Coffe Machine Philips HD 5670/A

This seems to be a "mildly old" coffee machine: it has been at my family's home for perhaps 20 years, and I could not find anything on it at internet (besides a complain on a second-hand unit).

It is a bulky unit (almost 30*30*15 cm), which does not use capsules (too modern!): it is a conventional, manual espresso machine. It requires that the granulated and toasted coffee is placed on a cup which is then placed against the steam outlet or grouphead. It also has a separated hot steam supply (the steam wand) for heating the milk (or the water).

Main Parts

The machine has mechanical, hydraulic and electrical parts, in three main systems:

- A pump, which receives (sucks) the water from the water tank and pumps it into a boiler.

- A boiler, which creates pressurized hot steam.

- The electrical controls, with sensors and switches on the other parts.

Besides its very simple control, operation-wise is similar to other coffee machine that I described here.

Schematics

The electrical part is very simple, as indicated in the attached schematics.

The operation is straight: switch S0 starts the machine on/off and the heating resistor (R1), while switch S1 sets the pump in operation (M1), creating the flow of steam. Switch S2 is in parallel to one of the thermal sensors in the boiler (TH4), so it bypasses its function with a kick of additional steam.

The light RD1 (red) is on as soon as the machine is connected (S0), and the light OR1 (orange) is on when the heating resistor is active.

The Pump

The pump is model CS M3637 from Eaton, Mod CP2, with a power of 70 W working at 25-60ºC. It is of the vibrating or solenoid type, described in another post. (Eaton is a giant, and it seems they do not manufacture these pumps anymore; there are a number of internet sites on these pumps and spares: one example here). It is mounted on rubber pads, and it is protected with a thermal fuse (Microtemp 4204A ZKAFZ 98 C; TH2) attached to the body of the pump. (Here on the operation and coding of these thermal fuses, although this one seems to be older).

The Boiler

Made in, in two pieces, bolted (th boiler in aluminium, the grouphead in inox). There is no mark on it. It has a release valve, manually regulated for the steam wand.

The heating resistor (R1) has approx. 43 ohm, which yields a power of some 1,150 W at 220 V (rated 1,260 W).

There are three temperature sensors in contact with the body: two switches from Campini TY60 T180 (TH3 and TH4), and one thermal fuse Microtemp 4300A ZHAHG 152 C (TH1).
(I'm curious about the two thermal switches and the temperature distribution in the boiler, but I have not yet a thermal camera!)

Here on the operation and coding of the thermal fuse, although this one also seems to be older; and here on the specifications of the Campini thermostat switch (“single pole thermostat with snap-action disc”).

The Switches

The three switches are mechanical, of the push type, normally open, with one pole. The manufacturer is ROLD, series CM. S0 and S1 are model E1026 A1 (they retain the closed position when pushed); Switch S2 is model E2015 A1 (does not retain the position when pushed).

ROLD is an Italian manufacturer, a “leader in the manufacture of components for household appliances”. Their webpage does not have catalogues.

Coffee Machine Krups Nespresso XN 2001

A Bit of History
Coffee machines have changed deeply with the appearance of the coffee capsules, not only at home.
The history is interesting: apparently, the idea of coffee capsules was developed at Nestlé in the 70's, but it did not pick-up as business. A second trial in the 80's created Nespresso, which signed contracts with appliance manufacturers to design elegant machines, while Nespresso maintained the name and the supply of the capsules. This confluence created a boom in the market etc. Here the story from Nestlé's side.
The man-behind-the-idea seems to be Eric Favre, not mentioned in the previous link. An engineer at Nestlé, he moved away and created his own company, Monodor, also working on the capsule business (later bought by a Brazilian firm). Here his account.
While in Europe and Asia Nespresso is leader, it seems that in the USA Keurig (K-cups) is their equivalent. There seem to be some design differences between the cups, and one important is that while Nespresso's are made with aluminium, K-cups are in plastic, which raises issues for both. Here a short comparison between the two leaders, and here an article on the recycling issues.

Krups XN 2001
I found this machine thrown on the street: it was missing the receptacle for the capsules, the drip grid and the water tank, but I picked it!

