JP2004313820A - Dehydrator, oil circulation system, dehydration system and dehydration method for sludge - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a dehydrator capable of enhancing the dehydration efficiency at a low production cost by using a means other than vapor, and to provide a dehydration system having the dehydrator. <P>SOLUTION: The dehydration system P1 has the dehydrator A, an oil circulation system B and a sludge supplying system C, and is constituted in such a manner that oil is supplied into a screw shaft body part 42 of a screw shaft 40 in the dehydrator A while being circulated by the oil circulation system B. That is, the oil is supplied into the screw shaft body part 42 via a hole part disposed on a shaft part of the screw shaft body part 42. By supplying the heated oil into the screw shaft body part 42, it is made possible that the sludge is heated and the dehydration efficiency is enhanced. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a dewatering device for dewatering sludge.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there is known a dewatering apparatus that dewaters sludge with a cover provided with a large number of holes and discharges the sludge as cake while feeding sludge by thrust of a screw shaft.
[0003]
Further, there is a method in which heated steam is fed into a screw shaft to heat the screw shaft from the inside, thereby lowering the filtration resistance of water and improving the dewatering efficiency. Further, in a conventional sludge dryer, there is a sludge dryer provided with a steam jacket and supplying heated steam to a screw blade (for example, see Patent Document 1).
[0004]
[Patent Document]
Japanese Patent No. 3196172 (FIG. 1 etc.)
[0005]
[Problems to be solved by the invention]
However, when heating steam is used, there is a problem that temperature control is difficult, and the manufacturing cost is high as a whole.
[0006]
Therefore, an object of the present invention is to provide a dehydrator capable of improving dehydration efficiency at a low manufacturing cost by using a method other than steam.
[0007]
[Means for Solving the Problems]
SUMMARY OF THE INVENTION The present invention has been made to solve the above problems. First, there is provided a screw press type dewatering apparatus for dewatering sludge, wherein an oil flow for flowing oil inside is provided. It is characterized by having a screw shaft having a path.
[0008]
In the dewatering device of the first configuration, since an oil flow path for flowing oil is provided inside the body of the screw shaft, the heated oil is supplied to the oil flow path while circulating. I do. Then, by heating the sludge to be dewatered, the filtration resistance of the sludge is reduced, and the water in the sludge is easily drained, thereby improving the dewatering efficiency. Furthermore, by heating the sludge, water adhering to the surface of the flocculated floc due to the viscosity of the flocculated floc itself can be easily drained, and pore water between the flocculated flocs can be easily drained. This also improves the dewatering efficiency. In addition, since the sludge is heated by the heated oil, the temperature control of the oil is easier than that of steam, and the temperature control device is cheaper than that of steam, and a system that circulates oil is included. The manufacturing cost of the entire system can be reduced.
[0009]
Secondly, there is provided a screw press type dewatering device for dewatering sludge, a body having an oil flow path for flowing oil therein, and a spiral provided on the surface of the body. And a screw shaft having the shape of a screw blade.
[0010]
In the dewatering device of the second configuration, since an oil flow path for flowing oil is provided inside the body of the screw shaft, the heated oil is supplied to the oil flow path while circulating. I do. Then, by heating the sludge to be dewatered, the filtration resistance of the sludge is reduced, and the water in the sludge is easily drained, thereby improving the dewatering efficiency. Furthermore, by heating the sludge, water adhering to the surface of the flocculated floc due to the viscosity of the flocculated floc itself can be easily drained, and pore water between the flocculated flocs can be easily drained. This also improves the dewatering efficiency. In addition, since the sludge is heated by the heated oil, the temperature control of the oil is easier than that of steam, and the temperature control device is cheaper than that of steam, and a system that circulates oil is included. The manufacturing cost of the entire system can be reduced.
[0011]
Thirdly, a screw press type dewatering apparatus for dewatering sludge has an oil flow path for flowing oil therein, and a flow path for flowing oil into the oil flow path. A screw shaft having a body having an inlet, an outlet for allowing oil to flow out of the oil flow path, and a helical screw blade provided on a surface of the body is provided.
[0012]
In the dewatering device of the third configuration, an oil flow path for flowing oil is provided inside the body of the screw shaft, and an inlet and an outlet are provided. The heated oil is caused to flow in, the heated oil is caused to flow out from the outlet, and the heated oil is supplied to the oil flow path while circulating. Then, by heating the sludge to be dewatered, the filtration resistance of the sludge is reduced, and the water in the sludge is easily drained, thereby improving the dewatering efficiency. Furthermore, by heating the sludge, water adhering to the surface of the flocculated floc due to the viscosity of the flocculated floc itself can be easily drained, and pore water between the flocculated flocs can be easily drained. This also improves the dewatering efficiency. In addition, since the sludge is heated by the heated oil, the temperature control of the oil is easier than that of steam, and the temperature control device is cheaper than that of steam, and a system that circulates oil is included. The manufacturing cost of the entire system can be reduced.
[0013]
Fourth, in the third configuration, the body portion has a cylindrical portion and a body portion having a space portion as the oil flow passage therein, and the body portion extends along an axis of the body portion. In the provided shaft portion, a hole portion, a first opening portion as one opening portion is provided on an end surface of the shaft portion, and a second opening portion as the other opening portion faces the space. And a shaft portion provided with a hole portion, wherein a first opening provided on an end face of the shaft portion is provided on each end side of the body portion, and one first opening portion is provided. The inflow port is provided, and the other first opening serves as the outflow port.
[0014]
In the dewatering device of the fourth configuration, when oil flows in from one of the first openings, the oil flows out of the second opening communicating with the first opening and reaches the space of the main body. Then, the oil flowing in the space flows out from the other first opening. In this manner, the oil can flow in the body.
[0015]
Fifth, in the third configuration, the body portion has a cylindrical portion and a body portion having a space portion as the oil flow passage therein, and the body portion extends along an axis of the body portion. In the provided shaft portion, at least an end surface of the shaft portion is exposed from both ends of the main body portion, and a hole portion is provided at both ends of the shaft portion, and one opening portion is provided at the end surface of the shaft portion. A shaft provided with a first opening and a hole provided with a second opening, which is the other opening, facing the inside of the space; and a pair of first openings, One of the first openings serves as the inflow port, and the other first opening serves as the outflow port.
[0016]
In the dehydration device having the fifth configuration, when oil flows in from one of the first openings, the oil flows out from the second opening communicating with the first opening and reaches the space of the main body. Then, the oil flowing in the space flows out of the other first opening through the other second opening. In this manner, the oil can flow in the body.
[0017]
Sixth, in the fourth or fifth configuration, the dewatering device may further include a second shaft fixed to an end of the screw shaft, and the dewatering device may be disposed on an axis of the second shaft. A second shaft portion having an insertion hole communicating with the hole portion provided in the shaft portion, and a transmission member fixed to the second shaft portion, the driving member driving the dehydrating device. And a transmission member for transmitting the rotational force of the motor for performing the rotation to the second shaft portion.
[0018]
Thus, when the motor rotates, the transmission member rotates, and with the rotation of the transmission member, the second shaft portion rotates, thereby rotating the screw shaft. The insertion hole provided in the second shaft portion can be used as an oil flow path, and the oil flowing from the end of the insertion hole can flow into the body portion of the body after flowing out to the shaft portion.
[0019]
Seventh, in any one of the fourth to sixth configurations, the dewatering device has a rotary joint that is directly or indirectly connected to the shaft. This makes it possible to rotate the screw shaft while circulating and supplying oil to the screw shaft.
[0020]
Eighth, in the sixth configuration, a rotary joint is connected to an end of the second shaft, and an end of the body is connected to a side to which the second shaft is connected. Is characterized in that a rotary joint is connected to the end of the shaft at the opposite end. This makes it possible to rotate the screw shaft while circulating and supplying oil to the screw shaft.
