This invention concerns an air heater with a connecting case for connecting the power supply and the air to be heated, as well as a heating element attached to the connecting case by means of a carrier, and with at least two line voltage contact elements located in the connecting case.
Such air heaters are common and are used extensively in industry. Used in many kinds of manufacturing processes, the air heaters heat the air that is supplied either by an external air source (blower) or by a blower that is attached directly to the air heater. The air is passed through a connecting case for the power supply, or it bypasses this case, and is then heated by a heating element.
Such air heaters must be of robust design to handle the generated heat as well as continuous operation. In addition, they should be designed for simple and quick assembly since a great number of such devices are produced in the course of mass production. In the air heater designs known so far, attaching the electrical connections in particular is a significant time-consuming factor during assembly.
From U.S. Pat. No. 5,033,208, a dry-air drying system for drying plastic granulates for plastic injection molding is known. A cylindrical housing contains two double-wall hollow cylinders of different diameters that are coaxial to each other and to the housing of the drying system. Between them, they form a drying chamber for the material to be dried. The walls of the hollow cylinders facing the drying chamber have openings serving as passages for heated air. The innermost hollow cylinder contains an electric heating system that heats the dry air supplied by a blower flanged to the outside of the housing before it enters the drying chamber. The heated air flows through the material to be dried in the drying chamber before entering the outer hollow cylinder from which it is purged by an exhaust air system.
It is common practice to make the electrical connections—especially with regard to their insulation from the housing—by means of flexible individual leads or flexible connection board connectors, where the electrical connection at the contact points is usually made with impulse welding or manual soldering. Making connections in this manner is time-consuming and leads to high assembly costs. In addition, there is a danger that the connection is interrupted by mechanical impacts or vibrations that would render the device inoperable. Another disadvantage of such connections made with leads is their labor-intensive disconnection in case of repairs.
In special applications, electrical connections are made with rubber-elastic electrically conductive connecting elements that do not have the disadvantages described above. Numerous designs of such elastic connecting elements for the electrical connection of components are known, and are being offered as ‘conductive rubber element’ by many manufacturers. The term ‘conductive rubber element’ indicates that it is a component with rubber-like characteristics that is electrically conductive, although it may not necessarily be made of rubber. The electrical conductivity of conductive rubber is achieved by adding conductive materials to the insulating base material. Such contact devices have long been used for the electrical connection of LCD displays with the conductors of connector circuit boards (DE 88 08 947 U1).
Difficulties with the use of conductive rubber elements occur whenever the components to be electrically connected are not parallel and/or if their surfaces are not flat. In such cases, specially shaped conductive rubber elements matching the geometry and the spatial orientation of the contact points to be connected are used. However, since such conductive rubber elements also need to have elastic properties, positive positioning, and thus the establishment of precise contact, is problematic because the conductive rubber elements may deform uncontrollably when the necessary contact pressure is generated.
This invention addresses the problem by proposing an air heater where the design and the arrangement of the connections for transmitting the electric heating current permit a cost-efficient and quick assembly. In addition, it should also permit the easy connection of an appropriate control device.
This problem is solved by the air heater with the characteristics listed in claim 1. Additional advantageous design variants are described in the sub-claims.
The air heater proposed by the invention has a connecting case for connecting the power supply and the air to be heated, as well as a heating element attached to the connecting case by means of a carrier. In the connecting housing, the carrier for transmitting the electrical heating current by means of a plug connection in the shape of contact pins on the carrier body and corresponding contact elements in the connecting housing is connected with a connection board where, for example, the terminals for the power supply are located. For this purpose, on its wall facing the heating element, the connecting housing has at least two insertion openings aligned with the contact pins on the carrier body. The contact pins are held in a receptacle angle bracket in the connecting housing (usually made of metal) and are electrically insulated from the connecting housing.
Preferably, this receptacle angle bracket is inserted in the connecting housing and has at least two cylindrical sleeves that pass through the insertion openings and insulate the contact pins. In principle, additional cylindrical sleeves may be provided for other connections. Besides serving as insulators, the cylindrical sleeves also function as spacers for the carrier during the assembly. In addition, rest elements and at least one attachment element for the connection board are provided. By designing the receptacle angle bracket as an insert, quick assembly becomes possible, while a secure input for the electric heating energy that is appropriately insulated from the connecting housing is provided at the same time. For this purpose, the receptacle angle bracket can preferably be locked into connecting housing.
In an additional advantageous design, in order to tap reference voltages for the control device, the contact pins can be connected to the conductors of the connection board by means of connecting elements made of conductive rubber in order to pass signals to a control device (microprocessor) located on the connection board. Preferably, an appropriately molded conductive rubber element is used to contact and connect the contact surfaces of the connection board and of the contact pins. Here, an insulating base material is filled with conductive metal or plastic particles that enable the conductive rubber to conduct electric currents. By varying the conductive material or its content, the conductive characteristic of the connecting element can be varied. Thus, the control device located on the connection board is able to detect and evaluate the voltage at the contact pins. In addition, the connecting elements can also be used for limiting the current.
In an advantageous design, the elastic connecting element is held in a support shell in the shape of a U-shaped half-shell at the bottom of the receptacle angle bracket. Placing the elastic connecting element in the support shell ensures its precise positioning and provides support so that the connecting element will not deform uncontrollably when the contact pressure is applied.
