wefalck

Manufactured housing spindle. To be continued...

Actually, on the real thing there were no treenails in the decks. What you see (or rather mostly not, except when really standing on a deck) are wooden plugs that cover the holes drilled for iron bolts (at least in later ships). The plugs do not show end-grain (as would treenails do) but were cut so that the grain runs in the same direction as the planks. The idea was to make them almost invisible for  aesthetic reasons.
 
It seems to be a fashion among modellers to use treenails to show how much effort they put into a model. There is also some mechanical reason, as the treenail securely fastens the plank. Otherwise, I would ignore them on a true 'scale' model.
 
wefalck

Actually, on the real thing there were no treenails in the decks. What you see (or rather mostly not, except when really standing on a deck) are wooden plugs that cover the holes drilled for iron bolts (at least in later ships). The plugs do not show end-grain (as would treenails do) but were cut so that the grain runs in the same direction as the planks. The idea was to make them almost invisible for  aesthetic reasons.
 
It seems to be a fashion among modellers to use treenails to show how much effort they put into a model. There is also some mechanical reason, as the treenail securely fastens the plank. Otherwise, I would ignore them on a true 'scale' model.
 
wefalck

Actually, on the real thing there were no treenails in the decks. What you see (or rather mostly not, except when really standing on a deck) are wooden plugs that cover the holes drilled for iron bolts (at least in later ships). The plugs do not show end-grain (as would treenails do) but were cut so that the grain runs in the same direction as the planks. The idea was to make them almost invisible for  aesthetic reasons.
 
It seems to be a fashion among modellers to use treenails to show how much effort they put into a model. There is also some mechanical reason, as the treenail securely fastens the plank. Otherwise, I would ignore them on a true 'scale' model.
 
wefalck

I gather you meant to grind the point of the needle flat ? What do you mean by 'deactivate the safety on the syringes' ?. Normally, the needle detach easily by turning them and pulling. Some also have a so-called Luer-Lock mechanism, which is short thread. You just turn the needle and it comes off.

Some travel got into the way of progressing this project and on reporting on it ….
 
******************************
 
In order to mount the y-axis to the column, an adapter is needed. This adapter is fashioned from a small aluminium-block that was bored for the 20 mm column. The top-side was milled to a close fit on the lower slide from the WW-lathe, which is clamped down with a bolt. In this way the lower slide can be moved by about 15 mm, giving a greater depth of throat, if needed. It was planned to use a rectangular key to lock the adapter to the column. However, it appears that the two set-screws lock it sufficiently secure to the column. Practical experience will show whether this is true.
 

Drilling the adapter for the y-axis
 
The 20 mm-hole was drilled and bored on a face-plate in the lathe to ensure that it is exactly vertical to the top and bottom of the adapter block. The aluminium-block was srewed down onto the face-plate using a 6 mm hexagonal bolt. Luckily, a suitable hole was needed anyway for the locking bolt of the slide. Other hexagonal bolts prevent the block from moving during the machining operations and act as counter-weights.
 

Boring the adapter for the y-axis
 
After the functional machining was complete, the adapter was 'beautified' by giving the edges a half-round camfer. For occasional jobs on aluminium like this, I use cheap woodworking router bits ... don't tell any real mechanic.
 

Camfering the adapter for the y-axis
 

Finished adapter block
The Lorch, Schmidt & Co. milling attachment will be held between two angle-irons screwed-down onto the slide. The locking will be effected by an excentric bolt acting as a cam. I had hoped to use the threaded holes that a previous owner of the slide had made, but they did not fit the angle-iron I had in my stock, so new holes had to be drilled and tapped. The pair of angle-irons was squared and trued on the mill using a fly-cutter.
 

Squaring and trueing angle-irons in pairs
 

Angle-irons to hold milling-head
 

Angle-irons to hold milling-head
 
The above picture shows also the drive unit made for the toolpost-grinder of the WW-lathe, which in fact looks very similar to what the future motorised milling head will look like.
 

Provisional set-up of motorised milling head
 
 
To be continued ...

