CN113606981A - Energy-saving heat exchange device - Google Patents

Abstract

The invention discloses an energy-saving heat exchange device which comprises a heat exchange main body, wherein a sealing end is arranged on the outer wall of the right side of the heat exchange main body, a connecting pipe is communicated with the left side of the top of the heat exchange main body, a communicating pipeline is communicated with the middle of the front of the heat exchange main body, two sides of the bottom of the heat exchange main body are fixedly connected with supporting bottom plates, and an exchange device is fixedly connected to the left side of the top of an inner cavity of the heat exchange main body. This energy-saving heat exchange device, and then increase inside airtight effect, reached heat retaining purpose, guarantee that device inside has sufficient rivers, and the sealing sleeve is connected with outer exchange frame, the heat that the device surface of being convenient for gived off carries out heat exchange work to rivers, the installation baffle can protect complementary unit when the leakproofness of improvement device, the effectual inside pressure that bears of device that has increased has avoided the condition that the internal installation caused the inside pipeline to block up along with the rivers flow.

Description

Energy-saving heat exchange device

Technical Field

The invention relates to the technical field of heat exchange, in particular to an energy-saving heat exchange device.

Background

Heat exchange is also called heat exchange, and the process of transferring heat energy from a hot fluid to a cold fluid indirectly (for example, through a partition wall) or directly is complex in nature, not only needs to consider heat conduction through the partition wall, but also needs to consider convective heat transfer of fluids at two sides of the partition wall, and sometimes also needs to consider radiative heat transfer.

According to the automatic heating that carries out the batching of energy-saving cold and hot balance heat exchange device that chinese patent No. CN110307637B discloses, prestore and go out of cold water in to getting into equipment through heating device, cold and hot heat exchange device carries out cold and hot balance to the hot water that heats well and the cold water that will add and reduces thermal intake for subsequent cold water heating, water yield measurement heating controlling means detects heating device and controls the intaking and to the heating of water, intake heating controlling means heats functions such as the water of adding in step when intaking, but inside some impurity that easily appears after the long-time use of device, the heat exchange efficiency of device has been reduced, lead to internal blocking easily, make rivers can not carry out the heat exchange, cause the damage of device.

In conclusion, after the device is used for a long time, partial impurities are easy to appear in the device, the heat exchange efficiency of the device is reduced, internal blockage is easy to cause, water flow cannot exchange heat, and the device is damaged.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides an energy-saving heat exchange device, which solves the problems that after the device is used for a long time, partial impurities are easy to appear in the device, the heat exchange efficiency of the device is reduced, internal blockage is easy to cause, water flow can not exchange heat, and the device is damaged.

(II) technical scheme

In order to achieve the purpose, the invention is realized by the following technical scheme: the utility model provides an energy-saving heat exchange device, includes the heat transfer main part, the right side outer wall of heat transfer main part is provided with sealed end, the top left side intercommunication of heat transfer main part has the connecting pipe, the front middle part intercommunication of heat transfer main part has the intercommunication pipeline, the bottom both sides fixedly connected with supporting baseplate of heat transfer main part, the inner chamber top left side fixedly connected with exchange device of heat transfer main part.

Preferably, exchange device includes sealed sleeve, sealed sleeve's both sides outer wall all is provided with outer exchange frame, sealed sleeve's left side outer wall fixedly connected with installation baffle, one side middle part that sealed sleeve was kept away from to the installation baffle is provided with complementary unit, complementary unit's right side is run through the installation baffle, sealed sleeve's inner chamber top right side fixedly connected with temperature regulating mechanism, through sealed sleeve and outer exchange frame's being connected, the heat that the device surface of being convenient for gived off carries out heat exchange work to rivers, has avoided the condition that the internal installation caused the inside pipe to block up along with the rivers flow.

