CN215983244U - High-temperature heat energy system and high-temperature heat energy control system - Google Patents

Abstract

The application discloses high temperature heat energy system and high temperature heat energy control system for reduce the energy that the heat energy system consumed in the heat production process. The system comprises at least one first heat energy device, wherein a circulating working medium for absorbing heat energy outside the system circulates in the first heat energy device, so that the heat-conducting medium flowing through the first heat energy device is heated through the circulating working medium, and the heat-conducting medium with first heat is led out through an outlet of the first heat energy device; at least one second thermal energy device, an inlet of the second thermal energy device is connected with an outlet of the first thermal energy device, and the second thermal energy device is used for heating the heat-conducting medium with the first heat flowing through the second thermal energy device to lead out the heat-conducting medium with the second heat. In the scheme, the first heat energy equipment can absorb the external heat energy of the system to primarily heat the heat-conducting medium, so that the heat energy of the heat-conducting medium is improved, the energy consumed by heating the second heat energy equipment is reduced, and the economical efficiency of the heat energy system is effectively improved.

Description

High-temperature heat energy system and high-temperature heat energy control system

Technical Field

The utility model relates to the field of industry, in particular to a high-temperature heat energy system and a high-temperature heat energy control system.

Background

In the industrial field, boilers or furnace systems are often employed to produce thermal energy by burning fuel. The types of boilers or heating furnaces and the types of fuels are various, but the heat loss of various fuel boilers in the heat production process is large, and the operation cost is high. In order to produce the required heat energy, the heat energy system usually needs to consume more energy, and heat loss is inevitable in the heat production process.

How to reduce the energy that heat energy system consumed in the heat production process is the technical problem that this application will solve.

SUMMERY OF THE UTILITY MODEL

An object of this application embodiment is to provide a high temperature heat energy system and high temperature heat energy control system to reduce the energy that the heat energy system consumed in the heat production process.

In a first aspect, there is provided a high temperature thermal energy system comprising:

at least one first heat energy device, wherein a circulating working medium for absorbing heat energy outside the system circulates in the first heat energy device, so that the heat-conducting medium flowing through the first heat energy device is heated by the circulating working medium, and the heat-conducting medium with first heat is led out through an outlet of the first heat energy device;

at least one second thermal energy device, an inlet of the second thermal energy device is connected to an outlet of the first thermal energy device, and the second thermal energy device is configured to heat the heat-conducting medium with the first heat flowing through the second thermal energy device to derive the heat-conducting medium with a second heat, where the second heat is greater than the first heat.

In a second aspect, there is provided a high temperature thermal energy control system comprising:

the high temperature thermal energy system of the first aspect;

and the control unit is in communication connection with the high-temperature heat energy system and is used for controlling the working condition of at least one heat energy device in the high-temperature heat energy system according to the temperature of the heat-conducting medium flowing through the high-temperature heat energy system.

In the embodiment of the application, the system comprises at least one first heat energy device, wherein a circulating working medium for absorbing heat energy outside the system circulates in the first heat energy device, so that the heat-conducting medium flowing through the first heat energy device is heated by the circulating working medium, and the heat-conducting medium with first heat is led out through an outlet of the first heat energy device; at least one second thermal energy device, an inlet of the second thermal energy device is connected to an outlet of the first thermal energy device, and the second thermal energy device is configured to heat the heat-conducting medium with the first heat flowing through the second thermal energy device to derive the heat-conducting medium with a second heat, where the second heat is greater than the first heat. In the scheme, the first heat energy equipment can absorb the external heat energy of the system to primarily heat the heat-conducting medium, so that the heat energy of the heat-conducting medium is improved, the energy consumed by heating the second heat energy equipment is reduced, and the economical efficiency of the heat energy system is effectively improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model and not to limit the utility model. In the drawings:

fig. 1 is a schematic structural diagram of a high-temperature thermal energy system according to an embodiment of the present invention.

Fig. 2 is a second schematic structural diagram of a high temperature thermal energy system according to an embodiment of the present invention.

Fig. 3 is a third schematic structural diagram of a high-temperature thermal energy system according to an embodiment of the present invention.

Fig. 4 is a fourth schematic structural diagram of a high temperature thermal energy system according to an embodiment of the present invention.