Some travel got into the way of progressing this project and on reporting on it ….
 
******************************
 
In order to mount the y-axis to the column, an adapter is needed. This adapter is fashioned from a small aluminium-block that was bored for the 20 mm column. The top-side was milled to a close fit on the lower slide from the WW-lathe, which is clamped down with a bolt. In this way the lower slide can be moved by about 15 mm, giving a greater depth of throat, if needed. It was planned to use a rectangular key to lock the adapter to the column. However, it appears that the two set-screws lock it sufficiently secure to the column. Practical experience will show whether this is true.
 

Drilling the adapter for the y-axis
 
The 20 mm-hole was drilled and bored on a face-plate in the lathe to ensure that it is exactly vertical to the top and bottom of the adapter block. The aluminium-block was srewed down onto the face-plate using a 6 mm hexagonal bolt. Luckily, a suitable hole was needed anyway for the locking bolt of the slide. Other hexagonal bolts prevent the block from moving during the machining operations and act as counter-weights.
 

Boring the adapter for the y-axis
 
After the functional machining was complete, the adapter was 'beautified' by giving the edges a half-round camfer. For occasional jobs on aluminium like this, I use cheap woodworking router bits ... don't tell any real mechanic.
 

Camfering the adapter for the y-axis
 

Finished adapter block
The Lorch, Schmidt & Co. milling attachment will be held between two angle-irons screwed-down onto the slide. The locking will be effected by an excentric bolt acting as a cam. I had hoped to use the threaded holes that a previous owner of the slide had made, but they did not fit the angle-iron I had in my stock, so new holes had to be drilled and tapped. The pair of angle-irons was squared and trued on the mill using a fly-cutter.
 

Squaring and trueing angle-irons in pairs
 

Angle-irons to hold milling-head
 

Angle-irons to hold milling-head
 
The above picture shows also the drive unit made for the toolpost-grinder of the WW-lathe, which in fact looks very similar to what the future motorised milling head will look like.
 

Provisional set-up of motorised milling head
 
 
To be continued ...

Some travel got into the way of progressing this project and on reporting on it ….
 
******************************
 
In order to mount the y-axis to the column, an adapter is needed. This adapter is fashioned from a small aluminium-block that was bored for the 20 mm column. The top-side was milled to a close fit on the lower slide from the WW-lathe, which is clamped down with a bolt. In this way the lower slide can be moved by about 15 mm, giving a greater depth of throat, if needed. It was planned to use a rectangular key to lock the adapter to the column. However, it appears that the two set-screws lock it sufficiently secure to the column. Practical experience will show whether this is true.
 

Drilling the adapter for the y-axis
 
The 20 mm-hole was drilled and bored on a face-plate in the lathe to ensure that it is exactly vertical to the top and bottom of the adapter block. The aluminium-block was srewed down onto the face-plate using a 6 mm hexagonal bolt. Luckily, a suitable hole was needed anyway for the locking bolt of the slide. Other hexagonal bolts prevent the block from moving during the machining operations and act as counter-weights.
 

Boring the adapter for the y-axis
 
After the functional machining was complete, the adapter was 'beautified' by giving the edges a half-round camfer. For occasional jobs on aluminium like this, I use cheap woodworking router bits ... don't tell any real mechanic.
 

Camfering the adapter for the y-axis
 

Finished adapter block
The Lorch, Schmidt & Co. milling attachment will be held between two angle-irons screwed-down onto the slide. The locking will be effected by an excentric bolt acting as a cam. I had hoped to use the threaded holes that a previous owner of the slide had made, but they did not fit the angle-iron I had in my stock, so new holes had to be drilled and tapped. The pair of angle-irons was squared and trued on the mill using a fly-cutter.
 

Squaring and trueing angle-irons in pairs
 

Angle-irons to hold milling-head
 

Angle-irons to hold milling-head
 
The above picture shows also the drive unit made for the toolpost-grinder of the WW-lathe, which in fact looks very similar to what the future motorised milling head will look like.
 

Provisional set-up of motorised milling head
 
 
To be continued ...

