KR200432174Y1 - Sludge movement apparatus - Google Patents

Abstract

According to the present invention, two pumping means are installed in parallel, and the other side is discharged while the discharge is made on the other side, so that the sludge can be transported continuously, and the hydraulic load remaining during operation in the hydraulic generator of the pumping means is filled in one place and then the transfer load is When it is caught, the pressure compensation is made to be made, and in particular, a sludge feed device is installed in the middle of the distant conveying line so that the long distance of sludge can be smoothly transported by additional hydraulic pressure.

To this end, the present invention is provided with first and second pumping pipes that allow the sludge to be sucked and discharged by generating vacuum pressure at both ends of the first and second suction pipes connected to the sludge input hopper, and the first and second suction pipes are provided in the first and second suction pipes. Suction switch valves are provided to selectively open and close them so that sludge is selectively sucked into the first and second pumping pipes, and first and second discharge pipes respectively connected to the first and second suction pipes are provided. The discharge pipe is provided with a discharge switching valve for operating the reverse of the suction switching valve to selectively discharge the sludge introduced into the first and second pumping pipe, the remaining hydraulic pressure of the hydraulic generator for generating the hydraulic pressure to the first and second pumping pipe Is provided with a hydraulic charger for sensing and charging it, the hydraulic charger is open when detecting the overload of the hydraulic generator is characterized in that configured to compensate for the shortage of hydraulic pressure .

Hydraulic Charger, Compensation Cylinder, Pressure Gauge, Compensation Valve

Description

Sludge movement apparatus

1 is a perspective view showing the concept of the conveying apparatus of an embodiment of the present invention

2 is a hydraulic circuit diagram of a transfer apparatus of an embodiment of the present invention

<Code Description of Main Parts of Drawing>

10: main suction pipe 11,12: first and second suction pipe

20: main discharge pipe 21,22: first, second discharge pipe

30: suction switching valve 31: suction valve case

32: suction valve body 33: suction passage

34: suction switching cylinder 40: discharge switching valve

41: discharge valve case 42: discharge valve body

43: discharge passage 44: discharge switching cylinder

50: first pumping pipe 51: first cylinder

52: first piston 60: second pumping pipe

61: second cylinder 62: second piston

70: hydraulic generator 80: hydraulic charger

81: filling valve 82: compensation valve

83: pressure gauge 84: gas tank

90: compensation pump tube 91: compensation cylinder

The present invention relates to a sludge conveying apparatus, and more specifically, a high viscosity and lumpy sludge (food waste, sludge of sewage treatment plant, etc.) is transported to a distance by a vacuum suction method, but the pressure of the hydraulic generator is increased. To the sludge conveying device to charge the sludge and open it when the load is applied to compensate for the insufficient pressure so that the transfer efficiency is improved. It is about.

Generally, the food waste that is thrown away has decayed foreign substances (bottles, paper, cans, wooden chopsticks, etc.) during the collection process. It easily broke down.

Conventionally, a technology using a pump such as a mono pump to transfer sludge having a high viscosity such as food waste has been registered in Korean Utility Model Registration No. 174569. However, since a conventional conveying apparatus uses a mechanical pump, when metallic waste or other foreign substances are included in food waste, parts constituting the pump are damaged or overloaded, resulting in a shortened life. And since there is always food waste inside the pump, there was a problem such that when the device is not operated, garbage is decayed and bad smell is generated.

In consideration of the conventional problem, the present inventors inhale and discharge a large amount of food waste sludge which has a high viscosity and may contain foreign substances in a lump by a certain amount inside the tube by using vacuum pressure, so that foreign substances contained in the food waste may be caught inside the apparatus. Since there is no concern and no residue is left inside the pipe after the discharge is completed, the hygienic sludge conveying device has been registered under Utility Registration No. 244822.

The present inventors can vacuum-suck food waste and sludge which are sediment from sewage treatment plant by vacuum suction on the pipeline and transfer the sludge to the pipeline continuously by injecting pumping means so that one side can discharge the sludge in the pipeline. In addition, a patent application No. 2006-18551 has been applied for a sludge conveying device that can be quickly switched by using a separate switching valve when opening and closing the suction and discharge pipe to increase the suction and discharge to improve the transfer efficiency.

The present invention relates to an improvement of the patent-applied sludge conveying apparatus, and an object of the present invention is to provide two pumping means in parallel while discharging is made on the other side so that the sludge is transported continuously and the pumping is possible. In the hydraulic generator of the Sudan, the hydraulic pressure remaining during operation is filled to one place and opened when the transfer load is applied, so that pressure compensation can be achieved.In particular, a compensation cylinder is installed in the middle of the long-distance conveying line so that the long-distance transfer of the sludge is It is to provide a sludge conveying device that is made smoothly.