[0021]
The following configuration may be adopted as a configuration dependent on the seventh configuration or the eighth configuration. That is, "the rotary joint is directly or indirectly connected to the shaft portion, and the rotating portion rotates with the rotation of the screw shaft, and the fixed portion connected to the rotating portion also rotates by the rotation of the screw shaft. And a non-fixing portion. "
[0022]
Ninth, in any one of the first to eighth configurations, the dewatering device may further include a filter formed by dehydration in a cylindrical filtration unit provided outside the screw shaft. It is characterized by having a filtration section provided with a hole for discharging.
[0023]
As a subordinate configuration of the ninth configuration, the diameter of the body of the screw shaft is formed so as to gradually increase from the supply side of the sludge to the discharge side thereof. May be formed uniformly from the supply side of the sludge to the discharge side. Further, as a configuration subordinate to the ninth configuration, the diameter of the body of the screw shaft is formed uniformly from the supply side of the sludge to the discharge side, and the inner diameter of the filtration unit is a supply of the sludge. It may be formed so that the diameter gradually decreases from the side toward the discharge side. Further, as a configuration subordinate to the ninth configuration, a diameter of a body portion of the screw shaft and an inner diameter of the filtration portion are uniformly formed from a supply side to a discharge side of sludge and provided on the screw shaft. The pitch of the screw blades may be formed so as to decrease from the supply side of the sludge to the discharge side.
[0024]
Further, in any of the first to ninth configurations, the body of the screw shaft may be formed in a tapered shape having a gradually increasing diameter from a sludge supply side to a sludge supply side. Good.
[0025]
A tenth aspect is an oil circulation system for supplying heated oil into a screw shaft in a screw press type dewatering device for dewatering sludge, comprising: an oil tank for storing oil; It has a heating device for heating the oil in the tank and a pump for pumping the oil.
[0026]
In the oil circulation system having the tenth configuration, the oil in the oil tank is heated by the heating device and pumped by the pump. Therefore, by connecting this oil circulating device to the dewatering device and supplying the oil to the inside of the screw shaft of the dewatering device, the sludge to be dewatered is heated, whereby the filtration resistance of the sludge is reduced and the water in the sludge is drained. Dehydration efficiency is improved. Furthermore, by heating the sludge, water adhering to the surface of the flocculated floc due to the viscosity of the flocculated floc itself can be easily drained, and pore water between the flocculated flocs can be easily drained. This also improves the dewatering efficiency. In addition, since the sludge is heated by the heated oil, the temperature control of the oil is easier than that of steam, and a device for controlling the temperature is cheaper than that of steam. Can be reduced.
[0027]
Eleventh, a dewatering system for dewatering sludge, wherein the dewatering device having any one of the above-described first to ninth constitutions and heated oil are supplied to the dewatering device while circulating. An oil circulation system, comprising: an oil circulation system for flowing oil through an oil flow path provided in a body of a screw shaft of the dehydrator.
[0028]
Since the oil circulation system is provided in the dehydration system of the eleventh configuration, the oil circulation system supplies heated oil to the dehydrator. That is, the oil circulation system circulates and supplies the heated oil to the oil flow path provided inside the body of the screw shaft. Then, by heating the sludge to be dewatered, the filtration resistance of the sludge is reduced, and the water in the sludge is easily drained, thereby improving the dewatering efficiency. Furthermore, by heating the sludge, water adhering to the surface of the flocculated floc due to the viscosity of the flocculated floc itself can be easily drained, and pore water between the flocculated flocs can be easily drained. This also improves the dewatering efficiency. In addition, since the sludge is heated by the heated oil, the temperature control of the oil is easier than that of steam, and the device for controlling the temperature is cheaper than that of steam. Can be reduced.
[0029]
A twelfth aspect is a dewatering system for dewatering sludge, which has an oil flow path for flowing oil therein, and an inflow port for flowing oil into the oil flow path; A dehydration device comprising a body having an outlet for allowing oil to flow out of the oil flow path, and a screw shaft having a helical screw blade provided on the surface of the body, An oil circulation system for causing heated oil to flow into the inflow port of the dehydrating device, and causing the oil to flow out of the outflow port to circulate the oil.
[0030]
In the twelfth dehydration system, an oil circulation system is provided, and the oil circulation system supplies heated oil to the dehydrator. That is, the oil circulation system causes the heated oil to flow into the inflow port of the dewatering device, and causes the oil to flow out from the outflow port to circulate the oil. Then, by heating the sludge to be dewatered, the filtration resistance of the sludge is reduced, and the water in the sludge is easily drained, thereby improving the dewatering efficiency. Furthermore, by heating the sludge, water adhering to the surface of the flocculated floc due to the viscosity of the flocculated floc itself can be easily drained, and pore water between the flocculated flocs can be easily drained. This also improves the dewatering efficiency. In addition, since the sludge is heated by the heated oil, the temperature control of the oil is easier than that of steam, and the device for controlling the temperature is cheaper than that of steam. Can be reduced.
[0031]
In a thirteenth aspect, in the eleventh or twelfth aspect, the dewatering device further includes a hole for discharging a filtrate generated by dehydration in a cylindrical filtration part provided outside the screw shaft. It is characterized by having a filtered part.
[0032]
Fourteenth, in any one of the eleventh to thirteenth configurations, the oil circulation system may include an oil tank that stores oil, a heating device that heats the oil in the oil tank, and an oil tank. And a pump for pumping. Thus, the oil in the oil tank is heated by the heating device, and the heated oil is pumped by the pump and supplied to the dehydrating device.
[0033]
Fifteenth, in the fifteenth configuration, the oil circulation system further includes an oil temperature in the oil tank and / or an oil in an oil flow path provided between the dehydrator and the oil circulation system. And a control device for controlling the heating device in accordance with the temperature detected by the temperature detecting device.
[0034]
Thus, the temperature of the circulated oil can be controlled, and the circulated oil can be maintained at a predetermined temperature or higher or in a predetermined temperature range. In addition, for example, when the temperature detected by the temperature detection device is lower than the predetermined temperature, the control device heats the heating device until the temperature reaches the predetermined temperature. Further, when detecting both the temperature of the oil in the oil tank and the temperature in the oil flow path, one of the temperature of the oil in the oil tank and the temperature in the oil flow path has become lower than a predetermined temperature. In this case, the control device may control the heating device until both of them reach a predetermined temperature or higher.
[0035]
Sixteenth, in the fifteenth aspect, in the fifteenth configuration, the control device may be configured such that the temperature detected by the temperature detection device is within a temperature range equal to or higher than the boiling point of water and lower than the boiling point of oil. It is characterized in that the heating device is controlled so as to reach the temperature. Thereby, it is possible to appropriately perform temperature control.
[0036]
In a seventeenth aspect, in any one of the eleventh to sixteenth configurations, the oil circulation system is a pipe portion further connected to the dehydrating device for allowing oil to flow. It has a 1st pipe part and a 2nd pipe part which is a pipe part for making oil flow out in a pipe part connected to the above-mentioned dehydration device, It is characterized by the above-mentioned.
[0037]
Eighteenth, in any one of the eleventh to seventeenth configurations, the dewatering system may further be a sludge supply system for supplying sludge to the dewatering device, wherein the sludge and the coagulant may be used. Having a sludge supply system comprising: a coagulation mixing tank for mixing the mixture, a stirring device for stirring the object to be stirred in the coagulation mixing tank, and a feeding device for sending the sludge in the coagulation mixing tank to the dewatering device. Features.
[0038]
In the dewatering system of the eighteenth configuration, after the sludge and the flocculant are mixed in the flocculation mixing tank, the object to be stirred, that is, the mixture of the sludge and the flocculant, is stirred by the stirring device. Then, the sludge becomes coagulated floc. Then, the flocculated floc sludge is sent to the dewatering device by the feeding device. In this way, the sludge can be supplied to the dewatering device.
[0039]
Nineteenthly, in any one of the eleventh to eighteenth configurations, the dewatering system is a drying device for further drying sludge dewatered by the dewatering device, wherein the oil circulation system An oil flow path for flowing the circulated oil is provided, and a drying device for drying sludge by flowing heated oil through the oil flow path by the oil circulation system is provided.
