KR102537570B1 - Thermal storage tank - Google Patents

Abstract

The present invention provides a heat exchange housing having an enclosure structure and equipped with a heater, a circulating water inlet formed on the lower side of the heat exchange housing and into which water flows, a circulating water outlet formed on the upper side of the heat exchange housing, and water through the heat exchange housing. It relates to a hot water heat storage tank including a hot water conversion pipe forming a passage through which it passes.

Description

Hot water storage tank {Thermal storage tank}

The present invention relates to a hot water thermal storage tank capable of providing hot water at a desired temperature to a user with high heat exchange efficiency and stably maintaining the temperature of supplied hot water.

And, it relates to a hot water heat storage tank equipped with a vortex generating ejector to obtain higher heat exchange efficiency.

In a conventional hot water storage tank, the temperature of hot water is controlled by heating circulating water with a heater built in the tank.

In addition, a hot water conversion pipe is positioned inside the tank so that the incoming cold water can be heated by circulating water passing through the heater and the hot water heat storage tank.

However, this conventional invention has a problem in that, when the amount of cold water passing through the hot water conversion pipe is greater than the surface area of the hot water conversion pipe, the cold water is not effectively heated.

In addition, since the heated hot water passing through the hot water conversion pipe is directly supplied to the hot water pipe, the temperature of the hot water changes rapidly in response to the amount of hot water passing through the hot water conversion pipe and the temperature of the heater, which causes great inconvenience to the user. There were also problems with it.

Therefore, the need for a new hot water heat storage tank capable of solving these conventional problems is emerging.

Patent Document 1) Korean Patent Publication No. KR 10-2016-0005811 A (2016.01.18), (Heat pump for heating and cooling hot water using heat storage tank and geothermal heat) Patent Document 2) Korean Patent Publication No. KR 10-2103-0058092 A (2013.06.04.), (Heating system using heat storage tank)

The present invention has been made to solve the above problems, and the present invention provides a hot water heat storage tank capable of effectively controlling the temperature of water passing through a hot water conversion pipe.

In addition, it is to provide a heating and thermal storage tank capable of minimizing discomfort that a user may feel due to rapid temperature change, in which water passing through the hot water conversion pipe is adjusted to an average temperature in the process of passing through the heat balance room.

And, to provide a hot water heat storage tank equipped with a vortex generating ejector capable of increasing heat exchange efficiency between heating water and a heater.

The hot water heat storage tank of the present invention for achieving the above object has a housing structure and includes a heat exchange housing 100 equipped with a heater 110; a circulation water inlet 200 formed below the heat exchanging housing 100 and into which water flows; a circulation water outlet 300 formed on the upper side of the heat exchanging housing 200; A hot water conversion pipe 400 forming a path through which water passes through the heat exchange housing 100 is included.

The hot water conversion pipe 400 includes a first bent part 401 having a spiral structure surrounding the edge of the heater 110 and a second bent part 402 spaced apart from the edge of the first bent part 401 and having a spiral structure. include

The hot water conversion pipe 400 includes an external heat exchange pipe 410 in which a heat exchange passage 411 is formed, and a passage area controlled by being accommodated inside the external heat exchange pipe 410 to adjust the cross-sectional area of the heat exchange passage 411. includes section 420 .

The passage area adjusting part 420 may include a wire or rod inserted into the heat exchange passage 411 .

The heat exchange housing 100 includes a separation plate 130 separating the heat exchange space 120 formed therein into a heat balance chamber 121 located on the upper side and a heat exchange chamber 122 located on the lower side.

The hot water conversion pipe 400 is coupled to the separation plate 130 to supply heat-exchanged water to the heat balance chamber 121, and the water introduced into the heat balance chamber 121 is transferred to the heat exchange housing 100. It is characterized in that it is discharged through the hot water discharge unit 500 formed in.

The heat exchange housing 100 includes an inflow water mixing unit 140 provided in the heat balance chamber 121 to mix the incoming hot water.

A vortex generating ejector 700 coupled to the circulating water inlet 200 to generate vortexes is further included.

The vortex generating ejector 700 has an ejector body 710 in which a circulating water inlet 711 is formed, and a plurality of ejector body 710 spaced apart in the circumferential direction on the side of the ejector body 710, and ejector body 710 It includes an ejection unit 720 that discharges the circulating water delivered from and forms a vortex.

The plurality of ejection parts 720 are coupled to the ejector body 710 at different angles.

The plurality of ejection parts 720 are characterized in that the diameters of the ejection holes 721 have different lengths.

