KR102256835B1 - Pneumatic conveyor - Google Patents

Abstract

The present invention is to provide a technology that can easily and accurately check whether a sticking phenomenon of an object to be transported has occurred on an inner surface of a sealed container at any time without disassembling the sealed container. According to the present invention, provided is a pneumatic conveyor comprising: a valve housing provided to be opened and closed by a valve; a sealed container accommodating therein an object to be transported falling from the open valve housing, and having an upper end detachably coupled to the valve housing and a lower end detachably coupled to a transfer pipe; a compressed air supply pipe provided to supply compressed air to pressurize the transported object toward the transfer pipe into the sealed container after closing the valve housing; and an inspection hole which is formed in the sealed container to communicate the inside and outside of the sealed container, and is opened and closed by a removable stopper, and to which an inspection device for checking whether the object to be transported adheres to an inner surface of the sealed container can be fastened after the stopper is removed.

Description

Pneumatic conveyor{PNEUMATIC CONVEYOR}

The present invention relates to a pneumatic conveyor, and more particularly, to a pneumatic conveyor for conveying an object to be conveyed such as sludge, sludge cake (dehydrated sludge) by pneumatic pressure.

Sewage thrown away from homes or factories is sent to a sewage treatment plant and then treated, and sludge generated during this treatment is treated through reduction processes such as concentration and dewatering. In the sludge reduction process, a screw conveyor, a belt conveyor, a pneumatic conveyor, and the like are used as devices for transporting objects to be conveyed such as sludge or sludge cake (dehydrated sludge).

The pneumatic conveyor generally includes a closed container. The valve housing is coupled to the upper end of the sealed container, the hopper into which the object to be transported is input is coupled to the upper end of the valve housing, and a transfer pipe extending to the destination is coupled to the lower end of the sealed container. In the valve housing, a dome-shaped valve is provided to be operated by a pneumatic cylinder. When the dome-shaped valve opens the valve housing, the object to be conveyed into the hopper can fall through the valve housing into the inner space of the sealed container, and when closed, the object to be conveyed into the hopper cannot fall into the valve housing. The object to be transported inside the sealed container is pushed by the compressed air supplied from the compressed air supply pipe connected to the side of the sealed container and transferred to the destination along the transport pipe.

Registered Patent Publication No. 10-0823999 (a waste conveying device using pneumatic pressure), Registered Patent Publication No. 10-1671849 (a sealing device of a pneumatic conveyor), Registered Patent Publication No. 10-1282723 (a pneumatic conveyor for conveying impurities), registered Utility Model Publication No. 20-0351162 (a waste conveying device using pneumatic and hydraulic pressure) discloses a pneumatic conveyor as described above.

Registered Patent Publication No. 10-0823999 (waste transfer device using pneumatic pressure) Registered Patent Publication No. 10-1671849 (sealing device for pneumatic conveyor) Registered Patent Publication No. 10-1282723 (Pneumatic conveyor for transporting impurities) Registered Utility Model Publication No. 20-0351162 (waste transfer device using pneumatic and water pressure)

The airtight container of the pneumatic conveyor has a structure consisting of three parts separably coupled to each other as disclosed in Registration Patent Publication No. 10-0823999, or can be separated from each other as disclosed in Registration Patent Publication No. 10-1282723. It has a structure consisting of two parts joined together.

In addition, if the transport of the transported object is repeated, the transported object is fixed to the inner surface of the airtight container regardless of the structure of the air-tight container of the pneumatic conveyor. The inner space of the sealed container becomes narrow due to water, and in severe cases, it may reach a state in which transport of the object to be transported cannot be performed.

Therefore, in the pneumatic conveyor, it is necessary to check whether the sticking phenomenon of the conveyed object has occurred on the inner surface of the sealed container, and to periodically clean the inner surface of the sealed container.In the conventional pneumatic conveyor introduced above, in order to check the sticking phenomenon of the conveyed object. There must be a hassle of separating the three or two parts of the airtight container.

In the above registered Utility Model Publication No. 20-0351162, a pressure gauge and a strain gauge that senses the internal pressure of the sealed container confirms the sticking of the transported object, but the internal pressure of the sealed container confirms the sticking of the transported object. It is difficult to apply to actual products because the accuracy is not only very low, but also causes damage of the strain gauge exposed to the high pressure environment formed in the inner space of the sealed container.

