JP2008290142A - Screw press - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a screw press having excellent dewatering performance for sludge and capable of improving treatment capacity for sludge by feeding an inorganic flocculant containing polyferric sulphate to sludge fed into a sludge pressing chamber. <P>SOLUTION: Regarding the screw press 1 where a sludge pressing chamber stored with a screw 5 composed of a screw shaft 7 and a screw vane 6 is formed within a cylindrical screen 4, a plurality of inorganic flocculant feed headers 40 provided with a plurality of ejectors 41 for feeding an inorganic flocculant containing polyferric sulphate are provided in a space with the screw vane 6 in the range of 1/3 to 2/3 from the small diameter side of the screw shaft 7 in the whole length of the screw 5, and in the central region between the inner circumferential face of the cylindrical screen 4 and the outer circumferential face of the screw shaft 7. The inorganic flocculant is periodically fed to the inorganic flocculant feed headers 40 via a plurality of feed ports in a rotary switch valve 38. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an improvement of a screw press, and more specifically, an inorganic flocculant such as polyferric sulfate is supplied to sludge supplied into a sludge pressurizing chamber of the screw press to improve the sludge dewatering rate. The present invention relates to a screw press that makes it possible.

Sludge generated from a sewage treatment plant or the like is dehydrated and treated by a sludge dewatering device or the like.
Usually, a polymer flocculant is added to sludge and mixed (mixed), and the agglomerated sludge containing flocs thus agglomerated is dehydrated. There are various types of sludge dewatering devices, and there is one called a screw press. Hereinafter, the screw press which concerns on a prior art example is demonstrated, referring an accompanying drawing. 8 is a partially longitudinal sectional side view of a screw press according to Conventional Example 1, and FIG. 9 is a partially longitudinal side view of a scraper attached to a screw blade of the screw press according to Conventional Example 1.

  That is, reference numeral 101 shown in FIG. 8 is a screw press, and this screw press 101 is horizontally mounted on the front and rear frames 102 and 103, and inside the outer cylinder 105 in which the screen 104 is stretched around the periphery, A screw shaft 107 around which a screw blade 106 is wound is provided. The outer cylinder 105 is divided into an outer cylinder 105a in the concentration zone in the first half and an outer cylinder 105b in the filtration / dehydration zone in the second half, and a bearing 108 is interposed between the outer cylinders 105a and 105b. Yes. A flange 111 is provided on the starting end side of the outer cylinder 105 a in the concentration zone, and this flange 111 is rotatably supported by a rotating plate bearing 112 fixed to the frame 102. The thrust receiver 113 provided with the flange 111 is provided with a sprocket 114. When the sprocket 114 is rotated forward and backward by a forward / reverse driving device 115, the outer cylinder 105a of the concentration zone in the first half is rotated forward and backward. It is comprised so that.

  In addition, a rotating plate 116 is provided on the rear end side of the outer cylinder 105 b of the latter filtration / dehydration zone, and the rotating plate 116 is rotatably supported by a rotating plate bearing 117 fixed to the frame 103. ing. The rotating plate 116 is provided with a sprocket 118, and the sprocket 118 is configured to be rotated by a driving machine 119. More specifically, when high-pressure washing water is jetted from the washing water pipe 120 provided along the outer cylinder 105 toward the screen 104, the outer cylinder 105b of the filtration / dehydration zone in the latter half is concentrated in the first half. It is configured to rotate together with the outer cylinder 105a of the zone. A supply pipe 121 is connected to a start end side of a screw shaft 107 provided in the outer cylinder 105, and a bearing portion 121a of the supply pipe 121 is an inner peripheral surface of the flange 111 fitted to the outer cylinder 105a of the concentration zone. Is pivotally supported.

  A drive shaft 122 provided at the rear end portion of the screw shaft 107 is supported by a bearing unit 123 fixed to the frame 103 and a bearing unit 125 provided on a mount 124 of the screw shaft 107. The drive shaft 122 is provided with a sprocket 126, and the screw shaft 107 is rotated by rotating the sprocket 126 with a rotary drive machine 127. A sludge supply path 128 is provided in a supply pipe 121 connected to the front end portion of the screw shaft 107, and the supply path 128 passes through the inside of the screw shaft 107, at the start end portion of the outer cylinder 105 of the screw shaft 107. The supply hole 128a communicates with the opening.

  That is, the sludge is supplied between the screw blades 106 wound around the screw shaft 107 from the supply hole 128 a, and the agglomerated soft sludge is not affected by the screw blades 106. In addition, a presser 130 is opposed to the discharge port 129 at the final end of the outer cylinder 105. More specifically, the presser 130 is suspended from the moving shaft 131, and the air cylinder 132 provided at the rear end of the presser 130 applies back pressure to the dehydrated cake through the cone portion of the presser 130. The opening amount of the discharge port 129 is configured to be adjusted.

  As shown in FIG. 9, a scraper 133 made of an elastic member having elasticity such as rubber is provided at the front end of the screw blade 106 from the start end of the concentration zone of the screw blade 106 to the end of the filtration / dehydration zone. It is fixed by 134 and a nut 135. The scraper 133 is configured to elastically slide in contact with the inner peripheral surface of the screen 104, and the concentrated water is separated by separating the filtered water from the screen 104a in the concentration zone in which clogging is prevented by the scraper 133. By increasing the amount of sludge supplied in the zone and scraping off the dewatered cake layer on the fine pores of the screen 104b in the filtration / dewatering zone for supplying concentrated sludge, high dewatering is performed (for example, , See Patent Document 1).

  Although the screw press which concerns on the said prior art example 1 is normally comprised so that the flocculant may be added and mixed (mixed) sludge may be supplied, it seems that a flocculant is added in the sludge in a screw press. There is something that was configured. The screw press according to Conventional Example 2 will be described with reference to FIG. 10 which is a schematic longitudinal sectional view of the main part of the screw press.

