JP6497756B2 - Multistage wedge screen - Google Patents

Description

  The present invention relates to a multistage wedge screen for dewatering livestock manure generated in the process of industrial sites and sewage treatment, and a method for producing the same.

  For livestock manure, solid manure with low water content can be used as solid compost, and liquid with high water content can be used as liquid fertilizer or purified, so the process of separating livestock manure into solid manure and liquid can be processed The machine used in this process is a livestock manure solid-liquid separator.

  In general, solid-liquid separation of livestock manure solid-liquid separators is roughly classified into filtration separation, centrifugation, and compression / pressing. Filtration is classified into roller pressure bonding (Roller Press), belt pressure bonding (Belt Press), screw pressure bonding (Screw Press), filter pressure bonding (Filter Press) and the like. This solid-liquid separation method should be installed and used in consideration of the state of feces and urine before treatment, solid feces and liquid treatment method after solid-liquid separation, initial installation cost, required power and maintenance management cost, etc. become.

  Among them, the screw crimping type livestock manure solid-liquid separator presses livestock manure with a screw and a pressure plate that applies pressure to the screw, and the liquid is discharged through a net that encloses the screw, thereby removing the liquid. The solid excrement of the excreted urine is configured to be transported by a screw shaft and pushed out of the pressure plate to be discharged. However, when a high front end pressure is applied to the pressure plate during work, the moisture content of the solid feces decreases the processing capacity of the low machine, and when a low front end pressure is applied, the processing capacity is high, but less water is removed and the water content is reduced. Solid feces with a high rate will be discharged. Therefore, it is very important to keep the front end pressure applied to the pressure plate constant as necessary in order to secure the processing capacity while maintaining the moisture content of the solid feces as constant as desired.

  FIG. 1 is a conceptual diagram showing the principle of a conventional livestock manure solid-liquid separator.

  As shown in FIG. 1, the conventional livestock manure solid-liquid separation maximizes the processing capacity because the front end pressure applied to the pressure plate changes according to the amount of solid feces discharged, so that the front end pressure is not evenly distributed. There were technical limitations in solving the two problems of minimizing the moisture content of solid feces. As technologies related to these livestock manure solid-liquid separation, there are an input unit into which livestock manure is introduced, a dehydration unit that solid-liquid separates livestock manure fed through the input unit by rotating a screw auger, and the dehydration unit A motor formed on one side for rotating the screw auger, a pressure adjusting unit for adjusting the pressure of the dehydrating unit, and a discharging unit formed on the other side of the dehydrating unit for discharging dehydrated solid matter The pressure adjusting part is formed in a “U” shape on the discharge part side, and has a guide hole formed on both side surfaces, and is movably provided on the frame. A pressure plate for pressurization, a guide shaft protruding from both sides of the pressure plate and guided by the guide hole, a movable pulley installed on the guide shaft, and a lower portion on one side of the dewatering unit A fixed pulley placed, one end fixed to the frame, a stainless steel wire wound around the movable pulley and the fixed pulley, and a weight attached to the other end of the stent wire, The movable pulley moves according to the weight of the weight, and the pressure plate moves together with the movable pulley to pressurize the discharge part (Korea published patent No. 2006-0050218). No.) has been proposed.

Korean Published Patent No. 2016-0050218

  The present invention has been devised in order to solve the above-described problems, and the object of the present invention is to make the front end pressure different for each area when separating livestock manure liquid and solid feces. It is to provide a multistage wedge screen that can solve the two problems of distribution and maximizing the processing capacity and minimizing the moisture content of solid feces, and a method for manufacturing the same.

  A multi-stage wedge screen according to the present invention is fastened to a plurality of fastening rings arranged in the longitudinal direction and having a plurality of fastening grooves formed in an inner peripheral surface along the circumferential direction, and the fastening grooves of the plurality of fastening rings. A plurality of unit screens including a plurality of wedge bars are connected in the longitudinal direction to each other, and a slit interval between the wedge bars of the unit screens is different for each unit screen.

  The unit screen may have a different fastening groove arrangement interval for each unit screen.

  In addition, the thickness of the wedge bar of the unit screen is different for each unit screen.