Fig. 5 is a schematic structural diagram of a high-temperature thermal energy control system according to an embodiment of the present invention.

Fig. 6 is a second schematic structural diagram of a high temperature thermal energy control system according to an embodiment of the utility model.

Fig. 7a is a third schematic structural diagram of a high-temperature thermal energy control system according to an embodiment of the present invention.

Fig. 7b is a fourth schematic structural diagram of a high temperature thermal energy control system according to an embodiment of the utility model.

Fig. 8 is a schematic structural diagram of a high temperature thermal energy system in a high temperature thermal energy control system according to an embodiment of the present invention.

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 some, 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. The reference numbers in the present application are only used for distinguishing the steps in the scheme and are not used for limiting the execution sequence of the steps, and the specific execution sequence is described in the specification.

In the industrial field, a boiler or a furnace system can consume fuel to provide heat energy, and is generally applied to various industrial scenes. The boiler or the heating furnace system usually has more heat energy loss in the operation, the operation cost is usually higher, and the operation cost is difficult to reduce while meeting the high-temperature heat energy output.

In order to solve the problems existing in the prior art, an embodiment of the present application provides a high temperature thermal energy system, as shown in fig. 1, including:

at least one first heat energy device 11, a circulating working medium for absorbing heat energy outside the system circulates in the first heat energy device 11, so that the heat-conducting medium flowing through the first heat energy device 11 is heated by the circulating working medium, and the heat-conducting medium with first heat is led out through an outlet 11b of the first heat energy device 11;

at least one second thermal energy device 12, an inlet 12a of the second thermal energy device 12 is connected with an outlet 11a of the first thermal energy device 11, and the second thermal energy device 12 is configured to heat the heat conducting medium with the first heat flowing through the second thermal energy device 12 to derive the heat conducting medium with a second heat, wherein the second heat is larger than the first heat.

In the system that this application embodiment provided, first heat energy equipment specifically can be the high temperature heat energy equipment of the outer low temperature heat energy of absorbable system for absorb outside heat, the heat-conducting medium that the primary heating flowed through improves heat utilization and rates, improves the economic nature. The second heat energy equipment is used for heating the heat-conducting medium to the required temperature, can adapt to various working conditions, and quickly improves the temperature of the heat-conducting medium. Since the heat transfer medium has already undergone preliminary heating, the fuel consumption of the second thermal energy device can be effectively reduced.

Based on the high temperature thermal energy system provided in the above embodiment, optionally, as shown in fig. 2, when the number of the first thermal energy devices 11 is multiple, the system includes at least two outlets of the first thermal energy devices 11 commonly connected to an inlet of the same second thermal energy device 11.

Fig. 2 shows a schematic view of a parallel connection of three first thermal energy installations. In practical applications, the system may also include a greater or lesser number of first thermal energy apparatuses, and a plurality of first thermal energy apparatuses may be connected by various connection manners. For example, two parallel-connected first thermal energy devices are connected in series with another first thermal energy device, or multiple groups of first thermal energy devices are connected in series, where each group of first thermal energy devices includes at least two parallel-connected first thermal energy devices, and the like.

Through the system that this application embodiment provided, can heat-conducting medium with a plurality of first heat energy equipment, the cycle medium among a plurality of first heat energy equipment can absorb the outer heat energy of system, improves heat utilization rate, reduces the heat loss.

Based on the high-temperature thermal energy system provided in the above embodiment, optionally, as shown in fig. 3, the system further includes:

at least one level of heating equipment group connected between the outlet of at least one of the second thermal energy equipments and the outlet of the high temperature thermal energy system, wherein any level of the heating equipment group comprises at least one third thermal energy equipment 13, and the third thermal energy equipment 13 is used for heating the heat transfer medium flowing through.

Fig. 3 shows a block diagram of a high temperature thermal energy system comprising a hierarchical heating device group, wherein the heating device group comprises a third thermal energy device 13, an inlet 13a of the third thermal energy device 13 is connected with an outlet 12b of the second thermal energy device, and the third thermal energy device 13 is used for heating the heat-conducting medium with the second heat.

