DE1291428B - Electric heater for heating liquid or gaseous media - Google Patents

Description

The invention relates to an electric heater for heating liquid or gaseous media as heat carriers for heating heatable Suits and especially for warming air intended for breathing.

The well-known electrical heating devices, through which a to be heated Medium flowing through it are used either to heat air, which is sent to the free Space is released for heating, or for heating liquid media, in particular Water.

In the known air heaters (German patent specification 811365) usually the air through a coaxially arranged to emem cylindrical housing Manhole sucked in, which is heated by means of radiators arranged around the air shaft will. The heating elements arranged between the air duct and the housing wall also emit heat through the outer wall of the housing and thus increase it Heat conduction the heating effect of the device. Through this desired heating effect However, the outer walls heat up, so that a Operator can easily burn himself when touching the outer walls.

In the known electrical heaters for heating liquid Media that only transfer the heat to the medium flowing through, but not to the ambient air should deliver (German Patent 904 924), the medium to be heated is in Coiled pipes, which are cast into the radiator: Um- a - blasting and to prevent the heat generated in the radiator from being dissipated to the environment, one or more insulating layers are generally arranged around the radiator. With continuous operation of such a radiator are for effective thermal insulation Strong insulation layers are required, making the construction of a small and light weight transportable heater in the way.

In addition, the known heaters are for optional heating of gaseous or liquid media useless, since liquid media in the known Air heaters are not suitable due to the cable routing and heating devices for Heating of liquid media due to the heat transfer and heat transfer conditions are not designed for heating air.

It is the object of the invention to provide a heater to create that allows the optional heating of gaseous or liquid media and by a corresponding arrangement of the heating device insulating layers for Eliminates the need for heat conduction to the outer skin of the device.

This is achieved according to the invention in that the device is a cylindrical housing with inlet port and outlet port and in its interior has a cylindrical heating element coaxial to the axis of the cylinder housing, together with a coaxially arranged around it and against the inner jacket of the Cylinder housing forms an annular channel by means of a sealing ring, through which the medium heated by the heater and coming from the inlet port passes through and on one inside the cylinder housing outside the tube attached, controlled by a resistance regulator and the radiator via a Relay influencing thermostat flows past and through the outlet port to the Consumer points.

The cylinder housing preferably consists of two, each with a base cylinder shells provided at their open ends having circumferential lips coaxially connected to each other at any angle of rotation by means of fastening screws are, which also seal the pipe against the inner jacket of the cylinder housing and sealing ring with trapezoidal cross-section, which has additional sealing rings attach to the inner jacket of the cylinder housing.

The bottom of the cylinder shells can be coaxial with the axis of the cylinder housing each have an inlet port and an outlet port and in their Cylinder jacket each one optionally lockable, perpendicular to the axis of the cylinder housing have standing inlet port and outlet port.

Preferably, a means are on the outer jacket of the cylinder housing Screws can be fastened anywhere around the outer circumference of the cylinder housing Mounting plate and a mounting plate for holding the resistance regulator provided, whereby the mounting plate can either be attached or removed for remote control.

The embodiment according to the invention is radiated from the radiator and heat given off to the medium flowing past by the heat surrounding the radiator Tube reflected and returned to the flowing through-1Vlediüni. The up to the outer skin of the pipe surrounding the radiator coaxially penetrated heat is released to the medium surrounding the pipe, so that on the outer skin of the housing the heater cannot penetrate any heat. The one emerging from the outlet port The heated medium is passed on to the consumer through appropriate lines.

The invention is explained in more detail below with reference to the drawings. In the drawings, F i g. 1 is a plan view of a heating device according to the invention, F i g. 2 shows a section along the line 2-2 in FIG. 1, seen in the direction of the arrows, F i g. 3 shows a section along the line 3-3 of FIG. 1, seen in the direction of the arrows, F i g. 4 is an end view from the left of the device shown in FIG. 1, FIG. 5 a section along lines 5-5 of FIG. 3 and F i g. 6 is a schematic circuit diagram the control device used with the device according to the preceding figures will.

F i g. 1 to 5 of the drawings show the heater 10 with a cylindrical housing 11. A heating device 12 is provided within the housing 11 , which receives electrical current passed through a thermostat 13 and a resistance regulator 14.

