Nexy Designer's Diary

[Nexy designer]

The following is a translation of an article I previously posted on a Korean community forum.
It’s a supplementary explanation about why blades are usually constructed with an odd number of plies.

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I have written before about different aspects of blade making, but I thought it might be helpful to go deeper into the topic of ply numbers, so I’m sharing this article.


As a blade designer for Nexy, I always feel a certain caution when writing articles like this. Information needs to be shared at a level that’s helpful, but not so detailed that it fuels excessive curiosity or equipment obsession. I’m also wary of the possibility that people who used to make blades without much understanding might start gaining systematic knowledge through my writing.


Still, my job is to share information and keep pushing beyond what I’ve already shared. If I just hold on to what I know, Nexy’s growth will slow. That’s why I’ve chosen to be bold in opening up this knowledge.

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Odd-number ply construction​

Table tennis blades are generally made with an odd number of plies.
Of course, there are exceptions such as single-ply blades (typical of Japanese penhold, e.g. hinoki one-ply), or three-ply blades (like Tibhar’s well-known hinoki blade H-3-9).
But the more common structures are five-ply and seven-ply.


With the advent of synthetic materials, when these are counted as one ply, a five-ply with synthetic material becomes equivalent to seven-ply, and a seven-ply with synthetic material becomes nine-ply.
There are also rare cases of 11-ply or 13-ply constructions, and some companies promote multiple carbon layers. But unless it’s a very specific case (like Tibhar’s Quad Wing series), adding many layers usually brings no real advantage.


From here, a few natural questions arise:

1. Why are Japanese penhold blades made with one single hinoki ply?
2. Why are there virtually no even-ply blades? (Tibhar’s IV-L is a rare four-ply example.)
3. Why is the five-ply structure regarded as the “standard” composition for blades?
4. Why is the seven-ply considered a “reinforced” version of the five-ply, especially for speed?
5. Why are nine-ply, eleven-ply and other high-ply all-wood blades so rare?

In this article, I’ll try to answer these five questions step by step.

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​

1. Why is a Japanese penhold blade with hinoki made from a single ply?​

In the past, some players who used one-ply hinoki penhold blades were so impressed with their power that they assumed hinoki itself was an inherently fast material. That’s actually a misunderstanding. The kind of hinoki used for one-ply penhold blades is quite soft and not particularly fast by nature. The speed comes from the thickness—about 10 mm—used in these blades, which allows hinoki’s unique “gripping” feel to be preserved while also giving sufficient pace.


If we were to make a shakehand blade of standard thickness (about 6 mm) from a single ply of hinoki, it would be extremely slow. But the reason thin one-plies are avoided is not only speed—it’s also about durability.


When you make a blade from a single piece of wood, the biggest issue is that over time the wood can warp or crack as it dries. Hinoki, with its distinct grain, tends to twist if the grain lies horizontally. To minimize this, a thick cut is required, and vertical grain orientation is preferred. Vertical grain reduces the risk of shrinkage and also improves performance: blades cut with diagonal or off-grain hinoki often produce weak shots and unpleasant vibration.


Another crucial step is long, careful drying. At Nexy, we use wood that has been processed into board form and then dried over an extended period, so by the time we make blades, most deformation has already occurred. Even so, if the grain isn’t straight or if the wood is too thin, warping risk remains, which is why single-ply blades are made from thicker material.


Other woods, because of higher risk of deformation, are rarely used for one-plies. An exception is Ayous, which has little grain structure and resists humidity changes. For this reason Galaxy/Yinhe makes some Ayous one-plies. In Korea, where summer and winter differ greatly in temperature and humidity, material choices are even more limited.


(A useful analogy: the soundboard of a grand piano, often made of spruce. Seasonal humidity changes in Korea frequently cause soundboards to crack. High-end pianos have built-in humidity control, but in winter it’s still common for soundboards to split. Similarly, wood stability is critical in blade construction.)

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2. Why are there almost no even-ply blades?​

To prevent warping more effectively, multiple plies are glued together with alternating grain directions. Since wood fibers usually run lengthwise, they shrink in that direction as they dry. Crossing the grains balances the forces and prevents warping.


This leads to the answer: the center ply must be lengthwise grain and as solid as possible, because it transmits ball impact cleanly to the handle. If the center ply were cross-grain, the feedback would be cut off mid-blade. That’s why the middle ply is always vertical grain.


Then comes the second ply in cross-grain, and finally the outer ply in vertical grain. This way the user feels the ball’s impact transmitted naturally down to the handle. It also looks and feels more consistent.


If you build an even-ply blade, the problem is at the center. You’d have to put two vertical-grain plies in the middle. These two could move together in one direction, overpowering the outer plies and causing warpage. If you cross them, then the outer plies end up mismatched, creating asymmetry and again leading to warping. That’s why odd-ply is the rule.


At Nexy, some 5th-generation blades (like Chakra, Arke) use front and back surfaces with different compositions—a bold attempt at asymmetry. When I first designed the Mushiro blade, Tibhar warned it might warp because of the asymmetry. But I had confidence: the core wood was stable, the outer plies were thin, and the carbon layer was placed at one-third depth. The result: no warping, and a success.


Now, with the 5th generation, we’ve refined this know-how. Other brands might fail if they copy it blindly. You could say one of the reasons our 5th generation represents the culmination of a decade’s work is precisely our ability to realize stable asymmetry in blade design.

