KR102239471B1 - Rotary heat recovery device - Google Patents

Abstract

The present invention relates to a rotary heat recovery apparatus. To implement this, the present invention comprises: a wastewater collection tank having a space for holding wastewater therein, having a wastewater inlet on a first side wall located at one side and having a wastewater outlet on a second side wall located at the other side opposite thereto; a driving shaft including a first shaft and a second shaft wherein the first shaft has one side connected to a clean water inflow pipe and the other side penetrating through the second side wall to be located within the wastewater collection tank in a state of being rotatable by a driving means, and the second shaft has one side connected to the first shaft and the other side penetrating through the first side wall to be connected to a clean water outflow pipe out of the wastewater collection tank; and disks each of which is formed in the form of a plate provided with an internal space, in each of which a first and a second shaft hole, through which the second shaft penetrates, are installed at the central portion of both side surfaces facing each other and a first and a second connection unit provided with first and second through holes connected to the internal space are formed, and a plurality of which are installed in the longitudinal direction of the second shaft, while being connected to each other such that the first and the second connection unit facing and coming into contact with each other are maintained airtight. The present invention can effectively prevent contamination on a heat exchange line and a blockage of a specific section caused by foreign substances.

Description

Rotary heat recovery device

The present invention relates to a heat recovery device for recovering heat from high-temperature wastewater, and to a rotary type heat recovery device capable of preventing contamination and blockage of the device due to foreign substances contained in wastewater.

In general, wastewater discharged from facilities using high-temperature water is discharged in a state containing a large amount of thermal energy, and a heat recovery device is used as a device for recycling by recovering heat from such high-temperature wastewater.

Such a heat recovery device may include a wastewater collection tank in which high-temperature wastewater is stored, and a heat exchange line installed in the wastewater collection tank to move cold and fresh water.

Therefore, the high-temperature wastewater is pumped to the wastewater collection tank, and the cold and fresh water is pumped to the heat exchange line provided in the wastewater collection tank, so that the hot wastewater and the cold fresh water flow in opposite directions within the wastewater collection tank, thereby cooling the heat of the wastewater. It is moved to fresh water, and then cold and fresh water is converted into hot and fresh water, and then used in the subsequent process.

On the other hand, high-temperature wastewater used in textile factories contains foreign substances, and these foreign substances contaminate the inside of the wastewater collection tank and the heat exchange line and block specific sections.Therefore, a plurality of filters are installed in the wastewater collection tank and wastewater through these filters. Is removing foreign substances.

However, the use of such a filter requires a lot of cost due to the installation and maintenance of the filter, and a separate manpower is required for the inspection and replacement of the filter, and the production line is temporarily stopped when the filter is inspected or replaced. Accordingly, there is a problem that productivity is lowered due to such interruption.

Republic of Korea Patent Publication No. 10-2010-0067000 (published on June 18, 2010)

The present invention was conceived to solve the above-described problem, and a rotary heat recovery device capable of effectively solving the problem that the heat exchange line is contaminated or the section is blocked due to foreign substances contained in high-temperature wastewater without using a filter. It is in providing.

The technical problem to be solved by the present invention need not be limited to the above-mentioned technical problem, and other technical problems that are not mentioned will be clearly understood by those of ordinary skill in the technical field to which the present invention belongs from the following description. I will be able to

In the rotary heat recovery apparatus according to the present invention for realizing the above-described object, a space for receiving wastewater is formed therein, a wastewater inlet is formed on one first sidewall, and a second sidewall facing the other side A wastewater collection tank in which a wastewater discharge port is formed in,

One side is connected to the fresh water inlet pipe and the other side penetrates the second side wall in a rotatable state by a driving means, and a first shaft positioned inside the wastewater collection tank and one side is connected to the first shaft, and the other side A drive shaft formed of a second shaft penetrating the first side wall and connected to a fresh water discharge pipe from the outside of the wastewater collection tank, and

It is composed of a plate shape with a space therein, and first and second connection portions having first and second shaft holes through which the second shaft is installed in the center of both sides facing each other, and first and second through holes connected to the space It is formed, and a plurality of are installed along the longitudinal direction of the second shaft, the first and second connecting portions facing each other to be in contact with each other is configured to include a disk connected to each other so as to maintain airtightness.

More preferably, the wastewater inlet may be configured to be located higher than the wastewater outlet.

More preferably, in the disk, a pair of first and second disks may be coupled to each other, and a plurality of first and second dimples may be formed on the surfaces of the first and second disks, respectively.

More preferably, the first and second dimples may be formed of either polygonal, circular, or streamlined shape, and may be radially disposed around the first and second shaft holes.