The housing 11 consists of an outlet part 16 and an inlet part 17, preferably made of light metal casting. The outlet part 16 has a cylindrical wall 18 which is made in one piece with a jacket wall 19 at one end thereof. The walls 18 and 19 have outlets 20 and 21, which can optionally be closed by a plug 22.

The left end of the housing wall 18 is provided with an annular lip part 23 of reduced cross-sectional dimension, which is provided in the area with eight spaced bolt holes.

In addition to the two outlets 20 and 21, the housing 16 has also a sleeve 25 for receiving a fitting 26 for the thermal cooler 13.

The inlet housing part 17 has a cylindrical body wall 27, which is closed at one end by an end wall 28. Each of the walls 27 and 28 is provided with inlets 29 and 30, one of which is optionally provided by means of plugs 31 is lockable. The wall 27 is also insulated with a sleeve 32 for receiving an electrical line 33 provided which receives an electrode assembly 34, the is connected to an electrical conductor 35 inside the inlet housing 17, which is in communication with the end terminal 36 of the electric heater.

In order to be able to mount the heating device 12 inside the housing, the inlet housing part is formed with three uprights 38,38.

The inner wall of the cylindrical body wall 27 of the inlet housing part 17 is formed into an annular mounting lip 40 at one end. The connecting bolts 41 are then through the openings in these lip parts in bores 42 with sealing ring 43 screwed in. Two O-rings 45, 45 are between the outer wall of the sealing ring 23 and the adjacent inner surfaces of the wall parts 18 and 27 of the two housing parts 16 and 17 arranged.

An adjustable mounting bracket 50 is provided which has a flat mounting base 51 with a pair lying in the same plane, laterally in the Spaced, parallel assembly legs 52, 52 with attachment parts 55 includes, each of which is provided with openings 53, 53, the fastening bolts 54, 54 record.

The attachment parts 55, 55 are each provided with an opening for the connecting bolts 41.

Another posture 60 similar to the mounting bracket 50 with a flat base plate part 61 with mounting leg 63 is connected to the housing.

The heating device 12 comprises an electrical resistance coil 65, which is cylindrical and with three fastening tabs 66, 66 to the Mounting kits 38, 38 is attached. The coil 65 is made of a cylindrical insulating tube 67 surrounded by means of three fastening lugs 68 with the mounting lugs 66 the coil 65 on the mounting lugs 38 by means of connecting bolts 69 in bores 70, 70 is screwed on. Coil 65 and insulating tube 67 are through an annular Space 71 separated, which forms an annular passage for the medium.

The heating device 65 receives its current via the electrical conductor 35, which is located between its end terminal 36 and the electrode connection device 34 is arranged. The thermostat 13 has an outer protective housing 75 with a protective cap and an insulated electrical connection device 76, which conductors 77- and 78 are connected in the circuit to a mercury thermostat 79.

The mercury thermostat is commercially available with a capillary tube 80, in which two balls 81 and 82 are located, which contain mercury.

The ball 81 of the mercury thermostat has a heating coil 83, which is actuated together with the heater 65. The capillary tube is also interrupted at two points 84 and 85 by electrode probes, the electrical conductors 86 and 87 have. The conductor 86 is grounded while the conductor 87 is connected to the conductor 77, which leads to the control device 14.

As in Fig. As shown in FIGS. 3 and 4, the control device 14 has a housing 88 which is removably attached to the upper mounting bracket 60 by bolts 89. When the line switch 92 is closed, electrical energy flows to the control device 14 via the conductor 94 with a potentiometer 95 with actuating button 96. The potentiometer 95 is connected in series with a fixed resistor R 1 across conductor 97, which is connected to the conductor 78 at a conventional clamp connector B 1. The head 78 extends between terminals B 1 and B 2 and is connected to the latter the heating coil 83 connected to the upper ball 81 of the mercury thermostat heard. Winding 83 is also grounded through conductor 98 and ground conductor 86, which belongs to the first probe point 84 of the mercury thermostat.

When switch 92 is closed, the circuit is through the Potentiometer 95 and the thermostatic heating coil 83 closed to earth and the named heating coil is charged with a constant energy value, which can be selected by the potentiometer 95 can be changed.