 

[SDC]

To prevent warping more effectively, multiple plies are glued together with alternating grain directions. Since wood fibers usually run lengthwise, they shrink in that direction as they dry. Crossing the grains balances the forces and prevents warping.

Citing yourself does not make your statements true. Specially this part about shrinkage is incorrect. These are not my words but from other trusted sources:

"Wood shrinkage is the reduction in a wood's dimensions as it loses moisture, occurring when the moisture content drops below the fiber saturation point (around 30%). This moisture loss causes wood to contract, with shrinkage happening most significantly in the tangential direction (along the growth rings), less in the radial direction (perpendicular to the rings), and negligibly in the longitudinal (parallel to the grain) direction. The amount of shrinkage varies by wood species and is an important consideration in construction and woodworking to prevent warping, cracking, and joint movement."

And to support my previous statement that wood's mechanical properties vary a lot with the direction:

" Wood's mechanical properties are its responses to external forces, which vary significantly with the direction of the grain due to its orthotropic nature. Key properties include stiffness (resistance to bending), tensile strength (resistance to pulling apart), compressive strength (resistance to crushing), shearing strength (resistance to forces that cause sliding), toughness (resistance to impact), and hardness (resistance to indentation). These properties are influenced by wood density, fiber length, and the angle of the grain deviation from the longitudinal axis.

Mechanical Properties by Direction
Wood has three principal axes along which its mechanical properties differ significantly:

• Longitudinal (L) Axis: Parallel to the wood fibers (the grain direction).
• Radial (R) Axis: Perpendicular to the growth rings, also perpendicular to the grain.
• Tangential (T) Axis: Tangent to the growth rings and perpendicular to the grain.

How Grain Direction Affects Properties

• Strength: Wood is strongest when loaded parallel to the grain (longitudinally) and weakest when loaded perpendicular to it. For example, tensile strength is much higher parallel to the grain than perpendicular to it.
  
  
• Stiffness: Similarly, wood is stiffer when the load is applied parallel to the grain.
  
  
• Grain Deviation: An increase in the angle of the grain deviation from the longitudinal axis (slope grain) significantly decreases wood's bending strength, an effect seen across different wood types. "

 

[Nexy designer]

Citing yourself does not make your statements true. Specially this part about shrinkage is incorrect. These are not my words but from other trusted sources:

"Wood shrinkage is the reduction in a wood's dimensions as it loses moisture, occurring when the moisture content drops below the fiber saturation point (around 30%). This moisture loss causes wood to contract, with shrinkage happening most significantly in the tangential direction (along the growth rings), less in the radial direction (perpendicular to the rings), and negligibly in the longitudinal (parallel to the grain) direction. The amount of shrinkage varies by wood species and is an important consideration in construction and woodworking to prevent warping, cracking, and joint movement."

And to support my previous statement that wood's mechanical properties vary a lot with the direction:

" Wood's mechanical properties are its responses to external forces, which vary significantly with the direction of the grain due to its orthotropic nature. Key properties include stiffness (resistance to bending), tensile strength (resistance to pulling apart), compressive strength (resistance to crushing), shearing strength (resistance to forces that cause sliding), toughness (resistance to impact), and hardness (resistance to indentation). These properties are influenced by wood density, fiber length, and the angle of the grain deviation from the longitudinal axis.

Mechanical Properties by Direction
Wood has three principal axes along which its mechanical properties differ significantly:

• Longitudinal (L) Axis: Parallel to the wood fibers (the grain direction).
• Radial (R) Axis: Perpendicular to the growth rings, also perpendicular to the grain.
• Tangential (T) Axis: Tangent to the growth rings and perpendicular to the grain.

How Grain Direction Affects Properties

• Strength: Wood is strongest when loaded parallel to the grain (longitudinally) and weakest when loaded perpendicular to it. For example, tensile strength is much higher parallel to the grain than perpendicular to it.
  
  
• Stiffness: Similarly, wood is stiffer when the load is applied parallel to the grain.
  
  
• Grain Deviation: An increase in the angle of the grain deviation from the longitudinal axis (slope grain) significantly decreases wood's bending strength, an effect seen across different wood types. "

Yes, of course.
I am not an authority, but a racket designer.
It’s not that I know everything and produce based on complete knowledge.
However, in many areas, I do have more practical experience than the average user might expect.


First, regarding what you mentioned about the wood grain: I never said there is no difference in strength depending on the direction of the grain.
What I meant is that not many woods actually show such pronounced grain structures, and especially in table tennis, the discussion should be about the impact and rebound of the ball rather than the strength measured by bending or breaking the wood.
That is why I mentioned spruce.


For example, hinoki wood can be easily scratched and is particularly weak across the grain compared to along the grain.
But when it comes to attaching rubber and hitting the ball, it has more than enough strength and hardness.
Spruce, in fact, has even greater strength than hinoki.


However, the idea of making a faster racket by adjusting the wood grain does not seem valid to me.
This is because all companies that use grained materials manufacture them in the same orientation.
There is no case where the core layer is placed with the grain running sideways instead of lengthwise.
This is simply common sense.

That is why I think discussing the grain in this context is not very useful.