The vortex generating ejector 700 includes a guide lip 730 coupled to an end of the ejection part 720 to guide a discharge path of the discharged circulating water.

The hot water storage tank according to the present invention has the advantage of being able to stably supply hot water even when the amount of hot water used is large because the water passing through the hot water conversion pipe is primarily heated by circulating water and secondarily heated by a heater.

The hot water storage tank according to the present invention has an advantage in that an amount of water that can be effectively heated always passes through the hot water conversion pipe because the cross-sectional area of the inner passage of the hot water conversion pipe is adjusted in a ratio suitable for the external surface area by the passage area adjusting unit.

The hot water storage tank according to the present invention has the advantage of solving the problem of causing an accident due to excessively hot water being provided to the user when the heated hot water is directly supplied, since the heated hot water passes through the hot water conversion pipe and is mixed and supplied in the heat balance room. .

The hot water storage tank according to the present invention has an advantage in that the hot water supplied to the heat balance room is effectively mixed by the inflow water mixing means, so that the temperature of the hot water provided to the user can be maintained more constant.

Since the hot water storage tank of the present invention discharges the circulating water introduced from the vortex generating ejector in various directions, the discharged circulating water forms a vortex, so that the circulating water and the heater are more smoothly contacted.

In addition, since the discharge angles and discharge pressures of the circulating water discharged from the respective jetting units are different, there is an advantage in that the circulating water discharged through the different jetting units collide with each other to create a more complicated flow of water.

In detail, the water flow is made in an irregular form, so that when the water has a regular flow, the water in some spaces is stagnant and does not exchange heat with the heater.

1 is a perspective view showing a hot water heat storage tank according to the present invention;
Figure 2 is a front view showing the internal structure of the hot water storage tank of the present invention.
Figure 3 is a plan view showing the hot water conversion pipe of the hot water storage tank according to the present invention.
4 is a conceptual diagram for explaining a passage area control unit formed inside a hot water conversion pipe of a hot water heat storage tank according to the present invention;
5 is a perspective view illustrating a passage area adjusting unit inserted into the hot water conversion pipe of the hot water storage tank according to the present invention;
Figure 6 is a perspective view for explaining the influent mixing means of the hot water storage tank of the present invention.
Figure 7 is a perspective view showing a vortex generating ejector of the present invention.
8 is a perspective view showing a vortex generating ejector of the present invention.
Figure 9 is a plan view showing the vortex generating ejector of the present invention.
10 is a plan view showing the arrangement of the vortex generating ejector and the hot water conversion pipe according to the present invention;
11 is a perspective view and a partially enlarged view showing that guide ribs and separation protrusions are formed in the vortex generating ejector of the present invention.

Advantages and characteristics of the embodiments of the present invention, and methods for achieving them will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms, only the present embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

In describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the embodiment of the present invention, which may vary according to the intention or custom of a user or operator. Therefore, the definition should be made based on the contents throughout this specification.

Hereinafter, the hot water heat storage tank 1000 according to the present invention will be described with reference to the accompanying drawings.

1 is a perspective view showing a hot water heat storage tank according to the present invention, FIG. 2 is a front view showing the internal structure of the hot water heat storage tank according to the present invention, FIG. 3 is a plan view showing a hot water conversion pipe of the hot water heat storage tank according to the present invention, and FIG. It is a conceptual diagram for explaining the passage area adjusting part formed inside the hot water conversion pipe of the hot water storage tank according to the present invention, and FIG. 5 is a perspective view illustrating the passage area adjusting part inserted inside the hot water conversion pipe of the hot water storage tank according to the present invention. 6 is a perspective view for explaining the inflow water mixing means of the hot water storage tank according to the present invention.

Referring to FIGS. 1 and 2, the hot water heat storage tank 1000 of the present invention has a housing structure and is formed on a heat exchange housing 100 provided with a heater 110 and a lower side of the heat exchange housing 100, and water The circulation water inlet 200 introduced, the circulation water outlet 300 formed on the upper side of the heat exchange housing 200 and the heated circulation water discharged, and the path through which water passes through the heat exchange housing 100 It is made including a hot water conversion pipe 400 to form.

In detail, the process in which the heater 110 is provided in the heat exchange space 120 inside the hot water storage tank 1000 and the circulating water introduced through the circulating water inlet 200 is discharged through the circulating water outlet 300 The hot water conversion pipe 400 is also provided on the heat exchange space 120 and the cold water passing through the hot water conversion pipe 400 by the thermal energy emitted from the heater 110 and the thermal energy transferred from the heating water It is heated and converted to hot water.