More preferably, the first and second dimples may be formed in a streamlined shape, with the head facing the first and second shaft holes, the tail facing the outer rim, and being curved and bent as a whole.

More preferably, the first and second dimples may have first and second auxiliary dimples between the tail portions.

More preferably, the first and second dimples have a head toward the first and second shaft holes, and a tail toward an outer rim, and are curved and bent as a whole, and the first and second dimples are opposite to each other. It can be composed of curves.

More preferably, one side of the first shaft is connected to the fresh water inlet pipe through a first rotation joint, and while a first coupler is installed on the other side, one side of the second shaft is connected to the center of the first coupler, so that the rotational force of the first shaft This is transmitted to the second shaft, and the outer circumference of the first coupler is connected to the first connection part of the disk so that the fresh water moved from the fresh water inlet pipe to the first coupler can be moved to the first through hole. Become,

The other side of the second shaft is connected to the center of one side of the second coupler, the other side of the second coupler is connected to the fresh water discharge pipe by a second rotation joint, and the outer circumference of one side of the second coupler is the second The fresh water connected to the connection part and discharged through the second through hole may be configured to be discharged to the fresh water discharge pipe through the second coupler and the second rotary joint.

More preferably, the first and second connection portions of the disk are formed with annular first and second installation grooves protruding outward from the first and second shaft holes, and first and second airtight holding members in the first and second installation grooves. Is installed, the first and second inclined surfaces are formed from the first and second shaft holes in the first and second installation grooves, and the first and second through holes may be radially spaced apart from the first and second inclined surfaces.

More preferably, a key groove may be formed in the inner circumference of the first and second shaft holes, and a key may be formed in the outer circumference of the second shaft so as to be detachable to the key groove.

More preferably, the inner circumference of the first and second shaft holes may be configured to be detached from the outer circumference of the second shaft through a gasket.

More preferably, the first and second dimples are welded to each other by contacting their inner surfaces in the inner space of the disk, and the overlapping outer circumferences of the first and second disks may be sealed.

More preferably, the sealing treatment may be configured to maintain airtightness by continuously caulking the outer circumferences of the first and second discs, or welding the outer circumferences of the first and second discs to maintain airtightness.

More preferably, the wastewater collection tank may be provided with a baffle plate protruding from the inner wall of the front and rear surfaces so that a part of the tip is sandwiched between the disks.

More preferably, a plurality of slots may be provided on the inner wall, and a baffle plate may be detachably installed in the slot.

The rotary heat recovery apparatus according to the present invention according to the configuration as described above has the following effects.

That is, when high-temperature wastewater is introduced from one side of the wastewater collection tank and discharged to the other side, fresh water is moved into a plurality of disks rotated inside the wastewater collection tank to achieve heat exchange. By accelerating and changing the flow, it is possible to effectively prevent contamination of the heat exchange line due to foreign substances contained in wastewater and blockage of a specific section without the use of a filter.

In addition, through the height difference between the wastewater inlet and the wastewater outlet installed in the wastewater collection tank, wastewater can be effectively moved even without using separate power, thereby reducing costs and has the effect of smoothly discharging wastewater.

In addition, since the disk is detachable from the drive shaft, replacement and maintenance of the disk are simplified, and heat exchange efficiency and pressure can be easily controlled by controlling the number and position of baffle plates installed between the disks. Have.

Since the effects of the present invention described as described above are naturally exerted by the composition of the contents described regardless of whether or not the designer is aware of it, the above-described effects are only a few effects according to the contents described, and all effects identified or actual by the designer are described. It should not be admitted to be.

In addition, the effect of the present invention will have to be further grasped by the overall description of the specification, and even if it is not described in an explicit sentence, a person having ordinary knowledge in the technical field to which the described content belongs will have such an effect through the present specification. If it is an effect that can be recognized as the effect will be seen as the effect described in the present specification.

1 is a perspective view of a rotary heat recovery device according to an embodiment of the present invention.
2 is a front view of a rotary heat recovery device according to an embodiment of the present invention.
3 is a side view of a rotary heat recovery device according to an embodiment of the present invention.
4 is another side view of a rotary heat recovery device according to an embodiment of the present invention.
5 is a plan view of a rotary heat recovery device according to an embodiment of the present invention.
6 is a front cross-sectional view of a main part of a rotary heat recovery device according to an embodiment of the present invention.
7 is a front cross-sectional view of another main part of the rotary heat recovery device according to an embodiment of the present invention.
8 is an exploded perspective view showing a disk of a rotary heat recovery device according to an embodiment of the present invention.
9 is a perspective view showing a state in which the disks of the rotary heat recovery device according to an embodiment of the present invention are coupled to each other.
10 is a front cross-sectional view illustrating a process of moving fresh water in the rotary heat recovery device according to an embodiment of the present invention.