1. Many woods without noticeable grain are also used.
2. It is standard practice to arrange the core layer with the grain running lengthwise, and the next layer crosswise.
3. In the case of a 7-ply blade, other arrangements may be considered, but even then, if non-grained woods are used, it is not an issue.
4. Therefore, grain orientation offers little room for increasing the racket’s power.

That said, our company uses a special gluing process to extend the limits of such materials.
By using polyurethane adhesive, we are enhancing the rebound performance of the racket.

 

[SDC]

Yes, of course.
I am not an authority, but a racket designer.
It’s not that I know everything and produce based on complete knowledge.
However, in many areas, I do have more practical experience than the average user might expect.


First, regarding what you mentioned about the wood grain: I never said there is no difference in strength depending on the direction of the grain.
What I meant is that not many woods actually show such pronounced grain structures, and especially in table tennis, the discussion should be about the impact and rebound of the ball rather than the strength measured by bending or breaking the wood.
That is why I mentioned spruce.


For example, hinoki wood can be easily scratched and is particularly weak across the grain compared to along the grain.
But when it comes to attaching rubber and hitting the ball, it has more than enough strength and hardness.
Spruce, in fact, has even greater strength than hinoki.


However, the idea of making a faster racket by adjusting the wood grain does not seem valid to me.
This is because all companies that use grained materials manufacture them in the same orientation.
There is no case where the core layer is placed with the grain running sideways instead of lengthwise.
This is simply common sense.

That is why I think discussing the grain in this context is not very useful.

1. Many woods without noticeable grain are also used.
2. It is standard practice to arrange the core layer with the grain running lengthwise, and the next layer crosswise.
3. In the case of a 7-ply blade, other arrangements may be considered, but even then, if non-grained woods are used, it is not an issue.
4. Therefore, grain orientation offers little room for increasing the racket’s power.

That said, our company uses a special gluing process to extend the limits of such materials.
By using polyurethane adhesive, we are enhancing the rebound performance of the racket.

Your are taking conclusions from your own incorrect premises, therefore your conclusions are incorrect too.

All woods have a pronounced grain structure, this is a fact, not my opinion. It appears to me that you do not know the difference between softwoods and hardwoods, which is surprising. Softwoods like Spruce, Pine or Cedar grow rapidly, so they exhibit a much clear difference between summerwood (denser and darker) and springwood (lighter and faster growing). Hardwoods grow much slower, so this distinction is not so clear to the naked eye, which forms a more homogeneous board, but it is there. Curiously, Ayous belongs to the hardwood family, despite being very soft, so it has nothing to do with density, but how the tree grows.

Again, I'm very surprised I'm even having this discussion with a blade maker...

Ply arrangement does not only take a part in controlling the warping of the blade, but it determines the blade's speed and feeling. Not only the direction of the plies, but also the nature and thickness. It's not only about making faster rackets, it's about manipulating these properties to reach a certain goal, may it be a fast or a slow blade.

Companies all use the same formula because they are all inside the same box, they are businesses in essence, so the goal is to make money after all, nothing wrong with that. So they just end up copying what is tried and true, that's why we have 846284982 Viscaria clones on the market, and every blade nowadays is using either Limba or Koto as the top ply.

Yes, it does make perfect sense using a core layer running sideways depending on what the goal for that blade is. Again, is not all about making a more powerful blade (I don't even understand this obsession...), it's about controlling other aspects like flexibility, sweetspot, feeling and of course speed. I've made and continue to make blades like this, but I can even give you a few examples that exist on the market. Your previous example of the Tibhar IV-L, the two central layers are running sideways. Another Tibhar blade, the Darco Jorgic, the Kiri core is running sideways. This case is even more interesting because they also rotated the ZLC layer. A very popular blade some time ago, the HL3 (and many 7 ply blades like it), also has a horizontal core. Another popular Tibhar blade for pure wood lovers, the Tibhar Lebesson, a 5 ply with vertical outer and medial layers and a horizontal core.

 

[Sriver1]

Your are taking conclusions from your own incorrect premises, therefore your conclusions are incorrect too.

All woods have a pronounced grain structure, this is a fact, not my opinion. It appears to me that you do not know the difference between softwoods and hardwoods, which is surprising. Softwoods like Spruce, Pine or Cedar grow rapidly, so they exhibit a much clear difference between summerwood (denser and darker) and springwood (lighter and faster growing). Hardwoods grow much slower, so this distinction is not so clear to the naked eye, which forms a more homogeneous board, but it is there. Curiously, Ayous belongs to the hardwood family, despite being very soft, so it has nothing to do with density, but how the tree grows.

Again, I'm very surprised I'm even having this discussion with a blade maker...

Ply arrangement does not only take a part in controlling the warping of the blade, but it determines the blade's speed and feeling. Not only the direction of the plies, but also the nature and thickness. It's not only about making faster rackets, it's about manipulating these properties to reach a certain goal, may it be a fast or a slow blade.

Companies all use the same formula because they are all inside the same box, they are businesses in essence, so the goal is to make money after all, nothing wrong with that. So they just end up copying what is tried and true, that's why we have 846284982 Viscaria clones on the market, and every blade nowadays is using either Limba or Koto as the top ply.