Some travel got into the way of progressing this project and on reporting on it ….
 
******************************
 
In order to mount the y-axis to the column, an adapter is needed. This adapter is fashioned from a small aluminium-block that was bored for the 20 mm column. The top-side was milled to a close fit on the lower slide from the WW-lathe, which is clamped down with a bolt. In this way the lower slide can be moved by about 15 mm, giving a greater depth of throat, if needed. It was planned to use a rectangular key to lock the adapter to the column. However, it appears that the two set-screws lock it sufficiently secure to the column. Practical experience will show whether this is true.
 

Drilling the adapter for the y-axis
 
The 20 mm-hole was drilled and bored on a face-plate in the lathe to ensure that it is exactly vertical to the top and bottom of the adapter block. The aluminium-block was srewed down onto the face-plate using a 6 mm hexagonal bolt. Luckily, a suitable hole was needed anyway for the locking bolt of the slide. Other hexagonal bolts prevent the block from moving during the machining operations and act as counter-weights.
 

Boring the adapter for the y-axis
 
After the functional machining was complete, the adapter was 'beautified' by giving the edges a half-round camfer. For occasional jobs on aluminium like this, I use cheap woodworking router bits ... don't tell any real mechanic.
 

Camfering the adapter for the y-axis
 

Finished adapter block
The Lorch, Schmidt & Co. milling attachment will be held between two angle-irons screwed-down onto the slide. The locking will be effected by an excentric bolt acting as a cam. I had hoped to use the threaded holes that a previous owner of the slide had made, but they did not fit the angle-iron I had in my stock, so new holes had to be drilled and tapped. The pair of angle-irons was squared and trued on the mill using a fly-cutter.
 

Squaring and trueing angle-irons in pairs
 

Angle-irons to hold milling-head
 

Angle-irons to hold milling-head
 
The above picture shows also the drive unit made for the toolpost-grinder of the WW-lathe, which in fact looks very similar to what the future motorised milling head will look like.
 

Provisional set-up of motorised milling head
 
 
To be continued ...

Some travel got into the way of progressing this project and on reporting on it ….
 
******************************
 
In order to mount the y-axis to the column, an adapter is needed. This adapter is fashioned from a small aluminium-block that was bored for the 20 mm column. The top-side was milled to a close fit on the lower slide from the WW-lathe, which is clamped down with a bolt. In this way the lower slide can be moved by about 15 mm, giving a greater depth of throat, if needed. It was planned to use a rectangular key to lock the adapter to the column. However, it appears that the two set-screws lock it sufficiently secure to the column. Practical experience will show whether this is true.
 

Drilling the adapter for the y-axis
 
The 20 mm-hole was drilled and bored on a face-plate in the lathe to ensure that it is exactly vertical to the top and bottom of the adapter block. The aluminium-block was srewed down onto the face-plate using a 6 mm hexagonal bolt. Luckily, a suitable hole was needed anyway for the locking bolt of the slide. Other hexagonal bolts prevent the block from moving during the machining operations and act as counter-weights.
 

Boring the adapter for the y-axis
 
After the functional machining was complete, the adapter was 'beautified' by giving the edges a half-round camfer. For occasional jobs on aluminium like this, I use cheap woodworking router bits ... don't tell any real mechanic.
 

Camfering the adapter for the y-axis
 

Finished adapter block
The Lorch, Schmidt & Co. milling attachment will be held between two angle-irons screwed-down onto the slide. The locking will be effected by an excentric bolt acting as a cam. I had hoped to use the threaded holes that a previous owner of the slide had made, but they did not fit the angle-iron I had in my stock, so new holes had to be drilled and tapped. The pair of angle-irons was squared and trued on the mill using a fly-cutter.
 

Squaring and trueing angle-irons in pairs
 

Angle-irons to hold milling-head
 

Angle-irons to hold milling-head
 
The above picture shows also the drive unit made for the toolpost-grinder of the WW-lathe, which in fact looks very similar to what the future motorised milling head will look like.
 

Provisional set-up of motorised milling head
 
 
To be continued ...

