KR20240000672U - Salt Farm Having Salinity Maintenance Structure - Google Patents

Abstract

A salt farm including a salinity maintenance structure is disclosed. A salt farm according to an embodiment of the present invention includes a reservoir formed adjacent to the sea, having a predetermined width and depth, extending a predetermined length along the coastline, and having a structure that stores seawater from the sea by a predetermined volume; an evaporation pond formed adjacent to the reservoir, extending inland by a predetermined width and length to have an area of a predetermined size, and receiving seawater from the reservoir and evaporating it to increase the salinity of the seawater; A crystallization pond formed adjacent to the evaporation pond, extending inland by a predetermined width and length to have an area of a predetermined size, and receiving seawater with an increased salinity from the evaporation pond and evaporating it to obtain sea salt crystals; A main body formed adjacent to the evaporation pond and having a structure for receiving seawater stored in the evaporation pond by an operator or providing seawater back to the evaporation pond; and installed adjacent to the seawater, operated by an operator to cover the upper surface of the seawater contained in the seawater to form a cover layer, and then supplying water to the upper surface of the cover layer to form a water layer of a predetermined thickness, The gist of the configuration is to include a seam cover portion that prevents foreign substances from penetrating into seawater.
According to the present design, it is possible to prevent the problem of rainwater and foreign substances penetrating into the evaporation pond and changing salinity due to rainy weather, and to manufacture high-quality solar salt by actively responding to weather changes and preserving the state of the evaporation pond. A salt pan containing the composition can be provided.

Description

Salt Farm Having Salinity Maintenance Structure}

The present invention relates to a salt farm, and more specifically, to a salt farm that includes a structure that can prevent salinity changes due to rainy weather by stably covering the evaporation pond and seaweed.

Salt is also referred to as table salt, and its chemical name is sodium chloride (NaCl). It is widely used in everyday life such as seasoning and salting, and is also used in large quantities in industrial fields such as the production of soda (sodium carbonate).

Salt is rich in minerals and has been known to be essential for the survival and prosperity of all living things. Salt is an important cation in human extracellular fluid that regulates the osmotic pressure of body fluids, participates in acid-base balance, and is not only a nerve impulse transmitter, but also aids in the production of gastric acid to form digestive juices, participates in enzyme activity, and produces the purest salty taste. Therefore, it is often used as a seasoning to enhance the taste of food and improve storage.

Such salt can be classified into sea salt, rock salt, mechanical salt, re-salt, processed salt, etc. Most of the world's salt production is rock salt or refined salt, but sea salt is traditionally preferred because it suits our tastes.

The purity of sea salt is 80 to 88% or higher and the salinity is low, but it contains impurities and therefore contains components harmful to the human body. Refined salt is 95 to 99% or higher and contains almost no components harmful to the human body, but also contains almost no mineral components beneficial to the human body. It has been known.

The characteristic of Korea's sea salt is that it is one of the five major mudflats in the world, specifically the east coast of Canada, the east coast of the United States, the North Sea coast of Germany, the Amazon River basin in Brazil, and the west coast of Korea, and is based on a mudflat salt farm rich in minerals. It is being done. Based on this production base, sea salt is an alkaline salt that is good for the body, has low oxidation, and contains various cations such as calcium (Ca), magnesium (Mg), and potassium (K), so it has an excellent softening prevention effect and is used in our traditional foods such as kimchi and sauce. , salted seafood, etc. have maintained their unique taste and flavor.

A salt farm that produces solar salt generally consists of a reservoir, an evaporation pond, and a crystallization pond, and in addition, a salt pond or road is built, and all of these facilities are cut off from external water by a seawater embankment and an inner embankment to prevent inland water intrusion.

Figure 1 is a diagram conceptually showing the structure of a general salt farm. Referring to FIG. 1, the reservoir (S) is a place to trap seawater, the evaporation pond (E) is a place to evaporate the salt water flowing in from the reservoir (S) with sunlight and wind, and the crystallization pond (C) refers to a place where the saturated water concentrated in the evaporation pond (E) is thinly spread and concentrated and the salt is crystallized to collect salt.

