RU107602U1 - HEATING ELEMENT (OPTIONS) - Google Patents

Abstract

 1. The heating element, made in the form of a resistive two-wire heating cable, consisting of two electrical conductors connected to a power source, one connecting crimp sleeve and a bimetal thermal switch with a given temperature, built into the heating cable, while two conductors connected to a power source to a crimp connector located on one of the conductors, and from the bimetallic thermal switch to the power source, are electrical conductors, and the conductor from the crimp connector to the bimetallic thermal switch is a heating conductor with a certain ohmic resistance. ! 2. The heating element, made in the form of a resistive two-core heating cable, consisting of two electrical conductors connected to a power source, two connecting crimp couplings and a bimetallic thermal switch with a predetermined temperature built into the heating cable, while two conductors connected to a power source up to the two crimp couplings located on each of them are electrical conductors, and the conductor from the first crimp couplings to bimetal thermal switch, as well as from a bimetallic thermal switch to the second connecting crimp sleeve, is a heating conductor with a certain ohmic resistance. ! 3. The heating element, made in the form of a resistive single-core heating cable, consisting of an electrical conductor connected to a power source, two

Description

The utility model relates to electric heating devices and can be used as an electric heating element, which is designed to heat objects of various shapes and sizes (floors, walls and ceilings, stairs, airfields, roads, sidewalks, stadiums, tunnels, soil in greenhouses, etc. .p.) and can also be used in the construction of a vehicle (electric seat heater).

A device is known for heating and controlling the degree of heating of the floor surface by means of an electric heating cable (1), which describes the floor structure in accordance with which floor panels are located on the floor surface with a certain step so that between the panels form channels into which the cable is laid. The structure also contains a heat-reflecting sheet, which is laid on metal panels and laid in folds in the channels under the heating cable.

Such a device is relatively complex and requires significant costs for the equipment of the heated floor. For example, it is required to arrange the panels and fix them in a position with a predetermined step between them so that the width of the formed channels corresponds to the width of the heating cable laid in these channels. Laying a heat-reflecting sheet requires even greater additional costs.

A vehicle seat heating device (2) is also known, comprising an electric resistive heating element, a temperature sensor, and a control unit located outside the seat. The temperature sensor is located on the seat and is electrically connected to the control unit, and consists of two thermistors, one is located under the wire of the heating element, and the other is located between the wires of the heating element. The reliability of the measurement of such a sensor is quite high.

The location of the sensor on the seat reduces the comfort of the driver's seat, and constant alternating loads reduce the durability of the sensor and the heating device as a whole. The device also has a complex control carried out by the remote unit.

The closest is a vehicle seat heater with a thermal relay (3) containing a contact group located in the housing consisting of a movable spring contact and a fixed contact, connected in series to the power circuit of the heater's electrical element, and a heat-sensitive element, which is installed with the possibility of acting through the rod on the movable contact , where the thermal relay housing is located in the heat-affected zone of an additional heater connected to the power supply circuit of the electric heating heater element. In this case, an additional heater is adjacent adjacent to at least two sides of the thermal relay housing.

The device has a complex structure, due to the many heating elements with which they control and adjust the temperature.

The technical result of the utility model consists in the absence of control and adjustment of the temperature of the heating cable itself by external temperature regulators, which leads to a simplification and cheapening of the design of the electric heating cable.

In the first embodiment, the technical result is achieved by the fact that the heating element is made in the form of a resistive two-core heating cable, consisting of two electrical conductors connected to a power source, one connecting crimp sleeve and a bimetal thermal switch with a given temperature, built-in to the heating cable, while two conductors connected to a power source, to a crimp connector located on one of the conductors, and from a bimetallic thermal switch to the power source are electrical conductors, and the conductor from the crimp connector to the bimetallic thermal switch is a heating conductor with a certain ohmic resistance.

In the second embodiment, the technical result is achieved by the fact that the heating element is made in the form of a resistive two-core heating cable, consisting of two electrical conductors connected to a power source, two connecting crimp couplings and a bimetal thermal switch with a predetermined temperature built into the heating cable, while two conductors connected to a power source, up to two crimp couplings located on each of them are electrical conductors, and The one from the first connecting crimp sleeve to the bimetallic thermal switch, as well as from the bimetallic thermal switch to the second connecting crimp sleeve, is a heating conductor with a certain ohmic resistance.

