CN216361426U - Multi-energy co-supply complementary efficient indoor temperature adjusting device and system - Google Patents

Abstract

A multi-energy co-supply complementary efficient indoor temperature adjusting device comprises a wall-mounted furnace, wherein the bottom of the wall-mounted furnace is communicated with a first water supply pipe and a first return pipe, a first water pump is mounted outside the first return pipe, and the end parts of the first water supply pipe and the first return pipe are communicated to a domestic water tank; a first three-way valve is arranged on the outer wall of the first water supply pipe, and a second three-way valve is arranged on the outer wall of the first water return pipe; the side wall of the domestic water tank is communicated with a second water supply pipe and a water replenishing pipe, and the outlet end of the second water supply pipe is communicated with a faucet and a shower head; the whole equipment is provided with the wall-mounted furnace and the heat pump main machine, the wall-mounted furnace can heat hot water in the living water tank and the cold and warm water tanks simultaneously, so that the heating difference of the heat pump main machine in winter is compensated, the temperature of the hot water in the cold and warm water tanks is kept at a set value, the heating effect of air and the buried coil pipe is further ensured, and finally high indoor heating efficiency and good constant temperature effect are realized.

Description

Multi-energy co-supply complementary efficient indoor temperature adjusting device and system

Technical Field

The utility model belongs to the technical field of indoor temperature regulation and control, and particularly relates to a multi-energy co-supply complementary efficient indoor temperature regulating device and system.

Background

For houses with larger house types, the indoor temperature regulation measures usually adopt a heat pump unit as an energy source, and a plurality of air outlet pipes and buried coil pipes are distributed as temperature control ends;

however, the existing heat pump unit is affected by low temperature in winter, the energy efficiency of the heat pump unit is greatly reduced, the supply amount of hot water is insufficient, the water temperature cannot be kept at a preset value, and meanwhile, the energy consumption of the heat pump unit is large.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model provides a multi-energy combined supply complementary high-efficiency indoor temperature adjusting device, which has the following specific technical scheme:

a multi-energy co-supply complementary efficient indoor temperature adjusting device comprises a wall-mounted furnace, wherein the bottom of the wall-mounted furnace is communicated with a first water supply pipe and a first return pipe, a first water pump is mounted outside the first return pipe, and the end parts of the first water supply pipe and the first return pipe are communicated to a domestic water tank; the first three-way valve is installed on the outer wall of the first water supply pipe, the second three-way valve is installed on the outer wall of the first water return pipe, the cold and hot water tank is connected to the first three-way valve in parallel through a third water supply pipe, the cold and hot water tank is connected to the second three-way valve in parallel through a third water return pipe, and the fresh air temperature adjusting assembly, the ground temperature adjusting assembly and the heat pump host are connected to the cold and hot water tank in parallel;

the side wall of the domestic water tank is communicated with a second water supply pipe and a water replenishing pipe, and the outlet end of the second water supply pipe is communicated with a faucet and a shower head.

Further, the fresh air temperature adjusting component comprises a cooling and heating coil box, a fresh air host, a main air outlet pipe and a plurality of branch air boxes, the cooling and heating water tank is communicated to the cooling and heating coil box through a fourth water supply pipe and a fourth water return pipe, a third water pump is mounted outside the fourth water supply pipe, an air inlet is formed in the top of the cooling and heating coil box, an outlet of the cooling and heating coil box is communicated to the fresh air host, an outlet of the fresh air host is communicated to the main air outlet pipe, and the main air outlet pipe is connected with the branch air boxes in parallel.

Furthermore, the side wall of the cold and warm water tank is communicated with a fifth water supply pipe and a fifth water return pipe, a control valve is mounted outside the fifth water supply pipe, and the fifth water supply pipe and the fifth water return pipe are communicated to the buried coil pipe.

Furthermore, the side wall of the cold and hot water tank is communicated to the heat pump host through a sixth water supply pipe and a sixth water return pipe, and a fourth water pump is installed outside the sixth water supply pipe.

Furthermore, a second built-in probe is installed inside the cold and warm water tank, a first built-in probe is installed inside the domestic water tank, and an external probe is placed outside the cold and warm water tank.