Figure 2 is a photograph showing the process of dyeing from the above-mentioned crystal paper (C) using a rolling pin.

Typically, the evaporation pond (E) is located at the top, and the crystallization pond (C) is arranged at the bottom. The evaporation pond (E) and the crystallization pond (C) are each divided into multiple stages, and the divided areas have a flat floor (1). is formed The collected salt is stored in the salt warehouse (G) to remove bittern.

Meanwhile, Haeju (H), that is, Haeju warehouse, for temporarily storing concentrated saturated water in situations such as rainy weather, is provided in the middle or on one side of the evaporation pond (E) or crystallization pond (C).

However, asbestos slate is mainly used as the roof of a conventional salt farm. In this case, the problem of salt water being contaminated by asbestos arises, and when coated steel plates are used, corrosion and salt water contamination due to corrosion ultimately occur. The problem of salt contamination arises.

In addition, since the conventional roof of Haeju blocks sunlight without transmitting it, the temperature of the salt water in the pool of Haeju falls and the salt water must be reheated in the evaporation or crystallization pond for a considerable period of time in order to evaporate again in the evaporation or crystallization pond. there is a problem.

Therefore, there is a need for technology that can solve the problems caused by the prior art.

Korean Patent Publication No. 10-2013-0003270 (Publication date: January 9, 2013)

The purpose of the present invention is to prevent the problem of rainwater and foreign matter mixing into the evaporation pond and the unroofed beach due to rain and changing the salinity, and to actively respond to weather changes to maintain the salinity of the evaporation pond and to maintain the water's surface. The purpose is to provide a salt farm that includes a configuration that can produce a large amount of sea salt by preserving the salinity state.

A salt farm according to one aspect of the present invention for achieving this purpose includes a reservoir formed adjacent to the sea, having a predetermined width and depth, extending a predetermined length along the coastline, and having a structure that stores seawater from the sea by a predetermined volume; an evaporation pond formed adjacent to the reservoir, extending inland by a predetermined width and length to have an area of a predetermined size, and receiving seawater from the reservoir and evaporating it to increase the salinity of the seawater; A crystallization pond formed adjacent to the evaporation pond, extending inland by a predetermined width and length to have an area of a predetermined size, and receiving seawater with an increased salinity from the evaporation pond and evaporating it to obtain solar salt crystals; A main body formed adjacent to the evaporation pond and having a structure for receiving seawater stored in the evaporation pond by an operator or providing seawater back to the evaporation pond; and installed adjacent to the seawater, operated by an operator to cover the upper surface of the seawater contained in the seawater to form a cover layer, and then supplying water to the upper surface of the cover layer to form a water layer of a predetermined thickness, It may be configured to include a seam cover that prevents rainwater and foreign substances from penetrating into seawater with increased salinity.

In one embodiment of the present invention, the evaporation pond is formed adjacent to the reservoir, extends inland by a predetermined width and length to have an area of a predetermined size, and receives seawater from the reservoir to perform primary evaporation. a first evaporation pond that increases the salinity of seawater and then delivers it to the second evaporation pond; And it is formed adjacent to the first evaporation pond, and extends inland by a predetermined width and length to have an area of a predetermined size. Seawater with an increased salinity is provided from the first evaporation pond and secondary evaporation is performed to produce seawater. It may be configured to include a second evaporation pond that increases the salinity and then transfers it to the crystallization pond.

In one embodiment of the present invention, the evaporation pond includes a first rail that extends a predetermined length in the direction along both ends of the evaporation pond and is mounted symmetrically on both sides; a sliding drive unit mounted on the first rail to change its sliding position; An inclination change part of a link structure that is mounted on the sliding drive unit by a hinge structure and is inclined in the direction of movement of the sliding drive unit; It is mounted on the slope change part, is mounted in pairs at a predetermined interval in the direction of extension of the first rail, has a predetermined height, is a plate-shaped structure having a length corresponding to the width of the evaporation pond, and is opposite to the upper surface of the evaporation pond. A push plate equipped at an end with an elastic member made of a flexible material having an elastic restoring force of a predetermined size; and a control unit installed adjacent to the salt farm, performing wireless communication with the worker's smart device, and controlling the operation of the sliding drive unit by a control signal received from the smart device.

