DE2725554A1 - Dental gold alloy pressure die casting furnace - has manual or automatic actuation microswitches and resistance heaters - Google Patents

Abstract

The electric furnace is used in pressure die castings of gold alloys or ceramic and gold alloys for dental purposes. The furnace ensures homogeneous molecular structure and stability of alloys. The melting system which can be controlled manually or automatically, is rapid. The furnace is connected to a horizontal shaft for tilting manually or automatically with the electric motor. The automatic control system has microswitches. The latter are actuated by the lever (AS, SA) held on the furnace tilting shaft (AZ). A vacuum control is built into the furnace housing or it is actuated by one of the microswitches. The furnace (FO) has cylindrical tilting shell (KA) which has internal projections for holding flask (CP) connected with the actual furnace. The furnace has electrical resistance heaters (RE), fireproof lining and a graphite crucible.

Description

Electric furnace for the die casting of precious metals

The invention relates to improvements in electric furnaces for the die casting of precious metals such as gold alloys or ceramic gold alloys for dental use.

The main aim of the invention is to develop a furnace for such Applications that have a homogeneous molecular structure of the alloy and its durability allows.

Another object of the invention is to develop an electric furnace which is operated automatically or manually to melt the alloy, whereby the melting process proceeds extremely quickly, as in dental applications required.

An essential advantage of the electric furnace according to the invention is its assignment to a land control and an automatic control an electric motor for tilting the furnace along a horizontal axis; the latter type of tax takes place with the help of microswitches which rotate with the furnace tilting shaft linked arms are controlled.

An application example of the invention is shown schematically in the drawing shown. 1 shows the furnace according to the invention in longitudinal section; Fig. Fig. 2 is a side view of the same; Fig. 3 is a section perpendicular to that of Fig. 1 with the furnace interior parts removed; 4 shows a simplified circuit diagram; 5 shows the diagram of the vacuum system.

In the following description, for the sake of convenience, the following Division made I: Furnace structure II: Assembly and general structure III: Pneumatic circuit IV: Circuit diagram V: Mode of operation I: OVEN ASSEMBLY With reference to FIG. 1, the furnace FO consists of an outer cylinder jacket KA made of stainless steel with bottom, provided with a lid CO on top that surrounds the horizontal Adise AZ can be swiveled. The latter works with a GU O-ring to form a seal a flange FL in the mentioned cylinder body together, the closed position blocked by a lever BC. This lever is L-shaped at the ends of two Articulated twin joints LL which in turn are articulated at IM at the end of the cover CO.

AR is an adjustable stop, preferably existing from a small bolt with the Sperriiebeleiide BC to lock the lid CO works together.

In Fig. 2 the actual furnace is omitted; with reference to Fig. 1, in which with CC a co-operating with a refractory, ring-shaped mating jacket CH Inner jacket is designated, inside the Cegenmantels is the tubular insulating cladding RU with the electrical resistance, this cladding accommodating a crucible which is marked with CR and consists e.g. of graphite. The CC coat is with one circular flange CP connected, the diameter of which is slightly less than the diameter of the furnace shell is KA; he wirtl through three approaches OR by means of fastening screws, held as indicated. With AD a guide ring is designated with weleliem three Radial spacers DI are welded, one end of which (outside) is welded to the inner part of the jacket KA works together and its other end (inside) with a cylindrical clamp CA cooperates to receive the melt and the prints; this ferrule will CA. from one side against the cover CP and from the other side against an asbestos seal AM clamped.

The jacket KA is firmly connected to a pipe TT, which is sealing the connection cable of the electrical resistors, not shown, receives, wherein the cable passes through a hole FR in an intermediate wall of the housing IN. It is clear from the above that the possibility is given the clamp GH is to be replaced by another suitable clamp, whereby of course replace the AD ring or adjust the spacers.

The furnace is mounted around the shaft AL, as will be explained in more detail below is explained and can be swiveled around 1800 (kil> pbar) uiid from the in Fig. 1 shown loading position in an unloading position.