Accordingly, an object of the present invention is to provide a technology that can easily and accurately check whether or not an object to be adhered to the inner surface of an airtight container has occurred without disassembling the airtight container.

The present invention, a valve housing provided to be opened and closed by a valve; An airtight container having an upper end detachably coupled to the valve housing and a lower end detachably coupled to the transfer pipe, receiving the object to be transported falling from the opened valve housing therein; A compressed air supply pipe provided to supply compressed air to pressurize the transported object toward the transport pipe to the inside of the sealed container after the valve housing is closed; And a checker for checking whether the object is fixed to the inner surface of the sealed container after being formed in the sealed container so as to communicate the inside and outside of the sealed container, opened and closed by a removable stopper, and after the stopper is separated It provides a pneumatic conveyor including; an inspection hole that can be fastened.

The inspection device includes a main body positioned outside the sealed container, an insertion part provided to extend from the main body and inserted into the inspection hole, and a hollow formed in the insertion part to expose the interior of the sealed container to the main body. Equipped inspection jig; And a distance measuring device for measuring a distance to a measuring point, which is an inner point of the sealed container located in a straight line with the hollow, while being fastened to the main body of the inspection jig.

The stopper is screwed into the inspection hole. And the insertion part is inserted into the inspection hole in a screwed manner. Alternatively, the insertion portion may be inserted in a manner that is pushed into the inspection hole. In this case, when the insertion portion is completely inserted into the inspection hole, the body is provided so as to contact the outer surface of the sealed container. A laser range finder may be used as the range finder.

The sealed container includes an upper portion having an upper end detachably coupled to the valve housing; And an upper portion detachably coupled to a lower end of the upper portion and a lower portion detachably coupled to the transfer pipe, and a lower portion provided with the inspection hole. In addition, the upper portion is provided in the form of an open upper narrow beam having a diameter gradually increasing from the upper end to the lower end.

The lower portion may include an upper portion coupling portion having an upper portion detachably coupled to a lower portion of the upper portion; And a transfer pipe coupling portion provided in an elbow shape having an upper end detachably coupled to a lower end of the upper portion coupling portion and a lower end detachably coupled to the transport pipe. In this case, the upper portion coupling portion is provided in an upper optical lower narrow shape having a diameter that gradually decreases as it goes from the top to the lower end. And, of the two sides of the upper part coupling part facing each other in the longitudinal section, the side located at the lower end of the transfer pipe coupling part is formed to have a steeper inclination than the other side.

According to the present invention, since the inspection work to check whether the object to be transported is fixed to the inner surface of the sealed container can be confirmed through an inspection device fastened to the inspection hole, the above inspection work can be easily performed at any time without disassembling the sealed container.

In addition, according to the present invention, since the relative position of the inspector with respect to the outer surface of the sealed container is the same for each inspection operation, the inspection operation can be accurately performed.

In addition, according to the present invention, no bridging phenomenon occurs anywhere in the upper and lower sections of the upper portion constituting the sealed container.

In addition, according to the present invention, when the upper part coupling part constituting the lower part is combined with the upper part, the circumferential coupling position of the upper part coupling part can be accurately identified only with the naked eye of the operator, and yet it is discharged from the upper part coupling part. It is possible to minimize the decrease in the discharge speed of the object to be transported.

1 shows a pneumatic conveyor according to the present invention.
FIG. 2 is an enlarged view of the transfer pipe coupling portion of FIG. 1.
3 is an exploded perspective view of an inspection device for fastening to the inspection hole of FIG. 2.
4 is a diagram illustrating a state of use of the inspection device shown in FIG. 3.

Hereinafter, preferred embodiments of the pneumatic conveyor according to the present invention will be described in detail with reference to the drawings. The terms or words used below should not be interpreted as being limited to their usual or dictionary meanings, and based on the principle that the inventor can appropriately define the concept of terms in order to explain his or her invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

The pneumatic conveyor 100 according to the present invention is a device used to convey an object to be conveyed such as sludge or sludge cake (dehydrated sludge) by pneumatic pressure, and as shown in FIG. 1, the valve housing 110 and the sealed It includes a container 120, a compressed air supply pipe 130, and an inspection hole 140.