In one embodiment of the present invention, the push plate is mounted on the first link of the tilt changing portion, has a plate-shaped structure having a predetermined width in the vertical height direction, and has an elastic member mounted at the bottom; and a second push plate mounted on the second link of the inclination change part, having a plate-shaped structure having the same upper and lower width as the first push plate, and having an elastic member mounted at the bottom.

In this case, the tilt changing part is mounted on one side of the sliding driving part to be rotatable by a predetermined angle by a hinge driving part, and is mounted in a structure that extends a predetermined length in a direction parallel to the extending longitudinal direction of the first rail. base link; a first link mounted on one end of the base link to be rotatable by a predetermined angle by a first rotating part and extending downward by a predetermined length; a second link mounted on the other end of the base link so as to be rotatable by a predetermined angle by a second rotating part and extending downward by a predetermined length; and a connecting link that connects the lower ends of the first link and the second link to each other by a hinge structure and has the same length as the base link.

In one embodiment of the present invention, the seam cover part includes a second rail that extends along both end edges of the seam by the length of the seam and is mounted symmetrically on both sides; an installation drive unit mounted on the second rail to change its sliding position; A cover fastening part mounted on the installation drive unit and having a structure coupled to one end of the cover member from the cover storage drum; A cover storage drum adjacent to the seam and having a structure having a width equal to the width of the seam, and having a structure in which the cover member is wound and stored; A plurality of water spray units are mounted on the cover storage drum at regular intervals and spray water supplied from the outside onto the upper surface of the cover member to form a water layer; And a control unit installed adjacent to the salt farm, performing wireless communication with the worker's smart device, and controlling the operation of the installation drive unit, cover storage drum, and water spray unit by a control signal received from the smart device. You can.

As explained above, according to the salt farm, by providing a reservoir, evaporation pond, crystallization pond, seaweed, and seawater cover of a specific structure, the problem of rainwater and foreign substances penetrating into the evaporation pond and seawater due to rainy weather and changing the salinity can be avoided. It is possible to provide a salt farm that includes a configuration that can produce a large amount of solar salt by actively responding to weather changes and preserving the salinity state of the evaporation pond and Haeju.

Figure 1 is a plan schematic diagram showing a salt farm structure according to the prior art.
Figure 2 is a photograph showing the pushing operation in a salt farm according to the prior art.
Figure 3 is a plan schematic diagram showing a salt farm according to an embodiment of the present invention.
Figure 4 is a plan schematic diagram showing the state in which seawater is collected on the shore of the salt farm shown in Figure 3.
Figure 5 is a plan schematic diagram showing a state in which the upper surface of the seabed is covered by operating the seam cover part of the salt farm shown in Figure 4.
Figure 6 is a plan schematic diagram showing a salt farm including a seam cover according to another embodiment of the present invention.
Figure 7 is a partial longitudinal cross-sectional view showing a state covered by the main cover portion according to an embodiment of the present invention.
Figure 8 is a partial enlarged view showing the bottom cover of a salt farm according to an embodiment of the present invention.
Figure 9 is a plan schematic diagram showing a salt farm according to another embodiment of the present invention.
FIG. 10 is a plan schematic diagram showing the first rail, sliding drive unit, inclination change unit, and push plate that can serve as a pusher for the salt farm shown in FIG. 9.
Figure 11 is a front view showing the first rail, sliding drive part, inclination change part, and push plate in Figure 10.
FIG. 12 is a partially enlarged view showing the sliding drive unit shown in FIG. 11 moving to the left and performing a pushing operation.
FIG. 13 is a partially enlarged view showing the sliding drive unit shown in FIG. 11 moving to the right and performing a pushing operation.
Figure 14 is a configuration diagram showing the control flow of a salt farm according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. Prior to this, terms and words used in this specification and claims should not be construed as limited to their usual or dictionary meanings, but should be interpreted as meanings and concepts consistent with the technical idea of the present invention.

Throughout this specification, when a member is said to be located “on” another member, this includes not only cases where a member is in contact with another member, but also cases where another member exists between the two members. Throughout this specification, when a part "includes" a certain component, this means that it may further include other components rather than excluding other components, unless specifically stated to the contrary.

