FR3152577A1 - THERMAL INSTALLATION - Google Patents

Abstract

THERMAL INSTALLATION The invention relates to a thermal installation (100) comprising solar units (102) with a reservoir (104) and heat pipes (106) with a transfer pipe (105) passing through each reservoir (104), a buffer tank (108), a heat exchanger (114) buried in the ground, a main pipe (112) comprising a first portion (112a) between the outlet of the reservoirs (104) and the heat exchanger (114) and a second portion (112b) connected between the heat exchanger (114) and the inlet of the reservoirs (104), a filling pipe (116) connected between the first portion (112a) and the buffer tank (108), a main valve (118) mounted on the first portion (112a) between the filling pipe (116) and the heat exchanger (114), and at the outlet of the tanks (104), the first portion (112a) has a sub-portion (112c) which rises above the last tank (104) before descending towards the filling pipe (116) and the heat exchanger (114). Fig. 1

Description

THERMAL INSTALLATION

The present invention relates to a thermal system comprising a plurality of solar units.

STATE OF THE PRIOR ART

There FIG. 3 shows a prior art thermal system 300. The thermal system 300 comprises a plurality of solar units 102. Each solar unit 102 has a reservoir 104 filled with a heat transfer fluid, typically water, and a set of heat pipes 106 provided to transmit the heat extracted from the solar flux to the heat transfer fluid.

The heat transfer fluid is stored in the tank 104 and the condenser of each heat pipe 106 immerses in said tank 104 in order to transfer the captured calories to the heat transfer fluid.

The plurality of solar units 102 has a transfer pipe 105 which successively passes through each tank 104. For this purpose, each tank 104 has an inlet through which the transfer pipe 105 enters the tank 104 and an outlet through which the transfer pipe 105 leaves the tank 104.

The solar units 102 are connected in series and the transfer pipe 105 thus extends between the inlet of the first tank 104, called transfer inlet 105a through which the transfer pipe 105 enters the first tank 104 and the outlet of the last tank 104, called transfer outlet 105b through which the transfer pipe 105 leaves the last tank 104.

The thermal system 300 also has a buffer tank 108 filled with water and equipped with a heating system 120 such as an electric resistor.

The buffer tank 108 is equipped with a first pipe 122a through which cold water arrives in the buffer tank 108 and a second pipe 122b through which hot water leaves the buffer tank 108.

The thermal system 300 also has a heat exchanger 114 which is buried in the ground and which has an inlet and an outlet. As explained below, the heat exchanger 114 makes it possible to evacuate excess calories to the ground, particularly in the event of overheating of the tanks 104, or to capture calories from the ground in the event of a risk of freezing of the tanks 104.

The thermal system 300 also has a main pipe 112 with a first portion 112a fluidly connected between the transfer outlet 105b and the inlet of the heat exchanger 114 and a second portion 112b fluidly connected between the outlet of the heat exchanger 114 and the transfer inlet 105a. The main pipe 112 thus forms with the transfer pipe 105 a loop in which water circulates.

The thermal system 300 also has a filling pipe 116 fluidly connected between the first portion 112a and the buffer tank 108.

Between the filling pipe 116 and the heat exchanger 114, the first portion 112a is equipped with a pump 119 and a main valve 118.

The thermal system 300 has a supply pipe 121 fluidly connected to the first portion 112a downstream of the main valve 118 and through which cold water arrives in the first portion 112a.

The arrival of cold water in the first portion 112a via the supply pipe 121 is controlled by a supply valve 124 and a non-return valve 126 mounted on the supply pipe 121.

In operation, the cold water arrives in the buffer tank 108 through the first pipe 122a under the control of a first valve 126a. The cold water is heated by the heating system 120 and exits through the second pipe 122b under the control of a second valve 126b.

When solar energy can be used, the main valve 118 is closed and the supply valve 124 is open. The cold water thus arrives from the supply pipe 121, circulates through a part of the first portion 112a, through the heat exchanger 114 then the second portion 112b to reach the transfer inlet 105a and circulates in the transfer pipe 105 through the tanks 104 to the transfer outlet 105b.

The water thus heated then reaches the buffer tank 108 via part of the first portion 112a and the filling pipe 116.

When there is no heating demand and the sun heats the heat pipes 106, it is necessary to remove heat from said heat pipes 106.

The supply valve 124 is then closed and the pump 119 is started and the main valve 118 is opened.