That is, a feed shaft 152 (screw shaft) having a feed blade 153 provided on the outer periphery is housed in an outer cylinder 151 provided with a metal mesh or the like, and a stock solution supply hopper is disposed above the starting end portion of the feed shaft 152. In a screw press in which the lower part of the hopper 154 and the starting end of the outer cylinder 151 are used as a concentrate zone for the stock solution, and the remaining part of the outer cylinder 151 following the concentration zone is used as a dewatering zone, A supply path 155 for soil improvement material is provided at the center, and among the feed blades 153, approximately one pitch of the feed blades 153 located in the middle part of the dewatering zone is defined as a hollow hollow blade 153a. A number of through holes 157 are provided on the front surface, and the hollow blades 153a communicate with the soil improvement material supply path 155 (see, for example, Patent Document 2).
Special table 2003-513805 gazette Japanese Utility Model Publication No. 6-15731

  The screw press according to Conventional Example 1 is supplied with sludge mixed with (added to) a flocculant, and in order to effectively dewater sludge with the screw press, the polymer flocculant is used. In addition, it is necessary to supply sludge having a higher degree of concentration by adding (mixing) an inorganic flocculant such as polyferric sulfate and mixing (mixing). Usually, a flocculant or a line mixer is installed in a sludge supply line communicating with a screw press from a stirring tank that mixes (mixes) a polymer flocculant with sludge. Inorganic flocculants such as these are supplied and mixed, and then supplied to a screw press for dehydration.

  However, in such a method for supplying the inorganic flocculant outside the machine, when the sludge and the inorganic flocculant are mixed, the inorganic flocculant shifts to the moisture side, so that sufficient sludge aggregation cannot be achieved. In addition, an installation space for a coagulation tank or a line mixer is required, and the number of devices increases. In this method, the maintenance space around the screw press can be secured and the number of equipment can be reduced, and the inorganic flocculant can be supplied to any position of the sludge that has been concentrated inside the screw press. Attempts have been made to feed directly into the screw press.

As a means for supplying an inorganic flocculant such as polyferric sulfate to a screw press, for example, a configuration according to the above-described conventional example 2 can be considered. Then, many through-holes were provided in the front surface of the screw blade, and the inorganic flocculant was supplied into the sludge from these many through-holes, and the dehydration test was conducted.
However, it has been found that the inorganic flocculant ejected from a large number of through holes flows along the surface of the screw blade and the outer peripheral surface of the screw shaft.

  In other words, the inorganic flocculant is mixed in the sludge layer interposed near the surface of the screw blade and the sludge layer interposed in the vicinity of the outer peripheral surface of the screw shaft, but between the screw blades, the inner peripheral surface of the cylindrical screen, and the screw shaft. Since the inorganic flocculant is not dispersed and uniformly mixed in the central area of the sludge surrounded by the outer peripheral surface, the inorganic flocculant cannot be used effectively, and the dewatered cake adheres to the screw and effectively dehydrates. There was a problem that the sludge treatment efficiency was low.

  Moreover, from a long-term viewpoint, as shown in FIG. 11 of the fixed state explanatory diagram of sludge (dehydrated cake), it was found that the sludge is fixed to the outer peripheral surface of the screw shaft and the front and back surfaces of the screw blades. . Then, the solidified sludge solidifies and gradually grows to thicken the solidified layer, and the region between the screw blades and the inner peripheral surface of the cylindrical screen and the outer peripheral surface of the screw shaft, that is, the sludge passage region However, the dehydration performance (sludge treatment amount and dehydrated cake moisture content) gradually decreases. In order to prevent such a decrease in dewatering performance (throughput and moisture content), the operation of the screw press is stopped, and the solidified layer of sludge adhering to the outer peripheral surface of the screw shaft and the front and back surfaces of the screw blades is removed. In addition to a reduction in the operating rate of the screw press, there is a problem that maintenance is increased.

In addition, when ferric sulfate, an inorganic flocculant, flows out of the micropores of the cylindrical screen together with water, it adheres to the micropores, dries, and gradually grows to narrow the micropores, thus reducing the dehydration efficiency.
Furthermore, in addition to frequent cleaning of the cylindrical screen, it is difficult to remove ferric sulfate compared to sludge and residue, so it is long for removing polyferric sulfate. Although it takes time and the clogging of the fine holes in the cylindrical screen due to polyferric sulfate can be prevented, the dewatering performance of sludge is improved, but it is difficult to put the ferric sulfate in-machine supply into practical use. I also found that there was a problem.

  Accordingly, an object of the present invention is to provide an excellent sludge dewatering performance by efficiently supplying an inorganic flocculant such as polyferric sulfate to the sludge supplied into the sludge pressurizing chamber. This prevents the dewatering cake from sticking to the front and back of the steel, improving the sludge dewatering capacity and preventing clogging of the micropores in the cylindrical screen due to inorganic flocculants such as polyferric sulfate. It is to provide a screw press that makes it possible to do.

  The present invention has been made in view of the above circumstances. Therefore, the means employed by the screw press according to claim 1 of the present invention includes a screw shaft that is rotated by a driving device inside a cylindrical screen, and A sludge pressurizing chamber is formed in which a screw composed of screw blades spirally arranged on the screw shaft is formed, and the sludge added from the sludge supply hole provided at one end of the sludge pressurizing chamber. The sludge supplied to the pressure chamber is pressurized while being transferred to the other end of the sludge pressurizing chamber, and a part of the water contained in the sludge is separated by a cylindrical screen to form a dehydrated cake, and the sludge pressurizing chamber In the screw press that discharges from the dewatered cake discharge port provided on the other end of the screw, the screw is within the range of 1/3 to 2/3 of the total length of the screw from the sludge supply hole side of the screw shaft. A plurality of inorganic flocculant supply headers provided with injection holes for supplying an inorganic flocculant are provided between the blades and in an area between the inner peripheral surface of the cylindrical screen and the outer peripheral surface of the screw shaft; The other end side of the inorganic flocculant supply line in which a plurality of inorganic flocculant supply passages for supplying the inorganic flocculant to the plurality of inorganic flocculant supply headers are provided in the screw shaft, and one end side is connected to a constant capacity pump In addition, a single switching valve having a plurality of supply ports can be connected to the inorganic flocculant, and an inorganic flocculant can be periodically supplied to each of the plurality of inorganic flocculant supply channels via the plurality of supply ports of the switching valve. It is configured as described above.