Preferably, temperature adjusting mechanism's component one includes spacing, the right side inner wall middle part of spacing is provided with the flow distribution disc, one side outer wall fixedly connected with heat preservation casing of spacing, heat preservation casing's left side inner wall middle part is provided with the water conservancy diversion frame, the both sides that the inner chamber of heat preservation casing is located the water conservancy diversion frame are provided with clean ring, and rivers through heat preservation casing inside move along with the water conservancy diversion frame, and inside entering water flow promotes clean ring simultaneously, is favorable to cleaing away the incrustation scale of inside, is convenient for reduce the interchange time of device.

Preferably, the first component of the auxiliary mechanism comprises a containing part, a cylinder is arranged in the middle of the outer wall of the right side of the containing part, the left end of the cylinder penetrates through the containing part and extends into the containing part, one end of the cylinder, far away from the containing part, of each bending block is fixedly connected with the two sides of the outer wall of the right side of each bending block, a heat conductor is fixedly connected with the middle of the outer wall of the right side of each bending block, an auxiliary plate is fixedly connected with the outer wall of the right side of the heat conductor, a collection cavity is formed by the containing part and the bending blocks, the auxiliary plate is convenient to collect fully, the cleanness of the water body which is not replaced inside is kept, and the phenomenon that the bending blocks drop suddenly after being used for a long time is avoided.

Preferably, the second component of temperature adjustment mechanism is including thermal-insulated shell, the left side inner wall middle part fixedly connected with protective bracket of thermal-insulated shell, protective bracket's right side outer wall is provided with the circulation piece, the right side inner wall middle part of thermal-insulated shell is provided with the rotor plate, the left side outer wall middle part fixedly connected with temperature control body of rotor plate opens and shuts sealed circulation mouth through the rotatory in-process of temperature control body along with the rotor plate, and then carries out the ration to inside rivers, and the effectual device that has reduced consumes when carrying out the heat exchange has further prolonged the life of device.

Preferably, the second component of the auxiliary mechanism comprises a flowing cylinder, the middle of the outer wall of the left side of the flowing cylinder is communicated with an exchange drain pipe, the middle of the inner wall of the left side of the flowing cylinder is provided with an auxiliary support, the middle of the outer wall of the right side of the auxiliary support is provided with a positioning clamping plate, the middle of the inner walls of the two sides of the flowing cylinder is provided with an arc-shaped auxiliary frame, and the connecting rod and the flowing cylinder which are arranged through the auxiliary support are connected, so that the pressure inside the flowing cylinder is reduced, internal parts are protected conveniently, and the storage time of internal high temperature is prolonged.

Preferably, the middle part of the outer wall of the left side of the auxiliary bracket penetrates through the flow cylinder and extends to the inside of the flow cylinder.

Preferably, the outer surface of the heat preservation shell is provided with a communication port.

A method for using an energy-saving heat exchange device comprises the following steps: fixing the device, communicating the connecting pipe with an external hot water pipe, filling the inside of the heat exchange main body with water, and connecting the sealing end with the heat exchange main body;

step two: the outer exchange frame is communicated with the sealing sleeve, external circulation of water flow is carried out on the outer exchange frame, the sealing sleeve is connected with the mounting partition plate to generate a sealing cavity, loss of internal heat is reduced, and internal quantitative heat exchange is realized;

step three: the water flows through the communication port on the surface of the heat-insulation shell to contact the flow guide frame and moves along with the flow guide frame, and the cleaning ring is driven by the water flow to clean the connection position of the cleaning ring and the heat-insulation shell;

step four: storing cold water by utilizing a collecting cavity generated by the bending block and the accommodating part, and connecting the heat conductor with the bending block to ensure that a fixing rod of the heat conductor fixes the position of the bending block;

step five: the rotating plate drives the temperature control body to rotate, the blocked holes are opened, the protective support is connected with the circulating piece, and the protective support and the temperature control body rotate together along with the connection position of the protective support and the temperature control body;

step six: be connected arc auxiliary frame and auxiliary stand for inside rivers circulate through the pipeline, and be connected auxiliary stand and location cardboard, reduced auxiliary stand's inside area of contact.