The water then circulates in a loop in the transfer pipe 105 and the main pipe 112. By passing through the heat exchanger 114, the water discharges its calories into the ground.

Conversely, in cold or even freezing weather, the same operation allows heat from the ground to be brought to reservoir 104.

Although such a thermal system 300 works well, it requires the use of a pump 119 and therefore electricity and it is therefore desirable to find a different arrangement in which it is not necessary to have a pump.

An object of the present invention is to provide a thermal system which does not have the drawbacks of the prior art.

For this purpose, a thermal system is proposed comprising:

- a plurality of solar units, each comprising a reservoir and a set of heat pipes whose condensers are immersed in said reservoir, where said plurality of solar units has a transfer pipe successively passing through each reservoir between a transfer inlet through which said transfer pipe enters the first reservoir and a transfer outlet through which said transfer pipe leaves the last reservoir,

- a buffer tank,

- a heat exchanger intended to be buried in the ground and comprising an inlet and an outlet,

- a main pipe comprising a first portion fluidly connected between the transfer outlet and the inlet of the heat exchanger and a second portion fluidly connected between the outlet of the heat exchanger and the transfer inlet,

- a fluidically connected filling pipe between the first portion and the buffer tank, and

- a main valve mounted on the first portion between the filling pipe and the heat exchanger,

the thermal system being characterized in that at the transfer outlet, the first portion has a sub-portion which rises above the last tank before descending towards the filling pipe and the heat exchanger.

Advantageously, the sub-portion has a rounded shape.

The above-mentioned and other features of the invention will become more clearly apparent from the following description of an exemplary embodiment, said description being made in relation to the accompanying drawings, among which:

FIG. 1 is a schematic representation of a thermal system according to the invention,

FIG. 2 is a perspective view of a solar unit implemented in the thermal system according to the invention, and

FIG. 3 is a schematic representation of a state-of-the-art thermal system.

DETAILED PRESENTATION OF IMPLEMENTATION METHODS

In the remainder of the description, the elements which are identical to those of the prior art bear the same reference, and the upstream and downstream references are taken relative to the direction of flow of the fluid in the pipeline.

There FIG. 1 shows a thermal system 100 according to the invention.

The thermal system 100 comprises a plurality of solar units 102. Each solar unit 102 has a reservoir 104 filled with a heat transfer fluid, typically water, and a set of heat pipes 106 provided to transmit the heat extracted from the solar flux to the heat transfer fluid.

The heat transfer fluid is stored in the tank 104 and the condenser of each heat pipe 106 immerses in said tank 104 in order to transfer the captured calories to the heat transfer fluid.

The plurality of solar units 102 has a transfer pipe 105 which successively passes through each tank 104. For this purpose, each tank 104 has an inlet through which the transfer pipe 105 enters the tank 104 and an outlet through which the transfer pipe 105 leaves the tank 104. The portion of the transfer pipe 105 which is in a tank 104 constitutes a heat exchanger between the water of the tank 104 and the water which circulates in the transfer pipe 105.

The solar units 102 are connected in series and the transfer pipe 105 thus extends between the inlet of the first tank 104, called transfer inlet 105a through which the transfer pipe 105 enters the first tank 104 and the outlet of the last tank 104, called transfer outlet 105b through which the transfer pipe 105 leaves the last tank 104.

The thermal system 100 also has a buffer tank 108 filled with water and equipped with a heating system 120 such as an electric resistor.

The buffer tank 108 is equipped with a first pipe 122a through which cold water arrives in the buffer tank 108 and a second pipe 122b through which hot water leaves the buffer tank 108. The cold water arrives under pressure, for example from a water supplier.

The thermal system 100 also has a heat exchanger 114 which is buried in the ground and which has an inlet and an outlet. As explained below, the heat exchanger 114 makes it possible to evacuate excess calories to the ground, particularly in the event of overheating of the tanks 104, or to capture calories from the ground in the event of cold weather or even frost.

The thermal system 100 also has a main pipe 112 with a first portion 112a fluidly connected between the transfer outlet 105b and the inlet of the heat exchanger 114 and a second portion 112b fluidly connected between the outlet of the heat exchanger 114 and the transfer inlet 105a. The main pipe 112 thus forms with the transfer pipe 105 a loop in which water circulates.

The thermal system 100 also has a filling pipe 116 fluidly connected between the first portion 112a and the buffer tank 108.

