CN212721005U - Titanium tube heat exchanger for swimming pool - Google Patents

Abstract

The utility model discloses a titanium tube heat exchanger for swimming pool, the on-line screen storage device comprises a base, the inside threaded connection of base has the barrel, and barrel top threaded connection has the top cap, the welding has the outlet pipe that link up each other with the top cap on the outer wall of top cap one side, the welding has the inlet tube that link up each other with the base on the outer wall of base one side, the board is all flowed to the barrel bottom is installed through the bolt, and all set up the equidistance on the board top outer wall and be the water guide hole that the loop configuration distributes, the welding has the sleeve on the board top outer wall all flowed to the board. The utility model discloses when using this titanium pipe coil pipe to carry out the heat transfer, the recess can improve the heat exchange medium in the titanium pipe coil pipe and the fluid area of contact outside the titanium pipe to improve the heat transfer area of titanium pipe coil pipe, zeolite granule in the zeolite filling layer can effectually prevent the water boiling upwards to strike simultaneously, and liquid can remain stable when making the heating, thereby has improved the security on the equipment use.

Description

Titanium tube heat exchanger for swimming pool

Technical Field

The utility model relates to a titanium tube heat exchanger technical field especially relates to a titanium tube heat exchanger for swimming pool.

Background

The titanium tube heat exchanger is also called a titanium gun, is refined by adopting titanium tubes and PVC tubes, and is widely applied to machines with corrosive water sources, such as a swimming pool heat pump machine, a seafood machine, a seawater source heat pump and the like.

At present, current titanium pipe heat exchanger is when using, and when the heat exchange medium in the titanium pipe and the fluid outside the titanium pipe carried out the heat transfer, received the restriction of titanium pipe outer wall surface area, and heat exchange efficiency is not very high, and current titanium pipe heat exchanger is at the in-process of heat transfer simultaneously, if the water temperature is too high and produce the boiling, can lead to the water to impact to the outside inflation, has certain potential safety hazard in the operation, consequently, need to design a swimming pool titanium pipe heat exchanger to solve above-mentioned problem urgently.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problem that the heat exchange efficiency of the existing titanium tube heat exchanger existing in the prior art is not very high and the titanium tube heat exchanger can realize boiling in the process of heat exchange to make the water expand and impact to the outside, and providing the titanium tube heat exchanger for the swimming pool.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a swimming pool titanium pipe heat exchanger, includes the base, the inside threaded connection of base has the barrel, and barrel top threaded connection has the top cap, the welding has the outlet pipe that link up each other with the top cap on the outer wall of top cap one side, the welding has the inlet tube that link up each other with the base on the outer wall of base one side, the board is all flowed to the barrel bottom is installed through the bolt, and all sets up the equidistance on the board top outer wall and be the water guide hole that the loop configuration distributes, the welding has the sleeve on the board top outer wall all flows, and sets up the through-hole that the equidistance is the loop configuration and distributes on the sleeve side outer wall, the titanium pipe coil pipe has been cup jointed.

Further, outlet pipe side outer wall is close to one end department and is close to the equal threaded connection of one end department with inlet tube side outer wall and has the connector head, inlet tube one end is installed through the bolt and is located the inside filter plate of connector head.

Furthermore, a temperature sensing pipe extending into the base is inserted into one side of the outer wall of the front side of the base, lug plates distributed in an annular structure at equal intervals are welded on the outer wall of the side surface of the base close to the bottom end of the base, and a zeolite filling layer is installed on the inner wall of the bottom of the base through bolts.

Furthermore, a second mounting nozzle is welded at the center of the outer wall of the top cover, and the second mounting nozzle is communicated with the top cover.

Further, the welding has the equidistance to be the first installation mouth that the annular structure distributes on the outer wall of top cap side, and first installation mouth link up each other with the top cap, two the equal threaded connection in first installation mouth top has the coupling, the delivery port and the water inlet of titanium pipe coil pipe communicate with two first installation mouths each other respectively through the pipeline.

The utility model has the advantages that:

1. through the groove arranged on the inner wall of the side surface of the titanium pipe coil, when the titanium pipe coil is used for heat exchange, the groove can improve the contact area of a heat exchange medium in the titanium pipe coil and fluid outside the titanium pipe, so that the heat exchange area of the titanium pipe coil is improved.

2. Through the zeolite filling layer that sets up, when using the device, the zeolite granule in the zeolite filling layer can effectually prevent the water boiling and upwards strike, and liquid can remain stable when making the heating to the security in the equipment use has been improved.