(III) advantageous effects

The invention provides an energy-saving heat exchange device. The method has the following beneficial effects:

(one), this energy-saving heat exchange device, the sealed end has been set up, the intercommunication pipeline, supporting baseplate, outer exchange frame, sealing sleeve, prepare to carry out the during operation, airtight end carries out the closure to the device, and then increase inside airtight effect, the heat retaining purpose has been reached, supporting baseplate's setting makes the area reduction of device and ground monitoring, circulate with outside hot water and cold water pipeline, guarantee that the device is inside to have sufficient rivers, and sealing sleeve and outer exchange frame's being connected, the heat that the device surface of being convenient for gived off carries out heat exchange work to rivers, the installation baffle can protect complementary unit when the leakproofness of improvement device, the effectual inside pressure that bears of device that has increased, the condition that the internal device caused inside pipe blockage along with the rivers flow has been avoided.

(II), this energy-saving heat exchange device, under the condition that changes is carried out through inside water, exchange drain pipe cooperates with the arc auxiliary frame, is convenient for discharge the water of inside different temperatures, and the connecting rod that auxiliary frame had goes on with the drum that flows simultaneously to reduced the inside pressure of drum that flows, be convenient for protect the internals, be favorable to prolonging the time of depositing of inside high temperature, further improved device thermal conversion efficiency.

(III), this energy-saving heat exchange device, through the inside in-process that carries out the flow of water, the temperature control body opens and shuts along with the rotatory in-process of rotor plate to sealed circulation mouth, and then carries out the ration to inside rivers, effectually reduced the consume when the device carries out the heat exchange, and the circulation piece can carry out the internal circulation of water, realizes the recycle of inside water, has avoided the water peculiar smell to appear when inside storage, has further prolonged the life of device.

(IV), this energy-saving heat exchange device, through the hole that separates heat exchanger shell surface has, a plurality of pipelines of effectual assurance intercommunication, the heat exchanger shell of being convenient for cooperates with the sleeve that flows, the effectual inside sealed effect that has increased, what avoided the during operation to produce rocks and leads to the internals to damage, and the location cardboard is convenient for cut apart the space of inside, alleviates the consume that the internals used.

(five), this energy-saving heat exchange device, the in-process of saving is carried out the rivers of inside through needs, the piece and the collection chamber that the piece produced of buckling, be convenient for fully collect, simultaneously to rivers deposit of stewing, be favorable to keeping the cleanness of the inside water of not changing, the heat conductor can be abundant spread into inside with the heat, the fixed column that the heat conductor has simultaneously can be fixed the piece of buckling, the phenomenon of dropping suddenly after having avoided the piece of buckling to appear long-time use.

(VI), this energy-saving heat exchange device, through the inside condition that appears the incrustation scale of the long-time use of device under, the inside rivers of heat preservation casing move along with the water conservancy diversion frame, and inside entering rivers promote clean ring simultaneously, are favorable to cleaing away the incrustation scale of inside to the heat exchange effect and the efficiency of device have been improved, simultaneously through the reposition of redundant personnel of flow distribution disc to rivers, the effectual incrustation scale that prevents moves along with the rivers and causes the condition of inside jam, the change-over time of the device of being convenient for reduce.

(VII) this energy-saving heat exchange device collects the dispersion of rivers through the flow distribution disc to reduced the operating time of device, rivers produce micro rocking in inside simultaneously, are favorable to rivers to the clearance of inside incrustation scale, make the pipeline of jam under the condition of rocking, the incrustation scale appears and drops and produce the gap, make the inside difficult stifled die of pipeline, thereby reduced the inside clearance degree of difficulty.

