CN221375786U - Combined heating device - Google Patents

Abstract

The utility model provides a combined heating device, which comprises a storage box, wherein the top of the storage box is provided with a water inlet pipe, the bottom of the storage box is provided with a water outlet pipe, the inside of the storage box is equidistantly provided with a waiting cavity and two heating cavities, the waiting cavity and the heating cavities are all separated by a heat insulation plate, the top of the storage box is provided with a translation component which corresponds the water inlet pipe with the cavity in the storage box, compared with the prior art, the water fed by the water inlet pipe is stored in the waiting cavity and the heating cavity, the heating rod in the heating cavity is used for heating and adjusting, when the water needs to be fed, the hot water corresponding to the heating cavity is selected to be fed, and the water reserved part in the heating cavity is used for mixing with the reserved hot water when cold water is newly injected through the separation component, so that the heating efficiency is improved, the consumption of resources is reduced, the whole device is arranged on one storage box, the heat loss is reduced, and the occupied area is smaller.

Description

Combined heating device

Technical Field

The utility model relates to the technical field of heating and heat supply, in particular to a combined heating and heat supply device.

Background technique

Heating is a technology that uses artificial methods to supply heat to the room to maintain a certain temperature in the room to create suitable living or working conditions. The heating system consists of three main parts: heat source (heat medium preparation), heat circulation system (pipe network or heat medium transportation) and heat dissipation equipment (heat medium utilization). The heating system is generally provided with heat by a heat source. Common heat sources include gas furnaces, oil furnaces, electric furnaces, etc. These heat sources can provide heat quickly. However, common heat sources consume a lot of energy when providing heat, especially in cold areas. Due to the low ambient temperature, the medium used for heat exchange requires more energy to reach the expected temperature, which is not conducive to energy saving and environmental protection.

Patent CN219589025U proposes a composite heating system with different heating temperature requirements. The first water inlet pipe and the drainage pipe are connected to the production well and the recharge well respectively. Groundwater is pumped to the plate heat exchanger by a water pump to preheat the medium in the heating system. The preheated medium enters the insulation water tank. If the heating demand temperature is low, it can be directly heated by a circulating pump; if the required temperature is high, the medium is secondary heated by a solar collector. After the temperature sensor detects that the temperature meets the standard, the controller controls the solenoid valve to open and the medium is used for heating. If the user needs rapid heating or requires a high temperature, the medium is heated by a heater, and high-temperature medium or steam medium is produced according to demand, and sent to the first radiator or the second radiator for heating, respectively, to meet the different heating temperature requirements of users, while achieving the purpose of saving energy and protecting the environment.

The shortcomings of the above scheme are: first, the output of different heating temperatures requires the use of multiple devices, which makes the device itself occupy a large area. In addition, different heating equipment is connected by pipes, and there are many pipes, which requires additional pipe insulation measures, increasing the cost. Otherwise, it is easy to cause heat loss during the transportation process due to many pipes.

Utility Model Content

In view of the deficiencies in the prior art, the purpose of the utility model is to provide a combined heating device to solve the problems raised in the above-mentioned background technology. The utility model has a novel structure, and the water sent in by the water inlet pipe is stored in the waiting chamber and the heating chamber, and the heating is adjusted by the heating rod in the heating chamber. When it needs to be sent out, the hot water in the corresponding heating chamber is selected to be sent out, and a part of the water in the heating chamber is reserved through a partition component, so that when new cold water is injected, it can be mixed with the reserved hot water, thereby improving the heating efficiency and reducing the consumption of resources. The whole device is arranged on a storage box to reduce heat loss and occupy a smaller area.