[0040]
With this drying device, the sludge dewatered by the dehydrating device can be dried. In addition, since a system for heating the body of the screw shaft in the dehydrator can be used for drying sludge in the drying device, there is no need to separately provide a heat source for drying sludge in the drying device.
[0041]
A twentieth aspect is a sludge dewatering method in which sludge is dewatered by a screw press type dehydrator equipped with a screw shaft, wherein the first or second or third or fourth or fifth or sixth or seventh or eighth or eight or By supplying heated oil to the oil flow path in the screw shaft of the dewatering device having the configuration of No. 9, the dewatering is performed while heating the sludge. Also, a twenty-first method is a sludge dewatering method in which sludge is dewatered by a dewatering device equipped with a screw shaft, wherein dewatering is performed while heating the sludge by supplying heated oil into the screw shaft. It is characterized by. According to the twentieth or twenty-first configuration, by heating the sludge to be dewatered, the filtration resistance of the sludge is reduced, the water in the sludge is easily drained, and the dewatering efficiency is improved. Furthermore, by heating the sludge, water adhering to the surface of the flocculated floc due to the viscosity of the flocculated floc itself can be easily drained, and pore water between the flocculated flocs can be easily drained. This also improves the dewatering efficiency. In addition, because the sludge is heated by the heated oil, the temperature control of the oil is easier than that of steam, and the equipment for temperature control is cheaper than that of steam, reducing the overall manufacturing cost. Can be.
[0042]
BEST MODE FOR CARRYING OUT THE INVENTION
Embodiments of the present invention will be described with reference to the drawings. The dewatering system P1 according to the present invention includes a dewatering device A, an oil circulation system B, and a sludge supply system C.
[0043]
Here, the dehydrating apparatus A has a base part A1, a supply-side mechanical part A2, a dewatering part A3, and a discharge-side mechanical part A4.
[0044]
The base section A1 is a base section on which the supply-side mechanism section A2, the dehydration section A3, and the discharge-side mechanism section A4 are installed.
[0045]
The supply-side mechanism A2 includes a supply-side stand 10, a bearing 12, a bearing stand 14, a ground box 16, a packing 18, a rotary joint 20, and the like. Here, the supply side stand 10 is a case-shaped member provided on the upper side of the base part A1, and is formed in a case shape by a plate-shaped member. That is, the supply side stand 10 has a side surface portion 10a provided on the sludge supply side (X1 side) and a side surface portion 10b provided on the discharge side (X2 side). It has a front part covering the near side in FIG. 2 between the part 10a and the side part 10b, a back part covering the back side, and an upper part covering the upper side.
[0046]
A bearing stand 14 is provided between the side surface 10a and the side surface 10b of the supply stand 10, and a gland box 16 and a packing 18 are provided inside the bearing stand 14. Further, the bearing base 14 is provided with a bearing 12. The bearing 12 rotatably supports a shaft portion 44 of the screw shaft 40.
[0047]
The supply side stand 10 is provided with a supply pipe 19 for supplying sludge, and an end of the supply pipe 19 opens into a space surrounded by the punching plate 32 on the discharge side of the side surface 10b. The opening 19 a of 19 is oriented in the direction of the axis of the screw shaft 40. The supply pipe 19 is connected to a pipe K13 described later.
[0048]
Further, the rotary joint 20 is attached to an end of the shaft portion 44 and has a fixed portion 22 and a rotating portion 24. The fixing portion 22 has a tubular shape, has a spring and packing inside, and rotatably supports the rotating portion 24. The rotating part 24 is rotatable with respect to the fixed part 22, and a thread groove (male thread) is formed on the outer periphery of the end part. The rotating part 24 is screwed into a screw hole 44 a of the shaft part 44.
[0049]
Further, the dehydrating section A3 has a filtering section 30 and a screw shaft 40. The filtration unit 30 has a cylindrical punching plate 32 provided with a large number of holes, and a frame-shaped drum 34 provided outside the punching plate 32. The drum 34 is provided with a plurality of ring-shaped portions 34a having a ring-shaped plate shape at predetermined intervals, and each ring-shaped portion 34a is fixed to a band-shaped band 34b. The inside diameter of the filtration unit 30, that is, the inside diameter of the punching plate 32 is formed uniformly from the sludge supply side to the sludge supply side.
[0050]
The screw shaft 40 has a screw shaft main body (body) 42 and a screw blade 62 provided on the outer periphery of the screw shaft main body 42. The screw shaft main body 42 has a shaft 44, plates 50 to 55, and a tubular part 60.
[0051]
The shaft portion 44 is a shaft having a circular cross section, and has a hole 46 and a hole 48 at its end.
[0052]
The hole 46 has a hole 46 a provided along the axis of the shaft 44, and holes 46 b and 46 c formed by opening from the hole 46 a toward the side of the shaft 44. I have. The hole 46a is exposed at the supply-side end of the shaft 44, and is formed to have a predetermined length from the supply-side end of the shaft 44. The holes 46a and 46b are both provided in a direction perpendicular to the axial direction of the shaft 44, and the holes 46b and 46c are provided in directions symmetrical to the hole 46a. The hole 46b and the hole 46c are provided at positions shifted from each other in the axial direction. The holes 46b and 46c are exposed in a space surrounded by the cylindrical portion 60, the plate portion 50, and the plate portion 51.
[0053]
The hole 48 has a hole 48 a provided along the axis of the shaft 44, and a hole 48 b formed to open from the hole 48 a toward the side of the shaft 44. I have. The hole 48a is exposed at the end of the shaft 44 on the discharge side, and has a predetermined length from the end of the shaft 44 on the discharge side. The hole 48b is provided in a direction perpendicular to the axial direction of the shaft 44. The hole 48b is exposed in a space surrounded by the tubular portion 60, the plate portion 54, and the plate portion 55. The opening on the end face side of the shaft portion 44 in the hole 48 corresponds to the first opening, and the opening on the side surface of the shaft portion 44 in the hole 48 (that is, the opening of the hole 48b) is the second opening. Hit the department.
[0054]
As shown in FIG. 4, the supply-side end of the shaft portion 44 projects from the bearing 12 to the supply side, and the rotating portion 24 of the rotary joint 20 is screwed to the supply-side end of the shaft portion. A screw hole 44a for attachment is formed.
[0055]
The plate portion 50 is provided at an end on the supply side of the screw shaft main body portion 42, has a circular shape, and is mounted inside the tubular portion 60. The plate portion 50 has a hole through which the shaft portion 44 is inserted. The plate portion 50 is formed without a gap with respect to the cylindrical portion 60. The plate portion 55 is provided at an end on the discharge side of the screw shaft main body portion 42, has a circular shape, and is mounted inside the tubular portion 60. The plate portion 55 has a hole through which the shaft portion 44 is inserted. The plate portion 55 and the tubular portion 60 are formed without a gap, the plate portion 55 and the tubular portion 60 are formed without a gap, and the hole provided in the plate portion 50 and the shaft portion 44 are formed. There is no gap between them, and further, there is no gap between the hole provided in the plate portion 55 and the shaft portion 44, and the space formed by the cylindrical portion 60, the plate portion 50, and the plate portion 55 is closed. Have been.
[0056]
Further, the plate portions 51 to 54 are arranged at predetermined intervals at positions between the plate portion 50 and the plate portion 55. The plate portions 51 to 54 are provided with holes for inserting the shaft portion 44, and the outer peripheral ends of the plate portions 51 to 54 are in close contact with the inner periphery of the cylindrical portion 60. The plate portions 51 to 54 are formed with openings J through which oil is inserted.
[0057]
The cylindrical portion 60 is basically formed in a tapered shape having a large diameter from the supply side to the discharge side. That is, most of the cylindrical portion 60 is formed in a tapered shape, and a portion on the discharge side is formed in a cylindrical shape. That is, the diameter gradually increases from the supply-side end toward the discharge side, and has the same diameter near the discharge-side end. The cross section of the cylindrical portion 60 cut along a plane perpendicular to the axis has an annular shape. Note that the entire cylindrical portion 60 may have a tapered shape.