  The means adopted by the screw press according to claim 2 of the present invention is the screw press according to claim 1, wherein a plurality of the switching valves are provided at the end of the screw shaft on the dewatering cake discharge port side or sludge supply hole side. The supply port side is provided with a swivel joint that communicates with the inorganic flocculant supply channel.

  The means employed by the screw press according to claim 3 of the present invention is the screw press according to any one of claims 1 and 2, wherein the switching valve is a rotary switching valve. It is what.

  In the screw press according to claims 1 to 3 of the present invention, the entire length of the screw, between the screw blades within the range of 1/3 to 2/3 from the sludge supply hole side of the screw shaft, and the inner periphery of the cylindrical screen A plurality of inorganic flocculant supply headers having injection holes for supplying an inorganic flocculant are provided in a region between the surface and the outer peripheral surface of the screw shaft, and a plurality of inorganic flocculant supply headers are provided in the screw shaft. A single switching valve having a plurality of supply ports is connected to the other end of the inorganic flocculant supply line provided with a plurality of inorganic flocculant supply passages for supplying the inorganic flocculant and having one end connected to a constant displacement pump. In addition, the inorganic flocculant can be periodically supplied to each of the plurality of inorganic flocculant supply channels via the plurality of supply ports of the switching valve.

  Therefore, according to the screw press according to claims 1 to 3 of the present invention, it is not necessary to provide a line mixer for mixing the flocculant into the sludge, which can contribute to the cost reduction of the sludge dewatering device equipped with the screw press. . And, the range of 1/3 to 2/3 from the sludge supply hole side of the screw shaft is the range that sandwiches the boundary between the concentration zone and the filtration / dehydration zone, and the sludge has favorable fluidity for mixing the inorganic flocculant. A plurality of inorganic flocculant supply header injection holes in the sludge area between the screw blades and between the inner peripheral surface of the cylindrical screen and the outer peripheral surface of the screw shaft, having such a preferable fluidity. Since the inorganic flocculant is periodically ejected from the inorganic flocculant, the inorganic flocculant is effectively mixed and mixed in the sludge. In addition, since one switching valve having a plurality of supply ports is connected to the other end of the inorganic flocculant supply line whose one end is connected to the constant capacity pump, each of the plural inorganic flocculant supply channels is connected. An inorganic flocculant can be supplied uniformly. Therefore, since the whole sludge aggregates equally, it can dehydrate effectively and can obtain the outstanding effect that the processing efficiency of sludge improves.

  In the screw press according to claim 2 of the present invention, the inorganic flocculant is supplied to the inorganic flocculant supply header via a swivel joint provided at the end of the screw shaft on the sludge discharge hole side or sludge supply hole side. The Therefore, since the inorganic flocculant can be supplied to any position of the sludge where the concentration inside the screw press has progressed, the inorganic flocculant can be used effectively and the maintenance space around the screw press can be secured. The number of equipment can be reduced.

  In the screw press according to claim 3 of the present invention, the switching valve is a rotary switching valve. Therefore, even though the switching valve has a simple configuration, an equal amount of inorganic flocculant can be easily supplied from each of the plurality of supply ports to each of the plurality of inorganic flocculant supply channels. It becomes possible.

  Hereinafter, the screw press which concerns on Embodiment 1 of this invention is demonstrated, referring an accompanying drawing. 1 is a partially longitudinal sectional side view of a screw press according to Embodiment 1 of the present invention, and FIG. 2 is a partially longitudinal side view of a scraper attached to the screw blades of the screw press according to Embodiment 1 of the present invention. FIG. FIG. 3 is an explanatory view of the installation state of the inorganic flocculant supply header and the arrangement state of the liner of the screw press according to the first embodiment of the present invention, and FIG. 4 (a) is a screw according to the first embodiment of the present invention. 4B is a cross-sectional side view of the rotary type switching valve of the press, FIG. 4B is a cross-sectional view taken along line AA of FIG. 4A, and FIG. 5 is a water spray header of the screw press according to Embodiment 1 of the present invention. It is typical structure explanatory drawing which shows the installation state of.

  Reference numeral 1 shown in FIG. 1 is a screw press according to Embodiment 1 of the present invention, and this screw press 1 is horizontally mounted by front and rear frames 2 and 3. Inside the cylindrical screen 4 in which a screen for separating sludge (dehydrated cake) having a pore diameter of about 0.7 to 1.5 mm and moisture (filtered water) is stretched around the periphery, one end side (sludge supply) The screw 5 is composed of a screw shaft 7 having a small diameter and gradually increasing in diameter toward the other end (dehydrated cake discharge side), and screw blades 6 spirally arranged on the screw shaft 7. A sludge pressurizing chamber 1a is formed. The cylindrical screen 4 is divided into a cylindrical screen 4a in the concentration zone in the first half and a cylindrical screen 4b in the filtration / dehydration zone in the second half, and a bearing 8 is provided between these cylindrical screens 4a and 4b. It is intervened.

A flange 11 is provided on the start end side of the cylindrical screen 4 a in the concentration zone in the front half, and this flange 11 is rotatably supported by a rotary plate bearing 12 fixed to the frame 2. Further, a sprocket 14 is provided on a thrust receiver 13 provided on the flange 11, and the sprocket 14 is rotated forward and backward by a forward / reverse drive machine 15, whereby the cylindrical screen 4 a in the concentration zone is forward / reverse. It is configured to be rotated.
The sludge supplied to the sludge pressurizing chamber 1a is pressurized in this concentration zone, and the water is discharged outside the cylindrical screen 4a, so that the sludge is concentrated to some extent (solid-liquid separation) and concentrated. The sludge that has been transferred is transferred to the filtration / dehydration zone in the latter half, and is further pressurized and moisture is discharged to the outside of the cylindrical screen 4b, thereby being filtered and dehydrated.

