KR200284145Y1 - Sand selector - Google Patents

Abstract

The present disclosure relates to a sand separator, which is used to efficiently separate and dehydrate sand from collected aggregates. The soil and sand are mixed with water, separated through a cyclone, the sand is dehydrated, and the water is circulated repeatedly. The present invention relates to a sand separator that can be reused.

The present invention is a gemstone screen for filtering foreign matter larger than sand from the aggregate using water supplied from the sedimentation tank; It is installed lower than the gemstone screen, the primary cyclone for sorting the sand primarily from the mixture of water, sand, soil, etc. that passed through the gemstone screen; And a storage tank discharged from the sand discharge port of the primary cyclone and passed through a dehydration screen to store the mixture from which sand is removed and the mixture discharged from the soil discharge port. The mixture stored in the storage tank is supplied by the driving of the sand pump, so that the sand is sorted and sent to the dewatering screen, and the rest is achieved as a secondary cyclone circulating back to the storage tank.

The present invention not only has excellent sand sorting ability, but can also be used by continuously circulating water, so there is no concern about environmental pollution.

Description

Sand Selector {Sand selector}

The present invention relates to a sand separator, and more particularly, to a sand separator that sorts sand using cyclones and screens.

Aggregate dredged in rivers such as Imjin River is mixed with sand in the sand. If used without properly removing the sand, bad concrete is produced. Therefore, only sand is to be supplied from the aggregate collected from nature. In the case of dredged sediment, which is a conventional separation method, the soil is dehydrated naturally after passing through the sorting machine. As a result of this improvement, there is a method of removing soil by using a screw, but this method also has a problem in that efficient sand separation and dehydration are not achieved.

The present invention is designed to efficiently separate and dehydrate sand from natural aggregates. After mixing soil and sand with water, the sand is separated through a cyclone, the sand is dehydrated, and the water is circulated and reused. The purpose is to provide a sand separator.

1 is a block diagram of the subject sand separator.

2 is an operation explanatory diagram of the primary cyclone of the present invention sand separator.

3 is an explanatory view of the operation of the secondary cyclone of the present invention sand separator.

4 is a view illustrating the operation of the storage tank and the settling tank of the present invention sand separator.

※ Explanation of Codes on Major Parts of Drawings

100: sedimentation tank 110: pump

200: gemstone screen 300: primary cyclone

310, 510: Inlet 320, 520: Sand outlet

330, 530: soil discharge outlet 400: storage tank

420: sand pump 500: secondary cyclone

522: nozzle 600: dewatering screen

700: Conveyor

The present invention for achieving this purpose is a gemstone screen for filtering foreign matter larger than sand from the aggregate by using the water supplied from the sedimentation tank, is installed lower than the gemstone screen, and the water passed through the gemstone screen The primary cyclone for screening heavy sands from the mixture of sand, soil, etc., the mixture discharged from the sand outlet of the primary cyclone and passed through the dehydration screen, and the mixture discharged from the soil discharge outlet The storage tank to be stored and the mixture stored in the storage tank are supplied by the driving of the sand pump, so that the sesa is screened and sent to the dewatering screen, and the rest is achieved as a secondary cyclone circulating back to the storage tank.

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

Figure 1 of the accompanying drawings is a block diagram of the present invention aggregate harvesting sand separator.

When the aggregate 10 collected in nature is supplied to the gemstone screen 200, the water 1 supplied from the sedimentation tank 100 is sprinkled onto the gemstone screen 200, so that sand and earth, etc. are primary with water. The gemstones moved to the cyclone 300 and larger than the mesh of the gemstone screen 200 are removed. Movement to the primary cyclone 300 is made of a natural force by the height difference. In the first cyclone 300, sand falls on the dehydration screen 600 together with water due to the weight, and the soil is light, so that the sand is discharged to the soil discharge port 330 and moved to the storage tank 400. However, sand still remains in the water discharged through the soil discharge outlet 330. In order to separate the sand is transferred to the secondary cyclone 500 from the storage tank 400, this transfer is made by the sand pump 420. The secondary cyclone 500 also undergoes the same process as the primary cyclone 300 so that sand is transferred to the dehydration screen 600 and the soil is transferred to the storage tank 400. The dewatering screen 600 consists of a reverse screen to remove water and residual soil contained in the water through the dewatering screen, and only sand is transferred to the conveyor 700.

Looking at the center of the water flow, the water (1) supplied from the settling tank is sprayed over the gemstone screen 200 through the pump 110, mixed with the natural aggregate on the gemstone screen 200, the gemstone large particles The remainder of the mixture 2 on the screen is fed to the primary cyclone 300. In the primary cyclone 300, water is divided into 3a and 3b. 3a is mainly mixed with sand, and 3b is mixed with some sand and soil. 3a goes through the dehydration screen and sand is removed and goes to the storage tank 400, and 3b moves to the storage tank as it is. The water stored in the storage tank is a mixture of sand and soil at the lower end of the hop mixture 4 is supplied to the secondary cyclone 500 at the pressure of the sand pump 420, and divided into 5a and 5b. 5a goes through the same process as 3a, and 5b goes directly to the storage tank. Meanwhile, the water at the top of the water stored in the storage tank having a relatively low content of sand and soil is moved to the settling tank 100 and continuously circulated.