[0058]
In other words, the screw shaft main body 42 is formed such that the oil flowing from the hole 48 sequentially flows from the space S1 to the spaces S2, S3, S4, and S5 and flows out from the hole 46.
[0059]
The tubular portion 60, the plate portion 50, and the plate portion 55 constitute the "main body portion having a tapered tubular portion and having a space as the oil flow path therein". A space surrounded by the cylindrical portion 60, the plate portion 50, and the plate portion 55 corresponds to the "space portion as an oil flow path".
[0060]
The screw blade 62 is a blade formed spirally on the outer periphery of the screw shaft main body 42.
[0061]
Further, the discharge-side mechanism A4 includes a discharge-side stand 70, a shaft (second shaft) 80, a bearing 90, a sprocket 100, a bearing 110, a rotary joint 120, and the like.
[0062]
The discharge-side stand 70 is a case-shaped member provided above the base portion A1, and is formed in a case-like shape by a plate-shaped member. That is, the discharge side stand 70 has a side surface portion 70a provided on the supply side (X1 side) and a side surface portion 70b provided on the discharge side (X2 side) arranged substantially in parallel. It has a front part that covers the near side in FIG. 2, a back part that covers the back side, and an upper part that covers the upper side, between FIG.
[0063]
The shaft portion 80 is provided in the X1-X2 direction, and is attached to the discharge-side end of the screw shaft 40 via the connection plate 84. That is, the connection plate 84 is fixed to the supply-side end of the shaft portion 80, and the connection plate 84 is fixed to the plate portion 55 by bolts. A screw hole 80a for screwing the rotating part 124 of the rotary joint 120 is formed at the end of the shaft part 80 on the discharge side. Further, an insertion hole 82 is provided from the deep portion of the screw hole 80a to the end on the supply side of the shaft portion 80. The insertion hole 82 is provided in parallel along the axis of the shaft 80, and the supply-side end of the insertion hole 82 is exposed at the supply-side end of the shaft 80. When the connection plate 84 is attached to the screw shaft 40, the insertion hole 82 and the hole 48 of the shaft 44 are in a state of communication.
[0064]
2 and 5, the bearing portion 90 is attached to a side surface portion 70b of the discharge side stand 70, and includes a bearing box 92, a bearing 94 provided in the bearing box 92, And a bearing box cover 96 attached to the bearing box 92. The bearing 94 rotatably supports a shaft portion 80 (described later). The bearing box 92 is connected to a rib 93 fixed to the side surface 70b of the discharge-side stand 70. The rib 93 has a band-like plate shape and is provided on all sides with the bearing box 92 as a center.
[0065]
Further, the sprocket 100 is fixed to the shaft portion 80. That is, the sprocket 100 is fixedly attached to the discharge side of the bearing section 90. A roller chain (not shown) is wound around the sprocket 100, and a motor 130 (see FIG. 1) is wound around the roller chain so that the rotation of the motor 130 causes the sprocket 100 to rotate. Has become. The sprocket 100 corresponds to the above-mentioned "transmission member fixed to the second shaft portion, and a transmission member for transmitting the rotational force of the motor for driving the dewatering device to the second shaft portion".
[0066]
The bearing section 110 is provided on a bearing section base 116 provided above the base section A1, and has a bearing box 112 and a bearing 114. The bearing 114 rotatably supports the shaft portion 80, and the bearing 114 is provided in the bearing box 112.
[0067]
Further, the rotary joint 120 is attached to an end of the shaft portion 80 on the discharge side, and has a fixed portion 122 and a rotating portion 124. The fixing portion 122 has a cylindrical shape, has a spring and a packing inside, and rotatably supports the rotating portion 124. Further, the rotating portion 124 is rotatable with respect to the fixed portion 122, and a thread groove (male thread) is formed on the outer periphery of the end portion. The rotating portion 124 is screwed into the screw hole 80a of the shaft portion 80.
[0068]
Next, the oil circulation system B includes an oil tank 200, an electric heater (heating device) 202, an oil level sensor 204, an oil thermometer 206, an oil pump (pump) 208, an oil thermometer 210, It has a device 220 and pipe sections K1 to K3.
[0069]
Here, the oil tank 200 is a tank for storing oil, and the electric heater 202 is for heating the oil in the oil tank 200. The oil level sensor 204 detects the oil level of the oil in the oil tank 200, and the oil temperature gauge 206 detects the temperature of the oil in the oil tank 200. The oil pump 208 is a pump for pumping oil in the oil tank 200 toward the pipe K2, and the oil thermometer 210 detects the temperature of oil flowing through the pipe K2. The control device 220 is connected to the oil temperature gauges 206 and 210, the oil level sensor 204, the electric heater 202, and the oil pump 208, and controls the operations of the electric heater 202, the oil pump 208, and the like. In particular, the control device 220 controls the operation of the electric heater 202, the oil pump 208, and the like based on the detection results of the oil temperature meters 206 and 210 and the oil level sensor 204. The oil temperature gauges 206 and 210 function as the above-mentioned temperature detecting device.
[0070]
The pipes K1 to K3 are pipe members for moving oil, the pipe K1 is provided between the oil tank 200 and the oil pump 208, and the pipe (first pipe) K2 is an oil pump. A pipe section (second pipe section) K3 is provided between the dehydrating apparatus A and the oil tank 200. That is, the pipe portion K2 is connected to the fixing portion 122 of the rotary joint 120, and the pipe portion K3 is connected to the fixing portion 22 of the rotary joint 20.
[0071]
Next, the sludge supply system C is a device for supplying sludge and the like to the dewatering device A, and includes a sludge storage tank 300, a sludge supply pump (feeding device) 302, a coagulation mixing tank 310, and a stirrer (stirring device). 312 etc.
[0072]
Here, the sludge storage tank 300 is a container-like member for storing sludge, and the sludge supply pump 302 is a pump for sending the sludge in the sludge storage tank 300 to the coagulation mixing tank 310. The coagulation mixing tank 310 is a container-shaped member for mixing the sludge and the coagulant, and the inside of the coagulation mixing tank 310 is sealed from the outside. The stirrer 312 is for stirring the object to be stirred in the coagulation mixing tank 310.
[0073]
A pipe K11 is provided between the sludge storage tank 300 and the mud feed pump 302, and a pipe K12 is provided between the sludge pump 302 and the coagulation mix tank 310. A pipe K13 is provided between the dehydrator A. Further, a pipe K14 connected to the first coagulant injection pump is connected in the middle of the pipe K12, and a pipe K15 connected to the second coagulant injection pump is connected to the coagulation mixing tank 310. It is connected. The pipe section K13 is connected to a supply pipe 19 provided on the supply side stand 10 of the dehydrating apparatus A. In addition, a pressure gauge (not shown) for detecting the pressure in the pipe portion K13 and a control device (not shown) for controlling the pressure of the mud feed pump 302 in accordance with the detection result of the pressure gauge are provided. ing.
[0074]
In addition, as shown in FIG. 1, valves Va are provided at various portions of the pipe portions K1 to K3 and the pipe portions K11 to K15.
[0075]
The operation of the dehydration system P1 having the above configuration will be described. The sludge is sent from the sludge supply system C to the dewatering device A in the form of flocculated flocs, and the sludge is discharged after being dewatered in the dewatering device A. At this time, the heated oil is supplied into the screw shaft 40 by the oil circulation system B, so that the heating by the oil lowers the filtration resistance of the sludge, makes it easier for the water in the sludge to escape, and improves the dewatering efficiency. I do. Furthermore, by heating the sludge, water adhering to the surface of the flocculated floc due to the viscosity of the flocculated floc itself can be easily drained, and pore water between the flocculated flocs can be easily drained. This also improves the dewatering efficiency.
[0076]
A more detailed operation of the dehydration system P1 will be described. The operation in the following description is performed using an operation panel (not shown).
[0077]
First, the oil is circulated by the oil circulation system B before the sludge is supplied to the dehydrator A. As this oil, for example, lubricating oil is used. The valves in the pipe sections K1, K2, and K3 are previously opened.