  A washing water pipe 20 is provided above the cylindrical screen 4 in the concentration zone and the filtration / dehydration zone. This washing water pipe 20 injects high-pressure washing water from a plurality of washing nozzles (not shown) provided at predetermined intervals along the longitudinal direction toward the cylindrical screen 4, thereby filtering performance of the cylindrical screen 4. In order to prevent the deterioration of the clogging, the clogging substance is periodically removed. Further, a supply pipe 21 for supplying sludge is connected to the start end side of the screw shaft 7 provided in the cylindrical screen 4, and the bearing portion 21a of the supply pipe 21 is fitted to the cylindrical screen 4a in the concentration zone. It is pivotally supported on the inner peripheral surface of the worn flange 11.

  A bearing unit 23 in which a drive shaft 22 provided at the rear end of the large-diameter side (dehydrated cake discharge side) of the screw shaft 7 is fixed to the frame 3, and a bearing unit 25 provided in a frame 24 of the screw shaft 7; Is supported by A sprocket 26 is provided on the drive shaft 22, and the screw shaft 7 is rotated by rotating the sprocket 26 with a rotary drive machine 27. The supply pipe 21 connected to the front end portion of the screw shaft 7 is provided with a sludge supply path 28, and this supply path 28 passes through the inside of the screw shaft 7, and the start end portion of the cylindrical screen 4 of the screw shaft 7. It communicates with the supply hole 28a that opens to the top.

  That is, the sludge is supplied from the supply hole 28 a between the screw blades 6 wound around the screw shaft 7, and the agglomerated soft sludge is not affected by the screw blades 6. Further, a presser 30 is opposed to the outer position of the discharge port 29 at the final end of the cylindrical screen 4. More specifically, the presser 30 is suspended from the moving shaft 31, and an air cylinder 32 provided at the rear end of the presser 30 applies back pressure to the dehydrated cake via the cone portion 30 a of the presser 30. However, the opening amount of the discharge port 29 is adjusted.

  As shown in FIG. 2, a scraper 33 made of an elastic member having elasticity such as rubber is provided at the tip of the screw blade 6 from the start end of the concentration zone of the screw blade 6 to the end of the filtration / dehydration zone. 34 and a nut 35. The scraper 33 is elastically slidably contacted with the inner peripheral surface of the cylindrical screen 4, and the filtered water is separated from the cylindrical screen 4 a in the concentration zone in which clogging is prevented by the scraper 33, and concentrated. By increasing the amount of sludge supplied in the zone and scraping the dehydrated cake layer on the micropores of the cylindrical screen 4b of the filtration / dehydration zone for supplying concentrated sludge, high dehydration is performed. .

  In the case of the screw press 1 according to the first embodiment of the present invention, the main configuration is the same as that of the screw press according to the conventional example 1 as well understood from the description related to the above configuration. It is. In the case of the screw press 1 according to the first embodiment of the present invention, as shown in FIG. 3, the screw shaft 7 is provided from the bearing unit 25 of the drive shaft 22 provided at the rear end portion on the large diameter side of the screw shaft 7. A swivel joint 36 having a known configuration is attached to the protruding end.

  The swivel joint 36 communicates with an inorganic flocculant supply line 37 for supplying a constant amount of inorganic flocculant such as polyferric sulfate per one rotation or one stroke discharged from one constant displacement pump P. is doing. More specifically, the inorganic flocculant supply line 37 is provided with a flow meter 37a and a rotary switching valve 38, which will be described later, in that order from the constant capacity pump P side. The supply port communicates with the swivel joint 36 via the pressure reducing valve 39. The flocculant reservoir 6 a provided on the back surface of the screw blade 6 (the surface on the small diameter side of the screw shaft 7) from the swivel joint 36 is installed in the drive shaft 22 and the screw shaft 7. The inorganic flocculant flow path 7a communicates, and the inorganic flocculant that has flowed into the flocculant reservoir 6a is supplied to an inorganic flocculant supply header 40 configured as described later.

  As shown in FIGS. 4A and 4B, the rotary switching valve 38 includes a valve body 38a. The valve main body 38a is provided with one inflow port 38b through which the inorganic flocculant flows, and flows in from the inflow port 38b in four directions orthogonal to the center line CL passing through the radial center of the inflow port 38b. Four supply ports 38c for discharging the inorganic flocculant are extended. Further, in this valve body 38a, an inorganic flocculant which is rotationally driven by a motor 38f with a reduction gear attached to the outside of the valve body 38a and flows in from the inflow port 38b is periodically supplied to the supply port 38c. A cylindrical switching valve body 38d having one outflow hole 38e to be discharged is accommodated. According to the rotary switching valve 38, the inorganic flocculant flows out from the supply port 38c once every time the switching valve body 38d rotates once. Accordingly, the inorganic flocculant flowing out from the respective supply ports 38c of the rotary type switching valve 38 is periodically supplied to the respective inorganic flocculant channels 7a and then depressurized to a predetermined pressure set by the pressure reducing valve 39. Then, it is supplied to the inorganic flocculant supply header 40 through the swivel joint 36 and the inorganic flocculant supply line 37.

  The outflow hole 38e of the switching valve body 38d of the rotary type switching valve 38 operates as a safety valve due to an increase in pressure when the pipe is closed. It is set to a dimension that allows communication. By setting the size of the outflow hole 38e as described above, when the outflow hole 38e of the switching valve body 38d is at an intermediate position between two adjacent supply ports 38c, the set pressure of the pressure reducing valve 39 on each downstream side is adjusted. As a result, the flow rate of each inorganic flocculant can be slightly adjusted.

  The inorganic flocculant supply header 40 is within a range of 1/3 to 2/3 from the small diameter side (sludge supply side) of the screw shaft 7, more specifically, from 2 pitches on the starting end side of the screw blade 6. An intermediate position (1/2 position of the blade length) of the blade height of the front surface of the screw blade 6 at the pitch (the surface on the large diameter side of the screw shaft 7) protrudes in parallel with the axis of the screw shaft 7 It has become. Injection holes 41 for injecting the inorganic flocculant are provided at several locations (100 to 200 mm pitch) on the side surface of the inorganic flocculant supply header 40. In this case, several injection holes 41 on the side surface are provided on the counter-rotating direction side of the screw shaft 7 so as to inject the inorganic flocculant in the sludge flow direction (tangential direction of the diameter of the screw shaft). It is configured.

