KR100965406B1 - Suspended solids transfer equipment type cam - Google Patents

Abstract

PURPOSE: A cam-type solid and fluid conveying apparatus is provided by discharging an object to an outlet to effectively convey the object to destination. CONSTITUTION: A cam-type solid and fluid conveying apparatus comprise a case(10), a rotor(20), a side panel(40), a rotor shaft(30), a cam follower(50), a power transfer unit(60), and a discharging unit. The case comprises a rotor hole(11), a feeder(13), an outlet(14), a step valve operating hole(12). A conveying protrusion(21) is formed on the outer circumference of the rotor. The conveying protrusion conveys the object supplied to the rotor hole from the feeder, to the outlet. The side panel closes both sides of the case. The rotor shaft passes through the center of the rotor and the side panel. The cam follower comprises the cam(51) installed at one side of the rotor shaft. The power transfer unit transfers the torque to the rotor shaft.

Description

Suspended solids transfer equipment type cam

The present invention relates to a cam-type solids and fluid transfer device for safely transporting dehydrated sludge, ie, solids and solids or various fluids (hereinafter referred to as "the corresponding objects") of solids and similar solids to the destination.

Each year, the amount of wastewater is increasing rapidly. As a result, the pollution problem of the surrounding environment is seriously raised, and accordingly, various technologies are being developed to effectively treat industrial wastewater.

In order to treat sludge contained in industrial wastewater, the wastewater is passed through a concentrator and a dehydrator, respectively, to solidify the sludge contained in the wastewater. Thereafter, the solidified sludge from which the water is removed is loaded into the waste storage box and then transferred to the waste transportation truck.

Conventionally, solidified sludge has been conveyed using a belt conveyor. That is, the solidified sludge conveying apparatus of the prior art collects the solidified sludges discharged from each of the plurality of dewatering machines listed, and loads the solidified sludge by the operation of the belt conveyor into the waste loading box.

However, the prior art solidified sludge conveying apparatus has to be installed on a high workbench or walkway in consideration of the height of the waste storage box and the installation height of the belt conveyor, which is a hassle to additionally install the workbench or workway. There was a feeling.

Therefore, there have been many efforts to solve this problem, and one of them is "Dewatered Sludge Transfer Device Using Air Pressure" of Korean Utility Model Registration No. 239939. Sludge conveying apparatus 100 using such air pressure is shown in Figure 1, the configuration is as follows.

The sludge conveying apparatus 100 using the pneumatic pressure is a hopper 110 into which the sludge is injected, a valve 120 opened and closed by the operation of the air cylinder, a valve 120 is installed at the top, the outlet 130 at the bottom ) Is installed, the main body 150 having a sludge temporary accommodation unit 140 of a predetermined space therein, and the air injection pipe 160 connected to the main body 150 to inject air into the main body 150. It is composed of

The sludge conveying apparatus 100 using the conventional air pressure having the configuration as described above, when a predetermined amount of solidified sludge is input to the sludge temporary accommodation unit 140, by discharging the air of high pressure through the air injection pipe 160, The solidified sludge is transferred to the desired waste load bin.

However, since the sludge conveying apparatus 100 of the prior art transfers sludge to instantaneous high pressure air, instantaneous excessive pressure is transmitted to the conveying line, so that the pipe connection portion of the conveying line is easily damaged. In addition, the sludge conveying apparatus 100 of the prior art has a problem that the workability during the leakage of air is significantly reduced, it is necessary to seal the conveying line tightly, otherwise the sludge conveying efficiency is sharply lowered.

The present invention has been invented to solve the above problems, the object of which is that the solid or various fluids (hereinafter referred to as the "applicable object") of the dehydrated sludge, that is, the solids and the particulates similar to the solids is not flowed back to the supply portion It is to provide a cam-type solids and fluid transfer device that is discharged to the discharge portion to be safely transported to the destination.

Characteristic technical features of the present invention for achieving the above object, a circular rotor hole 11 is formed so that both sides are in communication with each other, each side 13 and the other side of each supply unit 13 and the communication with the rotor hole and A discharge part 14 is formed and a case 10 formed by forming a step valve operation hole 12 in an upper portion of the rotor hole; A rotor 20 having an outer diameter smaller than the inner diameter of the rotor hole and having a transfer protrusion 21 for transferring a corresponding object supplied to the rotor hole from the supply portion to the discharge portion on an outer circumferential surface thereof; Respective side panels 40 installed to seal both sides of the case; And a rotor shaft 30 installed through the center and the side panel of the rotor. A cam follower 50 provided with a cam 51 on one side of the rotor shaft so as to be located at the side panel side of the one side; A power transmission unit 60 connected to the rotor shaft to transmit rotational force to the rotor shaft; The step valve operation hole is formed in conjunction with the cam is composed of a discharge means 70 for discharging the corresponding object supplied from the supply to the discharge.