The potentiometer 95 is also coupled in a parallel circuit to a second resistor R 2 that includes a conductor 100, a resistor R 2 and a movable relay contact 101. The relay contact 101 is movable from a normal de-energized position, which is shown in solid lines in FIG. 6, engaging a contact 102 in circuit with conductor 97 to a energized position (shown in dashed lines in FIG. 6) engaging contact 103. The working movement of the relay contact 101 is brought about by energizing a relay coil 105, which is connected in the circuit with the conductor 94 via the conductor 106 and with the second electrode probe point 85 of the mercury thermostat via the conductor 107, the end terminal connection A 1, the conductor 77, the end terminal A 2 and the conductor 87 which is connected to the probe point 85 stands. When the mercury bridges the probe points 84 and 85, the relay coil circuit is completed to ground through the grounded conductor 86.

The relay operating coil 105 operates in addition to the operation of the movable contact 101 also has a second movable contact 110, which is in the Circuit with the line 90, 91 via the switch 92 and the conductor 111 is. The relay contact 110 moves between a normal de-energized position, the in full lines in FIG. 6 is shown engaging the fixed contact 112, in an energized position as shown in dashed lines in this one Figure is shown in which he is at a. fixed dead contact 113 attacks. The contact 112 is in the circuit with the heating unit 65 via the conductor 114, the electrode connector 34, the conductor 35 and the end connector 36 on the heating unit 65. Typically, the heating unit can be of the order of of 250 watts. A pilot lamp circuit is also provided to indicate when heating unit 65 is energized, and that circuit includes one Incandescent lamp 115, which is fed via a conductor 116 between the heating unit supply line 114 and earth is on.

When line switch 92 is closed, heater unit 65 is normally energized through conductor 11, closed relay contacts 110 and 112, conductors 114 and 35 to ground. At the same time the control lamp circuit is energized in order to show the operator by means of a visual signal that the heating unit is energized. At the same time, normal period current is fed to winding 83 of the sensing unit 13 via the earth circuit, which leads to earth via conductor 94, adjustable potentiometer 95, resistor R 1, conductors 97 and 78, winding 83 of the mercury thermostat and conductors 98 and 86 . The coil 83 for the mercury thermostat also receives periodic pulses or receives additional energy every time the heating unit 65 is energized. The circuit for supplying such additional energy to the thermostat coil 83 comprises the conductor 91, the line switch 92, the conductor 94, potentiometer 95, parallel circuit conductor 100, resistor R 2, the closed relay contacts 101 and 102, the conductors 97 and 98, the heating coil 83 and conductors 98 and 86 to earth. In that additional energy is periodically supplied to the thermostat winding 83 in accordance with the energization of the heating unit 65, the mercury thermostat anticipates the action of the heating unit and in particular the increased temperature of the medium heated by the heating unit. This anticipation eliminates excessive temperature of the outflowing air or other medium emitted by the apparatus of the invention, as will be described below.

Whenever the relay coil 105 is energized, the heating unit 65 is de-energized and the anticipation function described above, which is created by the excess pulse energy to the alternating control circuit including the resistor R 2, is interrupted every time the mercury is in the capillary tube 80 of the sensing unit rises to a level sufficient to bridge and close the contact between electrode probe points 84 and 85 so as to complete the electrical circuit through relay coil 105, conductors 107, 77, 87 and 86 to ground. This relay feed circuit is the circuit that runs through the end connectors A 1, A 2 and is therefore referred to hereinafter as the "A circuit". When the "A circuit" is thus made, the relay coil will cause relay contacts 101 and 110 to move to their dashed line positions, as shown in FIG. 6, in order to de-energize the heating unit 65 and at the same time de-energize the circuit through the resistor R 2, which supplies the additional "pulse" heat energy to the winding 83 of the mercury thermostat. As soon as this additional energy is removed from the sense unit winding 83, the mercury in the capillary tube 80 quickly falls and breaks the contact or circuit between the probe points 84 and 85 therein, whereby the relay coil 105 is de-energized and the current is fed back to the heating coil of the heating unit and also the additional "impulse" force is conducted to the sensing unit winding 83 via the control circuit, which consists of the resistance conductor 100, resistor R 2 and the relay contacts 101 and 102.