According to the said structure, since it is not necessary to provide the line mixer which mixes a flocculant in sludge, it can contribute to the cost reduction of the sludge dehydration apparatus provided with the screw press, and it is 1 / from the sludge supply hole side of the screw shaft 7. The range of 3 to 2/3 is a range including the boundary between the concentration zone and the filtration / dehydration zone, and the sludge has a favorable fluidity for mixing the inorganic flocculant, and has such a desirable fluidity. The inorganic flocculant is injected from the injection holes 41 of the plurality of inorganic flocculant supply headers 40 between the screw blades 6 and in an intermediate region between the inner peripheral surface of the cylindrical screen 4 and the outer peripheral surface of the screw shaft 7. Therefore, the inorganic flocculant is effectively mixed and mixed in the sludge.
Therefore, since the whole sludge aggregates equally, it can dehydrate effectively and can obtain the effect that the processing efficiency of sludge improves.

  By the way, in the case of the screw press 1 according to Embodiment 1 of the present invention, as described above, the inorganic flocculant supply header 40 protrudes at a position that is 1/2 of the blade length of the most preferable screw blade 6. However, a preferable position is 1/5 to 4/5 of the blade height of the screw blade 6, and a more preferable position is 2/5 to 3/5. That is, for example, when the inorganic flocculant supply header 40 protrudes at a position near 1/5 or 4/5 of the blade height, the sludge is more than when it protrudes at a position 1/2 of the blade height. The uniformity of the mixing of the inorganic flocculant into the inside decreases. However, since the inorganic flocculant is uniformly mixed in the sludge as it is, it has been confirmed that the sludge aggregation and sludge treatment capacity are acceptable and practical.

The inorganic flocculant is a central region between the screw blades 6, between the inner peripheral surface of the cylindrical screen 4 and the outer peripheral surface of the screw shaft 7, and in a range sandwiching the boundary between the concentration zone and the filtration / dehydration zone In the range which has the preferable fluidity in, it is supplied in the sludge.
Such inorganic flocculant supply headers 40 are projected at four locations per pitch of the screw blades 6 (90 ° intervals with respect to the rotation center of the screw 5), and a total of eight inorganic flocculant supply headers 40 are provided.

  Further, in the case of the screw press 1 according to Embodiment 1 of the present invention, the outer peripheral surface of the screw shaft 7 of the screw 5 and the front surface and the back surface of the screw blade 6 excluding the scraper 33 can prevent sludge from adhering. It is covered with a liner 42 made of a synthetic resin having a friction coefficient. As for the synthetic resin of this liner 42, the surface layer (layer which contacts sludge) which consists of a polytetrafluoroethylene (PTFE) sheet | seat, and the back surface layer (layer which contacts a screw shaft and a screw blade) which consist of rubber sheets are laminated | stacked. This is a two-layer sheet. Further, although not shown, the surface of the cone portion 30a of the presser 30 is also covered with a synthetic resin composed of the same two-layer sheet as the synthetic resin of the liner 42.

  The two-layer sheet is fixed with an adhesive or integrally molded (for example, “Nevaran xF” manufactured by Tohoku Rubber Co., Ltd.). Further, the two-layer sheet, the screw shaft 7 and the screw blade 6 are fixed with an adhesive. As a result, a rubber sheet is interposed between the outer peripheral surface of the screw shaft 7 and the front and back surfaces of the screw blade 6, and the non-adhesive polytetrafluoroethylene sheet having a low friction coefficient with the metal screw shaft or screw blade. It is preferable that a non-adhesive synthetic resin having a low friction coefficient can be easily coated and a structure having excellent durability can be obtained. In addition, although the surface layer used what consists of a polytetrafluoroethylene sheet as the liner 42, it is not restricted to this. For example, fluorine-based synthetic resin sheets such as polytetrafluoroethylene / perfluoroalkyl vinyl ether copolymer (PFE) and tetrafluoroethylene / hexafluoropropylene copolymer (FEP) can be used.

By the way, in the case of the screw press 1 according to the first embodiment, as described above, the injection holes 41 are provided at the three positions on the side surface of the inorganic flocculant supply header 40. Since the number may be four or more, the number of the injection holes 41 is not particularly limited.
In addition, a plurality of inorganic flocculant supply headers 40 having one injection hole 41 having different lengths are bundled, and one inorganic flocculant supply header 40 having a plurality of injection holes 41 as described above, A configuration having a similar function is also possible. Further, although the flocculant supply header 40 protrudes at four places per pitch of the screw blades 6, it may be five or more, or may be three places. It is not limited.

  The flocculant supply header 40 is formed in a straight shape, but the tip of the inorganic flocculant supply header 40 may be bent in the moving direction of the sludge interposed between the screw blades 6. In addition, it may be curved so as to bend in the moving direction of the sludge interposed between the screw blades 6 from the base end side toward the tip end side. By bending the inorganic flocculant supply header 40 in this way, the effect of reducing the amount of hair residue, lint, and other residue that is contained in the sludge to the inorganic flocculant supply header 40 can be reduced. Can be obtained. Thereby, there is no trouble in the movement of the sludge, and the stable operation of the screw press 1 can be continued for a long time.

  Furthermore, in the screw press 1 according to Embodiment 1 of the present invention, as shown in FIG. 5, the cylindrical shape of the filtration / dehydration zone is positioned above the cylindrical screen 4 b of the filtration / dehydration zone of the cylindrical screen 4. The screen 4b is provided with a watering header 51 having a plurality of watering holes for spraying water like a shower. More specifically, a watering header 51 having a length equivalent to that of the cylindrical screen 4b of the filtration / dehydration zone is directly above the center line passing through the radial center of the cylindrical screen 4b of the filtration / dehydration zone. These are arranged in parallel with the cylindrical screen 4b of the filtration / dehydration zone. The washing water pipe 20 is disposed not directly above the center line passing through the radial center of the cylindrical screen 4b in the filtration / dehydration zone, but above one of the left and right eccentric positions.