In order to achieve the above-mentioned purpose, the utility model is implemented through the following technical scheme: a combined heating device, including a storage box, a water inlet pipe is arranged on the top of the storage box, and a water outlet pipe is arranged on the bottom of the storage box, a waiting chamber and two heating chambers are equidistantly arranged inside the storage box, and the waiting chamber and the heating chamber are separated by an insulation board, a translation component that corresponds the water inlet pipe to the internal chamber of the storage box is arranged on the top of the storage box, and a heating rod is arranged in the heating chamber, and a partition component that divides the heating chamber into two layers is installed on the surface of the heating rod, a mixing component is arranged at the bottom of the storage box, and the mixing component includes a connecting pipe, the bottom of the connecting pipe is connected to the water outlet pipe, and three delivery pipes are fixed on the top of the connecting pipe, and the delivery pipes are connected to the corresponding waiting chamber and heating chamber.

Furthermore, the translation assembly includes a long board, which is slidably inserted into the opening at the upper end of the storage box, and both ends of the long board pass through the storage box, a screw is rotatably installed on one side of the top of the storage box through a bearing seat, and a motor is fixed to the position of the storage box at one end of the screw, the output end of the motor is fixed to the screw, and the long board is meshed and sleeved on the screw through a connecting piece.

Furthermore, a corrugated pipe is fixed to the bottom of the water inlet pipe, and the other end of the corrugated pipe passes through the middle position of the long plate.

Furthermore, the partition assembly includes a fixed plate, a fixed plate is fixed on the middle surface of the heating rod, and a movable plate is slidably sleeved on the upper end of the heating rod located on the fixed plate, leakage grooves are equidistantly provided on the surfaces of the movable plate and the fixed plate, protrusions are fixed between adjacent leakage grooves, and the leakage grooves and protrusions of the movable plate and the fixed plate are correspondingly arranged.

Furthermore, an electric push rod is sealed and fixed to the outer side of the fixed plate, and the extended end of the electric push rod is fixed to the movable plate, and a first temperature sensor is installed on the surface of the fixed plate.

Furthermore, the mixing assembly also includes a stirring rod, the stirring rod is rotatably installed inside the connecting tube through a bearing, a motor is fixed to the outer end of the connecting tube, the output end of the motor is fixed to the stirring rod, and a second temperature sensor is fixed inside the connecting tube.

Furthermore, solenoid valves are installed inside the delivery pipe and the water outlet pipe.

Beneficial effects of the utility model: a combined heating device of the utility model comprises a storage box; a water inlet pipe; a water outlet pipe; a waiting chamber; a heating chamber; a translation assembly; a screw rod; a motor; a long plate; a bellows; a mixing assembly; a delivery pipe; a connecting pipe; a motor; a solenoid valve; a stirring rod; a second temperature sensor; a partition assembly; a fixed plate; a heating rod; a first temperature sensor; a moving plate; a convex block; a drain groove; an electric push rod;

1. The utility model delivers the hot water in the heating chamber into the connecting pipe, waits for the warm water or cold water in the chamber to be partially delivered into the connecting pipe, the motor drives the stirring rod to rotate, accelerates the mixing of the hot and cold water, monitors and adjusts the water temperature through the second temperature sensor, and then delivers the water of the temperature required by the user from the water outlet pipe.

2. The utility model pulls the movable plate and the fixed plate together through an electric push rod. At this time, the protrusions and leakage grooves of the two are plugged into each other and sealed to separate the space inside the heating chamber. Some hot water is reserved at the top of the heating chamber. After the hot water at the lower end is sent out, cold water is sent in from the water inlet pipe to mix with the reserved hot water, thereby improving the heating efficiency and reducing the consumption of resources.

3. The utility model moves left and right along the top of the storage box by meshing the long plate with the screw rod, and makes the bottom outlet of the bellows correspond to different chambers inside the storage box, thereby completing the transportation and storage of water in different chambers.

