RU2347155C1 - Continuous rotor-type heater - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: continuous rotor-type heater relates to heating engineering and can be used for heat and hot water supply to the industrial and household facilities. The heater comprises a stationary casing with a cylindrical cavity, its walls are fitted with intake and outlet channels and two openings of a bypass channel. A rotor is mounted in the cylindrical casing cavity with a gap, it is fixed on the shaft of the electrical engine and made as a disc with radial rows of holes which are facing blind holes made on the opposite casing surfaces. Additionally, a second cylindrical cavity is made in the casing and the rotor is equipped with a second disc set with a gap in the second cylindrical casing cavity. Through holes analogous to the holes in the first casing cavity and first rotor disc are made in the second casing cavity on the opposite surfaces and in the second rotor disc. Both casing cavities are connected to each other by the bypass channel with one its opening being placed at the periphery of the first casing cavity and the other - at the centre of the second casing cavity. The intake channel is placed in the centre of the first casing cavity and the outlet channel - at the periphery of the second casing cavity.

EFFECT: increasing the heater efficiency.

2 cl, 1 dwg

Description

The invention relates to heat engineering, and in particular to devices containing rotating elements for heating fluids, and can be used for heating liquids in housing and communal services, in industry and in domestic conditions.

A device for heating liquid is known, taken as a prototype (see patent RU 2290573, IPC F24J 3/00, publ. December 27, 2006 Bull. N36). The device for heating the liquid contains a stationary case with a cylindrical cavity, in the walls of which an inlet channel, an outlet channel and two openings of the bypass channel are made, as well as a rotor mounted with a gap in the cylindrical cavity of the body, mounted on the motor shaft and made in the form of a disk with radial rows of deaf holes located opposite blind holes made on opposite surfaces of the housing.

The disadvantage of the prototype is the lack of heat production, insufficient use of the functionality of the device.

The present invention solves the problem of reducing energy consumption during flowing heating of a liquid.

The technical result obtained by carrying out the invention is to increase the efficiency of the heating device.

The specified technical result is achieved by the fact that in the proposed flow-through heater of the rotary type, comprising a fixed housing with a cylindrical cavity, in the walls of which an inlet channel, an outlet channel and two openings of the bypass channel are made, as well as a rotor mounted on the shaft with a gap in the cylindrical cavity of the housing electric motor and made in the form of a disk with radial rows of holes located opposite blind holes made on opposing surfaces of the housing, new is t that a second cylindrical cavity is made in the housing, and the rotor is provided with a second disk placed with a gap in the second cylindrical cavity of the housing, while holes in the second cylindrical cavity of the housing on opposing surfaces and on the second rotor disk are similar to holes made in the first cylindrical the cavity of the housing and the first rotor disk, the holes on both rotor disks are made through, the cylindrical cavity of the housing is interconnected by a bypass channel, one hole of which is placed about the periphery of the first cylindrical cavity of the housing, and the second - the middle of the second cylindrical cavity, the inlet channel is positioned at the center of the first cylindrical cavity of the housing, and the outlet duct - at the periphery of the second cylindrical cavity of the housing. The housing with the rotor and the electric motor are housed in a sealed stainless steel container, reinforced in a heat-insulating non-conductive material, equipped with inlet and outlet nozzles, while an adjustable choke is installed on the outlet nozzle, which controls the temperature of the outgoing fluid flow.

The implementation of a stationary cylindrical body with two cylindrical cavities is due to the need to create two heat-generating cavities in which the fluid is sequentially heated and brought to the maximum possible temperature.

The implementation of the rotor in the form of two disks with radial rows of through holes, each located in its cavity and mounted on the motor shaft, allows, firstly, to increase the productive heat generation area, which allows to reduce the diameter of the casing and the disk, and secondly, to provide double pumping liquids through active heat-generating regions.

Since the input channel is the gap between the motor shaft and the hole in the housing located in the center of its first cylindrical cavity, the liquid under pressure from the network to which the heater is connected enters the first cavity into the low-pressure zone formed by the action of centrifugal forces during rotation rotor, which allows for the supply of fluid with the least loss.

The location of the output channel on the periphery of the second cylindrical cavity of the housing allows you to divert the heated liquid after it has reached a significant temperature increase, having passed the active heat generation zones in the first and second cavities.

The connection of the cylindrical cavities of the housing with each other bypass channel, one hole of which is located on the periphery of the first cylindrical cavity, and the second in the center of the second cylindrical cavity, allows you to apply fluid with increased pressure from the action of centrifugal forces from the first cavity to the second cavity in the low pressure zone and repeat the heating cycle a second time.