Some travel got into the way of progressing this project and on reporting on it ….
 
******************************
 
In order to mount the y-axis to the column, an adapter is needed. This adapter is fashioned from a small aluminium-block that was bored for the 20 mm column. The top-side was milled to a close fit on the lower slide from the WW-lathe, which is clamped down with a bolt. In this way the lower slide can be moved by about 15 mm, giving a greater depth of throat, if needed. It was planned to use a rectangular key to lock the adapter to the column. However, it appears that the two set-screws lock it sufficiently secure to the column. Practical experience will show whether this is true.
 

Drilling the adapter for the y-axis
 
The 20 mm-hole was drilled and bored on a face-plate in the lathe to ensure that it is exactly vertical to the top and bottom of the adapter block. The aluminium-block was srewed down onto the face-plate using a 6 mm hexagonal bolt. Luckily, a suitable hole was needed anyway for the locking bolt of the slide. Other hexagonal bolts prevent the block from moving during the machining operations and act as counter-weights.
 

Boring the adapter for the y-axis
 
After the functional machining was complete, the adapter was 'beautified' by giving the edges a half-round camfer. For occasional jobs on aluminium like this, I use cheap woodworking router bits ... don't tell any real mechanic.
 

Camfering the adapter for the y-axis
 

Finished adapter block
The Lorch, Schmidt & Co. milling attachment will be held between two angle-irons screwed-down onto the slide. The locking will be effected by an excentric bolt acting as a cam. I had hoped to use the threaded holes that a previous owner of the slide had made, but they did not fit the angle-iron I had in my stock, so new holes had to be drilled and tapped. The pair of angle-irons was squared and trued on the mill using a fly-cutter.
 

Squaring and trueing angle-irons in pairs
 

Angle-irons to hold milling-head
 

Angle-irons to hold milling-head
 
The above picture shows also the drive unit made for the toolpost-grinder of the WW-lathe, which in fact looks very similar to what the future motorised milling head will look like.
 

Provisional set-up of motorised milling head
 
 
To be continued ...

Some travel got into the way of progressing this project and on reporting on it ….
 
******************************
 
In order to mount the y-axis to the column, an adapter is needed. This adapter is fashioned from a small aluminium-block that was bored for the 20 mm column. The top-side was milled to a close fit on the lower slide from the WW-lathe, which is clamped down with a bolt. In this way the lower slide can be moved by about 15 mm, giving a greater depth of throat, if needed. It was planned to use a rectangular key to lock the adapter to the column. However, it appears that the two set-screws lock it sufficiently secure to the column. Practical experience will show whether this is true.
 

Drilling the adapter for the y-axis
 
The 20 mm-hole was drilled and bored on a face-plate in the lathe to ensure that it is exactly vertical to the top and bottom of the adapter block. The aluminium-block was srewed down onto the face-plate using a 6 mm hexagonal bolt. Luckily, a suitable hole was needed anyway for the locking bolt of the slide. Other hexagonal bolts prevent the block from moving during the machining operations and act as counter-weights.
 

Boring the adapter for the y-axis
 
After the functional machining was complete, the adapter was 'beautified' by giving the edges a half-round camfer. For occasional jobs on aluminium like this, I use cheap woodworking router bits ... don't tell any real mechanic.
 

Camfering the adapter for the y-axis
 

Finished adapter block
The Lorch, Schmidt & Co. milling attachment will be held between two angle-irons screwed-down onto the slide. The locking will be effected by an excentric bolt acting as a cam. I had hoped to use the threaded holes that a previous owner of the slide had made, but they did not fit the angle-iron I had in my stock, so new holes had to be drilled and tapped. The pair of angle-irons was squared and trued on the mill using a fly-cutter.
 

Squaring and trueing angle-irons in pairs
 

Angle-irons to hold milling-head
 

Angle-irons to hold milling-head
 
The above picture shows also the drive unit made for the toolpost-grinder of the WW-lathe, which in fact looks very similar to what the future motorised milling head will look like.
 

Provisional set-up of motorised milling head
 
 
To be continued ...