In order to achieve the above object, the present invention includes first and second pumping pipes, which generate vacuum pressure while reciprocating at both ends of the first and second suction pipes connected to the sludge input hopper, to allow the sludge to be sucked and discharged. The second suction pipe is provided with a suction switching valve for selectively opening and closing them so that the sludge is selectively sucked into the first and second pumping pipes, and the first and second discharge pipes respectively connected to the first and second suction pipes. The first and second discharge pipes are provided with discharge switching valves for operating sludge in the first and second pumping pipes while being operated opposite to the suction switching valves, and generating hydraulic pressure to the first and second pumping pipes. A hydraulic charger is provided to sense the remaining hydraulic pressure of the generator and charge the same, and the hydraulic charger is opened when the overload of the hydraulic generator is detected to compensate for the shortage of hydraulic pressure. There is generated features.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing the concept of the conveying apparatus of an embodiment of the present invention. The transfer device of the present invention is provided with a main suction pipe 10 is connected to the hopper (not shown) in which the sludge is injected, the main suction pipe 10 is divided into two branch pipes and the first suction pipe 11 and The second suction pipe 12 is configured. In the middle of the first and second suction pipes 11 and 12, a pair of first and second discharge pipes 21 and 22 are vertically inserted, and the tip ends of the first and second discharge pipes 21 and 22 are vertically positioned. Is gathered in one place and connected to the main discharge pipe (20).

The first and second suction pipes 11 and 12 are provided with suction switching valves 30 for opening and closing them, and the first and second discharge pipes 21 and 22 are also provided with discharge switching valves 40 for opening and closing them. do.

The suction switching valve 30 is provided with one suction valve case 31 which connects the first and second suction pipes 11 and 12 in common, and the suction valve case 31 reciprocates in the suction valve case 31. The valve body 32 is provided. In addition, the suction valve body 32 is formed with one suction passage 33 for selectively opening and closing the first and second suction pipes 11 and 12 in a reciprocating process, and the suction valve body 32 is It is reciprocated by the suction switching cylinder 34.

The discharge switching valve 40 is provided with one discharge valve case 41 for connecting the first and second discharge pipes 21 and 22 in common, and discharge the reciprocating movement in the discharge valve case 41 The valve body 42 is provided. In addition, the discharge valve body 42 is formed with one discharge passage 43 for selectively opening and closing the first and second discharge pipes 21 and 22 in the reciprocating process, the discharge valve body 42 is It is reciprocated by the discharge switching cylinder 44.

The first and second pumping pipes 50 and 60 are connected to the front ends of the first and second suction pipes 11 and 12, respectively, and the first inside the first and second pumping pipes 50 and 60. The second pistons 52 and 62 are connected to the first and second cylinders 51 and 61 so as to reciprocate.

2 is a hydraulic circuit diagram of a transfer apparatus of an embodiment of the present invention. The present invention connects the lower ports of the first and second cylinders 51 and 61 to each other, and the upper ports of the first and second cylinders 51 and 61 are connected to the hydraulic generators 70 to connect one closed circuit. It is made up. When the hydraulic pressure is supplied to the upper port of the second cylinder 61 connected to the hydraulic generator 70, the second cylinder 61 is reversed, and the first cylinder 51 connected to the lower port thereof is advanced to suck and discharge the sludge. Let's do it. When the lower ends of the first and second cylinders 51 and 61 are connected to each other, one closed circuit is formed to reduce the operating flow rate, thereby reducing the pump capacity of the hydraulic generator 70.

The hydraulic generator 80 is connected to the hydraulic generator 70 and the filling valve 81 is provided. The hydraulic charger 80 detects the hydraulic pressure remaining during the operation of the hydraulic generator 70 and serves to fill and receive feedback through the charging valve 81 which is automatically opened. In addition, the hydraulic pressure charged by nitrogen gas is additionally charged. If weak, compensate for this.

The hydraulic charger 80 and the hydraulic generator 70 are connected through a compensation valve 82, when the pressure gauge 83 detects this when the hydraulic generator 70 is overloaded, the compensation valve 82 is automatically Open hydraulic pressure is configured to be supplied, is connected to the gas tank 84 filled with nitrogen gas is configured to increase the hydraulic force by the gas pressure.

And in the middle of the pipeline of the main discharge pipe 20 is provided with a compensation cylinder 91 for generating additional hydraulic pressure in order to smoothly transport the sludge, the compensation cylinder 91 is connected to the hydraulic generator 92 and the compensation cylinder (91) The front compensation pump pipe (90) is provided with check valves (93) (94) that open in opposite directions to each other.