Drawings

FIG. 1 is a schematic structural view of the present invention as a whole;

FIG. 2 is a schematic structural diagram of a switching device according to the present invention;

FIG. 3 is a schematic structural diagram of a first component of the temperature regulating mechanism of the present invention;

FIG. 4 is a schematic structural diagram of a first component of the auxiliary mechanism of the present invention;

FIG. 5 is a schematic structural diagram of a second component of the temperature regulating mechanism of the present invention;

FIG. 6 is a schematic structural diagram of a second member of the auxiliary mechanism of the present invention.

In the figure: the heat exchanger comprises a sealed end 1, a heat exchange main body 2, a communication pipeline 3, a support base plate 4, a connecting pipe 5, an exchange device 6, an outer exchange frame 61, a sealing sleeve 62, a temperature adjusting mechanism 63, a 631 limiting frame, a diverter disc 632, a thermal insulation shell 633, a guide frame 634, a 635 cleaning ring, a d1 thermal insulation shell, a d2 protective support, a d3 circulating piece, a d4 temperature control body, a d5 rotating plate, a 64 mounting partition plate, a 65 auxiliary mechanism, a 651 accommodating piece, a 652 bending block, a 653 thermal conductor, a 654 cylinder, a 655 auxiliary plate, a t1 exchange drain pipe, a t2 flowing cylinder, a t3 auxiliary support, a t4 arc auxiliary frame and a t5 positioning clamping plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The first embodiment is as follows:

referring to fig. 1-6, the present invention provides a technical solution: the utility model provides an energy-saving heat exchange device, includes heat transfer main part 2, and the right side outer wall of heat transfer main part 2 is provided with sealed end 1, and the top left side intercommunication of heat transfer main part 2 has connecting pipe 5, and the front middle part intercommunication of heat transfer main part 2 has communicating pipe 3, the bottom both sides fixedly connected with supporting baseplate 4 of heat transfer main part 2, the inner chamber top left side fixedly connected with exchange device 6 of heat transfer main part 2.

Wherein, exchange device 6 includes sealing sleeve 3, and sealing sleeve 3's both sides outer wall all is provided with outer exchange frame 61, and sealing sleeve 3's left side outer wall fixedly connected with installation baffle 64, and the one side middle part that sealing sleeve 3 was kept away from to installation baffle 64 is provided with complementary unit 65, and complementary unit 65's right side runs through installation baffle 64, and sealing sleeve 62's inner chamber top right side fixedly connected with temperature regulating mechanism 63.

Wherein, the first component of the temperature adjusting mechanism 63 includes the limiting frame 631, the right inner wall middle part of the limiting frame 631 is provided with the flow distribution disc 632, one outer wall fixedly connected with of the limiting frame 631 keeps warm the casing 633, the left inner wall middle part of the casing 633 that keeps warm is provided with the flow guide frame 634, and the both sides that the inner chamber of the casing 633 that keeps warm is located the flow guide frame 634 are provided with the cleaning ring 635.

The first component of the auxiliary mechanism 65 includes a receiving part 651, a cylinder 654 is disposed in the middle of the outer wall of the right side of the receiving part 651, the left end of the cylinder 654 penetrates through the receiving part 651 and extends into the receiving part 651, two sides of one end of the cylinder 654, which is far away from the receiving part 651, are fixedly connected with a bending block 652, a heat conductor 653 is fixedly connected in the middle of the outer wall of the right side of the bending block 652, and an auxiliary plate 655 is fixedly connected to the outer wall of the right side of the heat conductor 653.

The second component of the temperature adjusting mechanism 63 comprises a heat insulation shell d1, a protection support d2 is fixedly connected to the middle of the left inner wall of the heat insulation shell d1, a circulating piece d3 is arranged on the right outer wall of the protection support d2, a rotating plate d5 is arranged in the middle of the right inner wall of the heat insulation shell d1, and a temperature control body d4 is fixedly connected to the middle of the left outer wall of the rotating plate d 5.