Yes, it does make perfect sense using a core layer running sideways depending on what the goal for that blade is. Again, is not all about making a more powerful blade (I don't even understand this obsession...), it's about controlling other aspects like flexibility, sweetspot, feeling and of course speed. I've made and continue to make blades like this, but I can even give you a few examples that exist on the market. Your previous example of the Tibhar IV-L, the two central layers are running sideways. Another Tibhar blade, the Darco Jorgic, the Kiri core is running sideways. This case is even more interesting because they also rotated the ZLC layer. A very popular blade some time ago, the HL3 (and many 7 ply blades like it), also has a horizontal core. Another popular Tibhar blade for pure wood lovers, the Tibhar Lebesson, a 5 ply with vertical outer and medial layers and a horizontal core.

Hipnotic is giving us a master class. Thank you!
This is a very valuable information.

 

[TheProfessor]

Do you think that simply increasing the weight makes the ball go faster?
This actually follows a curve similar to the graph I posted. Up to a certain point, increasing the weight will indeed increase the speed. However, there is a limit to the user’s physical strength, and in dynamics what matters is whether the player can swing at an appropriate speed and whether the racket can be used over a long period of time.

Therefore, an increase in weight does not necessarily mean an increase in ball speed. In fact, as the weight increases, the arm speed slows down, and in the end it becomes harder to play effectively.

View attachment 37704


In my case, by using a new glue layer I can increase elasticity without increasing the weight. I assume you may be using an epoxy-based glue layer. Epoxy always increases the weight, which means you are constantly fighting against it. Of course, good racket design always involves important choices in structure, but by changing the glue layer I do not have to deal with that particular problem.

At Nexy, we are currently working on a new project aiming to produce the fastest racket in the world. This product will be both highly innovative and extremely fast, but it will not be excessively heavy.

I will also share answers to some of the other issues you raised.

@hipnotic @Nexy designer
How would we take into account weight when it comes to power and speed of the ball, just curious if the formula of force which is F=MA matters in this situation, but also considering elasticity of the blade and stiffness.
When having a heavier blade this will increase the mass but likely decrease the acceleration... I wonder what will be the best middle ground and just had a thought as well, how different will a 157x150mm 90gram blade feel from a 161*150mm 90gram blade.

 

[TheProfessor]

Your are taking conclusions from your own incorrect premises, therefore your conclusions are incorrect too.

All woods have a pronounced grain structure, this is a fact, not my opinion. It appears to me that you do not know the difference between softwoods and hardwoods, which is surprising. Softwoods like Spruce, Pine or Cedar grow rapidly, so they exhibit a much clear difference between summerwood (denser and darker) and springwood (lighter and faster growing). Hardwoods grow much slower, so this distinction is not so clear to the naked eye, which forms a more homogeneous board, but it is there. Curiously, Ayous belongs to the hardwood family, despite being very soft, so it has nothing to do with density, but how the tree grows.

Again, I'm very surprised I'm even having this discussion with a blade maker...

Ply arrangement does not only take a part in controlling the warping of the blade, but it determines the blade's speed and feeling. Not only the direction of the plies, but also the nature and thickness. It's not only about making faster rackets, it's about manipulating these properties to reach a certain goal, may it be a fast or a slow blade.

Companies all use the same formula because they are all inside the same box, they are businesses in essence, so the goal is to make money after all, nothing wrong with that. So they just end up copying what is tried and true, that's why we have 846284982 Viscaria clones on the market, and every blade nowadays is using either Limba or Koto as the top ply.

Yes, it does make perfect sense using a core layer running sideways depending on what the goal for that blade is. Again, is not all about making a more powerful blade (I don't even understand this obsession...), it's about controlling other aspects like flexibility, sweetspot, feeling and of course speed. I've made and continue to make blades like this, but I can even give you a few examples that exist on the market. Your previous example of the Tibhar IV-L, the two central layers are running sideways. Another Tibhar blade, the Darco Jorgic, the Kiri core is running sideways. This case is even more interesting because they also rotated the ZLC layer. A very popular blade some time ago, the HL3 (and many 7 ply blades like it), also has a horizontal core. Another popular Tibhar blade for pure wood lovers, the Tibhar Lebesson, a 5 ply with vertical outer and medial layers and a horizontal core.

Which Darko blade has the central layer running sideways? I'll definitely give that one a try.

 

[Nexy designer]

Your are taking conclusions from your own incorrect premises, therefore your conclusions are incorrect too.

All woods have a pronounced grain structure, this is a fact, not my opinion. It appears to me that you do not know the difference between softwoods and hardwoods, which is surprising. Softwoods like Spruce, Pine or Cedar grow rapidly, so they exhibit a much clear difference between summerwood (denser and darker) and springwood (lighter and faster growing). Hardwoods grow much slower, so this distinction is not so clear to the naked eye, which forms a more homogeneous board, but it is there. Curiously, Ayous belongs to the hardwood family, despite being very soft, so it has nothing to do with density, but how the tree grows.

Again, I'm very surprised I'm even having this discussion with a blade maker...

Ply arrangement does not only take a part in controlling the warping of the blade, but it determines the blade's speed and feeling. Not only the direction of the plies, but also the nature and thickness. It's not only about making faster rackets, it's about manipulating these properties to reach a certain goal, may it be a fast or a slow blade.

Companies all use the same formula because they are all inside the same box, they are businesses in essence, so the goal is to make money after all, nothing wrong with that. So they just end up copying what is tried and true, that's why we have 846284982 Viscaria clones on the market, and every blade nowadays is using either Limba or Koto as the top ply.