Figure 3 shows a plan schematic diagram showing a salt farm according to an embodiment of the present invention, Figure 4 shows a plan schematic diagram showing a state in which seawater is collected on the main edge of the salt farm shown in Figure 3, and Figure 5 shows a A plan schematic diagram showing the state in which the upper surface of the seabed is covered by operating the seam cover part of the salt farm shown in Figure 4 is shown.

Referring to these drawings, the salt farm 100 according to this embodiment is provided with a reservoir 110, an evaporation pond 120, a crystallization pond 130, a basin 140, and a basin cover 150 of a specific structure. By doing so, it is possible to prevent the problem of rainwater and foreign matter penetrating into the evaporation pond 120 and Haeju 140 due to rainy weather and changing salinity, and actively responding to weather changes to evaporate the evaporation pond 120 and Haeju (140). 140) It is possible to provide a salt farm that includes a configuration capable of producing a large amount of sea salt by preserving the salinity state.

Hereinafter, each component constituting the salt farm 100 according to this embodiment will be described in detail with reference to the drawings.

Figure 6 is a plan schematic diagram showing a salt farm including a seam cover according to another embodiment of the present invention, and Figure 7 is a partial longitudinal cross-section showing a state covered by a seam cover according to an embodiment of the present invention. A diagram is shown, and Figure 8 shows a partially enlarged view showing the main cover portion of a salt farm according to an embodiment of the present invention.

Referring to FIGS. 3 to 8, the reservoir 110 according to this embodiment is formed adjacent to the sea, has a predetermined width and depth, and extends a predetermined length along the coastline, and receives seawater from the sea by a predetermined volume. It is a water storage structure.

The evaporation pond 120 according to this embodiment is formed adjacent to the reservoir 110, and is formed to extend inland by a predetermined width and length to have an area of a predetermined size, and receives seawater from the reservoir 110. It is provided and evaporated to increase the salinity of sea water.

Specifically, the evaporation pond 120 may be configured to include a first evaporation pond 121 and a second evaporation pond 122 of a specific structure, as shown in FIGS. 3 to 6 . The first evaporation pond 121 of the evaporation pond 120 is formed adjacent to the reservoir 110 and extends inland by a predetermined width and length to have an area of a predetermined size, and the reservoir 110 ), the seawater can be first evaporated to increase the salinity of the seawater, and then delivered to the second evaporation pond (122). The second evaporation pond 122 of the evaporation pond 120 is formed adjacent to the first evaporation pond 121, and extends inland by a predetermined width and length to have an area of a predetermined size, Seawater with increased salinity can be received from the first evaporation pond 121, secondary evaporation is performed to increase the salinity of the seawater, and then it can be delivered to the crystallization pond 130.

The crystallization pond 130 according to this embodiment is formed adjacent to the evaporation pond 120, and is formed to extend inland by a predetermined width and length to have an area of a predetermined size, and the evaporation pond 120 Sea salt crystals are obtained by receiving seawater with increased salinity and evaporating it.

The seawater 140 according to this embodiment is a configuration formed adjacent to the evaporation pond 120, and accommodates seawater stored in the evaporation pond 120 by an operator or provides seawater back to the evaporation pond 120. It is a structure.

The seaweed cover 150 according to this embodiment is a configuration installed adjacent to the seawater 140 and the crystallization pond, and is operated by an operator to cover the upper surface of the seawater contained in the seawater 140 to form a cover layer. After that, water is supplied to the upper surface of the cover layer to form a water layer of a predetermined thickness, thereby preventing rainwater and foreign substances from penetrating into seawater with increased salinity from the outside.

Specifically, the bottom cover part 150 includes a second rail 151 of a specific structure, an installation drive part 152, a cover fastening part 153, a cover storage drum 154, a water spray part 156, and a control part (C). It may be a configuration including.