Hereinafter, a configuration and operation according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

This is for explaining in detail enough that those of ordinary skill in the art to which the present invention pertains can easily implement the contents of the present invention, and this does not mean that the technical spirit and scope of the present invention are limited. .

In addition, in adding reference numerals to elements of each drawing, it should be noted that the same elements are marked with the same numerals as much as possible, even if they are indicated on different drawings, and take into account the configuration and operation of the present invention. Therefore, specially defined terms may vary according to the intentions or customs of users and operators, and definitions of these terms should be determined based on the contents throughout the present specification.

In addition, throughout the specification, when a certain part "includes" a certain component, it means that other components may be further included rather than excluding other components unless otherwise stated.

Hereinafter, the configuration of the present invention will be described in more detail with reference to the illustrated drawings.

First, the rotary heat recovery device according to the present invention includes a wastewater collection tank in which wastewater is temporarily accommodated, a drive shaft installed in the wastewater collection tank, and a drive shaft installed on such a drive shaft to move fresh water while rotating inside the wastewater collection tank. It can be broadly divided into a disk, and each configuration will be described in detail with reference to the drawings exemplified below.

First, the wastewater collection tank 100,

It may be configured in the shape of a housing having a predetermined size of the inner space, and a certain amount of wastewater is temporarily stored in the inner space.

The wastewater collection tank 100 may be in the form of a substantially rectangular parallelepiped as a specific embodiment, and the first side wall 110 and the second side wall 120 located on both sides in the length direction and the bottom surface located at the bottom, and in the front and rear sides in the width direction. It may be configured to include a pair of inner walls 130 located and a cover (not shown in the drawing) installed above the inner space to be closed.

The wastewater collection tank 100 has at least one wastewater inlet 111 formed on the first side wall 110 to allow the wastewater to flow into the inner space of the wastewater collection tank 100, and the second side wall 120 on the opposite side to collect wastewater. At least one wastewater discharge port 121 is formed to discharge the wastewater introduced into the inner space of the tank 100.

At this time, the wastewater inlet 111 formed in the first sidewall 110 is configured to be positioned higher from the installation surface than the wastewater outlet 121 formed in the second sidewall 120, so that the wastewater inlet 111 and the wastewater outlet ( The wastewater flowing into the inner space through the wastewater inlet 111 due to the height difference of 121) can be naturally discharged to the outside through the wastewater outlet 121 even without using separate power.

On the other hand, the wastewater inlet 111 and the wastewater outlet 121 may be provided with a separate control means capable of controlling the movement and movement amount of the wastewater, and such a control means is a manual valve that can be controlled manually or automatically controlled. It can be configured with an automatic valve that can be used.

If a problem occurs when the wastewater flowing into the wastewater collection tank 100 is discharged, a problem may occur in the internal pressure of the wastewater collection tank 100, so an overflow pipe (not shown in the drawing) This can be installed, and a drain part (not shown in the drawing) is provided on the bottom side of the wastewater collection tank 100 to remove water used for internal cleaning or foreign substances contained in the wastewater and settled on the floor. I can.

On the other hand, a fresh water inlet pipe 160 is installed on the second side wall 120 of the wastewater collection tank 100, and a fresh water discharge pipe 150 is installed on the opposite first side wall 110, and Inside, the fresh water inlet pipe 160 and the fresh water discharge pipe 150 are connected to each other through the drive shaft 200 and the disk 300 to be described later, so that the fresh water flowing into the fresh water inlet pipe 160 is transferred to the drive shaft 200 and the disk ( It is discharged to the fresh water discharge pipe 150 through 300).

Here, in the fresh water inlet pipe 160, a safety valve (not shown in the drawing) may be branched and installed in case a pressure problem occurs due to a flow of fresh water being blocked.

A support bracket may be installed at the bottom of the wastewater collection tank 100 so that it can be firmly and stably fixed to the floor installation surface.In another embodiment, a rolling means such as a roller is installed on the bottom of the wastewater collection tank 100 The collection tank 100 may be configured to be easily moved and installed.

The drive shaft 200,

It is installed rotatably along the longitudinal direction inside the above-described wastewater collection tank 100, and rotates the disk 300, which will be described later.

The drive shaft 200 is divided into a first shaft 210 and a second shaft 220 that are connected to each other in a specific embodiment, and the first shaft 210 has a first rotation joint 212 on one side of the fresh water inlet pipe 160. ), and the other side is connected to the driving means 230, so that the first shaft 210 is rotated according to the driving of the driving means 230.

Here, even if the first shaft 210 is rotated by the driving means 230, the fresh water inlet pipe 160 connected to one side of the first shaft 210 and the first rotation joint 212 is not affected by rotation. .

