CN215446609U - Water-free floor heating separate and flow collecting device and water-free floor heating system - Google Patents

Abstract

The utility model provides a waterless floor heating current dividing and collecting device and a waterless floor heating system, wherein the waterless floor heating current dividing and collecting device comprises a box body, a current dividing and collecting component is arranged in the box body, and two ends of a capillary component extend into the box body from outside; the current collecting component and the current dividing component are respectively connected with two ends of the capillary tube component through a branch tube. By adopting the technical scheme of the utility model, the waterless floor heating separate-collecting device can be arranged on a wall body or a wall surface, all welding points or connecting points are concentrated in the box body and are not buried under a concrete floor or a wood floor, if the connecting points leak, the leaking points can be conveniently found, and the maintenance can be carried out in time under the condition of not damaging the floor; furthermore, the capillary tube component can be provided with a control valve, and if some rooms do not need heating, the capillary tube component in the room can be closed, so that electric energy is saved.

Description

Water-free floor heating separate and flow collecting device and water-free floor heating system

Technical Field

The utility model relates to the technical field of heating equipment, in particular to a waterless floor heating split-collecting device and a waterless floor heating system.

Background

The air energy waterless floor heating system is characterized in that working media circulate in air energy equipment and a capillary copper pipe in a floor through a heat pump to transfer outdoor heat to the indoor space, so that the purpose of increasing the indoor temperature is achieved. The specific implementation of such a system is: outdoor installation air can host computer, the host computer passes through the heat pump principle and absorbs outdoor heat, indoor, adopt copper pipe connection indoor copper pipe heat dissipation end outward, it is terminal as the heat dissipation indoor, the heat dissipation end lays the capillary according to the determining deviation in being the floor, a set of capillary subassembly is constituteed to many capillaries, the capillary subassembly forms a closed loop system with copper pipe branching pipe connection, adopt welding or other tight fit's mode to link into an organic whole, constitute indoor a heat dissipation end, then all buried under concrete floor or timber apron, when the heat that the working medium carried is at the copper pipe inner loop, transmit indoor intensification after the floor absorbs the heat.

However, the existing method has the following defects:

1. once the connection point leaks, it is difficult to accurately judge the leakage point and timely maintain the leakage point, if the leakage point is to be accurately found, the floor is damaged and each connection point is checked, the mode has long troubleshooting time, high maintenance cost and large floor damage area, brings great inconvenience to the life of a user, and is generally difficult to accept the maintenance mode.

2. Each group of capillary tube components is not controlled by an independent valve switch, and if some rooms do not need heating, working media flowing to the rooms cannot be closed, so that electric energy is wasted.

SUMMERY OF THE UTILITY MODEL

Aiming at the technical problem, the utility model discloses a waterless floor heating separate and combined flow device and a waterless floor heating system, wherein if leakage occurs at a connecting point, a leakage point can be conveniently found, and the waterless floor heating separate and combined flow device can be maintained in time under the condition of not damaging a floor; and the capillary assembly can be controlled individually.

In view of the above, the technical proposal of the utility model,

a waterless floor heating current dividing and collecting device comprises a box body, wherein a current dividing and collecting component is arranged in the box body, and two ends of a capillary component extend into the box body; the current collecting component and the current dividing component are respectively connected with two ends of the capillary tube component through a branch tube. Wherein the capillary assembly is comprised of a plurality of capillaries. Furthermore, the box body is arranged on a wall body or a wall surface.

By adopting the technical scheme of the utility model, the welding of the capillary tube assembly and the branching tube is transferred into the box body from the floor, and the box body can be positioned on a wall body or a wall surface, so that when a problem occurs, the box body is directly opened for searching, and the overhauling and maintenance are convenient.

As a further improvement of the utility model, the current collecting component and the current dividing component are respectively welded and connected with the corresponding capillary tube assemblies through the branch tubes.

As a further improvement of the utility model, a flow dividing member mounting bracket and a flow collecting member mounting bracket are fixedly arranged in the box body, the flow dividing member is fixedly connected with the flow dividing member mounting bracket, and the flow collecting member is fixedly connected with the flow collecting member mounting bracket.

As a further improvement of the present invention, the shunt member is fixed to the shunt member mounting bracket by a fixing buckle, and the current collecting member is fixed to the current collecting member mounting bracket by a fixing buckle.