In the third embodiment, the technical result is achieved by the fact that the heating element is made in the form of a resistive single-core heating cable, consisting of an electrical conductor connected to a power source, two crimp couplings and a bimetal thermal switch with a predetermined temperature built into the heating cable, with one connecting the crimp sleeve is located upstream of the bimetallic thermal switch, and the other connecting crimp sleeve is upstream of the bimetal thermal switch ovyklyuchatelya, wherein the first connecting conductor by crimping the sleeve to the bimetallic thermal switch and by a bimetallic thermal switch, to the second coupling is a heating conductor with a specific ohmic resistance.

In the fourth embodiment, the technical result is achieved in that the heating element is made in the form of a resistive single-core heating cable, consisting of an electrical conductor connected to a power source, a connecting crimp sleeve and a bimetal thermal switch with a predetermined temperature, built into the heating cable, while the connecting crimp sleeve located after the bimetallic thermal switch, the conductor from the bimetallic thermal switch to the connecting crimp The coupling is a heating conductor with a specific ohmic resistance.

The above set of features in comparison with the prior art allows us to conclude that the claimed technical solution meets the condition of "novelty." At the same time, the claimed technical solution is applicable in various industries, construction, transport, utilities and agriculture, therefore, it meets the condition of "industrial applicability".

The essence of the claimed utility model is illustrated by graphic materials on which:

- figure 1 and 2 depict options for a heating element made in the form of a resistive two-core heating cable;

- figure 3 and 4 depict options for a heating element made in the form of a resistive single-core heating cable.

The heating element according to the first embodiment (Fig. 1) and the second embodiment (Fig. 2) is made in the form of a resistive two-core heating cable, which consists of two electrical conductors (3) connected to a power supply Upit., One or two crimp couplings ( 4) and a bimetallic thermal switch (1) with a predetermined temperature built into the heating cable. Also, the resistive two-core heating cable, according to both options, has insulation (6).

The heating element according to the third embodiment (Fig. 3) and the fourth embodiment (Fig. 4) is made in the form of a resistive single-core heating cable, which consists of one electric conductor (3) connected to a power supply Upit., One or two crimp couplings ( 4) and a bimetallic thermal switch (1) with a predetermined temperature built into the heating cable. Also, the resistive single-core heating cable, according to both options, has insulation (6).

The principle of operation of the heating element according to the first embodiment (figure 1). When you turn on the power source electric current passes through two electric conductors (3), through a crimp connector (4) located on one of the conductors (3), and enters the bimetallic thermal switch (1) with a given temperature, which is built into the heating cable. The electric circuit of the bimetallic thermal switch (1) closes, as a result of which the conductor from the crimp connector to the bimetallic thermal switch (1), which is a heating conductor (2) with a certain ohmic resistance, is heated. When a certain temperature is reached, the electric circuit of the bimetallic thermal switch (1) opens, while the specified heating conductor (2) with a certain ohmic resistance starts to cool. When the specified heating conductor (2) cools down to a certain temperature, the electric circuit of the bimetallic thermal switch (1) closes again. Thus, the process is cyclically repeated until the power source Upit is turned off.

The principle of operation of the heating element according to the second embodiment (figure 2). When you turn on the power source electric current passes through two electric conductors (3), through two crimp couplings (4) located on each of the electric conductors (3), and enters the bimetallic thermal switch (1) with a given temperature, which is built into the heating cable. The electric circuit of the bimetallic thermal switch (1) closes, as a result of which the conductor from the first connecting crimp sleeve (4) to the bimetallic thermal switch (1), as well as from the bimetallic thermal switch (1) to the second connecting crimp sleeve (4), which is a heating conductor (2 ) with a certain ohmic resistance, heats up. When a certain temperature is reached, the electric circuit of the bimetallic thermal switch (1) opens, while the specified heating conductor (2) with a certain ohmic resistance starts to cool. When the specified heating conductor (2) cools down to a certain temperature, the electric circuit of the bimetallic thermal switch (1) closes again. Thus, the process is cyclically repeated until the power source Upit is turned off.