The driving means 230 may include, for example, a motor, a pulley, a belt, etc., and a pulley connected to the rotation shaft of the motor and a pulley connected to the first shaft 210 are connected by a belt to drive the motor. Accordingly, the first shaft 210 may be rotated.

In addition, the first shaft 210 has a hollow portion formed therein, so that the fresh water flowing into the fresh water inlet pipe 160 moves along the inner hollow portion of the first shaft 210, and the inside of the wastewater collection tank 100 The other end of the positioned first shaft 210 is provided with a first coupler 211 and is connected to a second shaft 220 to be described later and a disk 300 to be described later.

The second shaft 220 is rotated by receiving the rotational force of the first shaft 210 while one side of the second shaft 220 is connected through the first coupler 211 of the first shaft 210. The end of the coupler 211 is installed on the second shaft 220 and the first connector 313 formed on the first disk 310 of the disk 300 to be located in the foremost position of the disk to be described in detail later. It is coupled to the first airtight holding member 317 to be provided in the installation groove 316.

Therefore, the fresh water moved to the first coupler 211 through the hollow portion of the first shaft 210 is moved to the first through hole 315 located between the first installation groove 316 and the first shaft hole 314 to be As the inner space of 300 passes through the second through hole 325 of the second disc 320 coupled to face the first disc 310, the continuously installed discs pass through the above process.

And the other side of the second shaft 220 is connected to the second coupler 221 penetrating the first side wall 110, the second coupler 221 is the fresh water discharge pipe 150 through the second rotary joint 222 And, at this time, the inward end of the second coupler 221 is a second installation groove in the second connection part 323 formed on the second disk 320 of the disk 300 positioned at the rearmost part of the disk. As it is coupled with the second airtight holding member 327 provided in the 326, it flows into the first through hole 315 formed in the first disk 310 of the disk 300 located in the rearmost position, and the disk 300 located in the rearmost position. The fresh water passing through the second through hole 325 formed in the second disk 320 of the disk 300 located at the rear of the inner space of) is discharged to the fresh water discharge pipe 150 through the second rotating joint 222 It can be.

Here, the second shaft 220 is connected to the first shaft 210 and rotates, but the other side of the second shaft 220 is connected to the fresh water discharge pipe 150 through the second rotation joint 222, Due to the rotation joint 222, the fresh water discharge pipe 150 is not affected by the rotation of the second shaft 220.

Meanwhile, since the first coupler 211 and the second coupler 221 penetrate through the second side wall 120 and the first side wall 110, respectively, the bearing members ( It is preferable that the first coupler 211 and the second coupler 221 are respectively installed, and the first coupler 211 and the second coupler 221 are rotatably installed in the first side wall 110 and the second side wall 120 through such a bearing member. .

The disk 300,

By being rotatably installed inside the wastewater collection tank 100 through the above-described drive shaft 200, contamination by wastewater moving inside the wastewater collection tank 100 is prevented, and a passage of fresh water for heat exchange is provided. And, by accelerating and changing the flow of wastewater, the wastewater can be smoothly discharged to the outside of the wastewater collection tank 100.

In a specific embodiment, the first disk 310 and the second disk 320 of the same size are coupled to each other so that a space is formed therein, and the first disk 310 and the second disk 320 are combined. A first shaft hole 314 and a second shaft hole 324 communicating with each other are formed at the center of each other and are installed on the second shaft 220 described above while being matched to each other, and such a disk 300 is a second shaft 220 ) Are connected and installed in a row while maintaining a right angle with respect to the length direction of ).

In addition, first and second connecting portions 313 and 323 are formed in the centers of outer surfaces of the first and second discs 310 and 320, respectively, and the first and second connecting portions 313 and 323 are first The first and second shaft holes 314 and 324 formed in the centers of the disc 310 and the second disc 320 and the first and second shaft holes 314 and 324 are spaced outward from the first and second shaft holes 314 and 324 to form an annular shape at a constant interval. A plurality of first and second through-holes 315 and 325 are arranged to be spaced apart from the first and second through-holes 315 and 325 to form an annular shape, and the first and second installation grooves 316 and 316 ( 326) may be included.

Here, the first and second installation grooves 316 and 326 are formed to protrude outward from the outer surfaces of the first disk 310 and the second disk 320, and the first and second installation grooves 316 and 326 First and second airtight holding members 317 and 327 such as silicone for airtightness may be installed respectively.