As a further improvement of the utility model, each flow dividing member is connected with 1-3 groups of capillary tube assemblies, and each flow collecting member is connected with 1-3 groups of capillary tube assemblies.

As a further improvement of the utility model, a control valve is arranged in the box body between the branch pipe and the capillary tube assembly. By adopting the technical scheme, the control valve is arranged between the branching pipe and the capillary tube assembly, and when some rooms do not need to be heated, some capillary tube assemblies can be closed according to needs, so that energy can be saved.

As a further improvement of the utility model, a filter is arranged between the branching pipe and the capillary tube assembly. By adopting the technical scheme, the capillary tube can be prevented from being blocked, and the use reliability is improved.

As a further improvement of the utility model, the current collecting components between the adjacent waterless ground heating current dividing and collecting devices are connected through copper pipes, and the current dividing components between the adjacent waterless ground heating current dividing and collecting devices are connected through copper pipes.

As a further improvement of the utility model, the waterless floor heating separate and combined flow device comprises a box cover connected with the box body.

As a further improvement of the utility model, a refrigerant detector is arranged in the box body. By adopting the technical scheme, when the refrigerant leaks, the refrigerant leakage detection device can be quickly positioned and timely maintained, and the pollution to the environment and the energy loss are reduced.

As a further improvement of the utility model, a temperature sensor is arranged in the box body. By adopting the technical scheme, when the temperature in the box body is abnormal, the temperature in the box body can be known in time so as to facilitate the collection measures.

As a further improvement of the utility model, a controller and a communication module are arranged in the box body, and the controller is connected with the communication module.

Furthermore, refrigerant detector, temperature sensor, control valve are connected with control module, can conveniently know the condition in the box at any time like this, if refrigerant detector leaks or temperature anomaly etc. appears, can acquire information fast, in time maintains. In addition, the switch of the reorganized capillary component can be controlled through the control valve, a room which does not need to be heated can be conveniently controlled, and energy is saved.

In the last anhydrous floor heating current dividing and collecting device, the outlet of the current dividing component is directly connected with the inlet of the current collecting component through the capillary component to form a closed loop.

The utility model discloses a waterless floor heating system which comprises an outdoor air energy host, capillaries laid under a bottom plate and a waterless floor heating current dividing and collecting device, wherein a plurality of capillaries form a group of capillary tube assemblies, and two ends of each capillary tube assembly extend into a box body of the waterless floor heating current dividing and collecting device and are respectively connected with a current collecting component and a current dividing component through a current dividing pipe.

Compared with the prior art, the utility model has the beneficial effects that:

by adopting the technical scheme of the utility model, the waterless floor heating separate-collecting device can be arranged on a wall body or a wall surface, all welding points or connecting points are concentrated in the box body and are not buried under a concrete floor or a wood floor, if the connecting points leak, the leaking points can be conveniently found, and the maintenance can be carried out in time under the condition of not damaging the floor; in addition, the capillary tube component can be provided with a control valve, and if some rooms do not need heating, the capillary tube component in the room can be closed, so that electric energy is saved.

Drawings

Fig. 1 is a schematic structural view of a waterless floor heating distribution and collection device in embodiment 1 of the present invention.

Fig. 2 is an exploded structural schematic view of a waterless floor heating distribution and collection device in embodiment 1 of the present invention.

Fig. 3 is an exploded view of a diversity stream module according to embodiment 1 of the present invention.

Fig. 4 is a schematic structural diagram of a diversity current assembly fixed in a box in embodiment 1 of the present invention.

Fig. 5 is a schematic structural diagram of an endmost in-box diversity current assembly according to embodiment 1 of the present invention.

Fig. 6 is a schematic structural diagram of a diversity flow module according to embodiment 2 of the present invention.

Fig. 7 is a schematic structural diagram of a diversity flow module according to embodiment 3 of the present invention.

Fig. 8 is a schematic structural diagram of a diversity flow module according to another aspect of embodiment 3 of the present invention.

Fig. 9 is a schematic structural diagram of an anhydrous underfloor heating system in embodiment 4 of the present invention.

The reference numerals include:

the device comprises a box body 1, a flow dividing and distributing assembly 2, a capillary assembly 3, a flow collecting member 4, a flow dividing member 5, a flow dividing pipe 6, a flow dividing member mounting bracket 7, a flow collecting member mounting bracket 8, a fixing buckle 9, a capillary tube 10, a flow dividing copper pipe 11, a flow collecting copper pipe 12, a flow dividing and distributing pipe 13, a flow dividing and distributing pipe 14, a control valve 15, an air energy host 16, a connecting copper pipe 17 and a box cover 18.