[0078]
That is, by operating the operation panel, the electric heater 202 is operated, the oil in the oil tank 200 is preliminarily heated by the electric heater 202, and the oil in the oil tank 200 is piped by the oil pump 208 to the pipe sections K1, K2. To the dehydration apparatus A via The heated oil reaches the insertion hole 82 of the shaft portion 80 from the rotary joint 120, and then reaches the screw shaft 40. That is, the oil flowing out of the insertion hole 82 reaches the inside of the screw shaft main body 42 through the holes 48a and 48b of the shaft 44. Then, the inside of the screw shaft main body 42 is moved to the sludge supply side (X1 side in FIG. 2) through the opening J provided in the plate portion 54 to the plate portion 51, and the hole portion 46 b of the shaft portion 44 is formed. From 46c to the end of the shaft 44 through the hole 46a. The oil that has flowed out of the shaft portion 44 further reaches the pipe portion K3 through the rotary joint 20, and returns to the oil tank 200 through the pipe portion K3.
[0079]
When oil is circulated in a state where there is no oil in the pipe sections K1 to K3 and the screw shaft 40, the oil in the oil tank 200 is heated and circulated, and the oil temperature is measured by the oil temperature meter 206 or the oil temperature meter. Heating and circulation are performed until the temperature of 210 reaches a predetermined temperature. In other words, even if the oil in the oil tank 200 is initially pumped at a predetermined temperature, the temperature decreases while passing through the pipes K1 to K3 and the screw shaft 40. Heat and circulate until the temperature reaches. On the other hand, when there is oil in the pipe sections K1 to K3 and the screw shaft 40, the oil is circulated by the oil pump 208 while the oil in the oil tank 200 is heated by the electric heater 202, and the oil temperature Heating and circulation are performed until the temperature of the oil thermometer 210 reaches a predetermined temperature. In addition, the above-mentioned "predetermined temperature" is any temperature within the temperature range of the boiling point of water or more and less than the boiling point of oil (may be "less than or equal to"). The temperature may be controlled so as to be within a predetermined temperature range in the temperature range. In addition, since it is necessary to circulate the oil as the amount of the oil, the liquid level of the oil is set to be higher than the upper end position of the shaft portion 44 in the screw shaft 40.
[0080]
Then, when the temperature of the oil thermometer 206 or the oil thermometer 210 reaches a predetermined temperature, the surface of the screw shaft main body 42 of the screw shaft 40 also assumes that the temperature has reached the predetermined temperature. Supply sludge to A. In this case, when the control device 220 detects that the temperature has reached the predetermined temperature, the control device 220 may automatically start the sludge pump 302 for supplying sludge to the dehydrating device A, After the operator confirms that the temperature has reached the predetermined temperature, the mud feed pump 302 may be started.
[0081]
That is, the sludge is pumped into the flocculation mixing tank 310 by operating the sludge supply pump 302 in a state where the sludge is contained in the sludge storage tank 300. At this time, the first coagulant is pumped from the first coagulant injection pump connected to the pipe K14, and the second coagulant is pumped from the second coagulant injection pump. Here, for example, an inorganic coagulant is used as the first coagulant, and a polymer coagulant is used as the second coagulant. Then, since the sludge, the first flocculant, and the second flocculant are mixed in the flocculation / mixing tank 310, the sludge is stirred by the stirrer 312. Then, the sludge is in a flocculated floc state. Since the inside of the flocculation / mixing tank 310 is in a closed state, the sludge in the flocculated floc state is supplied to the dewatering device A by the pressure from the mud feed pump 302. Then, the water is sent from the opening 19 a into the filtering unit 30 through the supply pipe 19 provided in the dehydrating apparatus A.
[0082]
Here, initially, there is no sludge in the filtration unit 30. Therefore, the screw shaft 40 is rotated until the predetermined area (for example, the area F) on the supply side in the filtration unit 30 is filled with the sludge. Instead, when the predetermined area is filled with sludge, the screw shaft 40 is rotated. That is, if the screw shaft 40 is rotated from the beginning of supplying the sludge into the filtration unit 30, the sludge is transferred to the discharge side with the rotation of the screw shaft 40, and the dewatering efficiency cannot be increased. On the other hand, by not rotating the screw shaft 40 until the sludge is filled in the predetermined area, the sludge is filled in the predetermined area, and the sludge in that part is solidified in a cake-like form. The sludge solidified in a cake shape becomes a wall and does not easily move in the transfer direction, so that the dewatering efficiency can be increased. In addition, according to the pressure detected by the pressure gauge provided between the coagulation mixing tank 310 and the dehydrating apparatus A, when the pressure rises above a predetermined value, the control device stops the pressure feeding by the mud feed pump 302 or The dewatering state can be maintained in a good state by reducing the pumping speed.
[0083]
The rotation of the screw shaft 40 is performed as follows. In other words, the sprocket 100 is rotated by rotating the motor 130, and the shaft 80 is rotated with the rotation of the sprocket 100, whereby the screw shaft 40 is rotated. Further, by rotating the motor 130, the rotating part 24 of the rotary joint 20, the screw shaft 40, the shaft part 80, the connection plate 84, the sprocket 100, and the rotating part 124 of the rotary joint 120 rotate. become. Since the boundary between the rotating member and the fixed member in the dehydrating device A is formed by a rotary joint, oil does not leak.
[0084]
With the rotation of the screw shaft 40, the sludge in the filtration unit 30 is guided to the screw blades 62 of the screw shaft 40 and transported to the large diameter side of the screw shaft 40, and the inner surface of the filtration unit 30 and the outer surface of the screw shaft 40. Is gradually narrowed toward the discharge side, whereby the sludge is dehydrated, and the discharge port (not shown) provided at the lower portion of the discharge side stand 70 is used to discharge the sludge. By the time the sludge is completely caked. Then, the sludge that has turned into a cake is discharged from the discharge port 65. The sludge attached to the screw shaft body 42 can be scraped off by a scraper (not shown) provided near the end of the screw shaft 40 on the discharge side of the screw shaft body 42. The discharged sludge can be deposited on the deposition section 400 provided below the discharge side stand 70. On the other hand, the filtrate discharged by dewatering the sludge is collected by a water collecting tray 67 provided below the filtration unit 30, and then stored in a filtrate tank 500. Predetermined processing is performed on cake-like sludge deposited in the deposition section 400 and the filtrate stored in the filtrate tank 500.
[0085]
When the sludge moves through the filtration unit 30, the surface of the screw shaft main body 42 is also heated by the heated oil in the screw shaft main body 42. When heated, the filtration resistance of the sludge is reduced, the water in the sludge is easily drained, and the dewatering efficiency is improved. Furthermore, by heating the sludge, water adhering to the surface of the flocculated floc due to the viscosity of the flocculated floc itself can be easily drained, and pore water between the flocculated flocs can be easily drained. This also improves the dewatering efficiency.
[0086]
At least during the dehydration process by the dehydrator A, the control device 220 monitors the oil thermometers 206 and 210, and when the temperature becomes lower than the predetermined temperature, the controller 220 controls the electric heater 202 until the temperature reaches the predetermined temperature. The oil is heated, and when the temperature reaches the predetermined temperature, the heating is stopped. Specifically, when at least one of the oil thermometers 206 and 210 has a temperature lower than the predetermined temperature, the electric heater 202 operates until both of the oil thermometers 206 and 210 reach the predetermined temperature or higher. Perform heating. Thereby, the temperature of the oil in the screw shaft main body 42 can be kept within a certain range.
[0087]
When the dewatering operation is completed, the mud feed pump 302 is stopped to stop the supply of the mud from the coagulation mixing tank 310 to the dehydrating apparatus A, and the oil pump 208 is stopped to stop the oil circulation. At the same time, the heating by the electric heater 202 is stopped. The stop of the sludge pump 302, the stop of the oil pump, and the stop of the heating by the electric heater 202 may be performed manually, or the amount of the sludge in the sludge storage tank 300 may be detected, and the predetermined amount may be set. It may be automatically stopped when the following amount is reached.