The utility model provides a complementary high-efficient indoor temperature regulating system of multipotency source allies oneself with confession which characterized in that: the air conditioner comprises a cold and warm water tank, wherein the cold and warm water tank is connected with a fresh air temperature adjusting component, a buried coil pipe and a heat pump host in parallel in a two-way mode through water pipes, the cold and warm water tank is communicated with a first water supply pipe through a third water supply pipe, a first three-way valve is arranged at the joint of the cold and warm water tank and the first water supply pipe, the cold and warm water tank is communicated with a first water return pipe through a third water return pipe, a second three-way valve is arranged at the joint of the cold and warm water tank and the first water return pipe, and a first water pump is arranged on the first water return pipe;

a second built-in probe is arranged inside the cold and hot water tank, a first built-in probe is arranged inside the domestic water tank, and an external probe is arranged outside the cold and hot water tank;

the wall-mounted furnace, the first water pump, the first three-way valve, the second three-way valve, the first built-in probe, the second built-in probe and the external probe are all connected to the operation host in parallel.

The utility model has the beneficial effects that:

the whole equipment is provided with two temperature adjusting sources of a wall-mounted furnace and a heat pump host, the wall-mounted furnace can heat hot water in a living water tank and a cold and warm water tank simultaneously, so that the heating difference of the heat pump host in winter is compensated, the temperature of the hot water in the cold and warm water tank is kept at a set value, the heating effect of air and a buried coil pipe is further ensured, and finally high indoor heating efficiency and good constant temperature effect are realized; meanwhile, the domestic water tank and the cold and warm water tank can ensure sufficient hot water supply.

Drawings

FIG. 1 is a schematic structural diagram of a multi-energy co-generation complementary high-efficiency indoor temperature regulating device of the utility model;

FIG. 2 shows a schematic diagram of a tempering system of the present invention;

shown in the figure: 1. a wall-mounted furnace; 2. a first water supply pipe; 21. a first three-way valve; 3. a first water return pipe; 31. a second three-way valve; 32. a first water pump; 4. a living water tank; 41. a water replenishing pipe; 42. a second water supply pipe; 44. a first built-in probe; 5. a faucet; 6. a shower head; 7. operating a host; 8. a cold and warm water tank; 81. a third water supply pipe; 82. a third water return pipe; 83. a fourth water supply pipe; 831. a third water pump; 84. a fourth water return pipe; 85. a fifth water supply pipe; 851. a control valve; 86. a fifth water return pipe; 87. a sixth water supply pipe; 871. a fourth water pump; 88. a sixth water return pipe; 89. a second built-in probe; 9. a fresh air temperature adjusting component; 91. a cooling and heating coil box; 92. a fresh air host; 93. a main air outlet pipe; 94. separating out an air box; 9a, burying a coil pipe; 9b, a heat pump host; 9c and an external probe.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, 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 some, but not all, embodiments of the present invention. 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.

Examples

As shown in fig. 1, a multi-energy co-generation complementary high-efficiency indoor temperature adjusting device comprises a wall-mounted furnace 1, wherein the bottom of the wall-mounted furnace 1 is communicated with a first water supply pipe 2 and a first water return pipe 3, a first water pump 32 is installed outside the first water return pipe 3, and the end parts of the first water supply pipe 2 and the first water return pipe 3 are communicated with a domestic water tank 4; a first three-way valve 21 is installed on the outer wall of the first water supply pipe 2, and a second three-way valve 31 is installed on the outer wall of the first water return pipe 3;

the cold and warm water tank 8 is connected in parallel to the first three-way valve 21 through a third water supply pipe 81, the cold and warm water tank 8 is connected in parallel to the second three-way valve 31 through a third water return pipe 82, and the cold and warm water tank 8 is also connected in parallel with a fresh air temperature adjusting component 9, a buried coil pipe 9a and a heat pump host machine 9 b;

a hot water supply pipeline formed by a water tap and a shower head, and the fresh air temperature adjusting component and the buried coil form another two hot water supply pipelines.

The whole equipment is provided with two temperature adjusting sources of a wall-mounted furnace and a heat pump host, the wall-mounted furnace can heat water in a living water tank and a cold and hot water tank simultaneously, so that the working energy consumption of the heat pump host in winter is reduced, the temperature of hot water in the cold and hot water tanks is kept at a set value, the heating effect of air and a buried coil pipe is further ensured, and finally, high indoor heating efficiency and good constant temperature effect are realized; meanwhile, the domestic water tank and the cold and warm water tank can ensure sufficient hot water supply.

As shown in fig. 1, a second water supply pipe 42 and a water replenishing pipe 41 are communicated with the side wall of the domestic water tank 4, and the outlet end of the second water supply pipe 42 is communicated with a faucet 5 and a shower head 6; the design of moisturizing pipe can be when the hot water in the domestic water tank is not enough mend water, and domestic hot water is direct to be passed through tap, gondola water faucet blowout.