The second rail 151 of the main cover portion 150 extends along both end edges of the main cover 140 to the length of the main part 140 and is mounted symmetrically on both sides. The installation drive unit 152 is mounted on the second rail 151 so that its sliding position can be changed. The cover fastening part 153 is a component mounted on the installation driving part 152 and has a structure that is coupled to one end of the cover member 155 from the cover storage drum 154. The cover storage drum 154 is adjacent to the base 140 and has a width equal to the width of the base 140, and is structured to wind and store the cover member 155. The water spray unit 156 is mounted on the upper part of the installation drive unit 152 or is mounted on the cover storage drum 154 at regular intervals, and sprays water supplied from the outside onto the upper surface of the cover member 155. Thus, a water layer can be formed. At this time, as shown in FIG. 7, the formed water layer can stably fix the position of the cover member 155, preventing it from being blown away by the wind. As shown in FIG. 14, the control unit (C) is a component installed adjacent to the salt farm and performs wireless communication with the worker's smart device, and controls the installation drive unit 152 and the cover by a control signal received from the smart device. The operation of the storage drum 154 and the water spray unit 156 can be controlled.

Figure 9 shows a plan schematic diagram showing a salt farm according to another embodiment of the present invention, and Figure 10 shows a first rail, a sliding drive unit, a slope change unit, which can serve as a pusher for the salt farm shown in Figure 9. A plan schematic diagram representing the push plate is shown. In addition, Figure 11 shows a front view showing the first rail, the sliding drive part, the inclination change part, and the push plate in Figure 10, and Figure 12 shows the sliding drive part shown in Figure 11 moving to the left and performing the push operation. A partially enlarged view showing the appearance is shown, and FIG. 13 shows a partially enlarged view showing the sliding drive unit shown in FIG. 11 moving to the right and performing a pushing operation. In addition, Figure 14 shows a configuration diagram showing the control flow of a salt farm according to another embodiment of the present invention.

Referring to these drawings, the salt farm 100 according to this embodiment may further include a configuration that serves as a pusher in the evaporation pond and the crystallization pond.

Specifically, the salt farm 100 according to this embodiment includes a first rail 123, a sliding drive unit 124, an inclination change unit 125, a push plate 126, and a control unit (C) of a specific structure. It may be a configuration. The first rail 123 extends a predetermined length in the direction of the evaporation pond 120 and the seam 140 along both ends of the seam and is mounted symmetrically on both sides. The sliding drive unit 124 is mounted on the first rail 123 so that its sliding position can be changed. The tilt changing unit 125 is a component mounted on the sliding driving unit 124 by a hinge structure and is a link structure that is inclined in the direction in which the sliding driving unit 124 moves. The push plate 126 is a component mounted on the inclination change unit 125, and is mounted in pairs at a predetermined interval in the extending direction of the first rail 123, has a predetermined height, and has a width of the evaporation pond 120. It has a plate-shaped structure with a length corresponding to, and an elastic member 127 made of a flexible material having an elastic restoring force of a predetermined size is mounted at the end opposite to the upper surface of the evaporation paper 120.

At this time, the control unit (C) according to this embodiment is installed adjacent to the salt farm, performs wireless communication with the worker's smart device, and controls the operation of the sliding drive unit 124 by the control signal received from the smart device. You can.

As shown in Figures 11 to 13, the push plate 126 and the inclination change part 125 according to this embodiment operate according to the change in position of the sliding drive part 124 and are driven to perform the push operation. .

Specifically, the push plate 126 may include a first push plate 126a and a second push plate 126b of a specific structure. The first push plate 126a is mounted on the first link 125b of the tilt changing portion 125, has a plate-shaped structure with a predetermined width in the vertical height direction, and is equipped with an elastic member 127 at the bottom. In addition, the second push plate 126b is mounted on the second link 125c of the tilt changing portion 125, has a plate-shaped structure having the same upper and lower width as the first push plate 126a, and has an elastic member 127 at the bottom. ) is installed.

The tilt change unit 125 according to this embodiment may be configured to include a base link 125a, a first link 125b, a second link 125c, and a connection link 125d of a specific structure.