The machine is from Krups, model XN 2001:

The model seems to be retired from production (Amazon), although spares are available (f.eg. here and here).
I have not found the manuals, but these seem to be close enough: Essenza C91,  Essenza C99 and Essenza C100.

Disassembling
Although I didn't intend to use it as a coffee machine, I tried to dismount it cleanly. The base has the usual message saying that there are no serviceable parts inside etc., and the plastic parts are attached with what initially seemed to me rivets. I was surprised because even at the repair workshops a rivet is hard to remove, but I though that the high pressure inside might require extra safety.

So, I broke the covers...
... Now I have found that they are screws, not rivets, and that they can be hacked (here and here). The special screws can even be bought in Amazon!

Some pictures of the disassembling process and parts:

The final result after removal of all supporting and protecting elements and the pipes:

Main Parts
The machine has mechanical, hydraulic and control systems, in four main parts:
- A pump, which receives the water from the water tank and pumps it into a boiler,
- A boiler, which creates a pressurized flow of hot water and steam,
- The piston which compresses the coffee capsule and allows the water to go through it,
- An electronic motherboard, with sensors and switches on the other parts.

Schematics
Without the details of the mother board (see below):

Parts
Vibrating Pump
The pump is of the vibrating or solenoid type, from Invensys, model CL7.
The operational principle can be seen in this video. The reason why such pump type is selected (which I never had heard of before) is probably the size and the pressure they can deliver, as explained in this other video.
Invensys, an Italian company, used to be part of Schneider Electric, an European giant, and was purchased in 2011 by ARS, a specialist firm.
The model of the machine seems to be out of production. I have not found the datasheet, but these ones from ARS might be similar.
Neither the pressure nor the volume flow is indicated in the label. From ARS' datasheets it seems that this pump can provide 200 ml/min against a back-pressure of 10 bar. It is also self-priming.
Interestingly, it requires 1.5-2 min off for each minute of operation, probably due to overheating. (It is worthy noting that the manuals don't mention this).

A temperature fuse is attached to the body of the pump. It is labelled: "MICROTEMP SVABGB E5A00 Tf 128 C". The specifications of these fuses can be found here. Although the coding seems to be modified, the fuse seems to have a nominal amperage of 20 A, and a functioning temperature of 128 ºC (which I find both surprisingly high: if the body of the motor is at 128 ºC, how hot will it be inside before the fuse works?)

Boiler/Heater
It is an aluminium body with a plastic base, and a series of connectors. The base can be removed (it is screwed) but the chassis is in one piece.
On the chassis it is labelled as EF1308, 230V 1200W. I have not found any other information.

The water inlet is on the top (of the picture), and the outlet at the bottom, in opposed corners of the chassis. Both are in brass-like alloy, 4 mm outer diam.
Close to the inlet and outlet, and at a slight angle, there are the connecting ends of what seems to be the heating resistor (measured approx. 50 ohm, or 4.9 A for the nominal 1200 W mentioned in the chassis and one of the sheaths of the resistor).

The line (brown cable) and neutral (blue cable) are connected (thermally) to the chassis through sheathed thermal fuses similar to the one described above (but here Tf=167ºC). 

The chassis is grounded. This is the only piece of the machine which is grounded, which I find surprising considering that it handles liquids.
Finally, in one corner of the chassis another sensor is fixed, likely to measure temperature (perhaps an NTC thermistor within the body of a bolt).

The water is transported through flexible pipes with quick fittings:

The Piston
The piston mechanically, manually, compresses the coffee capsule and places it into a suitable socket. It also perforates the capsule and allows the hot water/steam pumped through the boiler to lixiviate the coffee and fall into the cup through the beak.
There is no sensor for the correct positioning of the capsule or the closing of the receptacle.

The Motherboard

The motherboard has some separated groups:
- The heater resistor is fed from a triac in TO-220 package attached to a large heat sink. It is labelled as BTB12 600BW from ST. The datasheet is here. The gate of this triac is controlled from a microcontroller PIC16F676 whose datasheet is here.