In addition, the discharge means 70 is provided with a shaft 71 penetrating the step valve operation hole, one side of the shaft is provided with a step valve 72 to prevent the reverse flow of the object by contacting the outer peripheral surface of the rotor On the other side of the shaft, a cam rod 73 for interlocking with the operation of the cam to operate the step valve is installed.

In addition, the step valve 72 is installed at the end of the sleeve (72a) and the extension portion (72b) extending a predetermined length from the sleeve coupled to one side of the shaft and the extension portion is formed in the shape of the letter "a" to the outer peripheral surface of the rotor Composed of a scraper 72c in contact with the cam rod 73, the cam rod 73 is installed at the end of the sleeve 73a coupled to the other side of the shaft, the extension portion 73b extending a predetermined length from the sleeve and the tip of the extension portion. It consists of the roller 73c rotated in contact with the outer peripheral surface of a cam.

In addition, a sealing member 41 is further installed between each side panel and both sides of the case, and the power transmission means 60 is a chain sprocket for transmitting the power of the power generating unit to the rotor shaft, and the transfer protrusion ( 21 are respectively formed on both sides in the diagonal direction of the rotor, the cam follower 50 is formed in such a way that the cam 51 having a protrusion 52 formed in the diagonal direction at the center thereof is interlocked with the power transmission means 60. Guide grooves 53 are formed between the outer circumferential surface of the cam and the inner circumferential surface of the cam follower 50.

The cam-type solids and the fluid transfer device according to the present invention having the configuration as described above has a peculiar effect of safely and effectively transporting the object to the destination by allowing all of the object to be discharged to the discharge part without being flowed back to the supply part.

1 is a cross-sectional view of a conventional sludge feeder;
Figure 2 is a perspective view of the cam type solids and fluid transfer device according to the present invention,
Figure 3 is an exploded perspective view of a cam-type solids and fluid transfer device according to the present invention,
Figure 4 is a cross-sectional view of the cam-type solids and fluid transfer device combined according to the present invention;
Figures 5a and 5b is a side view showing the cam and the position of the rotor and the initial state of the cam-type solids and fluid transfer device in accordance with the present invention,
Figure 6a and Figure 6b is a side view representing the position of the cam and the rotor showing the action of the cam-type solid state and the fluid transfer device in accordance with the present invention,
Figures 7a and 7b is a side view showing the position of the cam and the rotor to the end of the cam-type solid state and fluid transfer device action according to the present invention.

Cam type solids and fluid transfer device according to the present invention is to dehydrate the water from the sludge dewatering device and to transfer the sludge or similar solids and fluid of the dehydrated solids to the destination, the configuration is shown in Figs. As shown in the circular rotor hole 11 is formed so that both sides are in communication with each other, each of the supply portion 13 and the discharge portion 14 is formed in communication with the rotor hole 11 on one side and the other side is In addition, the upper part of the rotor hole 11 is provided with a case 10 formed by forming a step valve operation hole 12 connected to the rotor hole 11.

The rotor hole 11 has an outer diameter smaller than the inner diameter of the rotor hole 11 and transfers the corresponding object supplied from the supply part 13 to the rotor hole 11 on the outer circumferential surface to the discharge part 14. The rotor 20 formed by forming the transfer projection 21 to be seated. At this time, the reason for making the outer diameter of the rotor 20 smaller than the inner diameter of the rotor hole 11 is that a predetermined space is formed between the outer diameter of the rotor 20 and the inner diameter of the rotor hole 11 so that the corresponding object is transferred. For sake.

In addition, both side surfaces of the case 10 are provided with respective side panels 40 for sealing both sides of the case 10, the center of the rotor 20 and the side panel 40 is the rotor shaft 30 ) Penetrates and is installed. Meanwhile, the rotor 20 and the rotor shaft 30 are fixed by using a key coupling or a fixing member to rotate integrally without idling.

In addition, a cam follower 50 having a cam 51 formed on one side of the rotor shaft 30 so as to be located at the side panel 40 on one side is installed to rotate together with the rotor shaft 30, and the cam follower Between the 50 and the side panel 40, a power transmission means 60 is installed to receive power from the power generating means (motor or engine) and transmit power to the rotor shaft 30. However, the power transmission means 60 may be a motor, and the motor may be directly installed at one end of the rotor shaft 30.

In addition, the step valve operation hole 12 is installed in conjunction with the cam 51 is provided with a discharge means 70 for discharging the corresponding object supplied from the supply unit 13 to the discharge unit (14).