3. Through the flow equalizing plate, when the device is used, the water guide holes in the flow equalizing plate can reduce the area of the water flow cross section entering the titanium tube heat exchanger, so that the flow velocity of water flow is increased, and the heat exchange efficiency of the titanium tube heat exchanger is improved.

Drawings

Fig. 1 is a front view of a titanium tube heat exchanger for a swimming pool according to the present invention;

fig. 2 is a front view structural cross-sectional view of a titanium tube heat exchanger for a swimming pool according to the present invention;

FIG. 3 is a sectional view of a flow equalizing plate and a sleeve structure of a titanium tube heat exchanger for a swimming pool according to the present invention;

fig. 4 is a cross-sectional view of the titanium pipe coil structure of the titanium pipe heat exchanger for the swimming pool.

In the figure: the device comprises a base 1, a cylinder 2, a top cover 3, a first mounting nozzle 4, a pipe joint 5, a water outlet pipe 6, a connecting pipe joint 7, a water inlet pipe 8, a temperature sensing pipe 9, an ear plate 10, a filter screen plate 11, a titanium pipe coil 12, a flow equalizing plate 13, a zeolite filling layer 14, a sleeve 15, a through hole 16, a water guiding hole 17, a groove 18 and a second mounting nozzle 19.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When a component is referred to as being "connected" to another component, it can be directly connected to the other component or intervening components may also be present. When a component is referred to as being "disposed on" another component, it can be directly on the other component or intervening components may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1 to 4, a titanium tube heat exchanger for a swimming pool comprises a base 1, a cylinder 2 is connected to the base 1 through a screw thread, a top cover 3 is connected to the top end of the cylinder 2 through a screw thread, a water outlet pipe 6 communicated with the top cover 3 is welded to the outer wall of one side of the top cover 3, so that water exchanging in the device can flow out of the device conveniently, a water inlet pipe 8 communicated with the base 1 is welded to the outer wall of one side of the base 1, so that water can be added into the device conveniently, a flow equalization plate 13 is installed at the bottom end of the cylinder 2 through bolts, the water guide holes 17 on the flow equalization plate 13 can reduce the cross-sectional area of water flowing into the titanium tube heat exchanger, so that the flow velocity of water is increased, thereby improving the heat exchanging efficiency of the titanium tube heat exchanger, and water guide holes 17 distributed in an annular structure at equal intervals, thereby make the velocity of flow of rivers increase, the welding has sleeve 15 on the outer wall of flow equalizing plate 13 top, be convenient for carry on spacingly to titanium pipe coil pipe 12, make titanium pipe coil pipe 12 keep steady at the device during operation, and set up on the sleeve 15 side outer wall and be the through-hole 16 that the equidistance is the annular structure and distributes, sleeve 15 outside has cup jointed titanium pipe coil pipe 12, set up on the inner wall of titanium pipe coil pipe 12 side and be the recess 18 that the equidistance structure distributes, recess 18 can improve the fluid area of contact outside heat exchange medium and the titanium pipe in titanium pipe coil pipe 12.

Further, the outer wall of the side surface of the water outlet pipe 6 is close to one end and is close to the equal threaded connection of one end with the outer wall of the side surface of the water inlet pipe 8, so that the external pipeline is installed on the water outlet pipe 6 and the water inlet pipe 8, and the filter screen plate 11 located inside the connector tube head 7 is installed at one end of the water inlet pipe 8 through bolts and is used for filtering water flow.

Further, base 1 openly outer wall one side is pegged graft and is had the temperature sensing pipe 9 that extends to the inside of base 1 for the inside temperature situation of perception this titanium tubular heat exchanger, so that the staff knows the inside temperature of this titanium tubular heat exchanger, and base 1 side outer wall is close to bottom department welding has the otic placode 10 that the equidistance is the annular structure and distributes, is convenient for install the device in suitable position through the bolt, installs zeolite filling layer 14 through the bolt on the base 1 bottom inner wall. The zeolite particles in the zeolite filling layer 14 can effectively prevent the upward impact of the boiling of the water body, so that the liquid can be kept stable during heating, and the use safety of the equipment is improved.

Furthermore, a second mounting nozzle 19 is welded at the center of the outer wall of the top cover 3, the first mounting nozzle 4 and the second mounting nozzle 19 are convenient for connecting the pipe joint 5 and the titanium pipe coil 12 together, and the second mounting nozzle 19 is communicated with the top cover 3.