In addition, as the first and second installation grooves 316 and 326 are formed protruding in this way, the first and second shaft holes 314 and 324 are relatively depressed, and the first and second installation grooves 316 The first and second inclined surfaces 318 and 328 are formed from 326 to the first and second shaft holes 314 and 324, and the first and second through holes 315 are formed on the first and second inclined surfaces 318 and 328. As the) 325 is formed, the flow of fresh water passing through the first and second through holes 315 and 325 may be improved.

On the other hand, the disk 300 is composed of a plurality of disks are continuously installed in close contact along the longitudinal direction on the second shaft 220, the second connecting portion 323 formed on the second disk 320 of one disk and the next disk. The second airtight holding member 327 and the first connection part 313 installed in the second installation groove 326 of the second connection part 323 as the first connection parts 313 formed on the first disk 310 of the are in contact with each other The plurality of disks 300 may be coupled to each other in a manner in which the first airtight holding members 317 installed in the first installation groove 316 of are closely coupled to each other to maintain airtightness.

Here, at least one or more first and second dimples 311 and 321 may be formed on the outer surfaces of the first disk 310 and the second disk 320 of the disk 300 to be recessed inward. , The first and second dimples 311 and 321 may be formed while being symmetrical or asymmetrical to each other.

Preferably, the first and second dimples 311 and 321 are formed in a plurality and are radially formed at regular intervals around the first and second shaft holes 314 and 324, thereby preventing the disk 300 from rotating. Due to the 1,2 dimples 311 and 321, the wastewater flowing into the wastewater collection tank 100 by accelerating or varying the flow of wastewater that is in contact with the outer surface of the disk 300 is transferred to the wastewater collection tank 100. It can be discharged smoothly and quickly to the outside.

The shape of the first and second dimples 311 and 321 as described above does not need to be set to any one, and may be variously deformed into, for example, polygonal, circular, or elliptical.

Preferably, the shape of the first and second dimples 311 and 321 may be streamlined, and more preferably, the shape of the first and second dimples 311 and 321 may be streamlined, and more preferably, the shape of the first and second dimples 311 and 321 is streamlined and curved. The two shaft holes 314 and 324 may be directed, and the tail portion of the narrow area may be configured to face the outer circumference of the disk 300.

In addition, the first and second dimples 311 and 321 of a streamlined and curved shape are centered on the first and second shaft holes 314 and 324 on the outer surfaces of the first and second discs 310 and 320. The first and second auxiliary dimples 312 and 322 may be further provided between the tail portions that are radially arranged and spaced, and the first and second auxiliary dimples 312 and 322 are also polygonal. However, it may be configured in a circular or elliptical shape or a streamlined shape and a curved streamlined shape.

In addition, since the first and second dimples 311 and 321 having a streamlined and curved shape are formed on the first and second disks 310 and 320, the first and second dimples 311 and 2 The curve of 321 may be configured to be symmetrical to each other so that the curves of the first dimple 311 and the second dimple 321 are bent in the same direction. Due to the first and second dimples 311 and 321 bent in opposite directions on the outer surfaces of the 310 and the second disk 320 to form a curve, the flow of wastewater is accelerated and changed in various ways, so that the flowability of the wastewater is improved. It may be configured to be better.

Meanwhile, since the disk 300 is installed on the second shaft 220 through the first and second shaft holes 314 and 324, the inner shaft circumference of the first and second shaft holes 314 and 324 of the disk 300 By forming a keyway and forming a key at the outer circumference of the second shaft 220 so that it can be detached from the keyway, the rotational force of the second shaft 220 while the disk 300 and the second shaft 220 can be detached and detached. It may be configured to be accurately transmitted to the disk 300.

In addition, as another example, the first and second shaft holes 314 and 324 and the second shaft 220 of the disk 300 may be detachably coupled to each other through a gasket, and the disk 300 It is also possible to prevent a phenomenon in which the fresh water moving inside escapes through the connection portion between the first and second shaft holes 314 and 324 and the second shaft 220.

In addition, in combining the first and second discs 310 and 320 to constitute the disc 300, the first and second dimples 311 and 311 are recessed in the first and second discs 310 and 320. As the inner surfaces of the first and second discs 310 and 320 come into contact with each other in the inner space of the first and second discs 310 and 320, the second dimple 321 and the inner side of the second disc 320 are Spot welding any one point of the first dimple 311 to be contacted at to fix each other, or to be in contact with the first dimple 311 of the first disk 310 on the outer surface of the second disk 320 Any one point of the second dimple 321 may be fixed to each other by spot welding.

When spot welding is performed on the first original plate 310, it may be applied to all of the first dimples 311 or any one or more selected first dimples 311, and applied to any one or more selected first dimples 311. In this case, it is preferable that each is applied to the first dimples 311 at least in all directions opposite to each other.