On the other hand, in the above configuration, the discharge means 70 is provided with a shaft 71 penetrating the step valve operation hole 12, one end of the shaft is in contact with the outer peripheral surface of the rotor 20 to prevent the reverse flow of the object The step valve 72 is installed, and the other side of the shaft 71 is provided with a cam rod 73 for operating the step valve 72 while interlocking with the operation of the cam 51.

The step valve 72 has a sleeve 72a fitted to one side of the shaft 71, an extension portion 72b extending a predetermined length from the sleeve, and a letter “A” at the tip of the extension portion 72b. And a scraper 72c installed in contact with the outer circumferential surface of the rotor 20, wherein the cam rod 73 is fitted between the sleeve 73a and the sleeve 73a which are fitted to the other side of the shaft 71. It is composed of an extension portion 73b extending a predetermined length and a roller 73c which is installed at the tip of the extension portion 73b and smoothly rotates in contact with the outer circumferential surface of the cam 51.

In addition, a sealing member 41 is further installed between each side panel 40 and both sides of the case 10, and the power transmission means 60 transmits the power of the power generating unit to the rotor shaft 30. It is a chain sprocket, the conveying projections 21 are formed on both sides in the diagonal direction of the rotor 20, respectively, the cam follower 50 has a cam 51 formed with a projection 52 in the diagonal direction in the center is formed Guide grooves 53 are formed on the outer circumferential surface of the cam 51.

The step valve 72 and the cam rod 73 installed on the shaft 71 which is the discharge means 70 are coupled by using a key coupling or coupling member so as to move integrally with the shaft 71.

Embodiments of the cam type solids and the fluid transfer device according to the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings 5a to 7b.

When the power of the power generating unit (not shown) made of an engine or a motor is transferred to the chain sprocket which is the power transmission means 60 by using a chain or other power transmission member (not shown), the rotor shaft 30 The rotor 20, the cam follower 50, and the power transmission means 60, which are rotated and installed at the same time as the rotor shaft 30, are rotated together. At this time, the discharge means 70 is also interlocked with the cam 51 formed on the cam follower 50.

As the rotor shaft 30 is rotated as described above, the rotor 20, the cam follower 50, the power transmission means 60 are rotated, and the discharge means 70 is interlocked. Moisture is dehydrated from h), and the corresponding object of the generated solid is supplied to the supply part 13 as shown in Fig. 5B.

When the object is supplied to the supply unit 13 as described above, the object is supplied is supplied to the space between the outer diameter of the rotor 20 and the inner diameter of the rotor hole 11, the supplied object is rotated in Figure 5b The transfer protrusion 21 formed on the outer circumferential surface of the rotor 20 transfers the corresponding object in the space toward the discharge portion 14.

At this time, the roller 73c installed at the tip of the extension portion 73b of the cam rod 73, which is the discharge means 70, is placed in the guide groove 53, as shown in Fig. 5A. The scraper 72c interlocked with each other and provided at the tip of the step valve 72 is in intimate contact with the outer circumferential surface of the rotor 20 as shown in FIG. 5B. It is to be discharged all to the discharge unit 14 while preventing the back flow to the supply unit (13).

The above operation is continuously performed while the rotor shaft 30 is rotated as shown in Figs. 6A and 6B, and as shown in Fig. 7A, the roller 73c is provided with the protrusions of the cam 51. 52, the roller 73c is raised to the same height as the protrusion 52, and the extension 73b and the sleeve 73a are rotated. As a result, the shaft 71 rotates so that the step valve The scraper 72c of 72 is lifted, and it is raised to the upper part of the conveyance protrusion 21 of the rotor 20. As shown in FIG.

Therefore, the scraper 72c of the step valve 72 discharges all of the scraper 72c to the discharge part 14 while preventing the object from flowing back through the discharge part 14 to the supply part 13 while avoiding collision with the transfer protrusion 21. It is to be made.

Meanwhile, the height of the protrusion 52 of the cam 51 and the height of the feed protrusion 21 of the rotor 20 are the same, or the height of the protrusion 52 of the cam 51 is higher than the height of the feed protrusion 21 of the rotor 20. By being formed high, the collision between the scraper 72c and the transfer protrusion 21 can be avoided.

When the above method is continuously repeated, the corresponding object supplied to the supply unit 13 is smoothly discharged to the discharge unit 14.

However, each side panel 40 installed to seal both sides of the case 10 serves to form a space between the outer diameter of the rotor 20 and the inner diameter of the rotor hole 11 and at the same time the rotor 20. As it rotates to generate a suction force in the direction of rotation serves to increase the transfer effect of the object.

