Technical field
[0001] An invention belongs to the heating engineering devices, in particular to the devices
for heating the liquid and generating steam which can be used for heat supply.
Background
[0002] For heating the houses and different industrial buildings there already have been
used for a long time the heating engineering devices in which the heating of liquid
and, at a necessity, generating of steam, is carried out by the transmission of heat
from a hot working medium to the liquid. Thus the obligatory condition of such process
is a necessity to have a working medium with a temperature more than temperature to
which it is necessary to warm a liquid. The use of gases of incineration of fuel such,
for example, as natural gas or fuel oil is most widespread for such working medium.
The basic lack of the use of such heating engineering devices is a low coefficient
of efficiency (CE), which in the best devices does not exceed 40 percents, and in
most cases in the conditions of production the real CE makes only 20-25 percents.
Gases of incineration of fuel after the use have a temperature far less than temperature
of surrounding environments, and this heat is seldom used, the warm gases are simply
thrown out in an atmosphere.
[0003] In addition, the use of gases of incineration of fuel creates an ecological problem
- these gases contain the harmful oxides of nitrogen, sulphur, carbon, and the emission
of unrefined gases results in contamination of atmosphere. Application of facilities
and equipment for cleaning of gases of incineration of fuel complicates the installation
of heat supply and increases charges for the heat supply.
[0004] As an alternative to the heating engineering devices with a hot working medium there
are devices in which the warming of liquid takes place at the terms of creation of
motion of liquid with certain hydrodynamic parameters, thus the kinetic energy of
motion of liquid changes into thermal energy and the liquid is heated.
[0005] There are known devices for heating liquids, in which a liquid is heated, when it
passes through the device, in which there is an immobile element (stator) and mobile
element which is revolved (rotor). In literature such devices are often called the
heat-generators. Thus, there is a known device for heating the liquid (the patent
of the USA of
US 6823820 B2, F22B 3/06, is published on 30.11.2004), in which a liquid is heated when it passes
through a gap between the internal walls of the housing of stator and external walls
of the housing of rotor. The housing of stator consists of two housing elements -
the front and back ones, which are united with each other. The axial openings are
made in the housing elements through which the shaft of a cylinder form passes. The
front housing element has an external form o a cylinder with two walls - butt end
and lateral. The internal surface of the butt end wall has a form of a ring, the internal
surface of lateral wall has a form of a truncated cone. The back housing element has
a form of cylinder in which one of surfaces of wall in form of a ring is internal.
[0006] At connection of the housing elements the butt end wall of front the housing element
and wall of back the housing element is spatially opposite, the lateral wall of front
the housing element is located between them, here an internal surface of butt end
wall of front the housing element and internal surface of wall of back the housing
element is perpendicular to the conditional longitudinal axis of billow. In the collected
housing there is a chamber the volume of which is limited to the internal surfaces
of three walls of the housing elements, and which has a form of a truncated cone.
[0007] On the shaft a rotor is fastened which is located in a chamber. A rotor is made with
three walls and has a form of a truncated cone, the external surfaces of walls of
which are conjugate with a gap in accordance with the internal surfaces of walls of
the housing. In the housing of rotor there is the through axial channel made alignment
to the longitudinal axis of the rotor the openings of which go out to two opposite
walls of the housing of rotor. The shaft passes through an axial channel in the housing
of the rotor. The external surface of the walls of the housing of the rotor is made
smooth.
[0008] The two channels are made in the walls of front housing element of stator for an
entrance and output of liquid - the channel of entrance of stream of liquid passes
through the lateral wall of the front f housing element, the channel of output of
liquid passes through the butt end wall of the front housing element. A liquid which
enters in a device under pressure gets in gaps between the internal surfaces of walls
of the housing of stator and external surfaces of walls of the housing of rotor. The
flow of the liquid at a contact with the walls of rotor which is revolved begins to
move in the turbulent mode. On the surface of walls of stator the motion of part of
stream of liquid is decelerated and the kinetic energy of motion of liquid changes
into thermal energy and the liquid is heated. The efficiency of heating of liquid
in a device depends on the degree of turbulence of stream of liquid and degree of
decelerating of stream of liquid - the higher degrees of turbulence and decelerating
of stream of liquid in the device the more the liquid is heated.