[0088]
As described above, according to the dehydration system P1 of the present embodiment, the sludge is heated by the heated oil to improve the dehydration efficiency, so that the temperature control of the oil is easier than that of steam, and Is also inexpensive compared to the case of steam, and the manufacturing cost of the dehydration system P1 can be reduced as a whole.
[0089]
In particular, in the case where there is no steam generation source equipment in an office or the like, or in the case where there is no excess heat source even if the equipment is provided, this is an effective system, and the total cost can be reduced. In other words, it is conceivable to select the heating of sludge by steam at a business establishment or the like that has a steam generating heat source and has an excess heat source. If there is no dewatering system, the cost can be reduced by using the dehydration system of this embodiment.
[0090]
Next, a second embodiment will be described. The dehydration system P2 of the second embodiment has substantially the same configuration as the dehydration system P1 of the first embodiment, except that a drying system D is further provided in the dehydration system P1 of the first embodiment. Primarily different.
[0091]
That is, in the dewatering system P2, since the configurations of the dewatering device A and the sludge supply system C are the same as those in the first embodiment, detailed description will be omitted.
[0092]
The configuration of the oil circulation system B is also substantially the same as that of the first embodiment, except that the tube portions K20 and K21 are further provided. That is, the oil circulation system B according to the second embodiment includes an oil tank 200, an electric heater 202, an oil level sensor 204, an oil thermometer 206, an oil pump 208, an oil thermometer 210, and a control device 220. , K1 to K3, K20, and K21.
[0093]
Here, the pipe portion K20 is provided to branch off from the middle of the pipe portion K2, and is connected to one end of an oil passage of a drying furnace main body 602 (described later). Further, a pipe portion K21 is also provided branching from the middle of the pipe portion K2, and is connected to the other end of the oil passage of the drying furnace main body 602. That is, the pipe portion K2 includes a pipe portion K2-1 provided between a branch position between the oil pump 208 and the pipe portion K20, and a pipe portion K2- provided between the branch position and the branch position between the pipe portion K21. 2 and a pipe section K2-3 provided between the branch position of the pipe section K21 and the dehydrating apparatus A.
[0094]
Further, in the oil circulation system B of the second embodiment, the oil tank 200, the electric heater 202, the oil level sensor 204, the oil temperature gauge 206, the oil pump 208, the oil temperature gauge 210, the control device 220, The configuration of the tube portions K1 to K3 is the same as the configuration in the first embodiment, and a detailed description thereof will be omitted.
[0095]
Next, the drying system D includes a cake drying furnace 600, a rotary valve 610, a dried cake hopper 620, a vacuum pump 630, and pipe sections K20 and K21.
[0096]
The cake drying furnace 600 has a drying furnace main body 602 having a cylindrical shape in a horizontal direction, and the drying furnace main body 602 has an input port 602a for inputting the sludge sent from the dehydrating apparatus A, and has generated the same. An outlet 602b for discharging gas is provided. Further, a stirring device 604 is provided inside the drying furnace main body 602. The stirring device 604 is connected to a motor 605, and the driving of the motor 605 causes the stirring device 604 to operate. The bottom and sides of the drying furnace main body 602 are provided with an oil passage for passing oil, and the inside of the drying furnace main body 602 is heated by passing heated oil. I have.
[0097]
The dried cake hopper 620 is for accumulating cake-like sludge after drying. Further, the vacuum pump 630 is connected to the outlet 602b and has a function of sending the gas discharged from the outlet 602b to the gas processing equipment.
[0098]
The operation of the dehydration system P2 will be described. The sludge is sent from the sludge supply system C to the dewatering device A in the form of flocculated flocs, as in the first embodiment, and the sludge is discharged after being dewatered in the dewatering device A. At this time, the heated oil is supplied into the screw shaft 40 by the oil circulation system B, so that the heating by the oil lowers the filtration resistance of the sludge, makes it easier for the water in the sludge to escape, and improves the dewatering efficiency. I do. Furthermore, by heating the sludge, water adhering to the surface of the flocculated floc due to the viscosity of the flocculated floc itself can be easily drained, and pore water between the flocculated flocs can be easily drained. This also improves the dewatering efficiency. Further, the sludge that has been dehydrated and formed into a cake is sent to a cake drying furnace 600, dried in the cake drying furnace 600, and then accumulated in a dried cake hopper 620.
[0099]
A more detailed operation of the dehydration system P2 will be described. The operation in the following description is performed using an operation panel (not shown).
[0100]
First, the oil is circulated by the oil circulation system B before the sludge is supplied to the dehydrator A. As this oil, for example, lubricating oil is used. The valves in the pipe sections K1, K2, K3, K20, and K21 are opened in advance except for a part. That is, the valves Va-1 and Va-2 provided in the pipe portions K20 and K21 are also opened so that the oil flows into the pipe portions K20 and K21. Note that the valve Va-3 is closed so that one loop-shaped circulation path is formed.
[0101]
That is, by operating the operation panel, the electric heater 202 is operated, the oil in the oil tank 200 is preliminarily heated by the electric heater 202, and then the oil in the oil tank 200 is dewatered by the oil pump 208 or the dehydrator A. The pressure is sent to the drying furnace main body 602. That is, the oil reaches the drying furnace main body 602 from the pipe section K2 via the pipe section K20, flows out of the drying furnace main body 602 through an oil passage in the drying furnace main body 602, and flows from the pipe section K21 to the pipe section K2-3. Through the dehydration apparatus A. That is, the oil reaches the insertion hole 82 of the shaft portion 80 from the rotary joint 120, and then reaches the screw shaft 40. That is, the oil flowing out of the insertion hole 82 reaches the inside of the screw shaft main body 42 through the holes 48a and 48b of the shaft 44. Then, the inside of the screw shaft main body 42 is moved to the sludge supply side (X1 side in FIG. 2) through the opening J provided in the plate portion 54 to the plate portion 51, and the hole portion 46 b of the shaft portion 44 is formed. From 46c to the end of the shaft 44 through the hole 46a. The oil that has flowed out of the shaft portion 44 further reaches the pipe portion K3 through the rotary joint 20, and returns to the oil tank 200 through the pipe portion K3.
[0102]
When the oil is circulated in a state where there is no oil in the pipe sections K1 to K3, the screw shaft 40, the pipe sections K20 and K21, and the cake drying furnace 600, the oil in the oil tank 200 is heated. The heating and circulation are performed until the temperature of the oil thermometer 206 or the oil thermometer 210 reaches a predetermined temperature. In other words, even if the oil in the oil tank 200 is initially pumped at a predetermined temperature, the temperature decreases while passing through the pipes K1 to K3 and the screw shaft 40. Heat and circulate until the temperature reaches. On the other hand, when there is oil in the pipe sections K1 to K3, the screw shaft 40, the pipe sections K20 and K21, and the cake drying furnace 600, the oil pump 200 is heated by heating the oil in the oil tank 200 with the electric heater 202. The oil is circulated at 208, and heating and circulation are performed until the temperature of the oil thermometer 206 or the oil thermometer 210 reaches a predetermined temperature. In addition, the above-mentioned "predetermined temperature" is any temperature equal to or higher than the boiling point of water and equal to or lower than the boiling point of oil. In addition, since it is necessary to circulate the oil as the amount of the oil, the liquid level of the oil is set to be higher than the upper end position of the shaft portion 44 in the screw shaft 40.
[0103]
Then, when the temperature of the oil thermometer 206 or the oil thermometer 210 reaches a predetermined temperature, the surface of the screw shaft main body 42 of the screw shaft 40 also assumes that the temperature has reached the predetermined temperature. Supply sludge to A. In this case, when the control device 220 detects that the temperature has reached the predetermined temperature, the control device 220 may automatically start the sludge pump 302 for supplying sludge to the dehydrating device A, After the operator confirms that the temperature has reached the predetermined temperature, the mud feed pump 302 may be started.