As shown in fig. 1, the fresh air temperature adjusting assembly 9 includes a cooling and heating coil box 91, a fresh air main unit 92, a main air outlet pipe 93 and a branch air box 94, the cooling and heating water tank 8 is communicated to the cooling and heating coil box 91 through a fourth water supply pipe 83 and a fourth water return pipe 84, a third water pump 831 is installed outside the fourth water supply pipe 83, an air inlet is formed in the top of the cooling and heating coil box 91, an outlet of the cooling and heating coil box 91 is communicated to the fresh air main unit 92, an outlet of the fresh air main unit 92 is communicated to the main air outlet pipe 93, and the main air outlet pipe 93 is connected in parallel with the branch air box 94; cold water or hot water in the cold and warm water tank are pumped to the cold and warm coil pipe case through the third water pump, then return to in the cold and warm water tank through the fourth wet return pipe, and the inspiratory outside new trend of new trend host computer enters into the cold and warm coil pipe case earlier, and cold water or hot water carry out the heat replacement with the air to carry out the precooling or preheat the new trend, so, alright reduce the work energy consumption of new trend host computer, improve the refrigeration or the effect of heating of minute bellows.

As shown in fig. 1, a fifth water supply pipe 85 and a fifth water return pipe 86 are communicated with the side wall of the cooling and heating water tank 8, a control valve 851 is installed outside the fifth water supply pipe 85, and both the fifth water supply pipe 85 and the fifth water return pipe 86 are communicated with the buried coil pipe 9 a; the hot water in the cold-hot water tank flows through the fifth water supply pipe and the fifth water return pipe in the buried coil pipe in a circulating mode, so that indoor heating is achieved, and the control valve is closed in summer.

As shown in fig. 1, the side wall of the cooling and heating water tank 8 is communicated to the heat pump main unit 9b through a sixth water supply pipe 87 and a sixth water return pipe 88, and a fourth water pump 871 is installed outside the sixth water supply pipe 87; the fourth water pump can circularly pump the water in the cold and warm water tank into the heat pump host for heating or refrigerating.

A second built-in probe 89 is arranged in the cold and warm water tank 8, a first built-in probe 44 is arranged in the domestic water tank 4, and an external probe 9c is arranged outside the cold and warm water tank 8; the water temperature in the living water tank is monitored through the first built-in probe, and the water temperature in the cold and hot water tank is monitored through the second built-in probe, so that the linkage of the overall monitoring is facilitated, the water temperature is kept constant, and the energy consumption is reduced.

As shown in fig. 1 and 2, a multi-energy co-supply complementary high-efficiency indoor temperature regulating system comprises a cold and warm water tank 8, wherein the cold and warm water tank 8 is connected with a fresh air temperature regulating component 9, a buried coil 9a and a heat pump host 9b in parallel in two directions through water pipes, the cold and warm water tank 8 is communicated with a first water supply pipe 2 through a third water supply pipe 81, a first three-way valve 21 is installed at the joint of the first water supply pipe and the first water supply pipe, the cold and warm water tank 8 is communicated with a first water return pipe 3 through a third water return pipe 82, a second three-way valve 31 is installed at the joint of the first water return pipe and the second water return pipe, and a first water pump 32 is installed on the first water return pipe 3;

a second built-in probe 89 is arranged in the cold and warm water tank 8, a first built-in probe 44 is arranged in the domestic water tank 4, and an external probe 9c is arranged outside the cold and warm water tank 8;

the wall-mounted furnace 1, the first water pump 32, the first three-way valve 21, the second three-way valve 31, the first built-in probe 44, the second built-in probe 89 and the external probe 9c are all connected to the operation host 7 in parallel;

the electrical equipment can be controlled in a linkage manner by operating the host.

The utility model is implemented as follows:

in winter:

the first three-way valve 21 and the second three-way valve 31 close and connect the openings of the third water supply pipe 81 and the third water return pipe 82 and connect the opening of the domestic water tank 4;

the first water pump 32 pumps water in the domestic water tank 4, the water in the domestic water tank 4 circulates through the wall-mounted furnace 1, the wall-mounted furnace 1 heats the water, and when the first built-in probe 44 detects that the temperature in the domestic water tank 4 is kept at 50 ℃, the first three-way valve 21 and the second three-way valve 31 open and connect openings of the third water supply pipe 81 and the third water return pipe 82 and close the opening connected with the domestic water tank 4;

the first water pump 32 and the fourth water pump 871 work simultaneously to pump a part of water in the cold and warm water tank 8 into the heat pump main unit 9b for heating, and the other part of water is heated through the wall-mounted furnace 1, so that the wall-mounted furnace 1 can solve the problem that the heat pump main unit 9b is insufficient in working efficiency in winter, and the heating effect is improved;

when the second built-in probe 89 detects that the water temperature in the cold and hot water tank 8 reaches a set value, the wall-mounted boiler 1 and the first water pump 32 stop working and are heated by the heat pump host;

when the water temperature in the cold and warm water tank 8 or the domestic water tank 4 is reduced to the limit, the first three-way valve and the second three-way valve are switched to the corresponding water tanks for cyclic heating;

during hot water partly enters into changes in temperature coil pipe box 91, the new trend of new trend host computer 92 suction is heated by changes in temperature coil pipe box 91, then hot-blast back of being filtered by the new trend host computer, rethread main play tuber pipe 93, divide bellows 94 dispersion discharge, simultaneously, another part hot water discharge to buried coil pipe 9a in, buried coil pipe 9a heats indoor to realize high efficiency and heat up.