  The watering header 51 is provided at a position above the watering header 51, and a water inflow pipe 53 communicates with a water storage tank 52 that is a water supply source. That is, by opening the on-off valve 53 a, the stored water (industrial water or the like) in the water storage tank 52 is configured to flow into the watering header 51 via the water inflow pipe 53 due to the head difference. During the dewatering of the sludge by the screw press 1, water is continuously supplied to the watering header 51, and water is sprayed in a shower shape on the cylindrical screen 4b in the filtration / dewatering zone. That is, during sludge dewatering, water is constantly sprayed or intermittently sprayed on the cylindrical screen 4b.

  In this way, water is sprayed onto the cylindrical screen 4b in the filtration / dehydration zone by the watering header 51 because of the location of the inorganic flocculant supply header 40, the cylindrical screen 4a in the concentration zone in the first half. This is because the ferric sulfate is not supplied to the sludge, and the ferric sulfate does not flow out from the fine holes of the cylindrical screen 4a in the concentration zone. In the case of the screw press 1 according to Embodiment 1 of the present invention, as described above, the stored water (industrial water or the like) flows from the water storage tank 52 into the watering header 51. It is also possible to supply industrial water to the watering header 51 directly from the commercial water supply.

  By the way, in the screw press 1 which concerns on Embodiment 1 of this invention, as above-mentioned, although it is comprised so that it may sprinkle from the sprinkling header 51 to the cylindrical screen 4b of a filtration and a dehydration zone, The cylindrical screen 4 including the cylindrical screen 4a in the concentration zone may be configured to spray water. Since the ferric sulfate does not flow out from the micropores of the cylindrical screen 4a in the concentration zone in the first half, it seems to be useless because it does not contribute to the cleaning of the ferric sulfate. However, since the sludge flowing out from the fine holes can be removed, it is possible to contribute to the extension of the cleaning operation interval of the cylindrical screen 4 by the cleaning water pipe 20 performed by stopping the operation of the screw press 1. Useful.

  In addition, in the case of the watering header 51 of the screw press 1 according to Embodiment 1 of the present invention, as described above, it has the same length as the cylindrical screen 4b of the filtration / dehydration zone. Water is sprayed from the water spray holes to the cylindrical screen 4b in the filtration / dehydration zone. However, the present invention is not limited to this configuration, and for example, a configuration can be adopted in which a watering header having a small number of watering holes is reciprocated in the longitudinal direction of the cylindrical screen 4b in the filtration / dehydration zone. Further, although the washing water pipe 20 by high-pressure water injection at the time of sludge dehydration stop and the sprinkling header 51 at the time of dewatering are separately provided, the washing water pipe 20 by high-pressure water injection at the time of dewatering sludge dewatering It is possible to use it. In this case, what is necessary is just to comprise so that it can sprinkle with the pressure of the grade which water comes out from the washing water pipe | tube 20 washing nozzle.

Hereinafter, the operation mode of the screw press 1 according to Embodiment 1 of the present invention will be described.
That is, according to the screw press 1 according to the first embodiment of the present invention, as described above, the inorganic flocculant passes from the injection hole 41 of the inorganic flocculant supply header 40 to between the screw blades 6 and between the cylindrical screen 4. Periodically supplied to sludge in a central region between the inner peripheral surface and the outer peripheral surface of the screw shaft 7 and having a preferable fluidity in a range sandwiching the boundary between the concentration zone and the filtration / dehydration zone. Is done. Therefore, it is not necessary to provide a line mixer for mixing the inorganic flocculant into the sludge, which can contribute to the cost reduction of the sludge dewatering device equipped with a screw press.

  Further, according to the screw press 1 according to Embodiment 1 of the present invention, the inorganic flocculant is passed through the swivel joint 36 provided at the end of the screw shaft 7 of the screw 5 on the sludge discharge hole side or sludge supply hole side. And supplied to the inorganic flocculant supply header 40. Thereby, since the inorganic flocculant can be supplied to an arbitrary position of the sludge in which the concentration inside the screw press 1 has progressed, the inorganic flocculant can be used effectively, and the maintenance management space around the screw press Can be secured and the number of equipment can be reduced.

  Since the mounting positions of the multiple inorganic flocculant supply headers are shifted in the longitudinal direction of the screw shaft, the dehydrated cakes around the multiple inorganic flocculant supply headers have different moisture contents and different hardness. There is a difference in back pressure at the time. However, the inorganic flocculant having a pressure corresponding to the back pressure can be supplied by appropriately setting the degree of pressure reduction by the pressure reducing valve 39. Therefore, according to the screw press 1 according to the first embodiment of the present invention, the inorganic flocculant supplied to the inorganic flocculant supply header 40 is not excessively or deficient, and the screw shaft of the entire length of the screw 5 is obtained. 7, the sludge within the range of 1/3 to 2/3 from the sludge supply hole side is reliably agglomerated and dehydrated, and the inorganic flocculant is not wasted.

  Further, according to the screw press 1 according to the first embodiment of the present invention, as described above, the outer peripheral surface of the screw shaft 7 and the front and back surfaces of the screw blades 6 have a friction coefficient that can prevent the adhesion of sludge. It is covered with a two-layer sheet in which a surface layer made of a fluoroethylene sheet (a layer in contact with sludge) and a back layer made of a rubber sheet (a layer in contact with a screw shaft and screw blades) are laminated. Therefore, ferric sulfate is added in the sludge pressurizing chamber 1a, and the sludge is discharged outside the apparatus without adhering to the outer peripheral surface of the screw shaft 7 and the front and back surfaces of the screw blades 6. Therefore, unlike the conventional screw press, the sludge passage area does not gradually narrow, and the sludge dewatering performance does not deteriorate. Moreover, since it is not necessary to remove the solidified layer of sludge from the outer peripheral surface of the screw shaft 7 and the front and back surfaces of the screw blades 6, it is possible to prevent the operating rate of the screw press 1 from being lowered and the maintenance cost from being increased.