Some travel got into the way of progressing this project and on reporting on it ….
 
******************************
 
In order to mount the y-axis to the column, an adapter is needed. This adapter is fashioned from a small aluminium-block that was bored for the 20 mm column. The top-side was milled to a close fit on the lower slide from the WW-lathe, which is clamped down with a bolt. In this way the lower slide can be moved by about 15 mm, giving a greater depth of throat, if needed. It was planned to use a rectangular key to lock the adapter to the column. However, it appears that the two set-screws lock it sufficiently secure to the column. Practical experience will show whether this is true.
 

Drilling the adapter for the y-axis
 
The 20 mm-hole was drilled and bored on a face-plate in the lathe to ensure that it is exactly vertical to the top and bottom of the adapter block. The aluminium-block was srewed down onto the face-plate using a 6 mm hexagonal bolt. Luckily, a suitable hole was needed anyway for the locking bolt of the slide. Other hexagonal bolts prevent the block from moving during the machining operations and act as counter-weights.
 

Boring the adapter for the y-axis
 
After the functional machining was complete, the adapter was 'beautified' by giving the edges a half-round camfer. For occasional jobs on aluminium like this, I use cheap woodworking router bits ... don't tell any real mechanic.
 

Camfering the adapter for the y-axis
 

Finished adapter block
The Lorch, Schmidt & Co. milling attachment will be held between two angle-irons screwed-down onto the slide. The locking will be effected by an excentric bolt acting as a cam. I had hoped to use the threaded holes that a previous owner of the slide had made, but they did not fit the angle-iron I had in my stock, so new holes had to be drilled and tapped. The pair of angle-irons was squared and trued on the mill using a fly-cutter.
 

Squaring and trueing angle-irons in pairs
 

Angle-irons to hold milling-head
 

Angle-irons to hold milling-head
 
The above picture shows also the drive unit made for the toolpost-grinder of the WW-lathe, which in fact looks very similar to what the future motorised milling head will look like.
 

Provisional set-up of motorised milling head
 
 
To be continued ...

Yes, having them alongside the boat on some blocks or trestles sounds a good idea.

Yes, having them alongside the boat on some blocks or trestles sounds a good idea.

Yes, having them alongside the boat on some blocks or trestles sounds a good idea.

Yes, having them alongside the boat on some blocks or trestles sounds a good idea.

Yes, having them alongside the boat on some blocks or trestles sounds a good idea.

Yes, having them alongside the boat on some blocks or trestles sounds a good idea.

Yes, having them alongside the boat on some blocks or trestles sounds a good idea.

Yes, having them alongside the boat on some blocks or trestles sounds a good idea.

Yes, having them alongside the boat on some blocks or trestles sounds a good idea.

The maker of the miniature Bridgeport is the British model engineer Barry Jordan: http://www.craftsmanshipmuseum.com/jordan.htm
 
@hof00: Proxxon (and all the other makers of small milling machines) don't make a machine of the Aciera/Sixis/SIP type as I discussed above. They all are conventional 3-axis-machines, to which perhaps a fourth axis can be added by deploying a rotary table or a dividing head. Even the smallest Proxxon, the MF70, still is somewhat bigger than what I am building here.
 
Updates will follow over the weekend, didn't have time to take and process the pictures yet.

Actually, I wanted to continue with my SMS WESPE model, but run into some technical difficulties and then this project came my way ...
 
The complex manual machining of very small parts on a milling machine requires smooth and precise movements of the slides as well as small masses to be moved. The slides of a watchmakers lathe fulfill these requirements. In addition, work-pieces and tools should be visible very well during machining.
 
Milling machines such as the Aciere F1 (or the older F12) or Sixis 101 are ideal for working on small parts, but are still far too large for my workshop (and have a too big price tag ...). Interesting from a design point of view would be also jig-borer and milling-machines by SIP (Société Genevoise d'Instruments de Physique), but they are very rare and difficult to come by. All these machines are massive and heavily constructed in order minimise vibrations by their inertia during the machining of precision parts for watches and instruments – too massive for my small workshop.
 