Detailed Description

Preferred embodiments of the present invention will be described in further detail below with reference to the accompanying drawings.

Example 1

As shown in fig. 1 to 5, the waterless floor heating current dividing and collecting device comprises a box body 1 and a box cover 18, wherein a current dividing and collecting component 2 is arranged in the box body 1, and two ends of a capillary component 3 extend into the box body 1; the current collecting component 4 and the current dividing component 5 are respectively welded with two ends of the capillary component 3 through a branch pipe 6. Wherein the capillary assembly 3 is composed of a plurality of capillaries 10. A flow dividing component mounting bracket 7 and a flow collecting component mounting bracket 8 are arranged in the box body 1, the flow dividing component 5 is fixed on the flow dividing component mounting bracket 7 through a fixing buckle 9, and the flow collecting component 4 is fixed on the flow collecting component mounting bracket 8 through the fixing buckle 9. The shunt member mounting bracket 7 and the current collecting member mounting bracket 8 are fixed in the box body 1, and the box cover 18 is mounted on the box body 1 to form a complete waterless floor heating current collecting device. The current collecting member 4 includes a current collecting copper tube 12 for collecting the refrigerant from the capillary assembly 3, and the flow dividing member 5 includes a capillary tube 11 for delivering the refrigerant to the capillary assembly 3.

Further, the box body 1 is arranged on a wall body or a wall surface.

Further, each flow dividing member 5 in the box body 1 is connected with 1-3 groups of capillary tube assemblies 3, and each flow collecting member is connected with 1-3 groups of capillary tube assemblies 3. 2 sets of capillary assemblies 3 connected in this example.

In the last anhydrous floor heating current collecting and distributing device, the outlet of the current collecting component 5 is connected with one end of a capillary component 3, and the other end of the capillary component 3 is connected with the inlet of the current collecting component 4 to form a closed loop.

Specifically, as shown in fig. 3, the shunt assembly includes two shunt branch tubes 13 welded in series to each other by a shunt copper tube 11, and one end of each of the shunt branch tubes 13 is welded to the capillary assembly 3. The current collecting assembly is formed by welding two current collecting branch pipes 14 in series by a current collecting copper pipe 12, and one end of each current collecting branch pipe 14 is welded with a capillary tube assembly 3. In a box body of the waterless floor heating current dividing and collecting device at the tail end of a floor heating circuit, one end of an inlet and an outlet of the current dividing component 5 and the current collecting component 4 is a capillary component 3, and the other end of the inlet and the outlet is a copper pipe connected with other waterless floor heating current dividing and collecting devices.

Example 2

In addition to embodiment 1, as shown in fig. 6, a control valve 15 is provided between the branching tube 6 and the capillary tube assembly 3 in the case 1. By adopting the technical scheme, the control valve 15 is arranged between the branching pipe 6 and the capillary components 3, and when some rooms do not need to be heated, some capillary components 3 can be closed according to needs, so that energy can be saved.

Further, a filter is arranged between the branching pipe 6 and the capillary tube assembly 3. By adopting the technical scheme, the capillary tube 10 can be prevented from being blocked, and the use reliability is improved.

Further, a refrigerant detector is arranged in the box body 1. By adopting the technical scheme, when the refrigerant leaks, the refrigerant leakage detection device can be quickly positioned and timely maintained, and the pollution to the environment and the energy loss are reduced.

Further, a temperature sensor is arranged in the box body 1. By adopting the technical scheme, when the temperature in the box body 1 is abnormal, the temperature can be known in time so as to collect measures.

Further, a controller and a communication module are arranged in the box body 1, and the controller is connected with the communication module. The refrigerant detector, the temperature sensor and the control valve 15 are connected with the control module. Therefore, the condition in the box body 1 can be conveniently known at any time, and if the refrigerant detector leaks or the temperature is abnormal, information can be quickly acquired, and maintenance can be performed in time. In addition, the on-off of the reorganized capillary tube assembly 3 can be controlled through the control valve 15, so that the room which does not need to be heated can be conveniently controlled, and energy is saved.