Further, the welding has the equidistance to be the first installation mouth 4 that the loop configuration distributes on the 3 side outer walls of top cap, be used for making coupling 5 peg graft on top cap 3, thereby make coupling 5 and titanium pipe coil 12 be linked together, in so that send heat transfer medium into titanium pipe coil 12, and first installation mouth 4 link up each other with top cap 3, the equal threaded connection in 4 tops of two first installation mouths has coupling 5, be convenient for make external pipeline and titanium pipe coil 12 link together, the delivery port and the water inlet of titanium pipe coil 12 pass through the pipeline and communicate each other with two first installation mouths 4 respectively.

The working principle is as follows: when the device is used, an operator can firstly connect an external pipeline with the water outlet pipe 6 and the water inlet pipe 8 of the titanium pipe heat exchanger, at the moment, the external pipeline can be inserted into the connector head 7, so that the external pipeline is connected with the titanium pipe heat exchanger, meanwhile, the operator connects the pipe joint 5 with external heat medium exchange medium storage equipment, then, when the titanium pipe heat exchanger works, water in a swimming pool can enter the titanium pipe heat exchanger through the external pipeline and the water inlet pipe 8 under the action of a water pump, at the moment, the filter screen plate 11 can filter impurities in water flow, so that the impurities are prevented from entering the titanium pipe heat exchanger to influence the work of the titanium pipe heat exchanger, meanwhile, the operator adds heat exchange medium into the titanium pipe coil 12 through the pipe joint 5, so that the water flow is in contact with the titanium pipe coil 12 for heat exchange, at the moment, the groove 18 can improve the contact area between the heat exchange medium in the, thereby improve the heat transfer area of titanium pipe coil 12, make the recess can improve the heat exchange medium in the titanium pipe coil and the fluid area of contact outside the titanium pipe, thereby improve the heat transfer area heat exchange efficiency improvement of titanium pipe coil, simultaneously when rivers pass through flow equalizer 13, the guiding hole 17 on the flow equalizer 13 can make the rivers cross sectional area who gets into in this titanium pipe heat exchanger reduce, thereby make the velocity of water flow increase, thereby improve titanium pipe heat exchanger heat exchange efficiency, and when the rivers boiling in the titanium pipe heat exchanger, zeolite filling layer 14 can upwards strike in the effectual prevention water boiling, liquid can remain stable during messenger's heating, thereby the security on the equipment use has been improved.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (5)

1. The titanium tube heat exchanger for the swimming pool comprises a base (1) and is characterized in that a barrel (2) is connected to the inner portion of the base (1) in a threaded manner, a top cover (3) is connected to the top end of the barrel (2) in a threaded manner, a water outlet pipe (6) which is communicated with the top cover (3) is welded to the outer wall of one side of the top cover (3), a water inlet pipe (8) which is communicated with the base (1) is welded to the outer wall of one side of the base (1), a flow equalizing plate (13) is installed at the bottom end of the barrel (2) through bolts, water guide holes (17) which are distributed in an annular structure at equal intervals are formed in the outer wall of the top of the flow equalizing plate (13), a sleeve (15) is welded to the outer wall of the top of the flow equalizing plate (13), through holes (16) which are distributed in, the inner wall of the side surface of the titanium pipe coil pipe (12) is provided with grooves (18) which are distributed in an equidistant structure.

2. The titanium tube heat exchanger for swimming pool as recited in claim 1, wherein the outer wall of the side of the outlet pipe (6) near one end is connected with the outer wall of the side of the inlet pipe (8) near one end by screw threads with a connector head (7), and one end of the inlet pipe (8) is provided with a filter screen plate (11) inside the connector head (7) by bolts.

3. The titanium tube heat exchanger for the swimming pool as recited in claim 1, wherein the temperature sensing tube (9) extending into the base (1) is inserted into one side of the outer wall of the front surface of the base (1), the outer wall of the side surface of the base (1) near the bottom end is welded with the ear plates (10) distributed in the annular structure at equal intervals, and the zeolite filling layer (14) is installed on the inner wall of the bottom of the base (1) through bolts.

4. The titanium tube heat exchanger for swimming pool as recited in claim 1, characterized in that the second nozzle (19) is welded at the center of the top outer wall of the top cover (3), and the second nozzle (19) and the top cover (3) are communicated with each other.

5. The titanium tube heat exchanger for the swimming pool as recited in claim 4, wherein the first mounting nozzles (4) are welded on the outer wall of the side of the top cover (3) and distributed in an annular structure at equal intervals, the first mounting nozzles (4) are communicated with the top cover (3), the top ends of the two first mounting nozzles (4) are respectively connected with a pipe joint (5) in a threaded manner, and the water outlet and the water inlet of the titanium tube coil (12) are respectively communicated with the two first mounting nozzles (4) through pipelines.

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