II: ASSEMBLY AND GENERAL STRUCTURE With particular reference to Fig. 1 and Fig. 2 with IN denotes a support housing which is welded from Sheet metal is made, which are connected with two shoulders PS-SP and for pivoting Serving (tilting) a furnace rotary shaft AL of the furnace FO, as will be described in more detail will be. The bearing shells 13R serve as bearings in a known manner. A shaft end is, as can be seen from the right part of Fig.l, with a hand control lever LC non-rotatably connected to swivel the actual furnace around 1800. The wave AL is hollow on one side and connected to a compressed air line TA, which is connected to a vacuum line TV is connected. The full part of the shaft AL is non-rotatable with a gear RD connected, the fever a chain CT works together with a counter gear DR, rotatable in one or the other direction by an electric motor MO. Next to the gear RD is provided with a sleeve MA, with which two arms AS-SA are firmly connected to work with three MC-MK-KK microswitches. The socket also has one as an end stop for the 180 ° rotation of the furnace around the axis AZ serving Pin PO on. Here, the microswitches are attached to the shoulder PS mentioned.

With reference to Fig. 3, P1 denotes an electronic pyrometer, with VU a vacuum gauge, with MT a manometer and with H1, H2,, AH, H5, H6 control lights ; DI, B2, B3,, AB, B5, 136 are switches that also have this designation in the Circuit diagram described below (see Part IV).

III: PNEUDIATIC CIRCUIT The vacuum pump is labeled PV and connected to the line TV, where TA denotes the compressed air line which is electromagnetically lockable. 4 shows the assembly of the vacuum knife and the pressure gauge. The line TA is connected to a compressed air source and the lines TA and TV both open inside the furnace jacket KA, as well can be seen from FIG. VE denotes a solenoid valve that is operated by the microswitch KK is controlled and the supply of the line TA is only permitted when the furnace is tilted.

IV: WIRING DIAGRAM Referring particularly to FIG. 3, TS is a Electrical transformer referred to by the electrical line LI in known Way is fed to the supply of the electrical resistor RE. With SU is denotes a bell, the ends of which with a controlled by an electric probe SO Temperature controller RT are connected. The switch B1 is a commonly known two-pole one Counter; switch B2 is the oven switch; switch B4 is the vacuum pump switch; the Switch B5 and switch B6 are the control switches of the electric motor MO to to switch the drive chain in one direction or the other.

H1, H2, H3, H4, H5, H6 are control lights for general control or furnace, bell, valcuumpump, furnace swing-out and furnace swing-out control.

The various switches, microswitches, transformers, pyrometers, Control lights are of a known type and therefore do not require any special description; also known s: i.id pressure gauges, pumps and solenoid valves.

V: OPERATING MODE The main switch Bl is switched on; with the Temperature controller RT, the melting temperature is specified, then the bell rings thereby pressing the switch B3 switched on, abandoned the metal, and, after extremely The metal charge in the furnace is melted in a short time (e.g. four minutes). If the oven is to be tilted by hand, it will obviously incline the lever LC towards it operate while switch B5 is to be printed, whereby switch B6 is used to start up. When melting is to start the melting process the switch AB of the vacuum pump is pressed, which is of Stand or can be done automatically.

After the furnace has been overturned, the microswitch is actuated that controls the Solenoid valve opens and actuates, with compressed air entering the furnace to do the filling to support printing. It tends to return to its original position, the Press switch B6. The arms AS-SA work with the microswitches MC-MK-KK together to control the above processes, while the pin PO is a stop element forms.

The activation of the electrical resistance RE is controlled by the temperature controller RT monitored as set out (Fig. 4).

L e r s e i t e

Claims (4)

Claim 1. Electric furnace for the die casting of precious metals thereby marked that it can be operated with one hand (LC) - or automatic, electromotive (B5-B6) control for tilting around a horizontal shaft (A2) is connected, the automatic control with microswitches (MC-MK-KK) cooperates through levers (AS-SA) connected to the furnace tilting shaft (AZ) in a rotationally fixed manner. 2. Electric furnace according to claim 1, characterized in that a vacuum control (PV-TV- Fig. 5) built into the furnace housing or through a (B4) the mentioned microswitch is switched. 3. Electric furnace according to claim 1 and 2, characterized in that the actual furnace (FO) consists of a cylindrical tiltable jacket (KA), DeF inside approaches for holding a bottle connected to the actual oven (cp), the furnace being made of electrical resistances (RE), the refractory Cladding and a graphite crucible and next to the flange mentioned with a cylindrical clamp (GH) to take the enamel impressions Spacer ring (AD) is provided. 4. Electric furnace according to the preceding claims characterized by a lever (BC) for quickly locking the furnace lid (CO), whereby this lever (BC) cooperates with a joint (LL-LL) profiled as two-L twin-like, one articulated end on the furnace lid and the other articulated on the locking lever end, wherein this lever interacts with an adjustable, relatively fixed stop (AR), to compensate for the degree of cover wear.