In summer:

the hanging stove heats for running water tank 4 alone, satisfies user's daily life hot water needs, and the heat pump host computer refrigerates the water in the changes in temperature water tank alone.

It is noted that, in this document, relational terms such as first and second, and the like, if any, are 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. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (6)

1. The utility model provides a complementary high-efficient indoor attemperator of multipotency source allies oneself with confession which characterized in that: the wall-mounted boiler comprises a wall-mounted boiler, wherein the bottom of the wall-mounted boiler is communicated with a first water supply pipe and a first water return pipe, a first water pump is arranged outside the first water return pipe, and the end parts of the first water supply pipe and the first water return pipe are communicated with a domestic water tank; the first three-way valve is installed on the outer wall of the first water supply pipe, the second three-way valve is installed on the outer wall of the first water return pipe, the cold and hot water tank is connected to the first three-way valve in parallel through a third water supply pipe, the cold and hot water tank is connected to the second three-way valve in parallel through a third water return pipe, and the fresh air temperature adjusting assembly, the ground temperature adjusting assembly and the heat pump host are connected to the cold and hot water tank in parallel;

the side wall of the domestic water tank is communicated with a second water supply pipe and a water replenishing pipe, and the outlet end of the second water supply pipe is communicated with a faucet and a shower head.

2. The indoor temperature regulating device of claim 1, wherein: the fresh air temperature adjusting component comprises a cooling and heating coil box, a fresh air host, a main air outlet pipe and a plurality of branch air boxes, the cooling and heating water tank is communicated to the cooling and heating coil box through a fourth water supply pipe and a fourth water return pipe, a third water pump is mounted outside the fourth water supply pipe, an air inlet is formed in the top of the cooling and heating coil box, an outlet of the cooling and heating coil box is communicated to the fresh air host, an outlet of the fresh air host is communicated to the main air outlet pipe, and the main air outlet pipe is connected with the plurality of branch air boxes in parallel.

3. The indoor temperature regulating device of claim 1, wherein: and the side wall of the cold and warm water tank is communicated with a fifth water supply pipe and a fifth water return pipe, a control valve is arranged outside the fifth water supply pipe, and the fifth water supply pipe and the fifth water return pipe are communicated to the buried coil pipe.

4. The indoor temperature regulating device of claim 1, wherein: the side wall of the cold and hot water tank is communicated to the heat pump host through a sixth water supply pipe and a sixth water return pipe, and a fourth water pump is installed outside the sixth water supply pipe.

5. The indoor temperature regulating device of claim 1, wherein: the domestic water tank is characterized in that a second built-in probe is arranged inside the cold and warm water tank, a first built-in probe is arranged inside the domestic water tank, and an external probe is arranged outside the cold and warm water tank.

6. The utility model provides a complementary high-efficient indoor temperature regulating system of multipotency source allies oneself with confession which characterized in that: the air conditioner comprises a cold and warm water tank, wherein the cold and warm water tank is connected with a fresh air temperature adjusting component, a buried coil pipe and a heat pump host in parallel in a two-way mode through water pipes, the cold and warm water tank is communicated with a first water supply pipe through a third water supply pipe, a first three-way valve is arranged at the joint of the cold and warm water tank and the first water supply pipe, the cold and warm water tank is communicated with a first water return pipe through a third water return pipe, a second three-way valve is arranged at the joint of the cold and warm water tank and the first water return pipe, and a first water pump is arranged on the first water return pipe; one end of the first water supply pipe and one end of the first water return pipe are communicated to the wall-mounted boiler, and the other end of the first water supply pipe and the other end of the first water return pipe are communicated to the domestic water tank;

a second built-in probe is arranged inside the cold and hot water tank, a first built-in probe is arranged inside the domestic water tank, and an external probe is arranged outside the cold and hot water tank;

the wall-mounted furnace, the first water pump, the first three-way valve, the second three-way valve, the first built-in probe, the second built-in probe and the external probe are all connected to the operation host in parallel.

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