4. Compared with the prior art, the utility model stores the water sent in by the water inlet pipe in the waiting chamber and the heating chamber, and adjusts the heating by the heating rod in the heating chamber. When it needs to be sent out, the hot water in the corresponding heating chamber is selected to be sent out, and a part of the water in the heating chamber is reserved through a partition component, so that when new cold water is injected, it can be mixed with the reserved hot water, thereby improving the heating efficiency and reducing the consumption of resources. The whole device is arranged on a storage box to reduce heat loss and occupy a smaller area.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of the overall structure of a combined heating device of the present invention;

FIG2 is a schematic diagram of the structure of a translational assembly of a combined heating and heating device of the present invention;

FIG3 is a schematic diagram of the internal structure of a storage box of a combined heating device of the present invention;

FIG4 is a schematic diagram of the structure of a partition assembly of a combined heating and heating device of the present invention;

FIG5 is a schematic diagram of the structure of a hybrid component of a combined heating device of the present invention.

In the figure: 1. storage box; 11. water inlet pipe; 12. water outlet pipe; 13. waiting chamber; 14. heating chamber; 2. translation assembly; 21. screw; 22. motor; 23. long plate; 24. bellows; 3. mixing assembly; 31. delivery pipe; 32. connecting pipe; 33. motor; 34. solenoid valve; 35. stirring rod; 36. second temperature sensor; 4. partition assembly; 41. fixed plate; 42. heating rod; 43. first temperature sensor; 44. moving plate; 45. bump; 46. drain groove; 47. electric push rod.

Detailed ways

In order to make the technical means, creative features, objectives and effects achieved by the present invention easy to understand, the present invention is further described below in conjunction with specific implementation methods.

Please refer to Figures 1 to 5. The utility model provides a technical solution: a combined heating device, including a storage box 1, a water inlet pipe 11 is arranged on the top of the storage box 1, and a water outlet pipe 12 is arranged at the bottom of the storage box 1. A waiting chamber 13 and two heating chambers 14 are equidistantly arranged inside the storage box 1. The waiting chamber 13 and the heating chamber 14 are separated by an insulation board. A translation component 2 is arranged on the top of the storage box 1 to correspond the water inlet pipe 11 to the internal chamber of the storage box 1, and a heating rod 42 is arranged in the heating chamber 14. A partition that divides the heating chamber 14 into two layers is installed on the surface of the heating rod 42. The mixing assembly 3 is provided at the bottom of the storage box 1, and the mixing assembly 3 includes a connecting pipe 32, the bottom of the connecting pipe 32 is connected with the water outlet pipe 12, and three delivery pipes 31 are fixed on the top of the connecting pipe 32, and the delivery pipes 31 are connected with the corresponding waiting chamber 13 and heating chamber 14. When the device is used, water is fed into the water inlet pipe 11, and is transported to the waiting chamber 13 and the heating chamber 14 through the translation assembly 2. The heating chamber 14 is heated to a predetermined temperature by the heating rod 42. When delivering, the water in a certain chamber can be delivered separately, or the water in the two chambers can be mixed and temperature-adjusted through the mixing assembly 3 before being delivered.

In this embodiment, the translation assembly 2 includes a long plate 23, and the long plate 23 is slidably inserted at the opening at the upper end of the storage box 1, and both ends of the long plate 23 pass through the storage box 1, and a screw 21 is rotatably installed on one side of the top of the storage box 1 through a bearing seat, and a motor 22 is fixed to the position of the storage box 1 at one end of the screw 21, and the output end of the motor 22 is fixed to the screw 21, and the long plate 23 is engaged and sleeved on the screw 21 through a connecting piece, and a bellows 24 is fixed to the bottom of the water inlet pipe 11, and the other end of the bellows 24 passes through the middle position of the long plate 23. When the motor 22 is turned on to drive the screw 21 to rotate, the long plate 23 is engaged with the screw 21 and moves left and right along the top of the storage box 1, and the bottom outlet of the bellows 24 corresponds to different chambers inside the storage box 1, thereby completing the transportation and storage of water in different chambers.