In addition, a sealing member 41 is further installed between each side panel 40 and both side surfaces of the case 10. The reason for installing the sealing member 41 is that the side panel (by friction with the corresponding object) When the inner surface of 40 is worn out, the side panel 40 needs to be replaced. At this time, since the side panel 40 is expensive, the sealing member 41 is worn when the sealing member 41 is worn through the sealing member 41. Only for easy exchange and use.

In the cam-type solids and fluid transfer device according to the present invention as described above, the number of the projections 52 formed on the cam 51 and the number of the transfer projections 21 formed on the rotor 20 should be the same and the position thereof will be the same. It is preferable to. This is because the step valve 72 and the cam rod 73 must operate in the same way.

As shown in FIG. 4, the bearings and the O-rings are installed between the components installed on the rotor shaft 30 and the shaft 71. The descriptions of the bearings and the O-rings, as well as the technical field, It is the most basic and general in the mechanical field, and a detailed description thereof is omitted.

In addition, the flange (15.16.42.43.61.74) for installing each component is provided to secure the rotor shaft 30 and the shaft 71, as well as to secure the coupling between the components.

The present invention as described above has the advantage that the object can be safely and effectively transported to the destination by allowing all of the object to be discharged to the discharge rather than backflow to the supply.

* Description of Signs of Main Parts of Drawings *
10 case 11 rotor hole
12: step valve operating hole 13: supply
15: outlet 20: rotor
21: feed projection 30: rotor shaft
40 side panel 41 sealing member
50: Cam Follower 51: Cam
52: protrusion 53: guide groove
60: power transmission means 70: discharge means
71: axis 72: step valve
72a: sleeve 72b: extension
72c; Scraper 73: Cam Rod
73a: sleeve 73b: extension
73c: roller

Claims (8)

Circular rotor holes 11 are formed to communicate with both sides, and one side and the other side are formed with respective supply portions 13 and discharge portions 14 communicating with the rotor holes, and a step above the rotor holes. A case 10 formed by forming a valve operation hole 12;
A rotor 20 having an outer diameter smaller than the inner diameter of the rotor hole and having a transfer protrusion 21 for transferring a corresponding object supplied to the rotor hole from the supply portion to the discharge portion on an outer circumferential surface thereof;
Respective side panels 40 installed to seal both sides of the case; And a rotor shaft 30 installed through the center and the side panel of the rotor.
A cam follower 50 provided with a cam 51 on one side of the rotor shaft so as to be located at the side panel side of the one side;
A power transmission unit 60 connected to the rotor shaft to transmit rotational force to the rotor shaft;
The step valve operation hole is installed in cooperation with the cam solid material and fluid transfer device of the cam type, characterized in that composed of a discharge means for discharging the corresponding object supplied from the supply to the discharge portion (70). The step valve of claim 1, wherein the discharge means (70) is provided with a shaft (71) penetrating through the step valve operation hole, and at one side of the shaft, a tip valve is in contact with the outer circumferential surface of the rotor to prevent reverse flow of the object. (72) is installed, the cam-type solids and fluid transfer device, characterized in that the cam rod (73) for operating the step valve while interlocking with the operation of the cam is installed on the other side of the shaft. The method according to claim 2, wherein the step valve 72 is installed in the shape of the "72" at the tip of the sleeve 72a and the extension portion 72b extending a predetermined length from the sleeve and coupled to one side of the shaft and the extension portion; Cam-type solids and fluid transfer device, characterized in that consisting of a scraper (72c) in contact with the outer peripheral surface of the rotor. The cam rod 73 is installed at the tip of the sleeve 73a which is fitted to the other side of the shaft, the extension portion 73b extending a predetermined length from the sleeve, and the extension portion to contact the outer peripheral surface of the cam. Cam-type solids and fluid transfer device, characterized in that consisting of a roller (73c) is rotated in the state. The cam-type solids and fluid transfer device of claim 1, wherein a sealing member is further provided between each side panel and both sides of the case. The cam-type solids and fluid transfer device of claim 1, wherein the power transmission means (60) is a chain sprocket for transmitting the power of the power generating unit to the rotor shaft. The cam-shaped solid and fluid transfer device of claim 1, wherein the transfer protrusions are formed on both sides in a diagonal direction of the rotor. The cam follower 50 of claim 1 or 6, wherein a cam 51 having a protrusion 52 formed in a diagonal direction at the center thereof is formed to interlock with a power transmission means 60, and an outer circumferential surface of the cam and the cam. Cam-shaped solid and fluid transfer device, characterized in that the guide groove 53 is formed between the inner peripheral surface of the follower (50).

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