- The pump is controlled from a small triac BT134W in SOT-223 package. The datasheet is here. Main terminal 2 (4) is directly linked to the pump, while terminal 1 goes to line, with a 220 uF electrolytic capacitor in parallel. The gate goes through SMDs that I cannot completely track (but see below).

- The power line is also protected with a capacitor CV75K10 (varistor, from Keko; datasheet here).
- Two additional film capacitors type PCX2 337 MKII with 470 nF and 220 nF protect the microcontroller (datasheet).
- The two moment touch switches are in separated modules, with rubber cups, and one LED in the selector of the coffee brewing.

I am not sure about several SMDs, and some connections may be missing, but the schematics of the motherboard (seen from behind) is probably something similar to this:

Microwave Oven Daewoo

A Daewoo Microwave Oven
In a previous page I have reviewed in some detail a microwave oven (Teka MW170).
I have found at home the electrical parts of another microwave oven, whose origin I do not remember, likely recollected from some street. It seems of the Daewoo brand.

I will review here the electrical parts, referring to the previous page for the common elements.

Wiring Diagram
The wiring diagram that I have prepared from the parts and the circuit is this one:

The diagram is incomplete as the timer/power motors are missing, but the connectors are there.

Parts
Power Source
While the Teka 170 had just a fuse, this one has a filter unit for high frequencies.
The board is labelled DWLF-M13 SS.

The fuse is rated 15 A at 250 V.
R1 is 1.5 Mohm
C1 is a film capacitor from Pilkor, box shaped, PCX2 335M MKP, with 100 nF, tolerance class M.
C2 and C3 are labelled "NW 222 MX1Y2", ceramic capacitors for interference filtering (X1Y2), 2.2 nF and tolerance class M.
No clue about L1...

Switches
S1, S3: from Gersun, GSM V1603A2, 16 A at 250 VAC, SPST NO,
S2: from Starion, SZM V16-FA-61, 16 A at 250 VAC, SPDT.

S4: from Starion, SZM V16-FA-63, 16 A at 250 VAC, SPST NO.

Thermal Swiches

Labelled:

- TH1: NT101 KTE, N1CO 90 5331

- TH2: NT101 KTE, N65 75 5324.

I have no information on where they were installed. From the wiring diagram it seems TH2 is on on the magnetron, the other in the oven's food compartment.

Turn-table Motor

Synchronous motor from GPS Corp. 5-6 rpm, 3-2.5 W, 220-240 V. Model ST-16 MN73MQAD.

Daewoo sees to use them frequently (f.eg. here).

Fan Motor
Motor shaded pole, with no references.
The motor was covered in grease, so either the ventilation was crappy, or the users of the oven were doing heavy cooking...

(Sorry, the plate was under the grease! Manufactured by Daewoo Electronics Corp. Label: "MV10CA, M02, 230 V 50 Hz,  0.28 A max, Z.P. B Class").

The motor runs an axial fan (on the Teka it was a centrifugal fan). Impeller diam. 11 cm.

Timer and Power Switch

The mechanism (motor) activating the timer is not in the parts that I have, just the geared switch and selector. 

One of the switches (TIM1) is normally off, and is set on when the time selector is moved from its zero position.

The function of the other switch (POW1) is unclear to me.

Transformer Feed

The power supply to the transformer is regulated by a small board, whose main element is a relay.

The board is labelled as "DWSR 1".

The relay, from Texcell, is model KH, contact arrangement 11 (form A, SPST-NO), termination TMP (for PCB), E-24H. Specifications are likely similar to these ones. 

It is unclear to me the operation of this relay. The model seems out of manufacture, and I have not found direct references to it. As per one catalog from Texcell for similar relays,  the schematics would be:

Based on this, the scheme of the regulating relay would be:

 

Transformer, Capacitor and Magnetron

The transformer is from Daewoo Electronics Copr., with no indication of ratings (230 V, 50 Hz, Class 220, R1S80).

The HV capacitor has a capacity of 0.98 uF, rated at 2100 V, with an internal resistor of 10 MOhm.

The diode is marked "C1 01" (or, perhaps, "1010").

The fuse is marked as: " 5 kV, 550 mA".

Finally, the magnetron is from Daewoo, 2M218 50323AN JF.