The valve housing 110 has a hollow cylindrical shape and includes a dome-shaped valve 112 that opens or closes the valve housing 110 while being rotated by a pneumatic cylinder 114. In addition, a hopper 116 is detachably coupled to an upper end of the valve housing 110. If the valve 112 is in a state where the valve housing 110 is open, the object to be transported into the hopper 116 passes through the valve housing 110 and falls downward, and if it is closed, the object to be transported into the hopper 116 is transported. Water cannot pass through the valve housing 110.

The upper end of the sealed container 120 is detachably coupled to the lower end of the valve housing 110, and the lower end of the sealed container 120 is detachably coupled to a transfer pipe (not shown) extending to the transfer destination. . The sealed container 120 accommodates the object to be transported falling from the open valve housing 110 therein.

The compressed air supply pipe 130 extends from the outside of the sealed container 120 to the inside of the sealed container 120 through the side of the sealed container 120. When the compressed air is supplied to the inside of the sealed container 120 through the compressed air supply pipe 130 while the valve 112 is closed the valve housing 110, the object to be transported filled in the sealed container 120 is compressed air. It is pressurized toward the transfer pipe by means of the transfer pipe and is transferred to the destination along the transfer pipe.

The inspection hole 140 is a hole formed in the sealed container 120 to communicate the inside and the outside of the sealed container 120. Since the inspection hole 140 is normally closed by the stopper 142, the transported object filled in the airtight container 120 cannot pass through the inspection hole 140. And so that the stopper 142 is not separated even in a high-pressure environment repeatedly formed inside the sealed container 120, the stopper 142 is fastened to the inspection hole 140 in a screwing manner.

It is good that the inner end of the stopper 140 exposed to the inside of the sealed container 120 does not form a step with respect to the inner surface of the sealed container 120 while the above stopper 140 is completely fastened to the inspection hole 140. , This leads to a phenomenon in which the object to be transferred is caught in the inspection hole 140 and adhered to the inner surface of the sealed container 120 when the inner end of the stopper 140 is inserted into the inspection hole 140. This is because it is easy to pick up, and if the inner end of the stopper 140 has a step in the form of protruding from the inspection hole 140, the object to be transported is caught on the inner end of the stopper 140 and is also on the inner surface of the sealed container 120. This is because it is easy to lead to a sticking phenomenon.

Unlike usual, during inspection, the stopper 142 is separated and the inspection hole 140 is opened. In addition, an inspection device 150 for checking whether the object to be transported is fixed to the inner surface of the sealed container 120 is fastened to the opened inspection hole 140. When the inspection is finished, the inspection device 150 is separated and the stopper 142 is fastened to the inspection hole 140 again.

The inspection device 150 includes an inspection jig 150a and a distance measuring device 150b as shown in FIG. 3.

The inspection jig 150a includes a body 154 and an insertion portion 152. The body 154 is a portion located outside the sealed container 120 during inspection. The insertion portion 152 is a portion extending forward from the front surface of the main body 154 and is inserted into the inspection hole 140 during inspection. The insertion portion 152 is formed with a hollow 153 penetrating in the longitudinal direction. Therefore, when the inspection jig 150a is fastened to the inspection hole 140, the interior of the sealed container 120 is exposed to the main body 154 of the inspection jig 150a due to the hollow 153.

The distance meter 150b may be attached to and detached from the main body 154 of the inspection jig 150a, and is provided to measure the distance to the measurement point P. The measuring point P is an inner point of the sealed container 120 located in a straight line with the hollow 153 of the insertion part 152.

A laser distance meter may be used as the distance meter 150b. In this case, the distance meter 150b receives the reflected laser (L) after being irradiated to the measurement point (P) and returns to measure the distance to the measurement point (P), while the laser (L) is inserted. It passes through the hollow 153 of the portion 152. In addition, the distance measurer 150b visually displays the measured distance on the display 155. The distance meter 150b is also provided with a button unit 156 such as an on/off button and a measurement start/end button.

