RU2047492C1 - Hand vulcanizer - Google Patents

Abstract

FIELD: repair of rubber articles, mainly tyres. SUBSTANCE: hand vulcanizer has support 1, screw clamp 4 with pressure screw 7 to press article 19 to heat conduit with edge projection 9. Connected to heat conduit 9 is heating element in form of posistor 10 connected with supply source. With supply source switched on, posistor 10 quickly heats heat conduit 8 to vulcanization temperature. EFFECT: enhanced reliability, facilitated operation. 3 cl, 3 dwg

Description

 The invention relates to equipment for local vulcanization and can be used, for example, in the repair of rubber products.

Known vulcanizer, which is a multi-link mechanism with hinges, springs and a slider to which a clamp is attached with a heating resistor [1]
The vulcanizer requires large amounts of electricity, because To prevent overheating of the vulcanized object, a small rated current must flow through the resistor, which heats the clamping device and the object to the set temperature for a long time, during which part of the heat is dissipated in the surrounding space is useless.

 In addition, the vulcanizer requires a large complexity of manufacturing, because consists of more than ten parts of complex shape, connected movably.

The closest in technical essence and the achieved result to the claimed invention is a manual vulcanizer containing a clamp with a clamping screw and a support, between which with the possibility of pressing the vulcanized object to the support is a heat sink to which a heating element is attached [2]
Known vulcanizer also requires large expenditures of electricity and laborious manufacturing, because the heat pipe is made in the form of a detachable mold.

 The technical result of the invention is to reduce energy consumption and the complexity of manufacturing.

 The specified technical result is achieved in that in a manual vulcanizer containing a clamp with a clamping screw and a support, between which with the possibility of pressing the vulcanizable object to the support there is a heat pipe to which the heating element is attached, the heat pipe is made in the form of a plate with an edge protrusion, and the heating element is made in the form of a posistor attached to a protrusion with an electric and thermal contact, equipped with a terminal on its free end and closed with a protrusion by a heat insulator. In addition, to increase the convenience of operation, the clamp is made collapsible in the form of a bracket and a removable support, fixed in the plane of the bracket. To reduce heat dissipation, the heat sink, in addition to the clamping surface, is covered with a layer of heat insulator.

 In FIG. 1 shows a vulcanizer in a working position; figure 2 heat pipe (top view); figure 3 is a variant of the heat sink with a clamping contact to the posistor.

 A square-shaped support 1, stamped from a steel sheet, has bent down edges 2 with coaxial square holes 3 in the middle of the opposite edges 2. The two sides of each hole are perpendicular to the plane.

 The clamp bracket 4 is connected perpendicularly to the support 1 with its long leg 5, having a square section, like the whole bracket 4.

 The bracket 4 is made of a standard square steel flexible bar, which reduces labor costs. At the end of the short leg 6 of the bracket 4, a clamping screw 7 is screwed under which a clamping heat pipe 8 with an edge protrusion 9 is located. The resistor 10 in the form of a tablet is glued with its end to the protrusion 9 with a layer 11 of electrically conductive glue. For example, soldered to the protrusion 9 is a warm-water terminal 12 (negative when powered by the vehicle’s electrical network), and a posistor terminal 13 is connected with an electrically conductive adhesive to the upper end of the posistor 10. The resistor 10 is filled with an electrical thermal insulator 14 made of electrical thermal insulation material or closed with a lid 15 made of similar material (Fig. . 3). In this case, the springs 16 press the contacts of the terminals 12 and 13 to the protrusion 9 and the resistor 10, respectively, resting against the walls of the cover 15.

 The surface of the heat pipe 8 can be covered with a durable electrothermal insulator 17, for example, a coating of epoxy adhesive, in addition to the clamping surface 18, under which a vulcanizable object 19, for example, a car camera, is placed.

 Details can be made in various ways, without going beyond the scope of the claims.

The heat pipe 8 can be made of duralumin and other metal and have a shape corresponding to the vulcanizable object, with several protrusions 9, and the resistors 10 can be on both sides of the protrusion 9. The bracket 4 can be made of an octahedron or a round bar with a flat, etc. d. then the holes 3 should have the corresponding shape. If the vulcanizer is designed to supply voltages up to 48 V, then terminal 12 can be connected to the heat pipe 8 in a known manner, for example, by screw, soldering, etc. or a layer of electrothermal conductive glue. If the vulcanizer is designed to supply voltages higher than 48 V, then the resistor 10 must be designed for the appropriate voltage and isolated by a heat-conducting electrical insulator from the heat pipe 8 or the entire heat pipe must be electrically insulated. The operation of the vulcanizer is as follows. The vulcanizer is stored disassembled, so it is collected before work: the long leg 5 of the bracket 4 is inserted into the holes 3 in the edges 2 so that the screw 7 is installed above the flat surface of the support 1, until it stops. Unscrew the screw 7 so that a vulcanizable object 19 and heat pipe 8 can enter under it, and press them with a screw 7 to the support 1 with a uniform distribution of specific pressure on the volume 19 to a predetermined torque value on the screw 7. The vulcanizer is placed in a convenient position, for example, is turned over for the best use of heat due to convection, and turn on the posistor 10. A large rated current of about 20 A flows through the posistor 10, which quickly heats the object 19 to the vulcanization temperature; by further increasing the temperature, e.g. to 170 ± 3 ° ^C, sharply posistor increases its resistance several orders of magnitude, i.e., practically the current stops so as not to overheat the object 19, but when cooled by a few degrees, the current rises again, thus maintaining the desired vulcanization temperature.

At the end of vulcanization, loosen screw 7, remove the product 19 and heat pipe 8, then remove the foot 5 from the holes 3, rotate it about an axis by 90 ^° and reinsert it into the holes, thereby reducing the dimensions of the product several times, screw the screw 7 until it stops and stacked in a box (not shown).

Claims (3)

 1. MANUAL VOLCANIZER containing a clamp with a clamping screw and a support, between which with the possibility of pressing the vulcanizable object to the support there is a heat pipe to which a heating element is attached, characterized in that the heat pipe is made in the form of a plate with an edge protrusion, and the heating element is in the form of an attached to the protrusion with the electric and thermal contact of the posistor, equipped with an output at its free end and closed together with the protrusion by a heat insulator.  2. The vulcanizer according to claim 1, characterized in that the clamp is made collapsible in the form of a bracket and a removable support, fixed in the plane of the bracket.  3. The vulcanizer according to claims 1 and 2, characterized in that the surface of the heat pipe, in addition to the clamping surface, is covered with a layer of heat insulator.

Images