[0009] The lack of the known device is low efficiency of heating of liquid. It is related
to the structural features of device: the external surface of basic walls of rotor
is made smooth and has a small area - that is why for achievement of the certain value
of turbulence of stream of liquid the considerable speeds of rotation of rotor are
needed, and accordingly considerable charges of energy are needed; the enter of stream
of liquid to the rotor through one channel results in the unevenness of turbulence
in the volume of stream of liquid and decline of degree of turbulence of stream of
liquid; a device can work only in the small range of volume of speed of stream of
liquid - with change of volume speed of stream of liquid the time of contact of stream
of liquid with the surface of walls of rotor at the turbulence of stream of liquid
and degree of turbulence of stream of liquid which results in diminishing of degree
of turbulence of stream of liquid and decline of temperature of heating of liquid.
Essence of invention
[0010] The task of invention is an improvement of the rotor of heat-generator for heating
the liquid by the change of form of the housing of the rotor and implementation of
elements of the housing of rotor. It will enable to promote speed of streams of liquid
and increase the area of surface of rotor, with which the stream of liquid contacts.
[0011] A task is solved by the rotor of heat-generator for heating the liquid, which contains
a housing which three basic walls and a cap, the first and the second basic walls
of the housing of the rotor are opposite and the third basic wall of the housing of
rotor is located between the first and the second basic walls of the housing of rotor,
there is an axial channel in the rotor for a shaft, the first and second basic walls
of the housing of rotor are executed with the external surfaces of the walls in form
of a truncated cone and with identical direction of tapering of external surfaces
of walls, the third basic wall of rotor is executed with the external surface of a
cylinder form, on the external surface of the first basic wall of the housing the
first grooves are executed for a passage-way for liquid, and the first grooves are
executed so, that pass from one edge to other of external surface of the first basic
wall of the housing, the cap is executed as a hollow cone with one lateral wall in
which the axial opening is made, the external surface and internal one of the wall
of cap are executed in form of a truncated cone, and the cap is connected with the
housing so that the internal surface of the wall of cap adjoins the external surface
of the first basic wall of the housing.
[0012] In addition, the housing contains additionally the first butt end wall which is located
between the first and third basic walls of the housing, and the external surface of
the first butt end wall of the housing is executed in form of a ring, the housing
contains additionally the second butt end wall which is located between the third
and second basic walls of the housing, and the external surface of the second butt
end wall of the housing is executed in form of a ring, on the external surface of
the first basic wall of the housing in the place of transition between the first basic
wall and the first butt end wall of the housing the first circular groove is executed,
which forms on the external surface of the first basic wall of the housing the surface
of a cylinder form on which the coulisses of semi-cylinder form are executed with
an even interval, on the external surface of the first basic wall of the housing a
few rows of the first blind openings are executed so that in every row the first blind
openings are spatially located on identical and certain distance from the conditional
longitudinal axis of rotor for every row, thus every row of the first blind openings
from the second to the last one contains the identical amount of the first blind openings
and the first row of the first blind openings contains twice more blind openings than
the second row of the first blind openings on the external surface of the first basic
wall of the housing, the first grooves are executed as spiral grooves so that their
amount equals the amount of the first blind openings in the second row of the blind
openings and each of the first grooves passes from the edge of external surface of
the first basic wall of the housing consistently through one first blind opening in
every row of the first blind openings and finishes near the coulisse of semi-cylinder
form.
[0013] Moreover, on the external surface of the first wall of the housing the additional
grooves are executed, thus every additional groove passes consistently through one
blind opening of the second and first rows of the first blind openings and finishes
near the coulisse of a semi-cylinder form, and the additional grooves pass through
such blind openings in the first row of the first blind openings and finish near such
coulisses of a semi-cylinder form, through which the first grooves do not pass and
near which they do not end.
[0014] Moreover, on the external surface of the first butt end wall of the housing the row
of the second blind openings and of the second grooves is executed, thus the second
blind openings are executed so that the longitudinal axes of all of the blind openings
are located on identical distance from the conditional longitudinal axis of rotor,
the second grooves are made so that one groove and longitudinal axes of grooves passes
through every second blind opening and is located under an identical corner in relation
to conditional radial lines, conducted from axes of the second blind openings to the
conditional longitudinal axis of the rotor.