The second component of the auxiliary mechanism 65 comprises a flow cylinder t2, the middle of the outer wall of the left side of the flow cylinder t2 is communicated with an exchange drain pipe t1, the middle of the inner wall of the left side of the flow cylinder t2 is provided with an auxiliary support t3, the middle of the outer wall of the right side of the auxiliary support t3 is provided with a positioning clamping plate t5, and the middle of the inner walls of the two sides of the flow cylinder t2 are provided with arc-shaped auxiliary supports t 4.

Example two:

referring to fig. 1-6, on the basis of the first embodiment, the present invention provides a technical solution: a method for using an energy-saving heat exchange device comprises the following steps: fixing the device, communicating the connecting pipe 5 with an external hot water pipe, filling water into the heat exchange main body 2, and connecting the sealing end 1 with the heat exchange main body 2;

step two: the outer exchange frame 61 is communicated with the sealing sleeve 62, external circulation of water flow is carried out on the outer exchange frame, the sealing sleeve 62 is connected with the mounting partition plate 64 to generate a sealing cavity, the loss of internal heat is reduced, and internal quantitative heat exchange is realized;

step three: the water flows through the communication port on the surface of the heat-insulating shell 633 to contact the guide frame 634, and moves along with the guide frame 634, and the cleaning ring 635 is driven by the water flow, so that the connecting position of the cleaning ring 635 and the heat-insulating shell 633 is cleaned;

step four: cold water is stored in a collecting cavity formed by the bent block 652 and the accommodating piece 651, and the heat conductor 653 and the bent block 652 are connected, so that a fixing rod of the heat conductor 653 fixes the position of the bent block 652;

step five: the rotating plate d5 is used for driving the temperature control body d4 to rotate, the blocked hole is opened, the protective bracket d2 is connected with the circulating piece d3, and the protective bracket d2 and the temperature control body d4 rotate together at the joint;

step six: the arc-shaped auxiliary support t4 is connected with the auxiliary support t3, so that the water inside the auxiliary support t3 flows through the pipeline, the auxiliary support t3 is connected with the positioning clamping plate t5, and the internal contact area of the auxiliary support t3 is reduced.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. The term "comprising", without further limitation, means that the element so defined is not excluded from the group consisting of additional identical elements in the process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. An energy-saving heat exchange device, includes heat transfer main part (2), its characterized in that: the heat exchanger is characterized in that a sealing end (1) is arranged on the outer wall of the right side of the heat exchange main body (2), a connecting pipe (5) is communicated with the left side of the top of the heat exchange main body (2), a communicating pipeline (3) is communicated with the middle of the front of the heat exchange main body (2), two sides of the bottom of the heat exchange main body (2) are fixedly connected with a supporting bottom plate (4), and an exchange device (6) is fixedly connected with the left side of the top of an inner cavity of the heat exchange main body (2).

2. An energy efficient heat exchange apparatus according to claim 1, wherein: exchange device (6) are including sealing sleeve (3), the both sides outer wall of sealing sleeve (3) all is provided with outer exchange frame (61), the left side outer wall fixedly connected with installation baffle (64) of sealing sleeve (3), one side middle part that sealing sleeve (3) were kept away from in installation baffle (64) is provided with complementary unit (65), installation baffle (64) are run through on the right side of complementary unit (65), inner chamber top right side fixedly connected with temperature regulating mechanism (63) of sealing sleeve (62).

3. An energy efficient heat exchange apparatus according to claim 2, wherein: the first component of the temperature adjusting mechanism (63) comprises a limiting frame (631), a flow distribution disc (632) is arranged in the middle of the inner wall of the right side of the limiting frame (631), a heat preservation shell (633) is fixedly connected to the outer wall of one side of the limiting frame (631), a flow guide frame (634) is arranged in the middle of the inner wall of the left side of the heat preservation shell (633), and cleaning rings (635) are arranged on two sides, located on the flow guide frame (634), of the inner cavity of the heat preservation shell (633).