The placement of the housing with the rotor and electric motor (in this case, the motor must be submersible) in a sealed stainless steel container reinforced in a heat-insulating non-conductive material, due to the need to exclude heat losses during operation of the heater, as well as the need to comply with electrical safety rules for devices for which a power source is an electric current. Electrical safety issues are especially relevant for the mass consumer, therefore, reinforcing a sealed container with non-conductive material is a prerequisite for heaters used in everyday life. Stainless steel, of which the tank is made, allows to increase the life of the heater.

If the pressure of the network to which the flow heater is connected is insufficient, it is necessary to reduce the flow rate of the liquid by means of an adjustable throttle installed on the outlet pipe. With a decrease in flow rate, the removal of the liquid heated in the heater will occur at a higher temperature. Thus, the throttle is a regulator of the temperature of the outgoing fluid flow.

Technical solutions with features distinguishing the claimed solution from the prototype are not known and do not follow explicitly from the prior art. This allows us to assume that the claimed technical solution is new and has an inventive step.

The invention is illustrated in the drawing, which shows a General diagram of a flow-through heater of rotary type.

The flow-through heater of the rotary type consists of a sealed container 1, reinforced with a heat-insulating non-conductive material 2, inside of which a submersible motor 4 with a housing 5 is rigidly fixed to the brackets 3. In cylindrical cavities 6, 7 of the housing 5, separated by a partition 8, on the shaft of the submersible motor 4 are fixed, respectively disks 9, 10 on which the radial rows of through holes are made 11. On the end walls of the cylindrical cavities 6, 7 on both sides of the partition 8 there are similar rows of blind holes rstiy 12. In the center of the cylindrical cavity 6 in the wall of the housing 5 there is an input channel 13, made in the form of a gap between the hole in the end wall of the housing 5 and the shaft of the submersible motor 4. The output channel 14 is made in the wall of the housing 5 on the periphery of the cylindrical cavity 7. Cavity 6 and 7 are interconnected by a bypass channel, the hole 15 of which is made in the wall of the housing 5 at the periphery of the cylindrical cavity 6, and the hole 16 is made in the wall of the housing in the center of the cylindrical cavity 7. The inlet 17 and outlet 18 of the sealed pipe e dice 1 are placed on opposite walls facing each other. Immediately after the outlet pipe 18, an adjustable choke 19 is installed.

Flow-through heater rotary type operates as follows. A liquid with a network pressure through the inlet pipe 17 is fed into the sealed container 1 with a fully or partially blocked adjustable throttle 19. The submersible motor 4 is turned on, the process of heating the liquid begins. The liquid entering through the inlet channel 13 into the cavity 6 is heated in the zones of the through holes 11 and the blind holes 12 while advancing to the hole 15 of the bypass channel on both sides of the disk 9. The heated fluid flow from the hole 15 of the bypass channel is fed into the cavity 7 into the low-area pressure from the action of centrifugal forces through the hole 16 of the bypass channel. The process of heating the liquid in the cavity 7 proceeds similarly to the process occurring in the cavity 6. Additionally, the heated liquid through the outlet channel 14 and then through the outlet pipe 18 enters the consumer. Depending on the network pressure, by regulating the flow rate of the fluid by the throttle 19, it is possible to achieve the optimum temperature regime of the fluid supplied to the consumer.

Claims (2)

1. A flow-through rotor-type heater comprising a stationary case with a cylindrical cavity, the walls of which have an inlet channel, an output channel and two openings of the bypass channel, as well as a rotor mounted with a gap in the cylindrical cavity of the body, mounted on a motor shaft and made in the form of a disk with radial rows of holes located opposite blind holes made on opposite surfaces of the housing, characterized in that the housing has a second cylindrical cavity, and the rotor It is filled with a second disk placed with a gap in the second cylindrical cavity of the housing, while in the second cylindrical cavity of the housing on opposing surfaces and on the second disk of the rotor holes are made similar to the holes made in the first cylindrical cavity of the housing and the first rotor disk, holes on both disks the rotors are made through, the cylindrical cavity of the housing is interconnected by a bypass channel, one hole of which is located on the periphery of the first cylindrical cavity of the housing, and the second about the center of the second cylindrical cavity of the housing, the inlet channel is positioned at the center of the first cylindrical cavity of the housing, and the outlet duct - at the periphery of the second cylindrical cavity of the housing. 2. The flow-through heater of the rotor type according to claim 1, characterized in that the casing with the rotor and the electric motor are housed in a sealed stainless steel container, reinforced in a heat-insulating non-conductive material, equipped with inlet and outlet pipes, while an adjustable choke is installed on the output pipe, which is regulator of the temperature of the outgoing fluid flow.