By means of the receptacle angle bracket, the connecting housing houses the plug connection consisting of plug contact parts and the corresponding contact pins along with the control device in a closed chamber. In a preferred design, the contact pins are designed as cylindrical sockets arranged on a ring-shaped carrier. The corresponding plug connection parts are designed as pins and attached to individual insulated electrical wires that can be connected via terminal boxes with the connection board of the control device. However, it is also possible to use contact pins on the carrier and sockets on the wires. The carrier has several contact pins of which at least two carry line voltage. The contact pins not carrying line voltage are used for connecting sensors of the control device and/or for grounding metallic parts of the housing. The voltages and signals needed by the control device for control purposes are tapped at the contact pins that can be contacted by the rubber-elastic connecting elements.
Preferably, the connecting element is homogeneous and designed as one piece, and has on its body a recess for accepting the contact pins. The geometry and dimensions of the recess match those of the contact pin; preferably, it is a bore whose inner circumference is slightly smaller than the outer circumference of the contact pin. When the contact pin enters the bore of the connecting element, it expands the bore which causes the connecting element to make positive contact, under pressure, with the surface of the contact pin.
In a further advantageous design, on its side facing the connection board, the connecting element has a pressure element for contacting the contact tracks of the connection board. The pressure element protrudes from the body of the connecting element, is of cylindrical shape, and is molded as part of the body of the connecting element. The pressure element may also have a different shape, or be composed of several individual pressure elements. Preferably, contacting the contact tracks is accomplished by pressing the connection board against the connecting elements—located in the receptacle angle bracket—that are penetrated by the contact pins. By locking the connection board in position on the receptacle angle bracket, the connecting element is compressed and the contact pressure is maintained.
In another advantageous design, on its side facing away from the connecting housing, the carrier has additional socket elements for plugging in the connection contacts of an electric heating element that are arranged in a circle. The socket elements for the heating element are electrically connected with the contact pins of the carrier. Preferably, the contact pins on the carrier are arranged in a row that is parallel to the bottom of the connecting housing and of the receptacle angle bracket. This makes it possible to arrange the connecting elements in the connecting housing in one plane so that only one design variant of the connecting element is needed.
Below, the invention is explained in detail with reference to a design variant shown in the drawings.
To the accomplishment of the foregoing and related ends, the invention, then, comprises the features hereinafter fully described and particularly pointed out in the claims. The following description and the annexed drawings set forth in detail certain illustrative embodiments of the invention. These embodiments are indicative, however, of but a few of the various ways in which the principles of the invention may be employed. Other objects, advantages and novel features of the invention will become apparent from the following detailed description of the invention when considered in conjunction with the drawings.
For the sake of clarity, the arrangement of the parts in assembled condition is shown in an exploded view in
The connecting housing 6 shown in
In the receptacle angle bracket 27, the connecting housing 6 houses the contact parts 3 and the corresponding contact pins 16 in a closed chamber 14. The contact pins 16 are designed as cylindrical contact sockets and are located on a ring-shaped carrier 4. The plug contact pieces 3 are attached to electrical wires 17 that are connected with the connection board 24 of the control device 2. The contact carrier 4 has four contact pins 16, with at least two of them carrying line voltage. The control device 2 contacts the contact pins 16 via three rubber-elastic connecting elements 1.
The connecting element 1 is homogeneous and of one piece, and has a bore 11 that accepts the contact pins 16. The contact pin 16 enters the bore 11 of the connecting element 1, making positive contact under pressure with the surface of the contact pin 16.
On its side facing the connection board 24, the connecting element 1 has a pressure element 9 for contacting the contact paths of the connection board 24. The pressure element 9 protrudes from the body 10 of the connecting element 1, is of cylindrical shape, and is molded as part of the body 10 of the connecting element 1.
The connecting housing 6 consists of three pieces, i.e. a housing body 12, a receptacle angle bracket 27, and a housing cover (not shown). The housing body 12 has an air duct 19 for carrying compressed air; at the ends of the air duct 19, two connecting pieces 22, 23 are molded as part of the housing body 12. The connecting pieces 22, 23 are designed as inlet piece 23 and outlet piece 22, are of round shape and have different sizes. The outlet piece 22 accepts the ring-shaped carrier 4 that is equipped with air passages 18 for the compressed air. Contact between the rubber-elastic connecting elements 1 and the contact pins 16 is established when the carrier 4 is inserted into the outlet piece 22 of the connecting housing 6. In the area of the outlet piece 22, the housing wall 15 of the housing body 12 and of the receptacle angle bracket 27 have openings 13 that are aligned with the contact pins 16, and through which the contact pins 16 enter the chamber 14 of the housing body 12.
On its side facing away from the connecting housing, the carrier 4 has additional socket elements 19′ for plugging in the connection contacts 20, arranged in a circle, of an electric heating element 21. The socket elements 19′ for the heating element 21 are electrically connected with the contact pins 16 of the carrier 4. The contact pins 16 on the carrier 4 are arranged in a row that is parallel to the bottom 8 of the connecting housing 6 and of the receptacle angle bracket 27. The connecting elements 1 in the connecting housing 6 are arranged in one plane that is aligned with the corresponding connection parts 16 arranged in a row.
The connecting element 1 as proposed by the invention, shown in an enlarged view in
They are designed to form the support wall 30 in the area of the support shells 5. In addition, three U-shaped support shells 5 for holding the connecting elements 1 are molded into the bottom 34 of the receptacle angle bracket 27; between two support shells 5, a bore 32 is provided into which a bolt (not shown) for attaching the connection board 24 can be screwed. At its bottom 34, the receptacle angle bracket 27 has a locking element 35 for locking it into the connecting housing 6. This allows the receptacle angle bracket to be inserted and locked in position quickly and easily. The cylindrical sleeves 29 serve as lateral contact protection.
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04023222 | Sep 2004 | EP | regional |
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Number | Date | Country | |
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20060068622 A1 | Mar 2006 | US |