4. An energy efficient heat exchange apparatus according to claim 2, wherein: the first component of the auxiliary mechanism (65) comprises an accommodating part (651), a cylinder (654) is arranged in the middle of the outer wall of the right side of the accommodating part (651), the left end of the cylinder (654) penetrates through the accommodating part (651) and extends into the accommodating part (651), two sides of one end, far away from the accommodating part (651), of the cylinder (654) are fixedly connected with bending blocks (652), the middle of the outer wall of the right side of each bending block (652) is fixedly connected with a heat conductor (653), and the outer wall of the right side of each heat conductor (653) is fixedly connected with an auxiliary plate (655).

5. An energy efficient heat exchange apparatus according to claim 2, wherein: the second component of the temperature adjusting mechanism (63) comprises a heat insulation shell (d1), a protection support (d2) is fixedly connected to the middle of the inner wall of the left side of the heat insulation shell (d1), a circulating piece (d3) is arranged on the outer wall of the right side of the protection support (d2), a rotating plate (d5) is arranged in the middle of the inner wall of the right side of the heat insulation shell (d1), and a temperature control body (d4) is fixedly connected to the middle of the outer wall of the left side of the rotating plate (d 5).

6. An energy efficient heat exchange apparatus according to claim 2, wherein: the second component of the auxiliary mechanism (65) comprises a flowing cylinder (t2), the middle part of the outer wall of the left side of the flowing cylinder (t2) is communicated with an exchange drain pipe (t1), the middle part of the inner wall of the left side of the flowing cylinder (t2) is provided with an auxiliary support (t3), the middle part of the outer wall of the right side of the auxiliary support (t3) is provided with a positioning clamping plate (t5), and the middle parts of the inner walls of two sides of the flowing cylinder (t2) are provided with arc-shaped auxiliary frames (t 4).

7. An energy efficient heat exchange apparatus according to claim 6, wherein: the middle of the outer wall of the auxiliary bracket (t3) on the left side penetrates through the flow cylinder (t2) and extends to the inside of the flow cylinder (t 2).

8. An energy efficient heat exchange apparatus according to claim 3, wherein: the outer surface of the heat preservation shell (633) is provided with a communication port.

9. The use method of the energy-saving heat exchange device is characterized in that: the method comprises the following steps: fixing the device, communicating the connecting pipe (5) with an external hot water pipe, filling the inside of the heat exchange main body (2) with water, and connecting the sealing end (1) with the heat exchange main body (2);

step two: the outer exchange frame (61) is communicated with the sealing sleeve (62), external circulation of water flow is carried out on the outer exchange frame, the sealing sleeve (62) is connected with the mounting partition plate (64) to generate a sealing cavity, loss of internal heat is reduced, and internal quantitative heat exchange is realized;

step three: the water flows through a communication port on the surface of the heat-insulating shell (633) to contact the flow guide frame (634), and moves along with the flow guide frame (634), and the cleaning ring (635) is driven by the water flow, so that the connecting position of the cleaning ring (635) and the heat-insulating shell (633) is cleaned;

step four: cold water is stored in a collecting cavity formed by the bent block (652) and the accommodating piece (651), and a heat conductor (653) is connected with the bent block (652), so that a fixing rod of the heat conductor (653) fixes the position of the bent block (652);

step five: the rotating plate (d5) drives the temperature control body (d4) to rotate, the blocked holes are opened, the protective bracket (d2) is connected with the circulating piece (d3), and the protective bracket (d2) and the temperature control body (d4) rotate together at the joint;

step six: the arc-shaped auxiliary frame (t4) is connected with the auxiliary support (t3) so that the internal water flows through the pipeline, the auxiliary support (t3) is connected with the positioning clamping plate (t5), and the internal contact area of the auxiliary support (t3) is reduced.

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