In the embodiment of the application, the third thermal energy device in the at least one tier of heating device group can further heat the heat transfer medium with the second heat. In practical application, the working condition of the third thermal energy device can be adjusted according to actual requirements so as to lead out the heat-conducting medium with required heat. The third thermal energy equipment can flexibly adjust the working condition according to the requirement, the heat quantity of the derived heat-conducting medium is adjusted within a certain range, the working condition of the second thermal energy equipment is prevented from being frequently adjusted, and the energy loss consumed by the second thermal energy equipment due to the change of the working condition is reduced.

Optionally, based on the system provided in the above embodiment, a plurality of levels of heating device groups are connected between the outlet of at least one of the second thermal energy devices and the outlet of the high-temperature thermal energy system, the plurality of levels of heating device groups are sequentially connected on a level basis, and the heat quantity of the heat transfer medium flowing through the plurality of levels of heating device groups increases step by step.

In the solution provided in this embodiment, a plurality of levels of heating device sets are used to heat the heat transfer medium flowing through step by step. In practical application, the heat-conducting medium can be led out after being heated by heating equipment groups of different levels according to the actual heat energy output requirement, and the actual heat energy output requirement can be favorably met.

Based on the high temperature thermal energy system provided in the above embodiment, optionally, as shown in fig. 4, the first thermal energy device 11 includes at least one first inlet 11a and at least one first outlet 11b, and the second thermal energy device 12 includes at least one second inlet 12a and at least one second outlet 12b, wherein at least one second inlet 12a is communicated with at least one first outlet 11 b.

In this embodiment, the system structure shown in fig. 4 is only used as an example to illustrate the present solution, and other connection methods may be applied in practical applications. Three first thermal energy apparatuses and two second thermal energy apparatuses are included in fig. 4. The first thermal energy device C comprises two first inlets, which are respectively connected to the heat-conducting medium from the inlet a and the inlet B. The first heat energy equipment B comprises two first outlets, and the heated heat-conducting medium is led out to the second heat energy equipment A and the second heat energy equipment B respectively.

In an embodiment of the application, the first thermal energy device may comprise a plurality of first inlets and a plurality of first outlets. Wherein a plurality of first inlets may be used for introducing the heat transfer medium to be heated from a plurality of sources outside the system. If the first thermal energy installation comprises a plurality of first outlets, the heat transfer medium with the first heat can be conducted out into a plurality of different second thermal energy installations. Optionally, the at least one first outlet is directly communicated with the at least one second outlet, so that heat loss can be effectively reduced, and the overall energy utilization rate of the system is improved. Through the scheme provided by the embodiment of the application, the first heat energy equipment and the second heat energy equipment can be flexibly connected according to actual requirements, and the overall energy loss of the system is reduced.

In order to solve the problems existing in the prior art, an embodiment of the present application further provides a high temperature thermal energy control system, as shown in fig. 5, including:

a high temperature thermal energy system 51 as described in any of the above embodiments;

and the control unit 52 is in communication connection with the high-temperature thermal energy system 51, and the control unit 52 is configured to control a working condition of at least one thermal energy device in the high-temperature thermal energy system according to the temperature of the heat transfer medium flowing through the high-temperature thermal energy system 51.

In this embodiment, the control unit may specifically be a control terminal. The control terminal can be a mobile phone, a computer or other electronic equipment with a computing function. Optionally, the high-temperature thermal energy system and the control unit may be connected through bluetooth or other wireless communication methods, so that a worker can perform remote control on the high-temperature thermal energy system.

Based on the system provided by the above embodiment, as shown in fig. 6, the system further includes:

at least one controllable valve K in communication connection with the control unit 52, where the controllable valve K is disposed at an inlet or an outlet of a thermal energy device in the high temperature thermal energy system, and the controllable valve K is used to control a flow rate of the heat transfer medium;

wherein the control unit 52 is configured to:

and controlling the opening degree of at least one controllable valve K according to the temperature of the heat-conducting medium flowing through the high-temperature heat energy system.

In the embodiment of the application, controllable valves K are arranged at least one inlet and one outlet of each heat energy device, and each controllable valve can be controlled in opening degree by the control unit according to the actual temperature of the heat-conducting medium, so that the flow of the heat-conducting medium led into the heat energy device and the flow of the heat-conducting medium led out of the heat energy device are controlled, and the working condition of each heat energy device in the system can be effectively controlled.