In this embodiment, the partition assembly 4 includes a fixed plate 41, a fixed plate 41 is fixed on the middle surface of the heating rod 42, and the heating rod 42 is located at the upper end of the fixed plate 41 and is slidably sleeved with a movable plate 44, and the surfaces of the movable plate 44 and the fixed plate 41 are equidistantly provided with leakage grooves 46, and protrusions 45 are fixed between adjacent leakage grooves 46, and the leakage grooves 46 and protrusions 45 of the movable plate 44 and the fixed plate 41 are correspondingly arranged, and an electric push rod 47 is sealed and fixed on the outer side of the fixed plate 41, and the extended end of the electric push rod 47 is fixed to the movable plate 44, and a first temperature sensor 43 is installed on the surface of the fixed plate 41. When water is injected, the movable plate 44 and the fixed plate 41 are provided with leakage grooves 46 at equal intervals. The plate 44 and the fixed plate 41 are separated by the electric push rod 47. At this time, water can fill the entire heating chamber 14 through the leakage grooves 46 of the movable plate 44 and the fixed plate 41, and is heated to a specified temperature by the heating rod 42 and monitored by the first temperature sensor 43. When hot water needs to be delivered, the electric push rod 47 pulls the movable plate 44 and the fixed plate 41 to merge. At this time, the protrusions 45 and the leakage grooves 46 of the two are plugged and sealed with each other to separate the space inside the heating chamber 14, and reserve some hot water at the top of the heating chamber 14. After the hot water at the lower end is delivered, cold water is sent into the water inlet pipe 11 to mix with the reserved hot water, thereby improving the heating efficiency and reducing the consumption of resources.

In this embodiment, the mixing assembly 3 also includes a stirring rod 35, the stirring rod 35 is rotatably installed inside the connecting pipe 32 through a bearing, and a motor 33 is fixed to the outer end of the connecting pipe 32, and the output end of the motor 33 is fixed to the stirring rod 35. A second temperature sensor 36 is fixed inside the connecting pipe 32, and the solenoid valve 34 is installed inside the delivery pipe 31 and the water outlet pipe 12. If the temperature in the heating chamber 14 is too high and does not meet the needs of the user, the hot water in the heating chamber 14 can be delivered into the connecting pipe 32, and the warm water or cold water in the waiting chamber 13 can also be partially delivered into the connecting pipe 32. The motor 33 drives the stirring rod 35 to rotate to accelerate the mixing of hot and cold water. The temperature of the water is monitored and adjusted by the second temperature sensor 36, and then the water with the temperature required by the user is delivered from the water outlet pipe 12 (the water outlet of the heating chamber 14 and the waiting chamber 13 needs to be delivered by the solenoid valve 34 of the delivery pipe 31, and the water capacity delivered can be adjusted to adjust the appropriate temperature).

When the device is used, water is fed in from the water inlet pipe 11, the motor 22 is turned on to drive the screw 21 to rotate, the long plate 23 is meshed with the screw 21 and moves left and right along the top of the storage box 1, and the bottom outlet of the bellows 24 corresponds to different chambers inside the storage box 1, thereby completing the transportation and storage of water in different chambers, and the heating chamber 14 is heated to a predetermined temperature by the heating rod 42. When hot water needs to be delivered, the electric push rod 47 pulls the moving plate 44 and the fixed plate 41 to merge. At this time, the protrusions 45 and the leakage grooves 46 of the two are plugged and sealed with each other, and the space inside the heating chamber 14 is separated, and some hot water is reserved in the heating chamber 1 4, after the hot water at the bottom is delivered, cold water is delivered from the water inlet pipe 11 to mix with the reserved hot water, so as to improve the heating efficiency and reduce the consumption of resources. The water in a certain chamber can be delivered separately. If the temperature in the heating chamber 14 is too high and does not meet the needs of the user, the hot water in the heating chamber 14 can be delivered to the connecting pipe 32, and the warm water or cold water in the waiting chamber 13 can also be partially delivered to the inside of the connecting pipe 32. The motor 33 drives the stirring rod 35 to rotate to speed up the mixing of the cold and hot water. The temperature of the water is monitored and adjusted by the second temperature sensor 36, and then the water with the temperature required by the user is delivered from the water outlet pipe 12.

