way, the stopper 70 is always urged in the closing direction by the urging means 77.

The screw shaft 30 is rotated by the drive of a motor 41 constituting the drive means 40, and due to the rotation of the screw shaft 30, the fine particles accommodated inside the cylindrical storage section 20 are moved by the screw 31 in the discharge direction (FIG. 13). (a)). These moving fine objects come into contact with the surface of the stopper part 71 (FIG. 13(b)), and further, the fine objects move due to the rotation of the screw shaft 30, and the fine objects push the stopper part 71, causing the aperture part 27 opens (FIG. 13(c)). The fine particles fall through the opening of the constriction section 27 and are collected into the collection container 61 (FIG. 13(d)).

In this way, when the fine particles accommodated inside the cylindrical accommodating part 20 are moved by the screw 31 in the discharge direction by the rotation of the screw shaft 30, are discharged from the cylindrical accommodating part 20, and are collected in the collection container 61, The liquid adhering to the fine particles is removed, and this liquid is collected into the storage tank 101 through the discharge hole 26.

[Configuration of form 2]
The fine particle removal device of this embodiment will be explained based on FIG. 14. FIG. 14 is a diagram showing a fine object removing device.

In this fine matter removing device 120, the same components as those of the first embodiment are given the same reference numerals, and the description thereof will be omitted. In this embodiment, a discharge tube 80 is connected to the discharge side of the cylindrical housing part 20, and the discharge tube 80 has a discharge opening 81 that opens upward from the cylindrical housing part 20. The structure is such that objects can be discharged from the discharge opening 81 of the discharge pipe 80.

This fine matter removal device 120 is not limited to the fine matter removal system of the embodiment described above, but may be a centrifugal separator that separates and precipitates fine matter contained in a liquid by centrifugal force, or a hopper that stores separated fine matter. The device is configured so that it can be connected to the device, and removes the liquid adhering to the fine particles and discharges the fine particles.

[Configuration of form 3]
The fine particle removal device of this embodiment will be explained based on FIG. 15. FIG. 15 is a diagram showing a fine object removing device.

This fine matter removal device 120 is connected to a centrifugal separator that separates and precipitates fine matter contained in a liquid by centrifugal force, or a hopper that collects the separated fine matter, and removes liquid adhering to the fine matter and finely deposits the fine matter. This is a device for discharging objects, and includes a horizontally arranged fine object removing section A and an obliquely arranged fine object removing section B.

The laterally arranged fine matter removal section A includes a screw shaft 200 that discharges the fine matter by rotation, and a drive means 201 that rotationally drives the screw shaft 200,
The configuration is such that fine particles are dropped directly onto the screw shaft 200 from an input section 202 connected to a centrifugal separator or a hopper.

The obliquely arranged fine object removal section B includes a cylindrical storage section 300 that accommodates fine objects to which liquid has adhered, and a screw shaft 301 that is arranged in the axial direction inside the cylindrical storage section 300 and discharges the fine objects by rotation. , and a drive means 302 for rotationally driving a screw shaft 301, and the fine particles fall from the opening 303 and are collected in the collection container 61.

By driving the horizontally disposed fines removing section A and driving the diagonally disposed fines removing section B, fines are directly transferred from the input section 202 to the screw shaft 200 of the horizontally disposed fines removing section A. When the fine particles fall, the rotation of the screw shaft 200 sends the fine particles from the horizontally arranged fine particle removing section A to the diagonally arranged fine particle removing section B.

In the obliquely disposed fine matter removing section B, the fine matter is lifted up by the rotational drive of the screw shaft 301, the liquid is removed, and the fine matter falls from the opening 303 and is collected in the collection container 61.

In this fine matter removing device 120, fine matters are constantly flowing through two screw shafts: a screw shaft 200 of the horizontally arranged fine matter removing section A and a screw shaft 200 of the horizontally disposed fine matter removing section A. As a result, fine particles can be discharged with a low load, and the motors constituting the drive means 201 and the drive means 302 can be downsized. Furthermore, even when stopped for a long period of time, a certain amount of water can be secured, making it possible to move with a minimum load. In addition, by constantly flowing even fine particles that tend to harden, it is possible to maintain water veins and prevent them from sticking inside to a minimum.

In the obliquely arranged fine matter removing section B, the screw shaft 301 can be adjusted to an arbitrary angle of 95 degrees to 180 degrees depending on the fine matter, for example, depending on the type of fine matter and the water content. Adjust the angle.

This fine matter removal device 120 is connected to a centrifugal separator that separates and precipitates fine matter contained in a liquid by centrifugal force, or a hopper that collects the separated fine matter, and removes liquid adhering to the fine matter and finely deposits the fine matter. This is a device for discharging objects, and the liquid adhering to the fine objects is removed and the fine objects are recovered by driving the horizontally arranged fine object removing section A and the obliquely arranged fine object removing section B.

[Configuration of form 4]
The fine matter removing device of this embodiment will be explained based on FIGS. 16 to 20. FIG. 16 is a front view of the fine matter removing device, FIG. 17 is a plan view of the fine matter removing device, FIG. 18 is a perspective view of the fine matter removing device, and FIG. 19 is a configuration in which the position of the discharge port can be changed. 20 are diagrams showing a configuration in which the angle can be varied using the center of the screw shaft as a fulcrum. In the configuration of the fourth embodiment, the same parts as those of the third embodiment are denoted by the same reference numerals, and the explanation thereof will be omitted.

The horizontally arranged fines removing section A and the diagonally arranged fines removing section B are provided. It is configured to be dropped. The input section 202 of the hopper is
It has an overflow cover 400, and by opening the overflow cover 400, the liquid that adheres to the separated fine particles and accumulates in the input part 202 of the hopper is discharged.