The sludge transport apparatus of the present invention configured as described above is bisected into the first and second suction pipes 11 and 12 having the first and second pump pipes 50 and 60 connected to the input hopper. The first and second discharge pipes 21 and 22 respectively connected to the first and second suction pipes 11 and 12 are connected through one main discharge pipe 20. The bisected suction and discharge pipes are provided with suction and discharge switching valves so that suction and discharge are continuously performed.

Referring to the operation of the embodiment of the present invention as follows.

First, when a transport object such as food waste or sludge in a sewage treatment plant is introduced into the input hopper, it is transferred to the main suction pipe 10 by the electric screw under the hopper.

The suction valve body 32 of the suction switching valve 30 is advanced and its suction passage 33 communicates with and opens the second suction pipe 12, and at the same time, the second piston of the second pump pipe 60 is opened. When the second cylinder 61 is operated such that 62 is retracted, sludge in the main suction pipe 10 is introduced into the second suction pipe 12. Since the discharge valve body 42 closes the second discharge pipe 22 by the discharge switching valve 40 operated in the opposite direction while the suction switching valve 30 is operated, the second suction pipe ( Sludge introduced into 12 is not introduced to the second discharge pipe 22 and is completely introduced into the second pumping pipe 60.

The first suction pipe 11 is closed by the suction switching valve 30 and the first discharge pipe 11 is opened by the discharge switching valve 40. Therefore, when the first cylinder 51 is operated so that the first piston 52 moves forward in the opposite direction to the second pumping pipe 60, sludge inside the first pumping pipe 50 (in the previous step) Sludge sucked in advance is discharged to the main discharge pipe 20 via the first discharge pipe (12).

Since the main discharge pipe 20 is in the form of a pipe, the main discharge pipe 20 can be freely made to a desired length regardless of distance and height.

The hydraulic generator 70 is charged to the hydraulic charger 80 by the opening of the filling valve 81 when the hydraulic pressure remaining during operation is sensed. And the hydraulic charger 80 is configured to receive the nitrogen gas pressure of the gas tank 84 to increase the hydraulic pressure. When the pressure of the pressure gauge 83 falls and the hydraulic generator 70 is overloaded while the hydraulic charger 80 is charged with hydraulic pressure, the hydraulic pressure charged while the compensation valve 82 is automatically opened is the hydraulic generator ( 70) to compensate the shortage of the hydraulic pressure to reduce the transport load of the sludge and to reduce the fatigue of the hydraulic generator 70 can extend the life.

In addition, a compensation cylinder 91 is additionally installed in the middle of the long line of the main discharge pipe 20 to compensate for the pressure, and the check valve 93 is opened while the compensation pump pipe 90 is advanced to generate hydraulic pressure. The 94 is closed to push the sludge in the main discharge pipe 20 more strongly to improve the transfer efficiency.

As above, the suction pipe is bisected to install a pair of pumping means, and the discharge pipe is bisected and connected to the respective pumping means, and then the switching valves for opening and closing them in opposite directions to the bisected suction and discharge pipes are opened and closed. In this way, the sludge can be continuously and quickly moved to a desired place by having the continuity for discharging the sludge in the other suction and discharge pipe while the sludge is sucked through the one suction pipe and the discharge pipe.

In addition, the remaining hydraulic pressure of the hydraulic generator is charged when the overload is applied to open the pressure compensation, thereby reducing the transfer load, thereby extending the life of the hydraulic generator, and generating additional hydraulic pressure in the middle of the distant pipeline. There is an effect such as to increase the transport efficiency of the sludge.

Claims (3)

Both ends of the first and second suction pipes connected to the sludge inlet hopper are provided with first and second pumping pipes that generate vacuum pressure while reciprocating to allow the sludge to be sucked and discharged. The first and second suction pipes are provided with suction switching valves to selectively open and close them so that sludge is selectively sucked into the first and second pumping pipes. First and second discharge pipes are connected to the first and second suction pipes, respectively, and the first and second discharge pipes are operated in the opposite direction to the suction switching valve so that the sludge introduced into the first and second pump pipes is selectively discharged. Discharge switch valve is provided, It is provided with a hydraulic charger for sensing the remaining hydraulic pressure of the hydraulic generator for generating the hydraulic pressure to the first, second pumping pipe and charging it, The hydraulic charger is opened when detecting the overload of the hydraulic generator is characterized in that the sludge transfer device, characterized in that configured to compensate for the shortage of hydraulic pressure. The method of claim 1, The hydraulic charger is a sludge conveying apparatus, characterized in that configured to increase the hydraulic force charged by the gas pressure of nitrogen gas. The method of claim 2, The first and second discharge pipes are combined into one main discharge pipe and transferred to a desired place. Sludge conveying apparatus, characterized in that the compensation cylinder for additionally pushing the sludge being transported is installed in the middle of the pipeline of the main discharge pipe can extend the main discharge pipe long.

Images