  The unit screen is divided into a drainage unit screen, a concentration unit screen, and a dehydration unit screen, and the slit interval between the wedge bars of the drainage unit screen is the largest, and between the wedge bars of the concentration unit screen. The slit interval is the second largest and the slit interval between the wedge bars of the dewatering unit screen is the third largest.

  The fastening ring may further include a round shape formed with a structure rounded on both surfaces of the fastening ring.

  The method for manufacturing a multistage wedge screen according to the present invention includes inserting a plurality of fastening rings each having a plurality of fastening grooves formed in an inner peripheral surface along a circumferential direction into a cylindrical fixing jig, and fastening the fastening rings. A plurality of wedge bars inserted into the groove and coupled to manufacture a unit screen; and a plurality of unit screens connected to each other in the longitudinal direction to manufacture a multistage wedge screen, The slit interval is different for each unit screen.

  The step of manufacturing the unit screen may further include a step of coupling a support bar to the fastening ring in order to fix the unit screen in a state where the spacing of the fastening ring is adjusted.

  Accordingly, in the solid-liquid separator equipped with the multistage wedge screen according to the present invention, the slit distance between the wedge bars of the unit screen is different for each unit screen, so that the front end pressure is different for each unit screen. Thus, there is an advantage that two problems of maximizing the processing capacity of livestock manure and minimizing the water content of solid feces can be solved.

FIG. 1 is a conceptual diagram showing the principle of conventional livestock manure solid-liquid separation. FIG. 2 is a perspective view showing a multistage wedge screen according to the present invention. FIG. 3 is an enlarged perspective view showing a fastening ring and a wedge bar according to the present invention. FIG. 4 is a conceptual diagram showing the principle of a multistage wedge screen according to the present invention. FIG. 5 is a schematic view showing a method for manufacturing a multistage wedge screen according to the present invention.

  Hereinafter, the technical idea of the present invention will be described more specifically with reference to the accompanying drawings.

  The accompanying drawings are merely examples provided for more specifically explaining the technical idea of the present invention, and the technical idea of the present invention is not limited to the accompanying drawings.

  2 is a perspective view showing a multi-stage wedge screen 1000 according to the present invention, and FIG. 3 is an enlarged perspective view showing a fastening ring 110 and a wedge bar 120 according to the present invention.

  As shown in FIGS. 2 to 3, the multi-stage wedge screen 1000 according to the present invention is used for the purpose of dehydrating livestock excrement while being transported in the longitudinal direction. A plurality of units including a plurality of fastening rings 110 in which a large number of fastening grooves 111 are formed on the surface along the circumferential direction, and a plurality of wedge bars 120 respectively fastened to the fastening grooves 111 of the plurality of fastening rings 110. The screens 100 are connected to each other in the longitudinal direction, and the slit interval between the wedge bars 120 of the unit screens 100 is different for each unit screen 100.

  In more detail, the fastening ring 110 is formed in a ring structure, and a plurality of fastening grooves 111 are arrayed along the circumferential direction on each inner peripheral surface.

  In addition, the fastening ring 110 is formed in at least two of the unit screens 100, and the fastening groove 111 is formed to be recessed in the inner peripheral surface of the fastening ring 110.

  Each of the plurality of wedge bars 120 has a cross section having a structure corresponding to the cross section of the fastening groove 111, and is slid and coupled to the fastening grooves 111 of the plurality of fastening rings 110. At this time, the multiple wedge bars 120 are slid into the multiple fastening grooves 111 and welded in the inserted state.

  Meanwhile, the unit screen 100 is configured such that the livestock manure is transferred from one side in the longitudinal direction to the other side by a transfer screw (not shown) installed and rotated inside, and the wedge bar 120 formed on the outer peripheral surface. Water separated from livestock manure is discharged into the slits between the two.

  At this time, in the unit screen 100, the wider the slit interval between the wedge bars 120, the greater the processing capacity of livestock manure, but the lower the recovery rate of solid feces, the lower the space between the wedge bars 120. The narrower the slit interval, the smaller the livestock manure treatment capacity, but the higher the solid feces recovery rate.

  In addition, as the unit screen 100 is formed with a wider slit interval between the wedge bars 120, the number of the fastening grooves 111 and the number of installed wedge bars 120 are reduced, and the slits between the wedge bars 120 are reduced. The narrower the interval, the greater the number of fastening grooves 111 formed and the number of wedge bars 120 installed.