[0015] In addition, on the external surface of the third basic wall of the housing a few
rows of the third blind openings, the third grooves and the second circular grooves
are executed, all of rows of the third blind openings have an identical amount of
the blind openings, and the third blind openings in every row are located so that
axes of the third blind openings are in the plane of conditional circle at identical
distance to each other and displaced in relation to the axes of the third blind openings
in nearby rows at a certain step, the third grooves are executed so that the amount
of grooves equals the amount of the blind openings in the row of the third blind openings
and each of the third grooves passes from one to other edge of external surface of
the third basic wall of the housing consistently through one blind opening in every
row of the third blind openings, the second circular grooves are located between the
rows of the third blind openings.
[0016] In addition, on the external surface of the wall of cap a few rows of the fourth
blind openings are executed so that in every row the fourth blind openings are spatially
located on identical and certain distance for every row from the conditional longitudinal
axis of the rotor.
[0017] In addition, on the external surface of the second basic wall of the housing a few
rows of the fifth blind openings are executed so that in every row the fifth blind
openings are spatially located on identical and certain distance from the conditional
longitudinal axis of rotor for every row.
[0018] In addition, on the external surface of the second butt end wall of the housing the
row of the sixth blind openings is executed, and the sixth blind openings are executed
so that the longitudinal axes of all of the sixth blind openings are located on identical
distance from the conditional longitudinal axis of the rotor.
[0019] New substantial signs in an invention have the following connection with the declared
technical result:
the presence of the blind openings and grooves on the external surfaces of walls of
rotor considerably increases the area of surface of rotor, with which the stream of
liquid contacts and the degree of turbulence of stream of liquid is accordingly increased.
an implementation of the first basic wall of the housing of rotor in form of a truncated
cone allows and the first grooves as spiral grooves to increase length of first grooves
on the external surface of the first basic wall, and accordingly additionally to speed
up the streams of liquid and increases the degree of turbulence of streams of liquid;
the presence of the cap form the internal channels in the rotor that additionally
speeds up the streams of liquid and increases the degree of turbulence of stream of
liquid;
List of figures of drafts
[0020]
Fig.1 is a side-view of rotor in collection with a shaft in a section.
Fig.2 is an above-view of the first basic and first butt end wall of the housing from
above.
Fig.3 is a side-view of overhead element of the housing in a cut section.
Fig.4 is a view of separate area B on the surface of the first basic and first butt
end walls of the housing on Fig.2 in the expanded scale.
Fig.5 is a view of separate area B on Fig.3 in the expanded scale.
Fig.6 is a cut by the line of G-G on Fig.4 in the expanded scale.
Fig.7 is a cut by the line of A-A on Fig.3 in the expanded scale.
Fig.8 is a side-view of cap.
Fig.9 is an above-view of cap.
Fig.10 is a general view of heat-generator for heating of liquid in a cut section.
Examples of realization of invention
[0021] On figures 1-9, as an example, the one of possible variants of implementation of
rotor of heat-generator for heating of liquid is shown and the possible variants of
implementation of separate elements of rotor are given.
[0022] Rotor
1 of heat-generator for heating of liquid (Fig. 1) consists of the housing
2 and the cap
3. The housing contains the three basic walls - the first basic wall
4, the second basic wall
5 and the third basic wall
6. The first and second basic walls of the housing are opposite. The third basic wall
of the housing is located between the first and second basic walls of the housing.
[0023] The first and second basic walls of the housing are made with external surfaces
7 and
8 in form of a truncated cone and with identical direction of tapering of external
surfaces of the walls. The third basic wall
6 of the housing is made with an external surface
9 of cylinder form. The second and third basic walls of the housing simultaneously
are the second and third walls of the rotor, and the external surfaces of the second
and third basic walls of the housing are the external surfaces of the second and third
walls of rotor.
[0024] On the external surface
7 of the first basic wall of the housing the first grooves
10 are made for a liquid passage-ways which pass from one edge to other edge of external
surface of the first basic wall of the housing.
[0025] A cap
3 (Fig. 1,8) is made as a hollow cone with one lateral wall
11, in which the axial opening
12 is made. External and internal surfaces
13 and
14 of walls of cap are made in form of a truncated cone. The cap
3 is connected with the housing so that the internal surface
14 of the wall of cap adjoins to the external surface
7 of the first basic wall of the housing of rotor.
[0026] Thus the internal surface of the wall of cap covers the opened parts of the first
grooves
10 on the external surface of the first basic wall of the cap with formation of internal
channels in the rotor.