Aciera F1 milling machine (Source: http://www.lathes.co.uk/aciera/)
 

Sixis 101 milling machine (Source: http://www.lathes.co.uk/sixis/)
 

SIP jig-borer and milling machine  (Quelle: http://www.lathes.co.uk/sip/)
 
A special feature of these machines is that the x-slide is not arranged horizontally under the milling spindle, but vertically in front of the main column. This permits the easy installation of a fourth and fifth machining axis.  However, this arrangement means that the movement in the y-axis is not effected by the cross-slide, but by the milling head. This in turn means that milling head and motor should ideally form a unit. A belt-drive is more difficult to arrange, because the angle between the pulleys changes, when the milling head moves along. The SIP jig-borer for these reason originally was driven through a flexible shaft.
A watchmakers lathe is a good starting point owing to the precision of the slides and spindles, but it lacks the z-axis. In more recent years kits became available to convert Chinese-made watchmakers lathes into small vertical milling machines, but the milling table on them is arranged in a conventional way.
 

Conversion of a modern Chinese watchmakers lathe into a vertical milling machine
 
In my stock of watchmakers lathe bits and pieces I have collected over the years parts for several D-bed lathes of variable state of conservation. Some ‘scrap’ was also bought on purpose. From this parts I now want to construct a micro-milling machine with as little work as possible.
As design specifications I decided that the mill should be able to machine in a space of u 20 mm x 20 mm x 20 mm. This requires movements along the x-, y-, and z-axes of around 40 mm. There should be a fourth axis with a 360° rotation, that should be able to rotated under load. This axis should also be able to be moved from the vertical into the horizontal (5th axis). All those movements should be realised with parts from watchmakers lathes, so that no dove-tail slides need to be machined from scratch.
The back-bone of the mill will be a special D-bed that I obtained recently. It was originally meant for the conversion of a lathe into a small precision pillar-drill. Its lower end is turned down to a diameter that fits into a lathe foot. The foot that I am going to use probably came from a British Pultra-lathe (http://www.lathes.co.uk/pultra/page8.html).
 

Column and foot
 
Another key part is an old and somewhat battered cross-slide from a Lorch, Schmidt & Co. D-bed lathe. This will be the x- and z-axis of the new milling machine.
 
Cross-slide from a D-bed watchmakers lathe
 
The y-axis will be constructed with the help of a nearly scrap lower-slide from the cross-slide of a Lorch, Schmidt & Co. WW-lathe that I was able to buy cheaply. The spindle and micrometer-dial will have to be made from scratch. A 6 mm-grinding spindle of unknown make will serve as milling spindle. This limits somewhat the maximum diameter of cutters that can be used to ones with about a 4 mm-shaft, but the machine is meant for light work after all. On the other hand, many years ago I made an adapter for 6 mm end-mill for use in the lathe together with a vertical slide (before I owned a milling machine).
 

Lower slide from a WW-lathe cross-slide and grinding spindle
 

Future arrangement for the y-axis of the micro-mill
 
The fourth and fifth axis will be formed by the dividing head that I made some years ago from a 6 mm-watchmakers lathe grinding-spindle. For the moment it will be simply screwed onto the cross-slide as for use with a lathe. This gives considerable flexibility for the positioning at any angle between vertical and horizontal. The setting will be a bit time-consuming and has to be done with templates.
 

Column, cross-slide and dividing head assembled
 

Column, cross-slide and dividing head assembled
 
So far the existing parts that need to be re-conditioned somewhat at a later point in time.
 
To be continued ...

The maker of the miniature Bridgeport is the British model engineer Barry Jordan: http://www.craftsmanshipmuseum.com/jordan.htm
 
@hof00: Proxxon (and all the other makers of small milling machines) don't make a machine of the Aciera/Sixis/SIP type as I discussed above. They all are conventional 3-axis-machines, to which perhaps a fourth axis can be added by deploying a rotary table or a dividing head. Even the smallest Proxxon, the MF70, still is somewhat bigger than what I am building here.
 
Updates will follow over the weekend, didn't have time to take and process the pictures yet.