Hereinafter, the operation of each part will be described in detail with reference to FIGS. 2 to 4.

Figure 2 of the accompanying drawings is an explanatory view of the operation of the primary cyclone of the present invention sand separator.

Cyclone is generally used to sort substances mixed in water according to specific gravity, and is composed of an inlet for supplying a mixture, a discharge port for discharging a heavy specific gravity in the mixture, and a discharge port for discharging a light specific gravity.

Cyclone applied to the sand separator is for separating sand and soil, and the sand discharge port is discharged from the sand and the soil discharge port is discharged.

The primary cyclone 300 of the present invention is a non-powered cyclone used as a natural force flowing from a high place to a low place. Therefore, it is preferable to be installed at a lower position than the gemstone screen 200.

The water supplied from the settling tank is a mixture containing sand and soil as it passes through the gemstone screen 200, and this mixture (2) to the inlet 310 of the primary cyclone 300 located lower than the gemstone screen Inflow. The mixture 2 thus introduced is rotated to form a vortex inside the primary cyclone 300, and the mixture 3a containing a lot of relatively heavy sand is discharged to the sand outlet 320 formed at the bottom thereof. While passing through the dehydration screen, the sand is sorted, dehydrated and transported to the conveyor side, and the remaining mixture falls to the storage tank, and the mixture 3b having a relatively low content of sand discharged to the soil discharge outlet 330 is stored as it is. . The mixture stored in the storage tank is then sorted again in the secondary cyclone. The primary cyclone 300 is a non-powered cyclone to select the heavy yarns having a relatively large particle size.

3 is an explanatory view of the operation of the secondary cyclone of the present invention sand separator.

Unlike the first cyclone, the secondary cyclone 500 of the present invention is a power cyclone that is transferred at the pressure of the sand pump, and its vortex strength is stronger than that of the primary cyclone. If simply formed on the side, due to the strength of the vortex, a large amount of sand will also flow out to the soil discharge outlet to reduce the efficiency of sand selection. Therefore, the secondary cyclone 500 of the present invention is formed below the inlet 510 by forming a soil discharging outlet 530 on the upper cover of the secondary cyclone and extending the soil discharging inlet 532 vertically downward. In order to discharge the mixture that overflows to the soil discharge port, sand does not flow out into the soil discharge port 530, and on the other hand, the nozzle 522 is formed in the sand discharge port 520 to overflow the flow rate. It was possible to control the degree of sand screening by controlling the. In the secondary cyclone 400, finer yarns smaller in size than particles selected from primary cyclones are selected.

The mixture 5a discharged from the sand discharge port is stored in the storage tank through the dehydration screen as in 3a of FIG. 2, and 5b is stored in the storage tank as it is in the same manner as in 3b.

4 is an explanatory view of the storage tank and the settling tank of the present invention sand separator.

All mixtures discharged from the primary and secondary cyclones are collected in the storage tank 400. The storage tank 400 is provided with discharge pipes 410 and 430 at the top and bottom, respectively, and relatively clear water is sent to the settling tank through the upper discharge pipe 430, and the content of sand and soil through the lower discharge pipe. Many mixtures are fed back to the secondary cyclone by the feed pressure of the sand pump 420.

The relatively clear water supplied through the upper discharge pipe 430 is transferred to the settling tank 100 again. The sedimentation tank 100 is divided into several compartments, and the water supplied from the storage tank 400 is sequentially stored for each compartment, and the water of the longest compartment of the storage period (if the storage time is long, the soil is naturally gone. Sit down and become clear water). The water is supplied and the soil remaining on the bottom is removed, and the compartment is filled with the mixture supplied from the storage tank 400, and the water is supplied to the screen of the gemstone again in another compartment so that the water can be continuously circulated. .

This sand separator is designed to mix the aggregate collected from nature with water and transfer it to the natural water flow and pump pressure, and to pass only the sand through the gem screen, primary cyclone and secondary cyclone to finally dewater. Transferring to the conveyor via the screen automatically results in a good sand sorting effect.

In addition, the sand separator of the present invention is used to recover the used water through the settling tank to be used again to bring excellent sand screening effect without causing environmental pollution.

Claims (4)

In the sand separator, A gemstone screen for filtering foreign matter larger than sand from the aggregate by using water supplied from the settling tank; It is installed lower than the gemstone screen, the primary cyclone for sorting the sand primarily from the mixture of water, sand, soil, etc. that passed through the gemstone screen; A storage tank discharged from the sand discharge port of the primary cyclone and passed through a dehydration screen to store the mixture from which sand is removed and the mixture discharged from the soil discharge port; Receiving the mixture stored in the storage tank is driven by the sand pump, the sand is sorted, characterized in that it comprises a secondary cyclone to send to the dewatering screen and the rest circulated back to the storage tank. The method of claim 1, The secondary cyclone forms a soil discharge outlet at the upper end of the secondary cyclone and the inlet portion is installed lower than the inlet through which the mixture is supplied from the storage tank, so that the overflowed mixture is discharged to the soil discharge outlet. Sand selector The method of claim 2, The secondary cyclone is provided with a nozzle in the sand discharge port formed in the lower portion, sand separator characterized in that for controlling the amount of the mixture discharged to the soil discharge outlet The method of claim 1, The sedimentation tank is a sand sorter, characterized in that divided into several compartments