Yes, it does make perfect sense using a core layer running sideways depending on what the goal for that blade is. Again, is not all about making a more powerful blade (I don't even understand this obsession...), it's about controlling other aspects like flexibility, sweetspot, feeling and of course speed. I've made and continue to make blades like this, but I can even give you a few examples that exist on the market. Your previous example of the Tibhar IV-L, the two central layers are running sideways. Another Tibhar blade, the Darco Jorgic, the Kiri core is running sideways. This case is even more interesting because they also rotated the ZLC layer. A very popular blade some time ago, the HL3 (and many 7 ply blades like it), also has a horizontal core. Another popular Tibhar blade for pure wood lovers, the Tibhar Lebesson, a 5 ply with vertical outer and medial layers and a horizontal core.

It seems the discussion is becoming heated, so I would ask let us calm down a little.
It is not that I am unaware of the different kinds of wood or their species.
What I cannot agree with is the idea that simply arranging the core layer with the grain running lengthwise can produce a significant difference.

Everyone knows that seasonal changes affect the way wood grows.
And of course, trees that grow in regions with less seasonal variation show less distinction.
But that is not the point I am making.

Using lengthwise grain for the core layer is what almost every company does today.
Then the next layer is placed crosswise.
So, there is little meaning in just discussing what is already common sense.

What I am saying is that, for blade makers who have been working under that standard for decades, my point may not be easily understood.
Our company has developed a manufacturing method that goes beyond what can be achieved through that conventional approach.
And we have patented that method. That is what I am trying to convey.

From the perspective of someone who has experienced that difference, I do not find much interest in discussions that focus solely on grain orientation.

The factory we operate is equipped with machines capable of producing hundreds or even thousands of identical blades under a standardized process.

 

[Nexy designer]

@hipnotic @Nexy designer
How would we take into account weight when it comes to power and speed of the ball, just curious if the formula of force which is F=MA matters in this situation, but also considering elasticity of the blade and stiffness.
When having a heavier blade this will increase the mass but likely decrease the acceleration... I wonder what will be the best middle ground and just had a thought as well, how different will a 157x150mm 90gram blade feel from a 161*150mm 90gram blade.

The shape and weight of rackets seem to have become a meaningless debate in recent years.
As I recall, about ten years ago there were rackets around 154x150mm, and also 161x150mm, but nowadays almost all rackets follow the 157x150mm standard.
Of course, many Chinese products are still often made about 2mm longer.

Nexy also once produced a 154mm model — that was the Akrasia.

I have found the development trend of racket sizes to be very interesting.
Who, I wonder, was the one that first established the 157x150mm size?

My guess is that as many companies copied Butterfly’s products, such standardization naturally took place.
Although I make slight variations in order not to follow such standardization, in the end, products that hold a dominant position in the market inevitably exert strong influence on every brand.

From experience, the racket size most commonly used by players is 157x150mm, with a weight of around 88g–90g.
There are very few cases where deviating from this range leads to success.

I sincerely hope that Nexy’s Fitting Racket Service will be a great success.
Behind this, I also hope that it will give rise to new rackets that can challenge the dominant structure of the market.
However, I do not believe that products holding a dominant form in the market gained such influence for no reason.

In fact, even I ultimately end up following that form.

 

[Nexy designer]

I would like to write a more in-depth piece about wood cracking.


Wood cracks over time.
Cracking occurs along with warping of the wood.
Warping also happens as the wood dries.


In other words, when moisture content drops below a certain point, the wood gradually begins to warp, and as a result, it can no longer withstand the stress and ends up cracking.

The woods used for table tennis equipment must be chosen with all of these phenomena in mind.


During the racket-making stage, only high-quality woods with little or no tendency to warp are used.
Softwoods that warp severely can not be used in rackets.
As I mentioned before, spruce and honoki may be used, but beyond those, woods prone to severe warping are avoided.


Ayous, which has been mentioned, is a hardwood without visible grain.
It is difficult to talk about the “grain direction” of ayous.
Other woods such as limba or koto can be described in terms of longitudinal and cross grain, but they are not like spruce or hinoki.


Many of the woods used as outer plies are hard, yet they sometimes also have little to no visible grain—mahogany being an example.


From the perspective of a racket-manufacturing factory, wood grain is not really something to agonize over.
The answer is already established.
There is little room to make big changes by simply altering grain orientation.


In a 5-ply racket, the core is placed lengthwise, the next layer crosswise, and then the outer ply lengthwise again.
In a 7-ply racket, the core is also lengthwise, the next layer crosswise, and the additional layers may be placed either way, but this does not have a major effect on the racket’s overall performance.
In many cases, the layer just beneath the outer ply is crosswise, while the next layer is something like ayous, a wood without a distinct grain.
There are also rackets with more than 7 plies, but such structures are not dominant in the market.


While producing Nexy products, I too have been constrained by these limitations.
However, our current factory has developed a groundbreaking type of glue.


This glue is neither epoxy nor water-based.
Yet by adding glue layers, the final elasticity of the racket changes—dramatically so.


That is why, in Nexy products, even with the same composition, performance can vary significantly depending on how many glue layers are used.
Those who have only used epoxy cannot fully understand this.