1 to 3, the hot water conversion pipe 400 surrounds the edge of the heater 110 and has a first bent part 401 having a spiral structure, and is disposed spaced apart from the edge of the first bent part 401 and has a spiral structure. It may include a second bent portion 402 having a structure.

In detail, the water introduced through the hot water inlet 600 is cold fresh water introduced through a water supply pipe, and when a user requires a large amount of hot water, it is difficult to quickly heat the cold fresh water to high temperature hot water. , After being preheated by the circulating water in the process of passing through the second curved portion 402, the cold fresh water passes through the first curved portion 401 and is heated to a desired temperature by the heater 110. .

In addition, the hot water conversion pipe 400 includes an external heat exchange pipe 410 in which a heat exchange passage 411 is formed, and a passage accommodated inside the external heat exchange pipe 410 to adjust the cross-sectional area of the heat exchange passage 411. An area adjusting unit 420 may be included.

In detail, if the amount of water passing through the hot water conversion pipe 400 is too large, the hot water conversion efficiency drops sharply and water at a desired temperature cannot be provided to the user. ) is adjusted so that the amount of water passing through the hot water conversion pipe 400 can always be adjusted to an amount that can effectively control the temperature.

At this time, the flow area adjusting unit 420 may include various shapes, and in one embodiment, as shown in FIG. 4 (a), a first type having a rod-shaped structure, as shown in FIG. The second type having a wire structure as shown in (c) of FIG. 421) is positioned at the center of the external heat exchange pipe 410, and the third type includes a positioning lip 422. A fourth type that minimizes the interference of the external heat exchange tube 410 and a fifth type including an anti-interference lip 424 formed at the end of the positioning lip 422 to extend the thickness of the positioning lip 422 can include

In detail, when the flow path area adjusting unit 420 is formed in a rod or wire shape as in the first type and the second type described above, the flow area adjusting unit 420 is not located in the center of the heat exchange flow path 411 and It is tilted to one side of the radial direction, and this tilting phenomenon hinders effective heating of the water passing through the heat exchange passage 411, so as described in the third type, the positioning lip 422 is formed so that the passage control body 421 can be located in the center of the heat exchange passage 411.

In addition, when the flow path area adjusting unit 420 is molded separately from the external heat exchange tube 410 and then assembled, the position adjusting lip 422 may rub against the external heat exchange tube 410 and the external heat exchange tube 410 may be damaged. Like the fourth type or the fifth type, a connection member 423 or an anti-interference lip 424 is formed at the end of the positioning lip 422 to prevent direct friction between the positioning lip 422 and the heat exchange tube 410. it was limited

At this time, in the fifth type, as shown in FIG. 5, the anti-interference lip 424 is coupled to the end of each position adjusting lip 422, and the plurality of anti-interference lips 424 are spaced apart. Water in the heat exchange passage 411 may directly contact the external heat exchange tube 410 .

Therefore, it is possible to have a relatively high heat exchange efficiency compared to the fourth type in which water in the heat exchange passage 411 does not directly contact the external heat exchange tube 410 due to the connection member 423 .

In addition, it is recommended that the external heat exchange tube 410 be made of a copper material having high soft conductivity, antibacterial properties, and corrosion resistance, and that the passage area control unit 420 be made of an aluminum material treated with anti-corrosion to prevent corrosion. However, this is an example, and the external heat exchange tube 410 and the flow area adjusting unit 420 may be formed of various materials, so they are not limited thereto.

1 and 2, the heat exchange housing 100 divides the heat exchange space 120 formed therein into a heat balance chamber 121 located on the upper side and a heat exchange chamber 122 located on the lower side. Plate 130 is included.

In detail, if the water heated while passing through the hot water conversion pipe 400 is directly discharged through the hot water discharge unit 500, excessively hot water may be supplied to the user, so that the heat balance room 121 is kept in the heat balance room 121 for a certain period of time. After mixing the water supplied during the period, the temperature stabilized water can be supplied to the user.

At this time, as shown in FIG. 6, an inflow water mixing unit 140 may be provided on the thermal balance room 121 to more effectively mix the inflowing hot water, and the inflow water mixing unit 140 discharges the hot water after the inflow. It may be a rod that causes water moving toward the unit 500 to collide to form a vortex, but in addition, it may also include a stirring blade that is idlingly coupled to the rod and rotates by the force of moving water.