[0027] An axial channel
15 is made for a shaft
30 in the housing. The shaft
30 is made in such way which executes the functions of turbulence promoter and distributor
of stream of liquid and through it a liquid passes in the internal channels of the
first wall of rotor.
[0028] Presence of internal channels in the rotor, through which the stream of liquid passes,
leads at the rotation of rotor (due to influence on the streams of liquid of centrifugal
force) to the acceleration of streams of liquid, which speeds up the streams of liquid
and increases the degree of turbulence of streams of liquid, implementation of the
first basic wall of the housing of rotor in form of a truncated cone allows to increase
length of internal channels in the rotor, and accordingly additionally to speeds up
the streams of liquid and increases the degree of turbulence of streams of liquid.
[0029] For simplification of making of the housing it can consist of overhead element
16 and lower element
17 that are united between them. For simplification of explanation of possible variants
of implementation of separate elements of the housing on Fig.3 the view of overhead
element is shown.
[0030] As a variant, the housing can contain additionally the first and second butt end
walls
18 and
19 (Fig. 1). The first butt end wall
18 of the housing is located between the first
4 and third
6 basic walls of the housing. The external surface
20 of the first butt end wall
18 of the housing is made in form of a ring. The second butt end wall
19 is located between the third
6 and second 5 basic walls of the housing. The external surface
21 of the second butt end wall
19 of the housing is made in form of a ring.
[0031] On the external surface of the first butt end wall of the housing the row of the
second blind openings
22 and the second grooves
23 (Fig. 2,4) can be made, and the second blind openings are made so that the longitudinal
axes of all of the second blind openings are located on identical distance from the
conditional longitudinal axis
24 of the rotor, and the second grooves are made so that through every blind opening
one groove passes and longitudinal axes of grooves are located under an identical
corner in relation to conditional radial lines, conducted from axes of the blind openings
to the conditional longitudinal
24 axis of the rotor.
[0032] On the external surface
21 of the second butt end wall of the housing the row of the sixth blind openings
25 can be made (Fig. 1), which is made alike to the row of the second blind openings
22 of the external surface of the first butt end wall
18.
[0033] On the external surface
7 of the first basic wall of the housing in the place of transition between the first
basic and first butt end walls of the housing the first circular groove 2
6 can be made (Fig. 2,3,4,5). The circular groove forms on the external surface of
the first basic wall of the housing the surface
27 of a cylinder form, on which the coulisses
28 of semi-cylinder form are made with an even interval (Fig. 2,4,5).
[0034] In addition, on the external surface
7 of the first basic wall of the housing a few rows of the first blind openings
29 can be made (Fig. 2). The rows of the first blind openings are made so that in every
row the first blind openings are spatially located on identical and certain distance
from the conditional longitudinal axis
24 of rotor for every row, every row of the blind openings
29 from the second to the last one contains the identical amount of the blind openings,
the first row of the blind openings
29 contains blind openings twice more than the second row of the blind openings and
amount of coulisses
28 equals the amount of the blind openings in the first row of the first blind openings
29.
[0035] In addition, the first grooves on the external surface
7 of the first basic wall of the housing can be made as spiral grooves (Fig. 2). First
grooves
10 are made so that their amount equals the amount of the blind openings in the second
row of the first blind openings
29 and each of first grooves
10 passes from the edge of external surface 7 of the first basic wall of the housing
consistently through one blind opening in every row of the first blind openings
29 and ends near the coulisse
28. Implementation of grooves
10 as spirals accordingly results in formation of internal channels of spiral form in
the rotor. It increases the speed of streams of liquid on an exit from internal channels
and increases the degree of turbulence of the stream of the liquid.
[0036] In addition, on the external surface of the first wall of the housing the additional
grooves
31 can be made (Fig. 2). Additional grooves
31 are made so that every additional groove passes consistently through one blind opening
of the second and first rows of the first blind openings
29 and ends near the coulisse
28 of a semi-cylinder form, here additional grooves
31 pass through such blind openings in the first row of the first blind openings
29 and coulisse
28, through which the first grooves
10 do not pass and near which they are not ended.