For example, in the Eiger blade, two glue layers are applied between the ALC material and the wood.
As a result, it shows much higher elasticity than conventional hinoki-outer products.
Of course, higher elasticity alone does not necessarily make a racket “better.”
However, achieving greater elasticity without adding weight is truly a remarkable milestone in the history of racket making.
If such a technology exists, it has the potential to bring a tremendous change to every racket in the world.


This is my point:
All other racket manufacturers are bound by conventional methods and think within those limits.
But Nexy is a little different.

 

[SDC]

It seems the discussion is becoming heated, so I would ask let us calm down a little.
It is not that I am unaware of the different kinds of wood or their species.
What I cannot agree with is the idea that simply arranging the core layer with the grain running lengthwise can produce a significant difference.

I can assure you I'm completely calm, my apologies if I conveyed the information in a way it made seem like otherwise.

However, this is a public forum, everyone has the write to reply. You are clearly trying to promote your glue method, and I don't want to get in the way of that, but you've written some incorrect things along the way. I only care about sharing correct information from a scientific point of view, my statements are supported and not based on personal feelings. So, if I see something incorrect written in my area of expertise, I will try to correct it. I'm not trying to change your mind, you are your own man and have your own views, but I will put the information out there so that everyone else can see it and judge it by themselves.

I also have my own experience, I have made thousands of blades and, apart from when customers ask me to make 3-4 of the same blade, they are pretty much all different from each other. Probably around 60-70% of these have distinct characteristics. I do so by manipulating these exact properties, and try to meet the goal of the customer, it's not just gluing layers.

Using lengthwise grain for the core layer is what almost every company does today.

Yes, and I do too, but I know why I do it, and it's not because everyone else does it.

Our company has developed a manufacturing method that goes beyond what can be achieved through that conventional approach.

Yes, the idea sounds great, but personally I like to have a firm grasp on the basics before moving forward.

In a 5-ply racket, the core is placed lengthwise, the next layer crosswise, and then the outer ply lengthwise again.
In a 7-ply racket, the core is also lengthwise, the next layer crosswise, and the additional layers may be placed either way, but this does not have a major effect on the racket’s overall performance.
In many cases, the layer just beneath the outer ply is crosswise, while the next layer is something like ayous, a wood without a distinct grain.

If you had actually made experiments with grain orientation within these structures, you wouldn't be saying this and would recognize the difference that it makes.

For example, in the Eiger blade, two glue layers are applied between the ALC material and the wood.

Ok, I finally understood what you mean by gluing the blade twice. Yes, I do this too. So, you laminate the ALC material separately, and then glue it to the wood plies using a Polyurethane adhesive. That's something I've done for a while, it's nothing new, and I have a suspicion that some very well know models from other brands are also made using this method, although that's purely conjecture, I have no way of confirming it. But yes, I can confirm it provides more speed, essentially an extra kick effect.

 

[SDC]

@hipnotic @Nexy designer
How would we take into account weight when it comes to power and speed of the ball, just curious if the formula of force which is F=MA matters in this situation, but also considering elasticity of the blade and stiffness.
When having a heavier blade this will increase the mass but likely decrease the acceleration... I wonder what will be the best middle ground and just had a thought as well, how different will a 157x150mm 90gram blade feel from a 161*150mm 90gram blade.

The simple answer is: there is no simple answer. 😅

The formula is simple and easy to understand, there is a potential for achieving more speed, if the mass and acceleration increases. However, there is a physical limitation to how much acceleration can be produced by a human. This is where technique comes in, it doesn't matter if you have a big swing or not, what matters is the acceleration of the racket at the point of impact. Of course that, bigger swings allow more acceleration, but that depends on the technique of the individual. That's why some blades like the W968 are so deadly and liked by many pros. The key to this blade is not only its composition, but also the fact that is head heavy. Pros are able to achieve more, and more consistent acceleration due to training, so the are able to extract the full power of the blade. By power I mean the combination of spin and speed, which produces a tremendous Magnus effect. Other pros have slower arm swings, or just a different personal preference, so they chose more handle balanced models. Either way, they generally chose the heavier specimens of these models because they feel more solid and are still able to generate more power because they are swinging more mass.

I don't want to get into the head size discussion, that's a lot of ink and I plan to make a post about it, but this is another area where there are a lot of misconceptions. Essentially it's about finding the correct balance for you and your playstyle.

 

[SDC]

Which Darko blade has the central layer running sideways? I'll definitely give that one a try.

Dynamic JC

 

[Egon]

@hipnotic @Nexy designer
How would we take into account weight when it comes to power and speed of the ball, just curious if the formula of force which is F=MA matters in this situation, but also considering elasticity of the blade and stiffness.
When having a heavier blade this will increase the mass but likely decrease the acceleration... I wonder what will be the best middle ground and just had a thought as well, how different will a 157x150mm 90gram blade feel from a 161*150mm 90gram blade.

Even if both blades have the same balance, the rackets assembled with the same rubber will feel slightly different and a sensitive player will be able to feel it. The second racket will have more rubber and accordingly it will be heavier, in addition the balance will shift to the head of the racket. The second racket will be more powerful on strong hits, but more inertial, which can have a negative effect on the banana.