Example 3

On the basis of embodiment 1, as shown in fig. 7 and 8, in this embodiment, each flow dividing member 5 in the tank 1 is connected to 1 group of capillary assemblies 3, and each flow collecting member is connected to 1 group of capillary assemblies 3.

Example 4

As shown in fig. 9, the waterless floor heating system comprises an outdoor air energy host 16, capillaries 10 laid under a bottom plate and a waterless floor heating branch and current collecting device as described above, wherein a group of capillary tube assemblies 3 are formed by a plurality of capillaries 10, two ends of each capillary tube assembly extend into a box body 1 of the waterless floor heating branch and current collecting device and are respectively connected with a current collecting member 4 and a current dividing member 5 through a branch tube 6, and the current collecting member 4 and the current dividing member 5 are respectively connected with the air energy host 16 through a connecting copper tube 17; the current collecting members 4 between the adjacent waterless ground heating current collecting and distributing devices are connected through connecting copper pipes 17, and the current dividing members 5 between the adjacent waterless ground heating current collecting and distributing devices are connected through connecting copper pipes 17.

By adopting the technical scheme, the heat absorbed by the working medium in the air energy host machine 16 outdoors is connected with one inlet end of the flow distribution member 5 through the connecting copper pipe 17, and one outlet end is connected with the other anhydrous floor heating flow distribution and control device through the connecting copper pipe 17. The flow dividing component 5 is communicated with the flow collecting component 4 through the capillary component 3, and heat carried by the working medium is dissipated by the capillary 10 to heat the indoor space; then the working medium flows into the inlet of the current collecting component 4, and then flows into the air energy host computer 16 from the outlet of the current collecting component 4 through the connecting copper pipe 17, and the circulation is continuously performed, and the indoor temperature is continuously increased.

The above-mentioned embodiments are preferred embodiments of the present invention, and the scope of the present invention is not limited thereto, and the equivalent changes in shape and structure according to the present invention are within the protection scope of the present invention.

Claims (10)

1. The utility model provides a divide mass flow device warms up anhydrous which characterized in that: the device comprises a box body, wherein a current dividing and collecting component is arranged in the box body, and two ends of a capillary component extend into the box body from outside; the current collecting component and the current dividing component are respectively connected with two ends of the capillary tube component through a branch tube.

2. The waterless floor heating current diversity device of claim 1, characterized in that: the current collecting component and the current dividing component are respectively connected with the corresponding capillary tube assemblies in a welding mode through the branch tubes.

3. The waterless floor heating current diversity device of claim 2, characterized in that: a flow dividing member mounting bracket and a flow collecting member mounting bracket are fixedly arranged in the box body, the flow dividing member is fixedly connected with the flow dividing member mounting bracket, and the flow collecting member is fixedly connected with the flow collecting member mounting bracket.

4. The waterless floor heating distribution and collection device of claim 3, characterized in that: the flow distribution component is fixed on the flow distribution component mounting bracket through a fixing buckle, and the current collecting component is fixed on the current collecting component mounting bracket through a fixing buckle.

5. The waterless floor heating distribution and collection device of claim 3, characterized in that: each flow dividing member is connected with 1-3 groups of capillary tube assemblies, and each flow collecting member is connected with 1-3 groups of capillary tube assemblies.

6. The waterless floor heating current diversity device of claim 1, characterized in that: in the box body, a control valve is arranged between the branching pipe and the capillary tube assembly.

7. The waterless floor heating current diversity device of claim 1, characterized in that: and a filter is arranged between the branching pipe and the capillary tube assembly.

8. The waterless floor heating separate and combined flow device according to any one of claims 1 to 7, characterized in that: the current collecting members between the adjacent waterless ground heating current collecting and distributing devices are connected through copper pipes, and the current distributing members between the adjacent waterless ground heating current collecting and distributing devices are connected through copper pipes.

9. The waterless floor heating current diversity device of claim 8, characterized in that: which comprises a box cover connected with a box body.

10. The utility model provides a waterless underfloor heating system which characterized in that: the water-free floor heating current dividing and collecting device comprises an outdoor air energy host, capillaries laid under a bottom plate and the water-free floor heating current dividing and collecting device according to any one of claims 1-9, wherein a plurality of capillaries form a group of capillary assemblies, two ends of each capillary assembly extend into a box body of the water-free floor heating current dividing and collecting device and are respectively connected with a current collecting component and a current dividing component through a current dividing pipe.

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