[0104]
That is, the sludge is pumped into the flocculation mixing tank 310 by operating the sludge supply pump 302 in a state where the sludge is contained in the sludge storage tank 300. At this time, the first coagulant is pumped from the first coagulant injection pump connected to the pipe K14, and the second coagulant is pumped from the second coagulant injection pump. Here, for example, an inorganic coagulant is used as the first coagulant, and a polymer coagulant is used as the second coagulant. Then, since the sludge, the first flocculant, and the second flocculant are mixed in the flocculation / mixing tank 310, the sludge is stirred by the stirrer 312. Then, the sludge is in a flocculated floc state. Since the inside of the flocculation / mixing tank 310 is in a closed state, the sludge in the flocculated floc state is supplied to the dewatering device A by the pressure from the mud feed pump 302. Then, the water is sent from the opening 19 a into the filtering unit 30 through the supply pipe 19 provided in the dehydrating apparatus A.
[0105]
Here, initially, there is no sludge in the filtration unit 30. Therefore, the screw shaft 40 is rotated until the predetermined area (for example, the area F) on the supply side in the filtration unit 30 is filled with the sludge. Instead, when the predetermined area is filled with sludge, the screw shaft 40 is rotated. That is, if the screw shaft 40 is rotated from the beginning of supplying the sludge into the filtration unit 30, the sludge is transferred to the discharge side with the rotation of the screw shaft 40, and the dewatering efficiency cannot be increased. On the other hand, by not rotating the screw shaft 40 until the sludge is filled in the predetermined area, the sludge is filled in the predetermined area, and the sludge in that part is solidified in a cake-like form. The sludge solidified in a cake shape becomes a wall and does not easily move in the transfer direction, so that the dewatering efficiency can be increased. In addition, according to the pressure detected by the pressure gauge provided between the coagulation mixing tank 310 and the dehydrating apparatus A, when the pressure rises above a predetermined value, the control device stops the pressure feeding by the mud feed pump 302 or The dewatering state can be maintained in a good state by reducing the pumping speed.
[0106]
With the rotation of the screw shaft 40, the sludge in the filtration unit 30 is guided to the screw blades 62 of the screw shaft 40 and transferred to the large-diameter side of the screw shaft 40, and the inner surface of the filtration unit 30 and the outer surface of the screw shaft 40. Is gradually narrowed toward the discharge side, whereby the sludge is dehydrated, and the discharge port (not shown) provided at the lower portion of the discharge side stand 70 is used to discharge the sludge. By the time the sludge is completely caked. Then, the sludge that has turned into a cake is discharged from the discharge port 65. The sludge attached to the screw shaft body 42 can be scraped off by a scraper (not shown) provided near the end of the screw shaft 40 on the discharge side of the screw shaft body 42. The discharged sludge can be deposited on the deposition section 400 provided below the discharge side stand 70. On the other hand, the filtrate discharged by dewatering the sludge is collected by a water collecting tray 67 provided below the filtration unit 30, and then stored in a filtrate tank 500. Predetermined processing is performed on cake-like sludge deposited in the deposition section 400 and the filtrate stored in the filtrate tank 500.
[0107]
When the sludge moves through the filtration unit 30, the surface of the screw shaft main body 42 is also heated by the heated oil in the screw shaft main body 42. When heated, the filtration resistance of the sludge is reduced, the water in the sludge is easily drained, and the dewatering efficiency is improved. Furthermore, by heating the sludge, water adhering to the surface of the flocculated floc due to the viscosity of the flocculated floc itself can be easily drained, and pore water between the flocculated flocs can be easily drained. This also improves the dewatering efficiency.
[0108]
At least during the dehydration process by the dehydrator A, the controller 220 monitors the oil thermometers 206 and 210, and when the temperature becomes lower than a predetermined temperature, the controller 202 controls the electric heater 202 until the temperature reaches the predetermined temperature. The oil is heated, and when the temperature reaches the predetermined temperature, the heating is stopped. Thereby, the temperature of the oil in the screw shaft main body 42 can be maintained within a certain range.
[0109]
The cake-like sludge deposited in the deposition section 400 is introduced into the inlet 602a of the cake drying furnace 600. In this charging, the sludge deposited in the deposition unit 400 may be manually loaded, or a transport device that transports the sludge deposited in the deposition unit 400 to the input port 602a may be provided and loaded by the transport device. You may do so.
[0110]
Then, the introduced sludge is subjected to a drying treatment in the cake drying furnace 600 to be in a state of a dried cake. In addition, at least at the stage of putting sludge into the cake drying furnace 600, the motor 605 is rotated to operate the stirring device 604. Thus, the sludge is dried by heat from the heated oil while being stirred by the stirring device 604. The sludge in a dried cake state is accumulated in the dried cake hopper 620 via the rotary valve 610. On the other hand, the gas generated in the cake drying furnace 600 is sucked by the vacuum pump 630 and sent to the gas processing equipment.
[0111]
When the dehydration operation is completed, the mud supply pump 302 is stopped to stop the supply of the mud from the coagulation mixing tank 310 to the dehydrator A, and the oil pump 208 is stopped to stop the oil circulation. At the same time, the heating by the electric heater 202 is stopped, and the operation of the stirring device 604 in the cake drying furnace 600 is also stopped. Note that the stop of the sludge pump 302, the stop of the oil pump, the stop of the heating by the electric heater 202, and the stop of the operation of the stirring device 604 may be performed manually, or the amount of the sludge in the sludge storage tank 300 may be reduced. The detection may be performed, and when the amount becomes equal to or less than the predetermined amount, the operation may be automatically stopped.
[0112]
As described above, according to the dewatering system P2 of the present embodiment, the sludge is heated by the heated oil to improve the dewatering efficiency, so that the temperature control of the oil is easier than that of steam, and Is also inexpensive compared to the case of steam, and the manufacturing cost of the dehydration system P2 can be reduced as a whole.
[0113]
In particular, in the case where there is no steam generation source equipment in an office or the like, or in the case where there is no excess heat source even if the equipment is provided, this is an effective system, and the total cost can be reduced. In other words, it is conceivable to select the heating of sludge by steam at a business establishment or the like that has a steam generating heat source and has an excess heat source. If there is no dewatering system, the cost can be reduced by using the dehydration system of this embodiment.
[0114]
Further, since the drying system D is provided, the sludge dewatered by the dewatering device A can be dried. In addition, since a system for supplying oil to the screw shaft 40 in the dehydrating apparatus A can be used for drying sludge in the drying system D, it is not necessary to separately provide a heat source for drying sludge in the drying system D.
[0115]
In the above description, one shaft portion 44 is provided in the screw shaft main body portion 42 of the screw shaft 40, but the shaft center of the screw shaft main body portion 42 is provided at both ends of the screw shaft main body portion 42. May be provided, and one of the shaft portions may be provided with the hole portion 46, and the other shaft portion may be provided with the hole portion 48. In this case, it is needless to say that the plate portions 51 to 54 do not need a hole for inserting the shaft portion 44.
[0116]
In the above description, in the dewatering device A, the diameter of the screw shaft main body portion (body portion) 42 of the screw shaft 40 is formed so as to gradually increase from the sludge supply side toward the discharge side. In addition, the inner diameter of the filtration unit 30 has been described as being formed uniformly from the supply side of the sludge to the discharge side, but the present invention is not limited to this, and may be applied to other types of dehydrators. . That is, the diameter of the body of the screw shaft is formed uniformly from the sludge supply side to the discharge side, and the inner diameter of the filtration unit is gradually reduced from the sludge supply side to the discharge side. It may be applied to a dewatering device of a type that is formed as such, and the diameter of the body portion and the inner diameter of the filtration portion in the screw shaft are formed uniformly from the sludge supply side to the discharge side. Alternatively, the present invention may be applied to a dewatering apparatus of a type in which the pitch of the screw blades provided on the screw shaft decreases from the supply side of the sludge toward the discharge side.