Between the filling pipe 116 and the heat exchanger 114, the first portion 112a is equipped with a main valve 118 but there is no pump as in the prior art.

The thermal system 100 has a supply pipe 121 fluidly connected to the first portion 112a downstream of the main valve 118 and through which cold water arrives in the first portion 112a.

The arrival of cold water in the first portion 112a via the supply pipe 121 is controlled by a supply valve 124 and a non-return valve 126 mounted on the supply pipe 121.

As shown in the FIG. 2 , the tank 104 is mounted on a frame 302 which elevates the tank relative to the ground and the heat pipes 106 are attached to the frame 302 below the tank 104.

At the transfer outlet 105b, the first portion 112a has a sub-portion 112c which rises above the last tank 104 before descending towards the filling pipe 116 and the heat exchanger 114.

With such an arrangement, in the event of a demand for hot water, the main valve 118 is closed, the hot water which leaves the last tank 104 at the transfer outlet 105b, rises along the sub-portion 112c before descending in the first portion 112a in the direction of the filling pipe 116 towards the buffer tank 108 under the pressure of the feed water from the supply pipe 121.

With such an arrangement, in the event of a risk of overheating of the tank 104, the main valve 118 is open, the hot water which leaves the last tank 104 at the level of the transfer outlet 105b rises along the sub-portion 112c before descending in the portion 112a towards the heat exchanger 114 by the effect of free convection and under the pressure of the feed water from the supply pipe 121.

In the event of a risk of the reservoir 104 freezing, by free convection, this system also makes it possible to raise the heat from the ground towards the reservoir 104, by the exchanger 114 via the main pipes 112 and transfer pipes 105.

Such operation without a pump is possible due to the free convection that is thus created.

In operation, the cold water arrives in the buffer tank 108 through the first pipe 122a under the control of a first valve 126a. The cold water is heated by the heating system 120 and exits through the second pipe 122b under the control of a second valve 126b.

When solar energy can be used, the main valve 118 is closed and the supply valve 124 is open. The cold water thus arrives from the supply pipe 121, circulates through a part of the first portion 112a, through the heat exchanger 114 then the second portion 112b to reach the transfer inlet 105a and circulates in the transfer pipe 105 through the tanks 104 to the transfer outlet 105b.

The water thus heated then reaches the buffer tank 108 via part of the first portion 112a and the filling pipe 116.

When there is no demand for heating and the sun heats the heat pipes 106, it is necessary to evacuate and store the overheating from the reservoirs 104.

The supply valve 124 is then closed and the main valve 118 is opened.

The water then circulates in a loop in the transfer pipe 105 and the main pipe 112. By passing through the heat exchanger 114, the water discharges its calories into the ground.

Conversely, in cold weather, or even when there is a risk of frost, the same operation allows heat from the ground to be brought to reservoir 104.

To limit pressure losses in the sub-portion 112c, it has a rounded shape, that is to say it is arched as it rises above the tank 104.

To fill the tanks 104, a supply pipe 130 is provided fluidically connected to the first tank 104 and for each subsequent tank 104, a complementary pipe 132 fluidically connected between two successive tanks 104.

Claims (2)

Thermal system (100) comprising:
- a plurality of solar units (102), each comprising a reservoir (104) and a set of heat pipes (106) whose condensers are immersed in said reservoir (104), where said plurality of solar units (102) has a transfer pipe (105) successively passing through each reservoir (104) between a transfer inlet (105a) through which said transfer pipe (105) enters the first reservoir (104) and a transfer outlet (105b) through which said transfer pipe (105) leaves the last reservoir (104),
- a buffer tank (108),
- a heat exchanger (114) intended to be buried in the ground and comprising an inlet and an outlet,
- a main pipe (112) comprising a first portion (112a) fluidically connected between the transfer outlet (105b) and the inlet of the heat exchanger (114) and a second portion (112b) fluidically connected between the outlet of the heat exchanger (114) and the transfer inlet (105a),
- a filling pipe (116) fluidically connected between the first portion (112a) and the buffer tank (108), and
- a main valve (118) mounted on the first portion (112a) between the filling pipe (116) and the heat exchanger (114),
the thermal system (100) being characterized in that at the level of the transfer outlet (105b), the first portion (112a) has a sub-portion (112c) which rises above the last reservoir (104) before descending towards the filling pipe (116) and the heat exchanger (114). Thermal system (100) according to claim 1, characterized in that the sub-portion (112c) has a rounded shape.