If the object to be transported is fixed to the measurement point (P), the measurement distance displayed on the display 155 will be smaller than the initial value, and if the object to be transported is not fixed to the measurement point (P), it is displayed on the display 155. The measurement distance will be the same as the initial value. Here, the initial value is a measured distance previously measured in a state in which the object to be transferred is not fixed to the measurement point P, and is a value known in advance to the operator. Therefore, by comparing the measured distance displayed on the display 155 and the initial value, the operator can know whether the object to be transported is fixed to the measuring point (P), and if he knows that the object to be transported is fixed to the measuring point (P), it is sealed. It is determined that the object to be transported is fixed to the inner surface of the container 120.

The insertion part 152 may be provided to be inserted into the inspection hole 140 in a screwing manner (not shown). In this case, by inserting the insertion part 152 into the inspection hole 140 until the screwing is completely completed, the distance between the distance measuring device 150b and the outer surface of the sealed container 120 can be kept the same at every inspection, so the measurement In measuring the distance to the point P, an error that may occur due to the separation distance of the distance measuring device 150b with respect to the outer surface of the sealed container 120 may be changed at each inspection can be eliminated. When the above screwing is completed, the body 150a may be spaced apart from the outer surface of the sealed container 120.

Unlike the above, the insertion part 152 may be inserted into the inspection hole 140 by simply pushing in without screwing. In this case, the front edge of the main body 154 is formed in a shape corresponding to the shape of the outer surface of the sealed container 120 around the inspection hole 140 as shown in FIG. When fully inserted into 140, the body 154 is brought into contact with the outer surface of the sealed container 120. Even in this case, the insertion method of the insertion part 152 may eliminate the error since the distance between the distance measuring device 150b and the outer surface of the sealed container 120 becomes the same at every inspection.

On the other hand, the sealed container 120 may be composed of an upper portion 122 and a lower portion 124. The upper end of the upper portion 122 is detachably coupled to the lower end of the valve housing 110. In addition, the upper portion 122 is provided in the form of an upper narrow beam that has a diameter that gradually increases from the top to the bottom. Therefore, referring to the longitudinal cross-sectional view of FIG. 1, the upper part 122 has the same absolute value of the inclination of both hypotenuses and the lower side has a trapezoidal shape longer than the upper side. When the upper part 122 is provided in this form, a bridging phenomenon in any of the entire section from the upper part to the lower part of the upper part 122 (the transported object is piled up as if it is over a bridge, preventing the transport of the transported object) Phenomenon) does not occur.

The lower portion 124 has an upper end detachably coupled to a lower end of the upper portion 122, and has a lower end detachably coupled to a transfer pipe (not shown). The sticking phenomenon of the object to be transported occurs more frequently in the lower part 124 than in the upper part 122, and the inspection hole 140 is preferably provided in the lower part 124.

The lower portion 124 may include an upper portion coupling portion 124a and an elbow-shaped transfer pipe coupling portion 124b. In this case, the upper end of the upper portion coupling portion 124a is detachably coupled to the lower end of the upper portion 122. And the upper end of the transfer pipe coupling portion 124b is detachably coupled to the lower end of the upper portion coupling portion 124a, and the lower end of the transport pipe coupling portion 124b is detachably coupled to the transport pipe.

The upper upper part coupling part (124a) is provided in the form of a situation that narrows while having a diameter that gradually decreases from the top to the bottom, and the right hypotenuse has a steeper inclination than the left hypotenuse when based on the longitudinal cross-sectional view of FIG. 1. It is formed to have. In addition, the elbow-shaped transfer pipe coupling portion 124b is bent toward the right hypotenuse, has a diameter that gradually decreases as it goes from the top to the bent portion, and maintains the same diameter in the section extending horizontally from the bent portion to the bottom. In the connection portion between the upper portion coupling portion 124a and the transfer pipe coupling portion 124b, the inner surfaces are smoothly connected without a step.

The reason why the inclination of the right hypotenuse is formed more rapidly than the inclination of the left hypotenuse in the upper part coupling part 124a is by making the operator visually recognize that the right hypotenuse is a part to be located on the side of the transfer pipe, so that the upper part This is to enable the circumferential coupling position of the upper portion coupling portion 124a with respect to 122 to be accurately grasped only with the naked eye.