The potentiometer 95 and the fixed resistor R 1 in the circuit are those to limit the lowest operating limit for the thermostatic sensing unit. When the temperature of the medium heated by the heater 65 is raised, this elevated temperature is sensed by the secondary sphere 82, which is in the stream of the moving medium is arranged to bring the level of mercury to the probe point 85 to raise. If the temperature of the medium or air that is being heated is assisted by the impulse heat energy supplied to the winding 83, the The level of mercury in the capillary tube rises enough to make a circuit connection Establish between the probe points 84 and 85 in the capillary tube, the relay coil 105 energized as described above, the heating unit 65 is de-energized is made and the control cycle is repeated.

Claims (7)

Claims: 1. Electric heater for heating liquid or gaseous media as a heat carrier for heating heatable suits and in particular for heating air intended for breathing, characterized in that the device (10) has a cylindrical housing (11) with an inlet port (29,30) and outlet connection (20, 21) and in its interior coaxially to the axis of the cylinder housing has a cylindrical heating element (65) which, together with a coaxially arranged around it and against the inner jacket of the cylinder housing (11) by means of a sealing ring ( 43) sealed tube (12) forms an annular channel through which the medium, heated by the heater (65) and coming from the inlet nozzle (29, 30), passes and is attached to an inside of the cylinder housing (11) outside the tube (12) , controlled by a resistance regulator (14) and the radiator via a relay influencing thermostat (13) flows past and through the outlet connection (20, 21) reaches the consumer points. 2. Electrical Heating device according to claim 1, characterized in that the thermostat (13) is a Capillary tube (79) filled with mercury with two spaced apart Has hollow spherical extensions, one of which is at the end of the capillary tube (79) arranged hollow spherical extension (82) the flowing medium inside of the cylinder housing (11) is exposed on the delivery side and the second in the protective cap (76) of the thermostat (13) arranged hollow spherical extension (81) is provided with a heating coil (83), one end of which is over the resistance regulator (14) connected to the radiator (65) and the other end of which is grounded, and the Capillary tube (79) has two contact points (84, 85) which are spaced apart from one another, of which one contact point (84) is grounded and the other contact point (85) with one of the relay flaps (101, 110) actuatable solenoid (105) is connected. 3. Electrical heater according to claim 2, characterized in that the one Relay contact (101), resistors (R 1, R 2) and a variable resistor (95) having Resistance regulator (14) with one end of the heating coil (83) and with the heating element (65) and connected to the switch (92) via a supply line (91) with electrical Electricity can be fed. 4. Electrical heater according to claim 1, characterized in that the cylinder housing (11) consists of two cylinder shells (18, 27) each having a base (16, 17), which ends at their open, circumferential lips (23, 40) are connected to each other coaxially at any angle of rotation by means of fastening screws (41), which simultaneously seal the tube (12) against the inner surface of the cylinder housing (11) and have additional sealing rings (45 ) with a trapezoidal cross-section on the inner surface of the cylinder housing (11 ) fasten. 5. Electrical heater according to claim 1 or 2, characterized in that the magnetic coil (105) by means of the contact points (84, 85) in the capillary tube (79) of the thermostat (13) connecting the mercury column (80) is energized and the Relay contacts (101, 110) moved to the "Off" position. 6. Electrical Heating device according to claim 4, characterized in that the cylinder shells (18, 27) in their bottom (16, 17) coaxially to the axis of the cylinder housing each have an inlet port (30) and outlet nozzle (21) and each one optionally closable in its cylinder jacket, inlet connection (29) and outlet connection perpendicular to the axis of the cylinder housing (20) have. 7. Electrical heater according to claim 1, characterized in that that on the outer jacket of the cylinder housing a mounting plate (50) by means of the Screws (41) can be fastened at any point around the outer circumference of the cylinder housing is. B. Electrical heater according to claim 1, characterized in that a Mounting plate (60) for fastening the resistance regulator (14) using screws (41) can be optionally fastened at any point around the outer circumference of the cylinder housing or can be removed for remote control.