[0037] In addition, on the external surface
9 of the third basic wall of the housing a few rows of the third blind openings
32, the third grooves
33 and second circular grooves
34 can be made (Fig. 3,7). All the rows of the third blind openings
32 have an identical amount of the blind openings, and the blind openings in every row
are located so that axes of the blind openings are in the plane of conditional circle
at the identical distance to each other and are displaced in relation to the axes
of the third blind openings
32 in nearby rows at a certain step. The third grooves
33 are made so that the amount of grooves equals the amount of the blind openings in
the row of the third blind openings
32 and each of the third grooves
33 passes from one to other edge of external surface
9 of the third basic wall of the housing consistently through one blind opening in
every row of the third blind openings
32. The second circular grooves
34 are made so that they are located between the rows of the third blind openings
32.
[0038] In addition, on an external surface
13 the walls of cap a few rows of the fourth blind openings
35 can be made (Fig. 8,9). In every row the fourth blind openings
35 are spatially located on identical and certain distance from the conditional longitudinal
axis
24 of rotor for every row.
[0039] In addition, on the external surface 8 of the second basic wall of the housing a
few rows of the fifth blind openings
36 are made (Fig. 1), they are made like the rows of the fourth blind openings
35 on the external surface
13 of wall of cap.
[0040] The presence of the blind openings and grooves on the external surfaces of walls
of rotor considerably increases the area of surface of rotor, with which the stream
of liquid contacts and the degree of turbulence of stream of liquid which results
in the increase of efficiency of transformation of kinetic energy of motion of stream
of liquid in thermal energy and increase of temperature of heating of liquid.
[0041] The example of work of rotor of heat-generator is shown on Fig. 10, where the general
view of heat-generator is represented. The rotor
1 is located in the stator
37, the internal surfaces of walls of which are conjugated with a gap with the external
surfaces of the walls of the rotor. An engine (it is not shown) drives the shaft
30 of heat-generator and rotor
1 of heat-generator into the rotation. Liquid, for example, water, is driven by a pump
to the entrance of the branch pipe
38 for a liquid. Passing through the entrance branch pipe, the flow of liquid gets in
the axial channel
39 of the shaft. Then the general stream of liquid is distributed into a few even streams
and passes through radial channels
40 in the housing of the shaft, whereupon streams get in internal channels
41 of the rotor. In internal channels the streams of liquid move in direction from the
axis of the shaft rotation. As a result of the rotation of rotor the streams of liquid
in internal channels
41 get an additional centrifugal acceleration and due to it there is an increase of
speed of streams of liquid and the degree of turbulence of streams of liquid rises.
[0042] Afterwards the internal channels of rotor the streams of liquid go out on the external
surface of the first wall of rotor and get in a gap between the external surfaces
of wall of rotor and internal surface of wall of stator, where on the walls of the
stator there is slowing down of part of the stream of liquid and the liquid is heated.
The heated liquid goes out from the heat-generator through a channel
42 in the wall of stator.
[0043] The given examples only illustrate the invention but they do not limit it.
1. Rotor of heat-generator for heating of liquid, which contains a housing which three
basic walls, the first and second basic walls of the housing of the rotor are opposite
and the third wall of the housing of rotor is located between the first and second
basic walls of the housing of rotor, there is an axial channel in the rotor for a
shaft, characterized in that the rotor (1) contains additionally a cap (3), the first and second basic walls (4,5)
of the housing (2) are executed with the external surfaces (7,8) of the walls in form
of a truncated cone and with the identical direction of tapering of external surfaces
of the walls, the third basic wall (6) of housing (2) is executed with the external
surface (9) of cylinder form, on the external surface (7) of the first basic wall
(4) of the housing the first grooves (10) are executed for a passage-way for liquid,
and the first grooves (10) are executed so, that pass from one edge to other of external
surface (7) of the first basic wall (4) of the housing, the cap (3) is executed as
a hollow cone with one lateral wall (11) in which the axial opening (12) is made,
the external surface (13) and internal one (14) of the wall of cap (3) are executed
in form of a truncated cone, and the cap (3) is connected with the housing (2) so
that the internal surface (14) of the wall of cap (3) adjoins the external surface
(7) of the first basic wall (4) of the housing (2).