Based on the system provided by the above embodiment, as shown in fig. 7a, the system further includes:

at least one temperature sensor T in communication with the control unit 52, the temperature sensor T being disposed at an inlet or an outlet of a thermal energy device in the high temperature thermal energy system, the temperature sensor T being configured to monitor a temperature of a heat transfer medium flowing therethrough.

In fig. 7a, temperature sensors T are disposed at positions of at least one of the first inlets 11a, at least one of the first outlets 11b, at least one of the second inlets 12a, and at least one of the second outlets 12b, and the temperature sensors T are configured to obtain temperature information of the heat transfer medium flowing through. In addition to the positions shown in fig. 7a, a temperature sensor T may also be provided at the outlet or inlet of at least one third thermal energy device of the at least one tier of heating device groups.

Fig. 7b shows a schematic diagram of the communication connection between the temperature sensors T, the controllable valve K and the control unit. The control unit can acquire the temperature of the heat-conducting medium passing through each heat energy device by issuing an instruction, and controls the opening of each controllable valve according to the form of issuing the instruction below the acquired temperature so as to realize the working condition control.

The temperature sensors provided at the respective inlets and outlets are used to monitor temperature information of the heat transfer medium introduced and discharged. The temperature information may specifically include real-time temperature, and may also include a rate of temperature change. According to the temperature information, the temperature difference between the heat-conducting medium before the heat-conducting medium is led into the heat energy equipment and the heat-conducting medium led out by the heat energy equipment can be determined, and further the heat energy absorbed by the heat-conducting medium flowing through the heat energy equipment can be determined. The temperature information acquired by the temperature sensor can be used for controlling the working conditions of each thermal energy device in the system, and the running state of the thermal energy device can be monitored.

In this embodiment, the control terminal may be a computer or other electronic device, and is configured to control the opening degree of each controllable valve according to the temperature information obtained by the temperature sensor. For example, the control terminal may specifically include a configuration and system connection module, a monitoring and comparing module, a comparison action module, a first determining module, a second determining module, a third module, an operation module 1, and an operation module 2.

The configuration and system connection module is used for connecting the first heat energy devices capable of absorbing the low-temperature heat outside the system in parallel, and the second heat energy devices incapable of absorbing the low-temperature heat outside the system are arranged at the downstream of the plurality of the first heat energy devices connected in parallel. According to actual requirements, when the heat energy carried by the heat-conducting medium required to be output is low, only a plurality of first heat-energy devices connected in parallel can be used, and the heat-conducting medium heated by the first heat-energy devices can be directly led out without being heated again by flowing through a second heat-energy device. Correspondingly, when only a plurality of first heat energy devices connected in parallel are used, the control terminal only needs to control the opening degrees of the controllable valves at the inlet and the outlet of the first heat energy device according to the temperature information obtained by the temperature sensors at the inlet and the outlet of the first heat energy device, so as to realize the flow control of the heat-conducting medium introduced into and led out of the system.

In addition, the temperature sensor and the control terminal can be connected in a wired mode, and can also be connected in a WIFI, Bluetooth or other wireless modes.

The monitoring and comparing module in the control terminal can be used for receiving temperature information obtained by the temperature sensors arranged at the inlet and the outlet of the first heat energy equipment capable of absorbing low-temperature heat outside the system, and comparing the temperature information with an allowable range which is stored in advance by the monitoring and comparing module and corresponds to a working condition. In practical application, the monitoring and comparing module may determine the working condition of the first thermal energy device, determine the temperature range corresponding to the working condition according to the stored data, and determine whether the temperature represented by the temperature information obtained by the temperature sensor is within the temperature range corresponding to the working condition. If the temperature is within the temperature range, the operation of the thermal energy equipment is normal, otherwise, the adjustment operation can be executed on the thermal energy equipment according to the amount that the temperature represented by the obtained temperature information exceeds the temperature range corresponding to the working condition, and specifically, the adjustment operation can be executed by the action module after comparison.