The above shows and describes the basic principles and main features of the utility model and the advantages of the utility model. For those skilled in the art, it is obvious that the utility model is not limited to the details of the above exemplary embodiments, and can be implemented in other specific forms without departing from the spirit or basic features of the utility model. Therefore, no matter from which point of view, the embodiments should be regarded as exemplary and non-restrictive. The scope of the utility model is defined by the attached claims rather than the above description, and it is intended to include all changes within the meaning and scope of the equivalent elements of the claims in the utility model. Any figure mark in the claims should not be regarded as limiting the claims involved.

In addition, it should be understood that although the present specification is described according to implementation modes, not every implementation mode contains only one independent technical solution. This narrative method of the specification is only for the sake of clarity. Those skilled in the art should regard the specification as a whole. The technical solutions in each embodiment can also be appropriately combined to form other implementation modes that can be understood by those skilled in the art.

Claims (7)

1. The utility model provides a joint heating device, includes bin (1), its characterized in that: the utility model discloses a heating device, including bin (1), connecting pipe (32) bottom, heating chamber (14), bin (1) top is provided with inlet tube (11), and bin (1) bottom is provided with outlet pipe (12), bin (1) inside equidistance is equipped with one waiting chamber (13) and two heating chamber (14), all cut off through the heated board between waiting chamber (13) and heating chamber (14), bin (1) top is equipped with translation subassembly (2) that correspond inlet tube (11) and bin (1) inside cavity, and is equipped with heating rod (42) in heating chamber (14), install on the surface of heating rod (42) divide into partition assembly (4) of two-layer with heating chamber (14), bin (1) bottom is equipped with mixing assembly (3), and mixing assembly (3) include connecting pipe (32), connecting pipe (32) bottom and outlet pipe (12) intercommunication, and connecting pipe (32) top are fixed with three delivery pipe (31), delivery pipe (31) and waiting chamber (13) and heating chamber (14) intercommunication that correspond.

2. A combined heating and heating unit as claimed in claim 1, wherein: the translation subassembly (2) is including longboard (23), the slip grafting of bin (1) upper end opening part has longboard (23), and longboard (23) both ends wear out bin (1), screw rod (21) is installed through the bearing frame rotation in bin (1) top one side, and bin (1) are located the position that screw rod (21) one end is fixed with motor (22), motor (22) output is fixed with screw rod (21), longboard (23) are cup jointed on screw rod (21) through the connecting piece meshing.

3. A combined heating and heating unit as claimed in claim 2, wherein: the bottom of the water inlet pipe (11) is fixed with a corrugated pipe (24), and the other end of the corrugated pipe (24) passes through the middle position of the long plate (23).

4. A combined heating and heating unit as claimed in claim 1, wherein: partition assembly (4) are including fixed plate (41), be fixed with fixed plate (41) on the surface in the middle part of heating rod (42), and heating rod (42) are located the upper end slip of fixed plate (41) and have cup jointed movable plate (44), leak groove (46) have been offered to the equal distance on the surface of movable plate (44) and fixed plate (41), adjacent be fixed with lug (45) between leak groove (46), and leak groove (46) and lug (45) of movable plate (44) and fixed plate (41) correspond the setting.

5. A combined heating and heating unit as defined in claim 4, wherein: an electric push rod (47) is fixed on the outer side of the fixed plate (41) in a sealing mode, an extension end of the electric push rod (47) is fixed with the moving plate (44), and a first temperature sensor (43) is mounted on the surface of the fixed plate (41).

6. A combined heating and heating unit as claimed in claim 1, wherein: the mixing assembly (3) further comprises a stirring rod (35), the stirring rod (35) is rotatably arranged inside the connecting pipe (32) through a bearing, a motor (33) is fixed at the outer end of the connecting pipe (32), the output end of the motor (33) is fixed with the stirring rod (35), and a second temperature sensor (36) is fixed inside the connecting pipe (32).

7. A combined heating and heating unit as defined in claim 6, wherein: solenoid valves (34) are arranged in the delivery pipe (31) and the water outlet pipe (12).