2. Rotor of heat-generator for heating of liquid according to claim 1, characterized in that the housing (2) contains additionally the first butt end wall (18) which is located
between the first (4) and third (6) basic walls of the housing (2), and the external
surface of the first butt end wall (20) of the housing is executed in form of a ring,
the housing (2) contains additionally the second butt end wall (19) which is located
between the third (6) and second (5) basic walls of the housing, and the external
surface of the second butt end wall (21) of the housing is executed in form of a ring,
on the external surface (7) of the first basic wall (4) of the housing in the place
of transition between the first basic wall (4) and the first butt end wall (18) of
the housing the first circular groove (26) is executed, which forms on the external
surface (7) of the first basic wall (4) of the housing (2) the surface of a cylinder
form (27) on which the coulisses (28) of semi-cylinder form are executed with an even
interval, on the external surface (7) of the first basic wall (4) of the housing a
few rows of the first blind openings (29) are executed so that in every row the first
blind openings (29) are spatially located on identical and certain distance from the
conditional longitudinal axis (24) of rotor (1) for every row, thus every row of the
first blind openings (29) from the second to the last one contains the identical amount
of the first blind openings (29) and the first row of the first blind openings (29)
contains twice more blind openings than the second row of the first blind openings
(29) on the external surface (7) of the first basic wall (4) of the housing, the first
grooves (10) are executed as spiral grooves so that their amount equals the amount
of the first blind openings (29) in the second row of the blind openings and each
of the first grooves (10) passes from the edge of external surface (7) of the first
basic wall (4) of the housing consistently through one first blind opening (29) in
every row of the first blind openings (29) and finishes near the coulisse (28) of
semi-cylinder form.
3. Rotor of heat-generator for heating of liquid according to claim 2, characterized in that on the external surface (7) of the first wall (4) of the housing (2) the additional
grooves (31) are executed, thus every additional groove (31) passes consistently through
one blind opening of the second and first rows of the first blind openings (29) and
finishes near the coulisse (28) of a semi-cylinder form, and the additional grooves
(31) pass through such blind openings in the first row of the first blind openings
(29) and finish near such coulisses (28) of a semi-cylinder form, through which the
first grooves (10) do not pass and near which they do not end.
4. Rotor of heat-generator for heating of liquid according to any claims 2-3, characterized in that on the external surface of the first butt end wall (20) of the housing the row of
the second blind openings (22) and of the second grooves (23) is executed, thus the
second blind openings (22) are executed so that the longitudinal axes of all of the
blind openings are located on identical distance from the conditional longitudinal
axis (24) of rotor (1), the second grooves (23) are made so that one groove and longitudinal
axes of grooves passes through every second blind opening and is located under an
identical corner in relation to conditional radial lines, conducted from axes of the
second blind openings (22) to the conditional longitudinal axis (24) of the rotor
(1).
5. Rotor of heat-generator for heating of liquid according to any claims 1-4, characterized in that on the external surface (9) of the third basic wall (6) of the housing (2) a few
rows of the third blind openings (32), the third grooves (33) and the second circular
grooves (34) are executed, all of rows of the third blind openings (32) have an identical
amount of the blind openings, and the third blind openings (32) in every row are located
so that axes of the third blind openings (32) are in the plane of conditional circle
at identical distance to each other and displaced in relation to the axes of the third
blind openings (32) in nearby rows at a certain step, the third grooves (33) are executed
so that the amount of grooves equals the amount of the blind openings in the row of
the third blind openings (32) and each of the third grooves (33) passes from one to
other edge of external surface (9) of the third basic wall (6) of the housing (2)
consistently through one blind opening in every row of the third blind openings (32),
the second circular grooves (34) are located between the rows of the third blind openings
(32).
6. Rotor of heat-generator for heating of liquid according to any claims 1-5, characterized in that on the external surface (13) of the wall of cap (3) a few rows of the fourth blind
openings (35) are executed so that in every row the fourth blind openings (35) are
spatially located on identical and certain distance for every row from the conditional
longitudinal axis (24) of the rotor (1).
7. Rotor of heat-generator for heating of liquid according to any claims 2-6, characterized in that on the external surface (8) of the second basic wall (5) of the housing (2) a few
rows of the fifth blind openings (36) are executed so that in every row the fifth
blind openings (36) are spatially located on identical and certain distance from the
conditional longitudinal axis (24) of rotor (1) for every row.
8. Rotor of heat-generator for heating of liquid according to any claims 3-7, characterized in that on the external surface of the second butt end wall (21) of the housing the row of
the sixth blind openings (25) is executed, and the sixth blind openings (25) are executed
so that the longitudinal axes of all of the sixth blind openings (25) are located
on identical distance from the conditional longitudinal axis (24) of the rotor (1).