 

[TheProfessor]

The simple answer is: there is no simple answer. 😅

The formula is simple and easy to understand, there is a potential for achieving more speed, if the mass and acceleration increases. However, there is a physical limitation to how much acceleration can be produced by a human. This is where technique comes in, it doesn't matter if you have a big swing or not, what matters is the acceleration of the racket at the point of impact. Of course that, bigger swings allow more acceleration, but that depends on the technique of the individual. That's why some blades like the W968 are so deadly and liked by many pros. The key to this blade is not only its composition, but also the fact that is head heavy. Pros are able to achieve more, and more consistent acceleration due to training, so the are able to extract the full power of the blade. By power I mean the combination of spin and speed, which produces a tremendous Magnus effect. Other pros have slower arm swings, or just a different personal preference, so they chose more handle balanced models. Either way, they generally chose the heavier specimens of these models because they feel more solid and are still able to generate more power because they are swinging more mass.

I don't want to get into the head size discussion, that's a lot of ink and I plan to make a post about it, but this is another area where there are a lot of misconceptions. Essentially it's about finding the correct balance for you and your playstyle.

Thanks for the reply, hoping to have my own SDC custom blade in the future!

 

[Nexy designer]

The simple answer is: there is no simple answer. 😅

The formula is simple and easy to understand, there is a potential for achieving more speed, if the mass and acceleration increases. However, there is a physical limitation to how much acceleration can be produced by a human. This is where technique comes in, it doesn't matter if you have a big swing or not, what matters is the acceleration of the racket at the point of impact. Of course that, bigger swings allow more acceleration, but that depends on the technique of the individual. That's why some blades like the W968 are so deadly and liked by many pros. The key to this blade is not only its composition, but also the fact that is head heavy. Pros are able to achieve more, and more consistent acceleration due to training, so the are able to extract the full power of the blade. By power I mean the combination of spin and speed, which produces a tremendous Magnus effect. Other pros have slower arm swings, or just a different personal preference, so they chose more handle balanced models. Either way, they generally chose the heavier specimens of these models because they feel more solid and are still able to generate more power because they are swinging more mass.

I don't want to get into the head size discussion, that's a lot of ink and I plan to make a post about it, but this is another area where there are a lot of misconceptions. Essentially it's about finding the correct balance for you and your playstyle.

It seems there are some misconceptions about the W968 blade.
Many of the W968 blades used by female players do not have a particularly head-heavy balance.
I have supplied hundreds of W968 blades to Korean national team players.
The players tell me the balance point they want, and I contact DHS to have the blades manufactured according to those balance specifications.
( I am suspicious about W968. But I will not write more here, because DHS is not my brand.)

It may be true that Ma Long’s blade has its balance shifted toward the head,
but that does not mean all W968 blades are like that.

My question is actually very simple:

When people say that a certain blade is fast, what kind of secret or technique is involved in manufacturing such a fast blade?
It is clear that when special materials like carbon are added, the blade becomes faster.
However, when metal sheets such as aluminum are used, the speed increase is not very significant.
So what is the difference between a metal sheet and a carbon layer?

I believe the biggest difference lies in vibration.
Also, applying multiple glue layers can have a major effect
(in our factory we use polyurethane glue layers, and we can apply up to three layers.
This technology is patented, and the exact method of producing the polyurethane glue layers is kept confidential within our company).
I think this glue-layer issue is also related to vibration.

The orientation of the wood grains in the blade (horizontal vs. vertical) can make some difference,
but it is not as dramatic as using a carbon layer or adjusting the glue layers.
In particular, there is very little room to freely change the grain orientation, so I don’t consider it a special know-how.

My goal is to write in a way that ordinary table tennis players can easily read and understand.
I will continue to write with that direction in mind.

 

[Nexy designer]

Even if both blades have the same balance, the rackets assembled with the same rubber will feel slightly different and a sensitive player will be able to feel it. The second racket will have more rubber and accordingly it will be heavier, in addition the balance will shift to the head of the racket. The second racket will be more powerful on strong hits, but more inertial, which can have a negative effect on the banana.

Below is what ChatGPT wrote about "F=MA".​

I think F=MA is not a formula we can apply to table tennis. ​

--------------------------------------------------------------------------------------------------------

How weight, stiffness, and elasticity affect power/speed​

• Momentum & impulse matter more than F = m·a alone.
  The outgoing ball speed depends on the impulse during contact (∫F dt), which is set by:
  1. your racket‐head speed at impact (from your swing torque and the racket’s swingweight/moment of inertia),
  2. the effective mass at the contact point, and
  3. the system’s restitution & damping (blade elasticity, rubber, glue, etc.).
• Heavier blade (same swing) trade-off:
  • Raises effective mass at the tip → better energy transfer and stability → potentially more peak power on full strokes.
    – Raises swingweight (I) → for the same player torque and timing, angular acceleration falls → can reduce racket-head speed, especially in quick strokes (banana flicks, late recoveries).
• Stiffness/elasticity (compliance):
  A stiffer blade (higher elastic modulus, lower dwell, usually higher eigenfrequency) tends to return energy faster (higher apparent COR) but can reduce spin window if too stiff. A slightly more elastic/damped face increases dwell/spin but may cap peak speed. There’s a player-dependent sweet spot where your swing speed × effective mass × restitution is maximized.