The principle of operation of the heating element according to the third embodiment (figure 3). When you turn on the power source electric current passes through the electric conductor (3), through two crimp couplings (4), and enters the bimetallic thermal switch (1) with a predetermined temperature, which is built into the heating cable. The electric circuit of the bimetallic thermal switch (1) closes, as a result, the conductor from one connecting crimp sleeve (4) located to the bimetallic thermal switch (1), and the other connecting crimp sleeve (4) located after the bimetallic thermal switch (1), which is a heating conductor (2) with a certain ohmic resistance, heats up. When a certain temperature is reached, the electric circuit of the bimetallic thermal switch (1) opens, while the specified heating conductor (2) with a certain ohmic resistance starts to cool. When the specified heating conductor (2) cools down to a certain temperature, the electric circuit of the bimetallic thermal switch (1) closes again. Thus, the process is cyclically repeated until the power source Upit is turned off.

The principle of operation of the heating element in the fourth embodiment (figure 4). When you turn on the power source An electric current passes through an electric conductor (3), through a crimp connector (4) located after the bimetallic thermal switch (1), and enters the bimetallic thermal switch (1) with a given temperature, which is built into the heating cable. The electrical circuit of the bimetallic thermal switch (1) closes, as a result of which, the conductor from the bimetallic thermal switch to the crimp sleeve (4), which is a heating conductor (2) with a certain ohmic resistance, is heated. When a certain temperature is reached, the electric circuit of the bimetallic thermal switch (1) opens, while the specified heating conductor (2) with a certain ohmic resistance starts to cool. When the specified heating conductor (2) cools down to a certain temperature, the electric circuit of the bimetallic thermal switch (1) closes again. Thus, the process is cyclically repeated until the power source Upit is turned off.

Information sources:

1. EP 588911 B1, E04F 15/04, G05D 23/19, 03/30/1994.

2. WO 0206913 A1, B60N 2/56, G05D 23/24, 01.24.2002.

3. RU 32049 U1, B60N 2/56, G05D 23/185, 04.30.2003.

Claims (4)

1. The heating element, made in the form of a resistive two-wire heating cable, consisting of two electrical conductors connected to a power source, one connecting crimp sleeve and a bimetal thermal switch with a given temperature, built into the heating cable, while two conductors connected to a power source to a crimp connector located on one of the conductors, and from the bimetallic thermal switch to the power source, are electrical conductors, and the conductor from the crimp connector to the bimetallic thermal switch is a heating conductor with a certain ohmic resistance. 2. The heating element, made in the form of a resistive two-core heating cable, consisting of two electrical conductors connected to a power source, two connecting crimp couplings and a bimetallic thermal switch with a predetermined temperature built into the heating cable, while two conductors connected to a power source up to the two crimp couplings located on each of them are electrical conductors, and the conductor from the first crimp couplings to bimetal thermal switch, as well as from a bimetallic thermal switch to the second connecting crimp sleeve, is a heating conductor with a certain ohmic resistance. 3. The heating element, made in the form of a resistive single-core heating cable, consisting of an electrical conductor connected to a power source, two connecting crimp couplings and a bimetallic thermal switch with a predetermined temperature, built into the heating cable, while one connecting crimping clutch is located up to the bimetallic thermal switch, and another connecting crimp coupling is located after the bimetallic thermal switch, and the conductor from the first connecting crimping The coupling to the bimetallic thermal switch and from the bimetallic thermal switch to the second coupling is a heating conductor with a certain ohmic resistance. 4. The heating element, made in the form of a resistive single-core heating cable, consisting of an electrical conductor connected to a power source, a connecting crimp sleeve and a bimetallic thermal switch with a predetermined temperature, built into the heating cable, while the connecting crimp sleeve is located after the bimetallic thermal switch, and the conductor from a bimetallic thermal switch to a crimp connector is a heating conductor with a specific ohm eskim resistance.