Hereinafter, a vortex generating ejector 700 according to the present invention will be described with reference to the accompanying drawings.

Figure 7 is a perspective view showing the vortex generating ejector of the present invention, Figure 8 is a perspective view showing the vortex generating ejector of the present invention, Figure 9 is a plan view showing the vortex generating ejector of the present invention, Figure 10 is a vortex generating ejector and hot water conversion of the present invention It is a plan view showing the tube arrangement form, and FIG. 11 is a perspective view and a partially enlarged view showing that a guide lip and a separation protrusion are formed in the vortex generating ejector of the present invention.

Referring to FIG. 2, the hot water storage tank according to the present invention has a circulating water inlet 200 coupled with a vortex generating ejector 700 generating vortexes, and a circulating water outlet on the upper side of the heat exchange housing 100 ( 300) is formed, it is possible to solve the problem of not effectively exchanging heat with the heater 310 because the introduced circulating water is quickly discharged.

In detail, the circulating water has a flow in the form of a cyclone in the heat exchange space 120 inside the heat exchange housing 100, so that a larger amount of circulating water can exchange heat with the heater 110 while moving.

At this time, as shown in FIGS. 7 to 9, the vortex generating jet 700 has a jet body 710 in which a circulating water inlet 711 is formed, and a circumferential direction on the side of the jet body 710. A plurality of ejectors are spaced apart from each other and include ejection units 720 that discharge circulating water transmitted from the ejector body 710 to form vortexes.

At this time, all of the ejection parts 720 may be coupled to the ejector body 710 at the same angle, but a plurality of ejection parts 720 are coupled to the ejector body 710 at two or more different angles. It is recommended that the circulation water discharged from the ejection unit 720 collide with each other to have a more complex flow.

In detail, when the flow of the circulating water is made in a standardized form, there is a problem that the circulating water is stagnant in some areas, and this stagnation of the circulating water reduces the amount of circulating water that exchanges heat with the heater 110, so that the heater 110 Since the heating effect of the circulating water is reduced, the coupling angles of the spouting parts 720 are made different so that the circulating water discharged from the spouting part 720 collides with each other to create an indiscriminate flow.

And, as shown in FIG. 9, the ejection part 720 includes a first ejection part 721, a second ejection part 722, and a third ejection part ( 723), the fourth jetting unit 724, the fifth jetting unit 725, and the sixth jetting unit 726, the first jetting unit 721 and the fourth jetting unit 724 disposed to face each other is horizontally coupled with the ejector body 710, and the second ejection part 722 and the fifth ejection part 725 are coupled to the ejector body 710 with an angle of 8 to 15 degrees in a clockwise direction, The third ejection part 723 and the sixth ejection part 726 can form a vortex more effectively when combined with the ejector body 710 in an inclined form of 8 degrees to 15 degrees in a counterclockwise direction, but this is one embodiment Yes, and the ejection unit 720 is not limited because it can be coupled to the ejector body 710 at various angles.

In addition, it is recommended that the plurality of ejection parts 720 have ejection holes 721 having different diameters, so that the circulating water discharged from each ejection part 720 spreads to different intensities and areas.

In detail, since the circulation water discharged from the jet unit 720 has a more complicated flow than when it hits with different forces at various positions, and this complicated flow has an effect of increasing heat exchange efficiency, the jet hole 721 By making the diameters of the circulating water different from each other, a more complex flow can be formed in the heat exchange space 120 inside the heat exchange housing 100.

In addition, as described above, the flow of circulating water created by differentiating the coupling angles of the plurality of ejection units 720 and different diameters of the ejection holes 721 heats the water passing through the hot water conversion pipe 400 It also has the effect of making it effective.

In detail, as shown in FIG. 10, since the hot water conversion pipe 400 having a spiral shape is located on the upper side of the vortex generating jet 700, the circulating water discharged from the jetting unit 720 forms a cyclone-shaped vortex. Since the water passes through the bent portion of the hot water conversion pipe 400, heat exchange between the circulating water and the hot water conversion pipe 400 is more effective.

In addition, referring to FIG. 11 , the vortex generating ejector 700 includes a guide lip 730 coupled to the end of the ejection part 720 to guide a discharge path of the discharged circulating water, and the guide lip 730 ) It is recommended that separation protrusions 740 are formed on the inner surface of the guided circulating water to separate and discharge a plurality of them.

