RU82027U1 - LIQUID HEATER HEATER - Google Patents

Abstract

1. A liquid heat carrier heater comprising a hollow body for supplying a heat carrier and a heat pipe located inside it, characterized in that a screw protrusion is located on the inner surface of the pipe. ! 2. The heater according to claim 1, characterized in that the casing consists of two parts, and the pipe consists of two half-pipes, each of which is fixed to the corresponding part of the casing, on the inner surface of each of the half-pipes there are half-turns of the specified screw protrusion with the possibility of docking them when the connection of the parts of the body and half pipes. ! 3. The heater according to claim 2, characterized in that the half tubes are made identical. ! 4. The heater according to claim 1, characterized in that the screw protrusion is made hollow with the possibility of supplying coolant through it. ! 5. The heater according to claim 1, characterized in that the screw protrusion has a rectangle in cross section connected to the pipe by its shorter side. ! 6. The heater according to claim 2, characterized in that the housing parts are identical. ! 7. The heater according to claim 2, characterized in that the housing parts are made in the form of half pipes of a larger diameter than half pipes of the flame tube. ! 8. The heater according to claim 2, characterized in that the housing parts are each made in the form of a U-shaped casing. ! 9. The heater according to claim 1, characterized in that the flame tube is made with heat-resistant lining at the inlet.

Description

The invention relates to heaters of a liquid coolant, in particular to boilers for converting the heat of combustion products and exhaust gases into heat of a coolant, and can be used for heat recovery, as well as for heating water due to the energy of the engine exhaust gases.

A fire-tube boiler is known, comprising a cylindrical body with a cylindrical deaf fire chamber located inside it, two strokes of smoke tubes of larger and smaller diameters relative to each other (see patent RU 2241902, class F22B 7/12, published December 10, 2004).

A disadvantage of the known boiler is its low efficiency in transferring thermal energy due to the insignificant heat removal area, as well as the complexity of installation and repair of the structure when it fails.

The technical result of the utility model is to increase the efficiency of transfer of thermal energy, as well as providing free access to the details of the heater fluid and the ability to quickly replace parts when the heater fails.

The technical result of the utility model is achieved due to the fact that the liquid heat carrier heater comprises a hollow body for supplying the heat carrier and a heat pipe located inside it, on the inner surface of which there is a screw protrusion.

In addition, the casing consists of two identical parts, and the pipe consists of two identical half-pipes, each of which is fixed to the corresponding part of the casing, while on the inner surface of each of the half-pipes there are half-turns of the specified screw protrusion with the possibility of joining them when connecting the parts of the casing and half-pipes . Parts of the body each can be made in the form of larger pipes

diameter than half pipes of the flame tube, or in the form of a U-shaped casing.

In addition, the screw protrusion can be made hollow with the possibility of supplying coolant through it, or have a rectangle in cross section connected to the pipe by its shorter side.

In addition, the flame tube can be made with heat-resistant lining at the inlet.

The utility model is illustrated by drawings.

Figure 1 shows the proposed heater, an axial section in an expanded form.

Figure 2 is the same, cross section.

The liquid coolant heater is described below on the example of a recovery boiler, which contains a housing consisting of two identical parts 1 and 2, inside of which there is a heat pipe consisting of two identical half pipes 3 and 4, mounted on the corresponding parts 1 and 2 of the housing. A screw protrusion 5 is located on the inner surface of the flame tube so that when the parts 1, 2 of the body with the half pipes 3 and 4 are disconnected, the screw protrusion 5 is divided along the pipe axis into two parts, forming half coils 6 located on the inner surfaces of the corresponding half pipes 3 and 4 so that makes it possible to dock them when connecting parts 1 and 2 of the casing with half pipes 3 and 4. When connecting parts 1 and 2 of the casing, a closed cavity 7 is formed for supplying coolant, covering the entire outer surface of the flame tube.

The screw protrusion 5 provides the maximum heat removal of the exhaust gas stream entering through the well 8 installed relative to its beginning in the half pipe 3 (4), which acts as a place for the burner or exhaust gas inlet from the internal combustion engine. The screw protrusion 5 can be hollow with the possibility of supplying coolant through it. Besides,

a well 8 installed in a half-pipe 4 (3) relative to the end of the screw protrusion 5 performs the function of the exhaust part of the boiler for exhaust gases.

In the case of the screw protrusion 5 being hollow, the heat pipe at its inlet in the area of the well 8 is made with heat-resistant lining (not shown).

Parts 1 and 2 of the body are made in the form of half pipes of a larger diameter than half pipes 3 and 4 of the flame tube, or each in the form of a U-shaped casing.

The device operates as follows.

Depending on whether the heater is used as a heat exchanger or heat exchanger, the outgoing gas stream from the internal combustion engine or burner, respectively, enters the heat pipe through the well 8 and is directed along the surface of the screw protrusion 5, excluding the direct-flow passage. By increasing the length of the passage of the outgoing gases and the large area of the screw protrusion 5, the maximum heat extraction of the outgoing gas flow is provided for converting it into the heat of a liquid heat carrier located inside the cavity 7 of the housing. After the passage of the gas stream through the flame tube, their exhaust is provided through the well 8 made in the flame tube relative to the end of the screw projection 5.

The heat carrier fluid can be used in the following options.

1. As a waste heat boiler, using heat energy from exhaust gases from internal combustion engines.

2. As a steam boiler. When the boiler is installed at an angle or vertically with the inlet part being higher than the outlet, due to the location of the maximum temperature zone in the upper part of the boiler, the maximum efficiency is provided for the transfer of thermal energy to the coolant due to the natural circulation of the coolant.

3. It can also be used as a heat exchanger when using a burner (not shown) installed in the area of the well 8 as a heat source.

4. In addition, it is possible to use the heater as a liquid heat exchanger, where hot liquid is supplied to the heat section instead of the gas stream.

Thus, due to this embodiment of the heater, the heat carrier is provided:

- maximum efficiency for the transfer of thermal energy to the coolant;

- minimum resistance to gas flow relative to the construction of the flame tube due to the tangential passage of gases;

- maximum access to all heater parts, short repair time of the flame tube, as well as the ability to quickly replace parts of the heater when it fails;

- the possibility of using the heater as both a hot water boiler and a steam boiler;

- the possibility of using as a source of heat supplied to the flame tube, burner, energy exhaust from ICE gases or hot liquid.

Claims (9)

1. A liquid heat carrier heater comprising a hollow body for supplying a heat carrier and a heat pipe located inside it, characterized in that a screw protrusion is located on the inner surface of the pipe. 2. The heater according to claim 1, characterized in that the casing consists of two parts, and the pipe consists of two half-pipes, each of which is fixed to the corresponding part of the casing, on the inner surface of each of the half-pipes there are half-turns of the specified screw protrusion with the possibility of docking them when the connection of the parts of the body and half pipes. 3. The heater according to claim 2, characterized in that the half tubes are made identical. 4. The heater according to claim 1, characterized in that the screw protrusion is made hollow with the possibility of supplying coolant through it. 5. The heater according to claim 1, characterized in that the screw protrusion has a rectangle in cross section connected to the pipe by its shorter side. 6. The heater according to claim 2, characterized in that the housing parts are identical. 7. The heater according to claim 2, characterized in that the housing parts are made in the form of half pipes of a larger diameter than half pipes of the flame tube. 8. The heater according to claim 2, characterized in that the housing parts are each made in the form of a U-shaped casing. 9. The heater according to claim 1, characterized in that the flame tube is made with heat-resistant lining at the inlet.