[0117]
【The invention's effect】
According to the dewatering device, the oil circulation system, the dewatering system and the sludge dewatering method according to the present invention, the sludge to be dewatered is heated by supplying the heated oil to the screw shaft of the dewatering device. The filtration resistance is reduced, the water in the sludge is easily drained, and the dewatering efficiency is improved. Furthermore, by heating the sludge, water adhering to the surface of the flocculated floc due to the viscosity of the flocculated floc itself can be easily drained, and pore water between the flocculated flocs can be easily drained. This also improves the dewatering efficiency.
[0118]
In addition, since the sludge is heated by the heated oil, the temperature control of the oil is easier than that of steam, and the device for controlling the temperature is cheaper than that of steam. Can be reduced.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing a configuration of a dehydration system based on a first embodiment of the present invention.
FIG. 2 is a sectional view of a main part showing a configuration of a dehydrating apparatus based on an embodiment of the present invention.
FIG. 3 is a cross-sectional view illustrating a configuration of a screw shaft main body in the screw shaft.
FIG. 4 is a sectional view of a main part showing a configuration of a supply-side mechanism.
FIG. 5 is a cross-sectional view illustrating a configuration of a discharge-side mechanism.
FIG. 6 is an explanatory diagram showing a configuration of a dehydration system based on a second embodiment of the present invention.
[Explanation of symbols]
P1, P2 dehydration system
A dehydrator
A1 base
A2 supply side mechanism
A3 dehydration section
A4 discharge side mechanism
B Oil circulation system
C Sludge supply system
10 Supply side stand
19 Supply pipe
20, 120 Rotary joint
30 Filtration unit
40 screw shaft
42 Screw shaft body
44 Shaft
46, 48 hole
50, 51, 52, 53, 54, 55 Plate part
60 tubular part
70 Discharge side stand
80 Shaft
90, 110 Bearing
200 oil tank
202 Electric heater
204 Oil level sensor
206, 210 Oil temperature gauge
208 oil pump
220 control device
300 Sludge storage tank
302 Sludge pump
310 Coagulation mixing tank
312 stirrer
600 Cake drying oven
610 Rotary valve
620 dried cake hopper
K1, K2, K3, K11, K12, K13, K14, K15, K20, K21

Claims (21)

A screw press type dewatering device for dewatering sludge,
A dewatering device comprising a screw shaft having an oil flow passage for flowing oil therein. A screw press type dewatering device for dewatering sludge,
A dewatering apparatus comprising: a body having an oil flow path for flowing oil therein; and a screw shaft having a helical screw blade provided on a surface of the body. A screw press type dewatering device for dewatering sludge,
Having an oil flow path for flowing oil inside, an inflow port for flowing oil into the oil flow path, and a body having an outflow port for flowing out oil from the oil flow path, A dehydration apparatus comprising a screw shaft having a spiral screw blade provided on a surface of the body. The torso,
A main body having a cylindrical portion and having a space therein as the oil flow path,
A shaft portion provided along the axis of the body portion, a hole portion, a first opening portion being one opening portion provided on an end surface of the shaft portion, and a second opening portion being the other opening portion. A shaft provided with a hole having an opening facing the space,
Has,
First openings provided on the end face of the shaft are provided on both ends of the body, respectively, and one first opening serves as the inlet and the other first opening serves as the outlet. The dehydration apparatus according to claim 3, wherein: The torso,
A main body having a cylindrical portion and having a space therein as the oil flow path,
A shaft provided along an axis of the main body, at least an end face of the shaft is exposed from both ends of the main body; A shaft portion provided with a first opening that is one opening at an end surface thereof and a hole provided with a second opening that is the other opening facing the space,
Has,
The dehydration apparatus according to claim 3, wherein one of the pair of first openings is the inlet, and the other is the outlet. The dehydration device further includes:
A second shaft portion fixed to an end of the screw shaft, and an insertion hole provided along an axis of the second shaft portion, the insertion hole communicating with the hole provided in the shaft portion; A second shaft portion having;
A transmission member fixed to the second shaft portion, a transmission member for transmitting a rotational force of a motor for driving a dehydrating device to the second shaft portion,
The dehydration apparatus according to claim 4, further comprising: The dehydration apparatus according to claim 4, wherein the dehydration apparatus has a rotary joint that is directly or indirectly connected to the shaft portion. A rotary joint is connected to an end of the second shaft, and a rotary joint is connected to an end of the shaft at an end of the body opposite to the side to which the second shaft is connected. The dewatering device according to claim 6, wherein a joint is connected. The said dehydration apparatus further has a filtration part provided with a hole part which discharges the filtrate generated by dehydration in a cylindrical filtration part provided outside the screw shaft, or The dehydration apparatus according to 2 or 3 or 4 or 5 or 6 or 7 or 8. An oil circulation system for supplying heated oil into the screw shaft in a screw press type dehydrator for dewatering sludge,
An oil tank for storing oil,
A heating device for heating the oil in the oil tank,
A pump for pumping oil,
An oil circulation system comprising: A dewatering system for dewatering sludge,
A dehydration device according to claim 1 or 2 or 3 or 4 or 5 or 6 or 7 or 8 or 9,
An oil circulation system that supplies heated oil to the dehydrator while circulating the oil, and an oil circulation system that supplies oil to an oil passage provided in a body of a screw shaft of the dehydrator,
A dehydration system comprising: A dewatering system for dewatering sludge,
Having an oil flow path for flowing oil inside, an inflow port for flowing oil into the oil flow path, and a body having an outflow port for flowing out oil from the oil flow path, A dehydration device having a screw shaft having a helical screw blade provided on the surface of the body,
An oil circulation system that allows heated oil to flow into the inflow port of the dewatering device, and allows the oil to flow out of the outflow port to circulate the oil;
A dehydration system comprising: The said dehydration apparatus, The filter part provided with the hole part which discharges the filtrate produced by dehydration in the cylindrical filtration part provided outside the said screw shaft, The filtration part characterized by the above-mentioned, or 13. The dehydration system according to 12. The oil circulation system is
An oil tank for storing oil,
A heating device for heating the oil in the oil tank,
A pump for pumping oil,
The dehydration system according to claim 11, 12 or 13, comprising: The oil circulation system further comprises:
A temperature detector for detecting the temperature of the oil in the oil tank and / or the temperature of the oil in the oil flow path provided between the dehydrator and the oil circulation system;
A control device for controlling the heating device according to the temperature detected by the temperature detection device;
The dehydration system according to claim 14, comprising: The control device controls the heating device such that the temperature detected by the temperature detection device is equal to or higher than the boiling point of water and lower than the boiling point of oil and is within a predetermined range set in a temperature range. The dehydration system according to claim 15, wherein The oil circulation system further comprises:
A first pipe section which is a pipe section for allowing oil to flow in a pipe section connected to the dehydrating device;
A second pipe section that is a pipe section for allowing oil to flow out of the pipe section connected to the dehydrating device;
The dehydration system according to claim 11, wherein the system comprises: The dehydration system further comprises:
A sludge supply system for supplying sludge to the dehydration device,
A coagulation mixing tank for mixing sludge and a coagulant,
A stirrer for stirring the object to be stirred in the coagulation mixing tank;
A feeding device for sending sludge in the coagulation mixing tank to the dewatering device,
The dewatering system according to claim 11, further comprising a sludge supply system having the following. The dehydration system further comprises:
A drying device for drying sludge dewatered by the dewatering device, the device having an oil flow path for flowing oil circulated by the oil circulation system, and heating the oil by the oil circulation system. The dehydration system according to claim 11, further comprising a drying device configured to dry sludge by flowing the oil in an oil flow path. A sludge dewatering method for dewatering sludge by a screw press type dewatering device equipped with a screw shaft,
Dehydration while heating sludge by supplying heated oil to an oil flow path in a screw shaft of the dehydration device according to claim 1 or 2 or 3 or 4 or 5 or 6 or 7 or 8 or 9. A method for dewatering sludge, characterized in that: A sludge dewatering method for dewatering sludge by a dewatering device having a screw shaft,
A sludge dewatering method, characterized in that dewatering is performed while heating sludge by supplying heated oil into a screw shaft.

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