In detail, in order to form a vortex in a wider area, the circulation water discharged from the jet unit 720 must spread farther, and to create a more complex flow, the circulation water must spread in various directions. A guide lip 730 is formed at the end to assist the circulation water to be discharged farther away, and a separation protrusion 740 is formed on the inner upper surface of the guide lip so that the discharged circulation water can be separated into a plurality of pieces and spread out. .

At this time, although the separation protrusion 740 is shown as a rectangular parallelepiped shape in the drawings, the separation protrusion 740 has a narrow thickness on one side in the longitudinal direction and a thickness on the other side in the longitudinal direction in contact with the circulating water so as not to interfere with the movement of the circulating water discharged. It is recommended to have a wide wedge-shaped cross-sectional shape.

Referring to FIG. 12, a speed control plate is installed inside the hot water conversion pipe 400, and a hole smaller than the inner diameter of the hot water conversion pipe 400 is formed in the speed control plate so that the water stays in the hot water conversion pipe 400. can increase

At this time, the speed control plate may include a first speed control plate 430 positioned in the middle of the longitudinal direction of the hot water conversion pipe 400 and a second speed control plate 440 positioned adjacent to the heat balance chamber 121. The inner diameter H1 of the first speed control plate 430 should be longer than the inner diameter H2 of the second speed control plate 440, and the inner diameter of the hot water conversion pipe 400 is 100 in a more correct embodiment. When the inner diameter of the first speed control plate is 36 to 50, it is recommended that the inner diameter of the second speed control plate is formed of 25 to 50.

The present invention is not limited to the above embodiments, and the scope of application is diverse, and anyone with ordinary knowledge in the field to which the present invention belongs without departing from the gist of the present invention claimed in the claims Of course, various modifications are possible.

100: heat exchange housing 110: heater
120: heat exchange space 121: heat balance room
122: heat exchange chamber 130: separation plate
140: influent mixing means
200: circulating water inlet
300: circulating water outlet
400: hot water conversion pipe 401: first bend
402: second bend 410: heat exchange tube
411: heat exchange passage 420: passage area control unit
500: hot water outlet 600: hot water inlet
700: Vortex generating ejector 710: ejector body
711: circulating water inlet 720: outlet
721: blowout hole 730: guide lip
740: separation protrusion

Claims (13)

The heat exchange space 120 formed inside is separated into a heat balance chamber 121 located on the upper side and a heat exchange chamber 122 located on the lower side by the separation plate 130, and the separation plate 130 converts hot water. The pipe 400 is coupled to supply heat-exchanged water to the heat balance room 121, and the water introduced into the heat balance room 121 has an enclosure structure in which it is discharged through the hot water outlet 500, and the heat exchange a heat exchange housing 100 in which a heater 110 is provided in a chamber 122;
a circulation water inlet 200 formed below the heat exchanging housing 100 and into which water flows;
A vortex generating ejector 700 coupled to the circulating water inlet 200 to generate vortexes;
a heating water outlet 300 formed on the upper side of the heat exchange housing 100 and discharging heated circulating water;
It is formed of a first bent part 401 having a spiral structure surrounding the edge of the heater 110 and a second bent part 402 spaced apart from the edge of the first bent part 401 and having a spiral structure, and a heat exchange passage ( 411) is formed inside the external heat exchange tube to adjust the cross-sectional area of the heat exchange passage 411. A hot water storage tank comprising a hot water conversion pipe (400).
delete delete According to claim 1,
The flow path area adjusting unit 420 includes a wire or rod inserted into the heat exchange flow path 411.
delete delete According to claim 1,
The heat exchange housing 100 includes an inflow water mixing unit 140 provided in the heat balance chamber 121 to mix the incoming hot water.
delete According to claim 1,
The vortex generating ejector 700 has an ejector body 710 in which a circulating water inlet 711 is formed, and a plurality of ejector body 710 spaced apart in the circumferential direction on the side of the ejector body 710, and ejector body 710 a jetting unit 720 that discharges the circulating water delivered from and forms a vortex; Including, hot water storage tank.
According to claim 9,
The hot water storage tank, characterized in that the plurality of ejection parts 720 are coupled to the ejector body 710 at different angles.
According to claim 10,
The plurality of ejection parts 720 are characterized in that the ejection holes 721 have different diameters and have different lengths.
According to claim 11,
The hot water storage tank including a guide lip 730 coupled to the end of the jetting part 720 and guiding a discharge path of the discharged circulating water.
According to claim 1,
The hot water conversion pipe 400 is located inside the hot water conversion pipe 400, the speed control plate for reducing the speed of the water passing through; including, hot water heat storage tank.

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