  Accordingly, in the solid-liquid separator equipped with the multistage wedge screen 1000 according to the present invention, the slit interval between the wedge bars 120 of the unit screen 100 is different for each unit screen 100, so that the front end is provided for each unit screen 100. There is an advantage that the two problems of maximizing the processing capacity of livestock manure and minimizing the water content of solid feces can be solved by distributing the pressure differently.

  In addition, the multistage wedge screen 1000 can be replaced or repaired by parts when breakage occurs, and there is an advantage that the maintenance and management costs of the product can be minimized.

  Meanwhile, a support bar 130 may be coupled to the fastening ring 110 in order to fix the unit screen 100 with the spacing of the fastening ring 110 adjusted.

  At this time, a pair of fastening rings 110 formed at both ends of the unit screen 100 can be coupled to the support bars 130 on both sides facing each other, and at this time, a pair of fastening rings formed at both ends of the unit screen 100. The ring 110 may be formed with a wider diameter than other fastening rings 110.

  Meanwhile, the multistage wedge screen 1000 may be formed with a structure in which the arrangement interval of the fastening grooves 111 of the unit screen 100 is different for each unit screen 100.

  At this time, the slit intervals between the wedge bars 120 of the unit screen 100 can be adjusted by adjusting the arrangement intervals L1, L2, and L3 of the fastening grooves 111 of the unit screen 100.

  In addition, the multistage wedge screen 1000 may be formed in a structure in which the thickness T of the wedge bar 120 of the unit screen 100 is different for each unit screen 100.

  At this time, the slit interval between the wedge bars 120 of the unit screen 100 can be adjusted by adjusting the thickness T of the wedge bar 120 of the unit screen 100.

  The unit screen 100 may be divided into a drainage unit screen 100-1, a concentration unit screen 100-2, and a dehydration unit screen 100-3. That is, the multistage wedge screen 1000 includes a drain unit screen 100-1, a concentration unit screen 100-2, and a dehydration unit screen 100-3 as an example of a unit screen.

  At this time, the slit interval D1 between the wedge bars 120 of the drainage unit screen 100-1 is the largest, the slit interval D2 between the wedge bars 120 of the concentration unit screen 100-2 is the second largest, The slit distance D3 between the wedge bars 120 of the dewatering unit screen 100-3 is formed to be the third largest.

  At this time, the drainage unit screen 100-1 receives the livestock manure transferred in the sewage tank, and the concentration unit screen 100-2 connected to the downstream side in the inflow direction is the drainage unit screen 100-1. The transported livestock manure is flown into, and the dewatering unit screen 100-3 connected further downstream thereof is fed with livestock manure transported from the concentration unit screen (100-2).

  On the other hand, the drainage unit screen 100-1 has the largest slit interval D1 between the wedge bars 120 and the highest processing capacity of livestock manure, but the solid feces contain the most water. The moisture content of solid feces is the most formed.

  In addition, the concentrating unit screen 100-2 has the second largest slit interval D2 between the wedge bars 120 and the second largest amount of livestock excreta, but the solid feces contain the second most water. As a result, the moisture content of solid feces is the second highest.

  Further, the dehydration unit screen 100-3 has the smallest slit interval D3 between the wedge bars 120, and has the lowest processing capacity of livestock manure, but it is solid feces and contains the least water. Feces are formed with the lowest moisture content.

  FIG. 4 is a conceptual diagram illustrating the principle of a multistage wedge screen 1000 according to the present invention.

  The drainage unit screen 100-1 can confirm that the livestock manure is separated into liquid and solid feces from the moment when the livestock manure is flown, and the processing capacity is the highest.

  Further, the concentration unit screen 100-2 can confirm that the amount of livestock excrement separated into liquid and solid feces increases and the processing capacity is the second highest.

  Further, the dehydration unit screen 100-3 can confirm that the amount of livestock manure separated into liquid and solid feces increases and the processing capacity is the lowest.

  Accordingly, in the solid-liquid separator equipped with the multistage wedge screen 1000 according to the present invention, the slit interval between the wedge bars 120 of the unit screen 100 is different for each unit screen 100, so that the front end is provided for each unit screen 100. There is an advantage that the two problems of maximizing the processing capacity of livestock manure and minimizing the water content of solid feces can be solved by distributing the pressures differently.