Even when spot welding is performed on the second disk 320 side, it may be applied to all of the second dimples 321 or any one or more selected second dimples 321, and applied to any one or more selected second dimples 321. In this case, it is preferable that each is applied to the second dimples 321 at least in all directions opposite to each other.

In addition, the overlapped outer circumferences of the first and second discs 310 and 320 may be sealed to prevent the inflow of wastewater into the inner space.

Here, the sealing treatment is performed to maintain airtightness by continuously caulking along the overlapped outer circumferences of the first and second discs 310 and 320, or the overlapped outer circumference of the first and second discs 310 and 320 It can be welded to maintain airtightness, and in addition, it can be modified and implemented in various types of assembly methods that can be kept airtight.

Meanwhile, in the wastewater collection tank 100, the wastewater is effectively moved between the disks 300 to increase the contact time between the wastewater and the fresh water flowing through the disk 300, so that the heat exchange efficiency of the fresh water can be improved. For this, at least one baffle plate 140 may be installed.

Preferably, the baffle plate 140 may be formed by protruding from the inner wall 130 located in front of the wastewater collection tank 100 so that the protruding end of the baffle plate 140 is sandwiched between the disks 300, or wastewater It may be formed by protruding from the inner wall 130 located at the rear of the collection tank 100 so that the protruding end of the baffle plate 140 is inserted between the disks 300, or the front and rear of the wastewater collection tank 100 The protruding ends of the baffle plate 140 may be formed to protrude from all of the inner walls 130 located in the disc 300 so that the protruding ends of the baffle plate 140 may be fitted to face each other.

Here, the baffle plate 140 may be configured to be sandwiched between all of the disks 300, but to be fitted in a regular or irregular arrangement between the disks 300 selected for heat exchange efficiency and internal pressure control. It can also be configured.

If the number of baffle plates 140 is large, the heat exchange efficiency increases, but pressure loss increases. On the contrary, if the number of baffle plates 140 is small, the heat exchange efficiency decreases, but pressure loss decreases. It is preferable that the volume of (100), the degree of the incoming wastewater, the internal pressure of the wastewater collection tank (100), the required heat exchange efficiency, etc. are determined, and the installation state of the baffle plate (140) can be varied and adjusted as necessary. Do.

In an embodiment for variable installation of the baffle plate 140, by installing a slot member on the inner wall 130, and configuring the baffle plate 140 to be detachably installed on the slot member, the interior of the wastewater collection tank 100 It is preferable that the number of baffle plates 140 installed in the baffle plate 140 are installed in various forms as necessary to effectively control heat exchange efficiency and pressure.

Meanwhile, the outer surfaces of the disk 300 or the baffle plate 140 or both the disk 300 and the baffle plate 140 described above are coated with an inorganic nano-coating agent of fine particles, so that the surface of the disk 300 and the baffle plate 140 It is possible to more effectively prevent contamination such as corrosion or adhesion of scales, and reduce the frictional force between the wastewater and the disk 300 and the baffle plate 140 to better improve the flowability of the wastewater.

Here, the above-described inorganic nano-coating agent may be aluminum oxide, silicon dioxide, titanium dioxide, zinc oxide, or the like, preferably anatase-type titanium dioxide (TiO ₂ ).

Titanium dioxide acts as a photocatalyst and prevents the propagation of microorganisms on the surface, so that the formation of scale by the microorganisms can be suppressed.

The particle size of the inorganic nano-coating agent may be 0.1 nm to 30 nm, preferably 1 nm to 10 nm.

In addition, the coating method of the inorganic nano-coating agent is to remove contaminants from the surface of the disk 300 or the baffle plate 140 or both the disk 300 and the baffle plate 140 to be coated, and then the disk 300 or the baffle plate. (140) or a primer layer is formed on the surface of both the disk 300 and the baffle plate 140, and the disk 300 or the baffle plate 140 or both the disk 300 and the baffle plate 140 on which the primer layer is formed Is immersed in an inorganic nano-coating agent, or applied with a brush, roller, or spray to form an inorganic nano-coating layer and dried at room temperature.

When the coating method of the inorganic nano-coating agent is described in more detail, the surfaces of the disk 300 or the baffle plate 140 or both the disk 300 and the baffle plate 140 are washed with water, After removing the contaminants, in order to remove the oil components remaining on the surface, methanol or ethanol, which is an organic solvent, is applied and cleaned through the disk 300 or the baffle plate 140 or the disk 300 and the baffle plate ( 140) First, remove foreign substances on the surface of everyone.

And the disk 300 or baffle plate 140 from which foreign matters are removed, or both the disk 300 and the baffle plate 140 are prepared with a primer consisting of 90 to 98% by weight of ethyl acetate and 2 to 10% by weight of trichloroisocyanuric acid. After immersing in 1 to 5 minutes, it is naturally dried at room temperature for 10 to 30 minutes to form a primer layer.