Specifically, the base link 125a of the tilt changing unit 125 is mounted on one side of the sliding driving unit 124 so that it can be rotated by a predetermined angle by the hinge driving unit 125e, and the first rail 123 ) is mounted in a structure that extends a predetermined length in a direction parallel to the longitudinal direction of the extension. The first link 125b is mounted on one end of the base link 125a so that it can be rotated by a predetermined angle by a first rotating part, and extends downward by a predetermined length. The second link 125c is mounted on the other end of the base link 125a so as to be rotatable by a predetermined angle by a second rotating part, and extends downward by a predetermined length. Additionally, the connecting link 125d connects the lower ends of the first link 125b and the second link 125c to each other through a hinge structure and has the same length as the base link 125a.

As shown in Figures 12 and 13, seawater with increased salinity can be effectively pushed out by the first push plate (126a) and the second push plate (126b) tilted opposite to the driving direction of the sliding drive unit 124. You can. At this time, when the sliding drive unit 123 is driven to the left, the bottom height of the first push plate 126a is changed to be higher than the bottom height of the second push plate 126b, and the seawater with increased salinity is stored in the spaced lower space. flows and is pushed by the second push plate (126b), and some salt crystals are pushed by the lower end of the first push plate (126a). On the other hand, when the sliding drive unit 123 is driven to the right, the bottom height of the second push plate 126b is changed to be higher than the bottom height of the first push plate 126a, and the seawater with increased salinity is stored in the spaced lower space. flows and is pushed by the first push plate (126a), and some salt crystals are pushed by the lower end of the second push plate (126b).

According to this embodiment including this configuration, by providing a configuration that can perform the pushing work in the evaporation pond and the crystallization pond, the pushing work can be performed effectively even in extreme weather conditions of high temperature and humidity, and the manpower required for the pushing work can be significantly reduced, and a salt farm can be provided that can significantly reduce the costs required for salt farm management and operation.

As described above, according to the salt farm, by providing a reservoir 110, an evaporation pond 120, a crystallization pond 130, a basin 140, and a basin cover 150 of a specific structure, rainwater and It is possible to prevent the problem of foreign substances penetrating into the seaweed and the evaporation pond 120 and changing the salinity, and by actively responding to weather changes and maintaining the salt water salinity in the seawater and the evaporation pond 120, a large amount of sea salt can be produced. It is possible to provide a salt farm containing a configuration capable of producing.

In the above detailed description of the present invention, only special embodiments thereof have been described. However, it should be understood that the present invention is not limited to the particular form mentioned in the detailed description, but rather includes all modifications, equivalents and substitutes within the spirit and scope of the present invention as defined by the attached claims. It has to be.

In other words, the present invention is not limited to the specific embodiments and descriptions described above, and anyone skilled in the art can make various modifications without departing from the gist of the present invention as claimed in the claims. is possible, and such modifications fall within the scope of protection of the present invention.

100: Salt farm
110: reservoir
120: Evaporation pond
121: First evaporation pond
122: Second evaporation pond
123: 1st rail
124: Sliding drive part
125: Slope change part
125a: Base link
125b: first link
125c: second link
125d: Connection link
125e: Hinge eastern part
126: Push plate
126a: First push plate
126b: Second push plate
127: Elastic member
130: decision
140: Haeju
150: Bottom cover part
151: 2nd rail
152: Installation drive unit
153: Cover binding part
154: Cover storage drum
155: Cover member
156: Water spray unit
C: Control section

Claims (5)