  Meanwhile, the fastening groove 111 further includes a fastening tapered surface 111-1 tapered to the inner peripheral surface of the fastening ring 110, and a fastening curved surface 111-2 curved at the end of the fastening tapered surface 111-1. The wedge bar 120 may further include a wedge tapered portion 121 corresponding to the fastening tapered surface 111-1 and a wedge curved surface portion 122 corresponding to the fastening curved surface 111-2.

  That is, the fastening groove 111 and the wedge bar 120 may be formed in a triangular prism structure to maximize the area where they are in contact with each other.

  In addition, the fastening groove 111 may further include a round shape formed with a structure rounded on both sides in the longitudinal direction.

  The round shape serves to guide the fastening groove 111 when the wedge bar 120 slid in the fastening groove 111 hits both sides of the fastening groove 111 in the longitudinal direction.

  FIG. 5 is a schematic view showing a method for manufacturing a multistage wedge screen according to the present invention.

  As shown in FIG. 5, the manufacturing process of the multistage wedge screen according to the present invention will be described.

  First, in the process of manufacturing the unit screen 100, a plurality of fastening rings 110 each having a plurality of fastening grooves 111 formed on the inner peripheral surface along the circumferential direction are inserted into the fixing jig P having a cylindrical structure, A plurality of wedge bars 120 are inserted into the fastening grooves 111 of the fastening ring 110 and joined to manufacture the unit screen 100. At this time, in order to maintain a gap between the fastening rings 110, spacers (not shown) having a circular arc structure can be further installed between the fastening rings 110.

  Next, in the step of manufacturing the multistage wedge screen 1000, a plurality of unit screens 100 are connected in the longitudinal direction to manufacture the multistage wedge screen 1000.

  Meanwhile, the step of manufacturing the unit screen 100 may further include a step of coupling a support bar 130 to the fastening ring 110 in order to fix the unit screen 100 with the spacing of the fastening ring 110 adjusted. At this time, a pair of fastening rings 110 formed at both ends of the unit screen 100 can be coupled to the support bars 130 on both sides facing each other, and at this time, a pair of fastening rings formed at both ends of the unit screen 100. The ring 110 may be formed with a wider diameter than other fastening rings 110.

  The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the gist of the present invention claimed in the claims as well as various application ranges. is there.

1000: Multistage wedge screen 100: Unit screen 100-1: Drain unit screen 100-2: Concentration unit screen 100-3: Dehydration unit screen 110: Fastening ring 111: Fastening groove 111-1: Fastening taper surface 111- 2: Fastening curved surface 120: Wedge bar 121: Wedge taper portion 122: Wedge curved surface portion 130: Support bar 200: Fixed jigs L1, L2, L3: Arrangement intervals D1, D2, D3 of the fastening grooves: Slit intervals between the wedge bars

Claims (1)

A unit including a plurality of fastening rings arranged in the longitudinal direction and having a plurality of fastening grooves formed along the circumferential direction on the inner peripheral surface, and a plurality of wedge bars respectively fastened to the fastening grooves of the plurality of fastening rings. A plurality of screens are connected to each other in the longitudinal direction,
Slit interval between the wedge bar of the unit screen, and Tsu different for each of the unit screens,
The unit screen is divided into a drainage unit screen, a concentration unit screen, and a dehydration unit screen. From the upstream side to the downstream side in the sewage transfer direction from one side of the longitudinal direction to the other side, the drainage unit screen, the concentration Unit screen, each unit screen of the dehydration unit screen is connected to each other in that order,
The slit spacing between the wedge bars of the drainage unit screen is the largest, the slit spacing between the wedge bars of the concentration unit screen is the second largest, and the slit spacing between the wedge bars of the dewatering unit screen is three. The second largest,
The plurality of fastening grooves include a pair of opposing fastening taper surfaces tapered in the groove depth direction, and a curved fastening curved surface formed at an end in the groove depth direction,
The wedge bar includes a wedge taper portion having a shape corresponding to the pair of fastening taper surfaces, and a wedge curved surface portion having a shape corresponding to the fastening curved surface .