Thereafter, the disk 300 or the baffle plate 140 on which the primer layer was formed, or both the disk 300 and the baffle plate 140 were immersed in the inorganic nano-coating solution for 1 to 5 minutes, and then naturally dried at room temperature for 20 to 28 hours. So that the coating layer is formed.

It is preferable that the thickness of the inorganic nano-coating layer is formed from 20 nm to 80 nm depending on the immersion time.

If necessary, the disk 300 or the baffle plate 140 on which the coating film is formed, or both the disk 300 and the baffle plate 140 may be re-deposited or applied with a brush, roller, or spray in order to secondary coat.

A process in which heat is recovered through the rotary heat recovery device of the present invention configured as described above is as follows.

First, the wastewater that has become hot while being used in facilities such as factories is introduced into the inside of the wastewater collection tank 100 through the wastewater inlet 111 of the first side wall 110, and the introduced wastewater is then the wastewater inlet 111. It is naturally discharged to the wastewater discharge port 121 located at a lower position, and in this process, the wastewater passes between the disks 300 rotating inside the wastewater collection tank 100.

Meanwhile, with the movement of such wastewater, fresh water at room temperature is introduced into the fresh water inlet pipe 160 located on the second side wall 120, and the introduced fresh water is passed through the first coupler 211 of the first shaft 210. After flowing into the first through hole 315 of the first connector 313 provided in the first disk 310 of the foremost disk 300 among the disks installed on the second shaft 220, the foremost disk 300 After passing through the inner space of the first and second disks 310 and 320, they are passed through the second through holes 325 of the second connector 323 provided in the second disk 320.

And in this way, after passing through the inner spaces of the disks connected to each other after the foremost disk 300, through the second coupler 221 and the second rotating joint 222 connected to the rearmost disk 300, the fresh water discharge pipe 150 It is discharged, and in this process, the fresh water at room temperature is heated to a predetermined temperature by performing heat exchange with the high temperature wastewater.

In addition, as the disk 300 is rotated through the driving means 230 as described above, it is possible to prevent foreign substances contained in wastewater from being deposited in the heat exchange line including the disk 300.

In addition, during the rotation of the disk 300, the disk 300 is affected by the first and second dimples 311 and 321 provided on the outer surfaces of the first and second disks 310 and 320 of the disk 300. By accelerating and variously changing the flow of wastewater passing through the outer surface, more effectively preventing foreign substances from depositing in the heat exchange line, and at the same time guiding the wastewater to the wastewater outlet 121 to help discharge the wastewater, thereby collecting wastewater. The flowability of wastewater passing through the tank 100 is improved, and the effectiveness and performance of the device may be doubled due to the self-cleaning action of the wastewater.

As described above, in the detailed description of the present invention, specific embodiments have been described, but, of course, various modifications may be made without departing from the scope of the described content. Therefore, the scope of the described content is not limited to the described embodiments and does not need to be defined, and should be determined by the claims and equivalents as well as the claims to be described later.

100: wastewater collection tank 110: first side wall
111: wastewater inlet 120: second side wall
121: wastewater outlet 130: inner wall
140: baffle plate 150: fresh water discharge pipe
160: fresh water inlet pipe 200: drive shaft
210: first axis 211: first coupler
212: 1st rotation joint 220: 2nd axis
221: second coupler 222: second rotation joint
230; Driving means 300: disk
310: first disk 311: first dimple
312: first auxiliary dimple 313: first connection
314: 1st shaft hole 315: 1st hole
316: first installation groove 317: first airtight holding member
318: first slope 320: second disk
321: second dimple 322: second auxiliary dimple
323: second connection part 324: second shaft hole
325: second through hole 326: second installation groove
327: second airtight holding member 328: second slope

Claims (15)