A reservoir 110 formed adjacent to the sea, having a predetermined width and depth and extending for a predetermined length along the coastline, and having a structure that stores seawater from the sea by a predetermined volume;
It is formed adjacent to the reservoir 110, extends inland by a predetermined width and length to have an area of a predetermined size, and is an evaporation pond that receives seawater from the reservoir 110 and evaporates it to increase the salinity of the seawater. (120);
It is formed adjacent to the evaporation pond 120, extends inland by a predetermined width and length to have an area of a predetermined size, and receives seawater with an increased salinity from the evaporation pond 120 and evaporates it to form solar salt crystals. Acquiring decision (130);
A main body 140 formed adjacent to the evaporation pond 120 and configured to accommodate seawater stored in the evaporation pond 120 by an operator or to provide seawater back to the evaporation pond 120; and
It is installed adjacent to the seawater 140, and is operated by an operator to form a cover layer by covering the upper surface of the seawater contained in the seawater 140, and then supplying water to the upper surface of the cover layer to create a water layer of a predetermined thickness. A seam cover portion 150 that forms and prevents foreign substances from penetrating into seawater from the outside;
A salt farm characterized in that it includes.
According to paragraph 1,
The evaporation pond 120 is,
It is formed adjacent to the reservoir 110, extends inland by a predetermined width and length to have an area of a predetermined size, and receives seawater from the reservoir 110 and increases the salinity of the seawater by primary evaporation. The first evaporation pond (121) is then transferred to the second evaporation pond (122); and
It is formed adjacent to the first evaporation pond 121, extends inland by a predetermined width and length to have an area of a predetermined size, and receives seawater with an increased salinity from the first evaporation pond 121. A second evaporation pond (122) that increases the salinity of seawater by evaporating it and then delivers it to the crystallization pond (130);
A salt farm characterized in that it includes.
According to paragraph 1,
The evaporation pond 120 is,
A first rail 123 extending for a predetermined length along both ends of the evaporation pond 120 in the direction of the bottom 140 and mounted symmetrically on both sides;
A sliding drive unit 124 mounted on the first rail 123 to change its sliding position;
An inclination change part 125 of a link structure that is mounted on the sliding driving part 124 by a hinge structure and tilts in the direction in which the sliding driving part 124 moves;
It is mounted on the slope changing unit 125, is mounted in pairs at a predetermined interval in the extending direction of the first rail 123, has a predetermined height, and has a length corresponding to the width of the evaporation pond 120. The structure includes a push plate 126 equipped with an elastic member 127 made of a flexible material having an elastic restoring force of a predetermined size at the end opposite to the upper surface of the evaporation pond 120; and
A control unit (C) installed adjacent to the salt farm, performing wireless communication with the worker's smart device, and controlling the operation of the sliding drive unit 124 by a control signal received from the smart device;
A salt farm characterized in that it includes.
According to paragraph 3,
The push plate 126 is,
A first push plate (126a) mounted on the first link (125b) of the tilt changing unit (125), has a plate-shaped structure with a predetermined width in the vertical height direction, and has an elastic member (127) mounted at the bottom; and
A second push plate (125c) is mounted on the second link (125c) of the tilt changing portion (125), has a plate-shaped structure having the same upper and lower width as the first push plate (126a), and has an elastic member (127) mounted at the bottom. 126b);
Including,
The slope changing unit 125,
The sliding driving part 124 is mounted on one side of the sliding driving part 124 to be rotatable by a predetermined angle by a hinge driving part 125e, and is mounted in a structure that extends a predetermined length in a direction parallel to the longitudinal direction of the extension of the first rail 123. base link (125a);
A first link (125b) mounted on one end of the base link (125a) to be rotatable by a predetermined angle by a first rotating part and extending downward by a predetermined length;
a second link (125c) mounted on the other end of the base link (125a) to be rotatable by a predetermined angle by a second rotating part and extending downward by a predetermined length; and
A connecting link (125d) connecting the lower ends of the first link (125b) and the second link (125c) with a hinge structure and having the same length as the base link (125a);
A salt farm characterized in that it includes.
According to paragraph 1,
The main cover part 150 is,
A second rail 151 extending along both ends of the seam 140 along the length of the seam 140 and mounted symmetrically on both sides;
An installation drive unit 152 mounted on the second rail 151 to change its sliding position;
A cover fastening part 153 that is mounted on the installation drive part 152 and is coupled to one end of the cover member 155 from the cover storage drum 154;
A cover storage drum 154 adjacent to the seam 140 and having a structure having the same width as the seam 140, and having a structure for winding and storing the cover member 155;
A plurality of water spray units 156 are mounted on the cover storage drum 154 at regular intervals and spray water supplied from the outside onto the upper surface of the cover member 155 to form a water layer; and
It is installed adjacent to the salt farm, performs wireless communication with the worker's smart device, and controls the operation of the installation drive unit 152, cover storage drum 154, and water spray unit 156 by control signals received from the smart device. A control unit (C) that does;
A salt farm characterized by comprising a.