  Further, in the screw press 1 according to the first embodiment of the present invention, the surface of the cone portion 30a of the presser 30 has a two-layer sheet made of the same material as the liner 42, that is, a friction coefficient that can prevent adhesion of sludge. It is covered with a two-layer sheet in which a surface layer made of a polytetrafluoroethylene sheet (a layer in contact with sludge) and a back surface layer made of a rubber sheet (a layer in contact with the surface of the cone portion) are laminated. Therefore, according to the screw press 1 according to the first embodiment of the present invention, sludge adheres to the surface of the cone portion 30a of the presser 30 and does not obstruct the discharge of the dehydrated cake, and is suitable for the dehydrated cake. Since the dewatered cake can be discharged from the discharge port 29 while applying pressure, stable operation is possible.

  Moreover, according to the screw press 1 which concerns on Embodiment 1 of this invention, by sprinkling water from the sprinkling header 51 to the cylindrical screen 4b of the filtration / dehydration zone, from the fine holes of the cylindrical screen 4b of the filtration / dehydration zone. In addition to inorganic flocculants such as ferric sulfate that flows out with the filtered water, part of the sludge and residue is washed away. Therefore, the fine pores of the cylindrical screen 4b in the filtration / dehydration zone are not narrowed by the inorganic flocculant such as polyferric sulfate, and sludge is caused by clogging of the inorganic flocculant such as polyferric sulfate. Since the dewatering efficiency of the liquid is not reduced, it is possible to extend the cleaning interval of the normal cylindrical screen 4 by jetting high-pressure water for removing clogged sludge and residue from the fine holes. The running cost of the screw press 1 can be reduced and the amount of sludge treated can be further increased. In addition, although the pressure in the sludge pressurization chamber 1a of the screw press 1 is different depending on the model, it is 10 to 15 kPa, for example, and has a high pressure. It has been confirmed that the moisture content of the dehydrated cake does not deteriorate.

  In addition, in the screw press 1 which concerns on the above Embodiment 1, the case where the inorganic flocculant supply header 40 protruded only on the front side of the screw blade 6 as described above was described as an example. However, the present invention is not limited to this configuration, and for example, the inorganic flocculant supply header 40 can be protruded only on the back side of the screw blade 6, and the intermediate screw blade 6 out of the two pitches of the screw blade 6. In this case, the inorganic flocculant supply header 40 can be alternately provided on the front side and the back side.

A screw press according to Embodiment 2 of the present invention will be described with reference to the accompanying drawings.
FIG. 6 is an explanatory view of the installation state of the inorganic flocculant supply header of the screw press according to Embodiment 2 of the present invention, and FIG. 7 is a cross-sectional view at the injection hole position of the inorganic flocculant supply header. In addition, the place where the screw press which concerns on Embodiment 2 of this invention differs from the screw press which concerns on the said Embodiment 1 exists in the difference in the arrangement position and direction of an inorganic flocculant supply header, and other than that, it is completely the above Since it is the same structure as Embodiment 1, it attaches | subjects the same code | symbol to what has the same thing and the same function, and demonstrates with the same name.

  The inorganic flocculant supply header 40 of the screw press according to the second embodiment of the present invention is within the range of 1/3 to 2/3 from the small diameter side of the screw shaft 7, more specifically, the start end of the screw blade 6. Four pairs are provided per circumference in the circumferential direction of the outer circumferential surface of the screw shaft 7 from 2 to 4 pitches on the side, and project radially from the axis of the screw shaft 7 at 90 ° intervals. The pair of inorganic flocculant supply headers 40 are equally arranged in one pitch, and the total number of inorganic flocculant supply headers 40 provided on the screw 5 is sixteen. An injection hole 41 for injecting the inorganic flocculant is provided on the side surface of the inorganic flocculant supply header 40. The height of the inorganic flocculant supply header 40 from the base end of the injection hole 41 is ½ of the blade height of the most preferable screw blade 6, but the preferable height is ５ of the blade height of the screw blade 6. It is ˜4 / 5, and a more preferable height is 2/5 to 3/5.

  In this case, two injection holes 41 for injecting the inorganic flocculant are provided in the circumferential direction of the inorganic flocculant supply header 40, and the injection direction is a tangential direction of the diameter of the screw shaft 7 and the adjacent injections. The angle θ formed by the injection direction of the inorganic flocculant injected from the hole 41 is set to be 60 °, for example. The inorganic flocculant is a central region between the screw blades 6 and between the inner peripheral surface of the cylindrical screen 4 and the outer peripheral surface of the screw shaft 7, and is a boundary between the concentration zone and the filtration / dehydration zone. It is supplied into the sludge within a range having preferable fluidity in a range where the slag is sandwiched.

  In the case of the second embodiment, as described above, two injection holes 41 are provided in the circumferential direction of the side surface of the inorganic flocculant supply header 40, but at least three locations in the longitudinal direction. However, the number of the injection holes 41 is not particularly limited because one piece may be provided in the circumferential direction. Further, although the flocculant supply header 40 protrudes from four locations in the circumferential direction of the screw shaft 7, it may be five or more or three locations. It is not limited.

  Further, the flocculant supply header 40 is formed in a straight shape, but the tip of the inorganic flocculant supply header 40 may be bent in the moving direction of the sludge interposed between the screw blades 6. In addition, it may be curved so as to bend in the moving direction of the sludge interposed between the screw blades 6 from the base end side toward the tip end side. By bending the inorganic flocculant supply header 40 in this way, as in the case of the first embodiment, the hair residue and the lint such as lint contained in the sludge to the inorganic flocculant supply header 40 are obtained. The effect that the amount of catching can be reduced is obtained.

  Hereinafter, the operation mode of the screw press 1 according to the second embodiment of the present invention will be described. The inorganic flocculant is interposed between the screw blades 6 by the inorganic flocculant supply header 40, the inner peripheral surface of the cylindrical screen 4, and the screw. It is fed into the sludge in a central region between the outer peripheral surface of the shaft 7 and having a preferable fluidity in a range sandwiching the boundary between the concentration zone and the filtration / dehydration zone. Therefore, the screw press according to Embodiment 2 of the present invention can obtain the same effect as the screw press according to Embodiment 1 described above.