In addition, the reason why the right hypotenuse is not vertically erected but inclined in the upper portion coupling portion 124a is that the lower diameter of the upper portion coupling portion 124a is formed to be narrower than that of the vertically erected, upper portion coupling portion This is to further increase the discharge speed of the object to be transferred discharged from the lower end of (124a).

Meanwhile, in FIG. 1, one inspection hole 140 is shown to be formed only at the bending portion of the transfer pipe coupling portion 124b, but the inspection hole 140 may be formed in another portion of the transfer pipe coupling portion 124b. , Two or more may be formed in the transfer pipe coupling portion 142b, may be formed in the upper portion coupling portion 124a, or may be formed in both the upper portion coupling portion 124a and the transfer pipe coupling portion 124b.

In addition, FIG. 1 shows an example consisting of an upper portion coupling portion 124a and a transfer pipe coupling portion 124b in which the lower portion 124 is detachably coupled to each other, but the lower portion 124 is an upper portion coupling portion 124a. ) And the transfer pipe coupling portion (124b) may be configured as a body integrally.

As described above, although the present invention has been described by the limited embodiments and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following by those of ordinary skill in the art to which the present invention pertains. It goes without saying that various modifications and variations may be made within the equivalent range of the claims to be described, and the above-described embodiments may be variously combined.

100: pneumatic conveyor 110: valve housing
112 valve 114 pneumatic cylinder
116: hopper 120: airtight container
122: upper portion 124: lower portion
124a: upper part coupling part 124b: transfer pipe coupling part
130: compressed air supply pipe 140: inspection hole
142: stopper 150: checker
150a: inspection jig 150b: distance meter
152: insertion part 154: body
155: display 156: button portion

Claims (7)

A valve housing provided to be opened and closed by a valve;
An airtight container having an upper end detachably coupled to the valve housing and a lower end detachably coupled to the transfer pipe, receiving the object to be transported falling from the opened valve housing therein;
A compressed air supply pipe provided to supply compressed air to pressurize the conveyed object toward the conveying pipe into the inside of the sealed container after the valve housing is closed; And
It is formed in the sealed container to communicate the inside and outside of the sealed container, is opened and closed by a removable stopper, and after the stopper is separated, a checker for checking whether the transported object is fixed to the inner surface of the sealed container Including; an inspection hole that can be fastened,
The checker,
An inspection jig having a main body located outside the sealed container, an insertion part provided to extend from the main body and inserted into the inspection hole, and a hollow formed in the insertion part to expose the inside of the sealed container to the main body ; And
A pneumatic conveyor comprising a; a distance measuring device for measuring the distance to the measuring point, which is an inner point of the sealed container located in a straight line with the hollow, while being fastened to the main body of the inspection jig. delete The method of claim 1,
The stopper is screwed into the inspection hole, and the inserting portion is inserted into the inspection hole in a screw connection manner. The method of claim 1,
The stopper is screwed with the inspection hole, the insertion portion is inserted in a manner that is pushed into the inspection hole, and when the insertion portion is completely inserted into the inspection hole, the main body abuts the outer surface of the sealed container. The method of claim 1,
The pneumatic conveyor used as the distance finder laser distance meter. The method of claim 1,
The sealed container,
An upper portion having an upper end detachably coupled to the valve housing; And
Consisting of; a lower portion having an upper portion detachably coupled to a lower end of the upper portion and a lower portion detachably coupled to the transfer pipe, and having the inspection hole,
The upper part is a pneumatic conveyor provided in the form of an upper narrow beam with a diameter gradually increasing from the upper end to the lower end. The method of claim 6,
The lower part,
An upper portion coupling portion having an upper end detachably coupled to a lower end of the upper portion; And
Includes; a transfer pipe coupling portion provided in the form of an elbow having an upper end detachably coupled to a lower end of the upper portion coupling portion and a lower end detachably coupled to the transport pipe,
The upper portion coupling portion is provided in a shape of an upper optical lower hyeop narrowing while having a diameter gradually decreasing from the upper end to the lower end,
Of the two sides of the upper part coupling part facing each other in the longitudinal section, the side located at the lower end of the transfer pipe coupling part has a steeper inclination than the other side.

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