The action module after comparison in the control terminal can output an instruction or prompt by the control unit according to the comparison result, and adjust the operation mode of the corresponding first heat energy equipment capable of absorbing the low-temperature heat outside the system according to the instruction or the prompt.

The first judging module in the control terminal can be used for judging whether the temperature corresponding to the temperature information acquired by the temperature sensor at the inlet of the first heat energy equipment is within a required temperature range, and the required temperature range can be the temperature range corresponding to the working condition where the heat energy equipment is located.

The first judging module in the control terminal may be configured to judge whether a temperature corresponding to temperature information acquired by the temperature sensor at the outlet of the first thermal energy device is within a required temperature range, where the required temperature range may be a temperature range corresponding to a working condition where the thermal energy device is located.

The third module in the control terminal may be configured to determine whether a second thermal energy device that does not absorb low-temperature heat outside the system is connected downstream of the at least one first thermal energy device.

And the operation module in the control terminal is used for adjusting the operation mode of the corresponding first heat energy equipment capable of absorbing the low-temperature heat outside the system when the judgment result of the third module is yes. When the judgment result of the third module is a 'no' result, the fluid demand can be adjusted or the abnormal alarm demand can be output.

Through the scheme that this application embodiment provided, can effectively monitor the heat-conducting medium's that thermal energy equipment imports through temperature sensor, the temperature of derivation, and then adjust each thermal energy equipment's in the system operating mode, guarantee that the heat-conducting medium of output satisfies the demand, be favorable to improving system operation flexibility.

Based on the high-temperature thermal energy system provided in the above embodiment, optionally, the heat conducting medium includes at least one of water, oil, gas, and an organic matter solution, and the temperature of the heat conducting medium led out by the at least one first thermal energy device 11 is greater than or equal to 100 ℃. The organic solution may be, for example, a glycol solution.

Based on the high-temperature thermal energy system provided by the above embodiment, optionally, at least one second thermal energy device includes a boiler or a heating furnace, and the fuel of the second thermal energy device includes fuel gas or oil.

In the following, the present solution is further explained with reference to an example, and fig. 8 shows a schematic structural diagram of a system provided in the embodiment of the present application, where the diagram includes:

010 pipeline, 020 pipeline, 300 first distribution piece, 200 second distribution piece, 500 third distribution piece, 1510 first thermal energy equipment assembly a1, 2510 high temperature thermal energy equipment assembly a2. -. n510 high temperature thermal energy equipment assembly an (n is more than or equal to 1, the same below), 1511 thermal energy equipment assembly b1, 2511 thermal energy equipment assembly b2.. -. n511 thermal energy equipment assembly bn, 500 pipeline, 010-2 pipeline, 1801 sensor, 1802 sensor, 1901 sensor, 050 monitor capable of absorbing low temperature heat outside the system.

11021. The first valve 1, the 11023 valve opening and closing sensor, the 11092 first valve 2, the 11022-1 electric mechanism, the 1105 first heat energy device which can absorb the low temperature heat outside the system, the 19105 second heat energy device which can not absorb the low temperature heat outside the system, the 1103 valve 1, the 1104 pieces of 1, 1106 valve 1, 1107 valve 1.

1701 first valve 2, 17013 valve opening and closing sensor, 1702 first valve 2, 1703 valve member 1, 19105 second heat energy equipment which can not absorb low temperature heat outside the system, 11082 valve 1, 11092 valve 1, 21092 valve 1.

21021 a second valve 1, 21023 a valve opening and closing sensor, 21092 a second valve 2, 27022-1 electric mechanism, 2105 a first heat energy device capable of absorbing low temperature heat outside the system, 29105 a second heat energy device capable of not absorbing low temperature heat outside the system, 2103 a valve 1, 2104 a piece 2, 2106 a valve 2, 2107 a valve 2.

2701, 2 nd valve 2, 27011-1 electric mechanism, 2 nd valve 2, 27013 valve opening and closing sensor, 2702 nd valve 2, 2703, valve 2, 29105, second heat energy equipment 2, 21082, 21092 valve 2 which can not absorb low temperature heat outside the system.

The n1021 nth valve 1, the n1023 valve opening and closing sensor, the n1022-1 electric mechanism, the n1092 nth valve 2 and the n105(n is more than or equal to 1) can absorb the low-temperature heat outside the system, the n9105 can not absorb the low-temperature heat outside the system, the second heat equipment n, the n103 valve n and the n104 valve n. n2106 valve n, n2107 valve n.