The obliquely arranged fine matter removal section B includes a fine matter discharge rail 410 that discharges the fine matter from which the liquid has been removed, and the fine matter discharge rail 410 has a configuration in which the position of the discharge port 411 can be changed. For example, the fine matter discharge rail 410 is rotatably provided with the connecting portion 412 on the cylindrical body of the obliquely arranged fine matter removal section B, and the position of the discharge port 411 is changed by rotating the fine matter discharge rail 410. By rotating the fine material discharge rail 410, the position of the discharge port 411 is positioned on the left side when viewed from the side in FIG. 19(a), and the position of the discharge port 411 is positioned on the right side when viewed from the side in FIG. 19(b). The position of the outlet 411 can be freely changed depending on the installation status of the equipment and device.

As shown in FIG. 20, the obliquely disposed fine matter removing section B has a structure in which the screw axis direction can vary the angle with the center of the screw shaft of the horizontally disposed fine matter removing section A as a fulcrum. For example, at the time of initial installation, the position of the obliquely arranged fine particle removing section B is taken into account, and the mounting angle of the obliquely arranged fine particle removing section B with respect to the horizontally disposed fine particle removing section A is determined, and bolts and nuts are set. It is tightened and fixed using a mounting means 500 such as the like. In addition, depending on circumstances such as subsequent changes to the equipment, the attachment means such as bolts and nuts may be removed and the mounting angle of the diagonally disposed fine particle removing section B relative to the horizontally disposed fine particle removing section A may be changed. - Tighten and fix with a mounting means 500 such as a nut. In this way, by changing the mounting angle of the obliquely disposed fines removing section B with respect to the laterally disposed fines removing section A, and changing the screw axis direction of the obliquely disposed fines removing section B, the removal can be achieved. The position of the exit 411 can be freely changed depending on the installation status of equipment and devices.

This invention can be applied to a fine particle removal device, which separates and removes fine particles contained in liquid by automatic operation, removes liquid adhering to fine particles, and collects fine particles, making it unmanned. enable driving.

10 Fine object removal system 20 Cylindrical storage part 21 Introduction opening 22 Introduction pipe 23 Mounting body 24 Bearing 27 Throttle part 30 Screw shaft 31 Screw 32 Input shaft part 40 Drive means 41 Motor 42 Output shaft 43 Connection member 70 Stopper 71 Stopper part 72 Support Shaft 73 Support tube 74 Holder 75 Mounting bolt 76 Support 77 Biasing means 78 Spring 80 Discharge tube 81 Discharge opening 100 Processing or processing device 101 Storage tank 102 Circulation path 103 Pump 110 Centrifugal separator 111 Sedimentation section 112 Fine substance amount Detection device 112a Ultrasonic sensor 112b Detection means 113 Control device 120 Fine object removal device 140 Introduction passage A Laterally arranged fine object removing section B Obliquely arranged fine object removing section

Claims (6)

A centrifugal separator that separates and precipitates the fine particles contained in a liquid using centrifugal force, or a fine particle removal device that connects to a sedimentation unit that collects the separated fine particles, removes the liquid that adheres to the fine particles, and discharges the fine particles. is a device,
a cylindrical storage section that stores fine objects to which liquid is attached;
a screw shaft that is disposed in the axial direction inside the cylindrical housing part and discharges the fine particles by rotation;
a driving means for rotationally driving the screw shaft,
removing the liquid adhering to the fine particles by rotating the screw shaft;
A fine matter removing device characterized in that the fine matter from which the liquid has been removed is discharged from the cylindrical storage portion. A constriction part is provided on the discharge side of the cylindrical storage part,
Covering the constriction part with a stopper,
Always biasing the stopper in the closing direction by a biasing means,
2. The device for removing fine particles according to claim 1, wherein the stopper is pushed by the fine particles discharged from the cylindrical accommodating portion, and the constriction portion can be opened and closed. Connecting a discharge cylinder to the discharge side of the cylindrical housing part,
The discharge tube has a discharge opening that opens upward from the cylindrical housing part,
The fine matter removing device according to claim 1, characterized in that the fine matter discharged from the cylindrical storage portion can be discharged from a discharge opening of the discharge tube. A centrifugal separator that separates and precipitates the fine particles contained in a liquid using centrifugal force, or a fine particle removal device that connects to a sedimentation unit that collects the separated fine particles, removes the liquid that adheres to the fine particles, and discharges the fine particles. is a device,
a screw shaft that discharges the fine particles by rotation;
a laterally disposed fine object removing section including a driving means for rotationally driving the screw shaft;
a cylindrical storage section that stores fine objects to which liquid is attached;
a screw shaft that is disposed in the axial direction inside the cylindrical housing part and discharges the fine particles by rotation;
a driving means for rotationally driving the screw shaft, and an obliquely arranged fine object removing section,
By driving the horizontally arranged fine object removing section and driving the obliquely arranged fine object removing section,
Sending fines from the horizontally arranged fines removing section to the obliquely arranged fines removing section,
A fine matter removing device, characterized in that the fine matter removing section removes liquid and discharges fine matter from the obliquely arranged fine matter removing section. The obliquely arranged fine matter removing section is
Equipped with a fine matter discharge rail that discharges fine matter from which liquid has been removed.
5. The fine matter removing device according to claim 4, wherein the fine matter discharge rail has a configuration in which the position of the discharge port can be changed. The screw axis direction of the obliquely arranged fine matter removing section is
6. The fine matter removing device according to claim 4, wherein the fine matter removing device is configured such that the angle of the horizontally arranged fine matter removing section can be varied using the center of the screw shaft as a fulcrum.