  In the screw press 1 according to Embodiments 1 and 2 described above, the case where the switching valve is a rotary switching valve has been described as an example, but the present invention is not limited to the rotary switching valve, and a plurality of supplies Any switching valve may be used as long as it has a port and can sequentially supply the flocculant to each supply port. In the screw press 1 according to the first and second embodiments, the sludge mixed with the polymer flocculant is supplied from the small diameter side (sludge supply side) of the screw shaft, and the inorganic flocculant is supplied to the large diameter of the screw shaft. The case where it supplies from the side (dehydrated cake discharge | emission side) was demonstrated as an example. However, the present invention is not limited to the configuration of the screw press 1 according to Embodiments 1 and 2, and design changes and the like can be freely made without departing from the technical idea of the present invention.

  Furthermore, in the screw press 1 according to the first and second embodiments, the screen has a cylindrical shape (the same diameter from the sludge supply side to the dewatered cake carry-out side), and the shaft diameter of the screw shaft is changed. However, it is also possible to adopt a configuration in which the screen has a conical shape (diameter reduced from the sludge supply side to the dewatered cake carry-out side) and the screw shaft has the same diameter. In the screw press 1 according to the first and second embodiments described above, the liner 42 has a configuration in which the surface layer is made of a polytetrafluoroethylene sheet and the back layer is made of a rubber sheet. It may be a single member having a coefficient, and in short, the structure in which the surface of the screw shaft, screw blades or presser cone contacted with sludge is covered with a layer (member) with a low coefficient of friction that can prevent sludge from adhering during dehydration. There may be.

It is a partial longitudinal cross-sectional side view of the screw press which concerns on Embodiment 1 of this invention. It is a partial vertical side view of the scraper attached to the screw blade | wing of the screw press which concerns on Embodiment 1 of this invention. It is explanatory drawing of the installation state of the inorganic flocculant supply header of the screw press which concerns on Embodiment 1 of this invention, and the arrangement | positioning state of a liner. 4 (a) is a side view showing a partial cross section of the rotary type switching valve of the screw press according to Embodiment 1 of the present invention, and FIG. 4 (b) is a cross sectional view taken along line AA of FIG. 4 (a). . It is typical structure explanatory drawing which shows the installation state of the watering header of the screw press which concerns on Embodiment 1 of this invention. It is installation state explanatory drawing of the inorganic flocculant supply header of the screw press which concerns on Embodiment 2 of this invention. It is sectional drawing in the injection hole position of the inorganic flocculant supply header concerning Embodiment 2 of this invention. It is a partial longitudinal cross-sectional side view of the screw press which concerns on the prior art example 1. FIG. It is a partial longitudinal cross-sectional side view of the scraper attached to the screw blade | wing of the screw press which concerns on the prior art example 1. FIG. It is a schematic longitudinal cross-sectional view of the principal part of the screw press which concerns on the prior art example 2. FIG. It is explanatory drawing of the adhering state of sludge (dehydrated cake).

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Screw press, 1a ... Sludge pressurization chamber, 2 ... Frame, 3 ... Frame, 4 ... Cylindrical screen, 4a ... Concentrated zone cylindrical screen, 4b ... Filtration / dehydration zone cylindrical screen, 5 ... Screw, DESCRIPTION OF SYMBOLS 6 ... Screw blade, 7 ... Screw shaft, 7a ... Inorganic flocculant flow path, 8 ... Bearing 11 ... Flange, 12 ... Rotary bearing, 13 ... Thrust receiver, 14 ... Sprocket, 15 ... Forward / reverse driving machine 20 ... Washing water pipe, DESCRIPTION OF SYMBOLS 21 ... Supply pipe, 22 ... Drive shaft, 23 ... Bearing unit, 24 ... Mount, 25 ... Bearing unit, 26 ... Sprocket, 27 ... Rotary drive, 28 ... Sludge supply path, 29 ... Discharge port 30 ... Presser, 30a ... Cone part,
DESCRIPTION OF SYMBOLS 31 ... Moving shaft, 32 ... Air cylinder, 33 ... Scraper, 34 ... Bolt, 35 ... Nut, 36 ... Supply swivel joint, 37 ... Inorganic flocculant supply line, 37a ... Flow meter, 38 ... Rotary type switching valve, 38a ... Valve body, 38b ... Inflow port, 38c ... Supply port, 38d ... Switching valve body, 38e ... Outflow hole, 38f ... Motor with speed reducer, 39 ... Pressure reducing valve 40 ... Inorganic flocculant supply header, 41 ... Injection hole, 42 ... Liner 51 ... Sprinkling header, 52 ... Water storage tank, 53 ... Water inflow pipe, 53a ... Open / close valve P ... Constant displacement pump

Claims (3)

  Inside the cylindrical screen, a sludge pressurizing chamber is formed in which a screw shaft that is rotated by a driving device and a screw blade that is spirally disposed on the screw shaft is housed. The sludge supplied into the sludge pressurizing chamber is pressurized from the sludge supply hole provided on one end side of the pressurizing chamber while being transferred to the other end side of the sludge pressurizing chamber, and a part of the sludge containing water is piped In a screw press that is separated into a dehydrated cake by a screen and discharged from a dehydrated cake discharge port provided at the other end of the sludge pressurizing chamber, the sludge supply hole side of the screw shaft of the full length of the screw Injection holes for supplying an inorganic flocculant in the region between the screw blades within the range of 1/3 to 2/3 and between the inner peripheral surface of the cylindrical screen and the outer peripheral surface of the screw shaft. A plurality of inorganic flocculant supply headers, a plurality of inorganic flocculant supply passages for supplying the inorganic flocculant to the inorganic flocculant supply headers are provided in the screw shaft, and one end side is a constant capacity pump. One switching valve having a plurality of supply ports is connected to the other end side of the inorganic flocculant supply line connected to the plurality of inorganic flocculant supply channels, and a plurality of supply ports of the switching valve are connected to each of the plurality of inorganic flocculant supply channels. A screw press characterized in that the inorganic flocculant can be periodically supplied.   A swivel joint that communicates a plurality of supply port sides of the switching valve to the inorganic flocculant supply flow path is provided at an end of the screw shaft on the dewatering cake discharge port side or sludge supply hole side. Item 2. A screw press according to Item 1.   The screw press according to any one of claims 1 and 2, wherein the switching valve is a rotary switching valve.

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