The n701 nth valve 2, the n7013 valve opening and closing sensors n, n17012 electric mechanisms and the n702 nth valve 2, the n703 valve n (n is more than or equal to 1) and the n9105 can not absorb the second heat energy equipment n of the low-temperature heat outside the system, the n1082 valve n and the n1092 valve n.

Through the system that this application embodiment provided, first heat energy equipment can absorb the outer heat energy primary heating heat-conducting medium of system, improves the heat energy that heat-conducting medium has, reduces the energy that second heat energy equipment heating will consume, effectively improves heat energy system economic nature.

It should be noted that, in this document, 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 like elements in a process, method, article, or apparatus that comprises the element.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solutions of the present invention may be embodied in the form of a software product, which is stored in a storage medium (such as ROM/RAM, magnetic disk, optical disk) and includes instructions for enabling a terminal (such as a mobile phone, a computer, a server, an air conditioner, or a network device) to execute the method according to the embodiments of the present invention.

While the present invention has been described with reference to the embodiments shown in the drawings, the present invention is not limited to the embodiments, which are illustrative and not restrictive, and it will be apparent to those skilled in the art that various changes and modifications can be made therein without departing from the spirit and scope of the utility model as defined in the appended claims.

Claims (9)

1. A high temperature thermal energy system, comprising:

at least one first heat energy device, wherein a circulating working medium for absorbing heat energy outside the system circulates in the first heat energy device, so that the heat-conducting medium flowing through the first heat energy device is heated by the circulating working medium, and the heat-conducting medium with first heat is led out through an outlet of the first heat energy device;

at least one second thermal energy device, an inlet of the second thermal energy device is connected to an outlet of the first thermal energy device, and the second thermal energy device is configured to heat the heat-conducting medium with the first heat flowing through the second thermal energy device to derive the heat-conducting medium with a second heat, where the second heat is greater than the first heat.

2. The system of claim 1, wherein when the number of first thermal energy apparatuses is plural, the system comprises at least two outlets of the first thermal energy apparatuses commonly connected to an inlet of the same second thermal energy apparatus.

3. The system of claim 1, further comprising:

at least one level of heating equipment group connected between the outlet of at least one second thermal energy equipment and the outlet of the high temperature thermal energy system, wherein any level of heating equipment group comprises at least one third thermal energy equipment which is used for heating the heat-conducting medium flowing through.

4. The system of claim 3, wherein a plurality of levels of heating device groups are connected between the outlet of at least one of the second thermal energy devices and the outlet of the high temperature thermal energy system, the plurality of levels of heating device groups are connected in sequence on a level basis, and the heat transfer medium flowing through the plurality of levels of heating device groups has an increasing amount of heat.

5. The system according to any one of claims 1 to 4, wherein the temperature of the heat transfer medium derived from at least one of the first thermal energy devices is greater than or equal to 100 ℃.

6. A system according to any one of claims 1 to 4, wherein at least one of the second thermal energy plants comprises a boiler and the fuel of the second thermal energy plant comprises gas or oil.

7. A high temperature thermal energy control system, comprising:

a high temperature thermal energy system according to any one of claims 1 to 6;

and the control unit is in communication connection with the high-temperature heat energy system and is used for controlling the working condition of at least one heat energy device in the high-temperature heat energy system according to the temperature of the heat-conducting medium flowing through the high-temperature heat energy system.

8. The system of claim 7, further comprising:

at least one controllable valve in communication connection with the control unit, wherein the controllable valve is arranged at an inlet or an outlet of a thermal energy device in the high-temperature thermal energy system, and is used for controlling the passing flow of the heat-conducting medium;

wherein the control unit is configured to:

and controlling the opening degree of at least one controllable valve according to the temperature of the heat-conducting medium flowing through the high-temperature heat energy system.

9. The system of claim 7 or 8, further comprising:

and the temperature sensor is arranged at an inlet or an outlet of a thermal energy device in the high-temperature thermal energy system and is used for monitoring the temperature of the heat-conducting medium flowing through.

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