Wastewater collection in which a space in which wastewater is accommodated is formed, a wastewater inlet 111 is formed on one of the first sidewalls 110, and a wastewater discharge port 121 is formed on the second sidewall 120 of the opposite side Tank 100;
One side is connected to the fresh water inlet pipe 160 and the other side is rotatable by the driving means 230 and penetrates the second side wall 120 to be located inside the wastewater collection tank 100 ( 210) and one side is connected to the first shaft 210, and the other side is connected to the fresh water discharge pipe 150 from the outside of the wastewater collection tank 100 by passing through the first side wall 110. ) Consisting of a drive shaft 200; And
The first and second shaft holes 314 and 324 through which the second shaft 220 is installed in the center of each side facing each other, and the first and second holes connected to the inner space The first and second connecting portions 313 and 323 provided with 315 and 325 are formed, and a plurality of the first and second connecting portions 313 and 323 are formed, and a plurality of them are installed along the longitudinal direction of the second shaft 220, Includes a disk 300 that is connected to each other so that the two connection portions 313 and 323 are kept airtight,
The first and second connecting portions 313 and 323 of the disk 300 protrude outward from the first and second shaft holes 314 and 324, and the annular first and second installations are recessed into the surface. Grooves 316 and 326 are respectively formed, and first and second airtight holding members 317 and 327 are respectively installed in the first and second installation grooves 316 and 326 so that the disk 300 is adjacent to each other. The first and second inclined surfaces 318 and 328 from the first and second installation grooves 316 and 3326 to the first and second shaft holes 314 and 324 are in close contact with each other when they are connected. The first and second inclined surfaces 318 and 328 have the first and second shaft holes 314 and 324 as a center, and the first and second through holes 315 and 325 are radially formed at uniform intervals. Spaced apart,
The first and second shaft holes 314, 324 are detachably installed on the outer circumference of the second shaft 220 while a gasket is installed on the inner circumference of the first and second shaft holes 314, 324, and Prevents fresh water from leaking through the connection gap of the second shaft 220,
The wastewater collection tank 100 has a baffle plate 140 formed protruding from the inner wall 130 on the front and rear surfaces so that a part of the tip is sandwiched between the disk 300 is installed, and a plurality of slots are provided in the inner wall 130. And the baffle plate 140 is detachably installed in the slot, so that the number of baffle plates 140 and the installation interval are adjusted. The method according to claim 1,
The wastewater inlet 111,
Rotatable heat recovery device, characterized in that configured to be positioned higher than the wastewater outlet (121). The method according to claim 1,
The disk 300,
A pair of first and second discs 310 and 320 are combined to face each other, and a plurality of first and second dimples 311 and 321 are provided on the surfaces of the first and second discs 310 and 320. Rotary type heat recovery device, characterized in that each formed. The method of claim 3,
The first and second dimples 311 and 321 are formed in either polygonal, circular, or streamlined shape, and are arranged radially while forming an annular shape around the first and second shaft holes 314 and 324. Rotary heat recovery device. The method of claim 4,
The first and second dimples 311 and 321 are,
A rotary heat recovery device comprising a streamlined shape, wherein the head faces the first and second shaft holes 314 and 324, the tail faces the outer rim of the disk 300, and is curved as a whole. . The method of claim 5,
The first and second dimples 311 and 321 are,
Rotatable heat recovery apparatus, characterized in that the first and second auxiliary dimples (312, 322) are provided between the tail. The method of claim 4,
The first and second dimples 311 and 321 are,
The head portion faces the first and second shaft holes 314 and 324, the tail portion faces the outer rim of the disk 300, and is formed by being curved as a whole, and the first dimple 311 and the second dimple (321) is a rotary type heat recovery device, characterized in that the curves in opposite directions to each other. The method according to claim 1,
One side of the first shaft 210 is connected to the fresh water inlet pipe 160 through a first rotation joint 212, and the other side is at the center of the first coupler 211 while the first coupler 211 is installed. One side of the second shaft 220 is connected so that the rotational force of the first shaft 210 is transmitted to the second shaft 220, and the outer circumference of the first coupler 211 is The fresh water connected to the first connector 313 and moved from the fresh water inlet pipe 160 to the first coupler 211 is configured to be moved to the first through hole 315,
The other side of the second shaft 220 is connected to the center of one side of the second coupler 221, and the other side of the second coupler 221 is connected to the fresh water discharge pipe 150 by a second rotation joint 222 And, the outer circumference of one side of the second coupler 221 is connected to the second connection part 323 of the disk 300, and the fresh water discharged through the second through hole 325 is connected to the second coupler 221 and the A rotary heat recovery device, characterized in that configured to be discharged to the fresh water discharge pipe 150 through a second rotary joint 222. delete The method according to claim 1,
The first and second shaft holes 314 and 324 have a key groove formed on the inner circumference, and a key is formed on the outer circumference of the second shaft 220 so as to be detachable from the key groove. . delete The method of claim 3,
The first and second dimples 311 and 321 are,
A rotary heat recovery device, characterized in that the inner surfaces of the disk 300 are in contact with each other and are welded to each other, and the overlapping outer circumferences of the first and second disks 310 and 320 are sealed. The method of claim 12,
The sealing treatment,
Maintaining airtightness by continuously caulking the outer circumferences of the first and second discs 310 and 320, or welding the outer circumferences of the first and second discs 310 and 320 to maintain airtightness. Rotary type heat recovery device, characterized in that. delete delete

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