Does F = m·a “matter” here?​

Partly. Your arm applies torque τ to a system with moment of inertia I (swingweight). The kinematics are τ = I·α. Increasing mass or moving mass farther from the hand increases I, so α (and final tip speed) tends to drop—unless you also increase τ or lengthen your swing time. Thus, heavier ≠ always faster; it’s a balance between tip speed and effective mass/COR.

157×150 mm 90 g vs 161×150 mm 90 g (same weight)​

Keeping mass the same but enlarging the head (161 vs 157 height) pushes more mass farther from the pivot → higher swingweight with roughly the same static weight.

• How much? (rough order-of-magnitude)
  A +4 mm head length on ~157 mm is ~+2.5% in length. Because swingweight scales with distance², expect roughly ~3–5% higher swingweight (exact number depends on layup and mass distribution).
  Caveat: This is an estimate, not a measured value.
• How it feels:
  • Slightly more stable on hard impacts and blocks; a touch more powerful on full swings.
  • Slightly slower to start/stop, so quick wristy strokes (banana flicks, late counters) feel a bit more inertial.
  • Dwell/feel can also change because larger heads often shift modal frequencies (you may perceive a different “click” or vibration note).

Practical “middle ground” guidelines​

• If you rely on whippy BH flicks/close-table counters, keep swingweight moderate (e.g., ~85–90 g with neutral or slight head balance; standard 157 head).
• If you’re a full-arm looper or power driver with good timing/strength, a heavier or slightly larger head (or head-heavier balance) can yield more stable impact and higher top-end speed.
• Don’t optimize weight alone—optimize swingweight. Two 90 g blades can feel very different if one’s balance point is 5–10 mm farther forward.
• Test with the same rubbers: measure your average rally speed/consistency (or record swing speed with a phone sensor) to find your personal maximum of tip speed × stability.

 

[Nexy designer]

If you had actually made experiments with grain orientation within these structures, you wouldn't be saying this and would recognize the difference that it makes.

I started Nexy in 2007.
Please, understand that this thread was not saying that wood grain had no effect on the blade.
But as I wrote, it couod be minor effect compared with composite layer and gluing process.

 

[SDC]

Below is what ChatGPT wrote about "F=MA".​

I think F=MA is not a formula we can apply to table tennis. ​

​

The rest of the answer is in accordance with everything I had already said previously and it basically shows how the equation is indeed applicable to TT. However, the problem is not static, but dynamic, as you had already pointed out previously as well, so the answer is not so clear and direct, there are other variables at play.

It seems there are some misconceptions about the W968 blade.
Many of the W968 blades used by female players do not have a particularly head-heavy balance.
I have supplied hundreds of W968 blades to Korean national team players.
The players tell me the balance point they want, and I contact DHS to have the blades manufactured according to those balance specifications.
( I am suspicious about W968. But I will not write more here, because DHS is not my brand.)

It may be true that Ma Long’s blade has its balance shifted toward the head,
but that does not mean all W968 blades are like that.

No misconception on my part 🙂. I trust you are telling the truth obviously, but it also proves my previous point where I stated that players who stay closer to the table prefer more handle heavy blades. Female players usually stay closer to the table than male and they have shorter arm swings.

However, the W968 composition is more head heavy by nature, due to the woods it uses. While its possible to manufacture lighter specimens of course, by selecting lower density cores and veneers, it's still a heavier composition than for example Vicaria, which uses a Kiri core.

The orientation of the wood grains in the blade (horizontal vs. vertical) can make some difference,
but it is not as dramatic as using a carbon layer or adjusting the glue layers.
In particular, there is very little room to freely change the grain orientation, so I don’t consider it a special know-how.

Please, understand that this thread was not saying that wood grain had no effect on the blade.
But as I wrote, it couod be minor effect compared with composite layer and gluing process.

I never said it's a special know how, in fact I wrote that it is basic woodworking knowledge. Of course that composite layers overcome the feeling and performance of a blade (as I have also wrote), but not all blades have composites and not all composites are the same. It's about trying to fully understand the behavior of the blade in all its parts. To me it's just funny that you won't acknowledge that changing the grain orientation of the woods, which basically changes the whole structure of the blade, plays a big part on how it feels and performs, yet you claim that the gluing process (which is probably around 1% of the blade) drastically changes the behavior (which totally does).

 

[Nexy designer]

The rest of the answer is in accordance with everything I had already said previously and it basically shows how the equation is indeed applicable to TT. However, the problem is not static, but dynamic, as you had already pointed out previously as well, so the answer is not so clear and direct, there are other variables at play.


No misconception on my part 🙂. I trust you are telling the truth obviously, but it also proves my previous point where I stated that players who stay closer to the table prefer more handle heavy blades. Female players usually stay closer to the table than male and they have shorter arm swings.

However, the W968 composition is more head heavy by nature, due to the woods it uses. While its possible to manufacture lighter specimens of course, by selecting lower density cores and veneers, it's still a heavier composition than for example Vicaria, which uses a Kiri core.




I never said it's a special know how, in fact I wrote that it is basic woodworking knowledge. Of course that composite layers overcome the feeling and performance of a blade (as I have also wrote), but not all blades have composites and not all composites are the same. It's about trying to fully understand the behavior of the blade in all its parts. To me it's just funny that you won't acknowledge that changing the grain orientation of the woods, which basically changes the whole structure of the blade, plays a big part on how it feels and performs, yet you claim that the gluing process (which is probably around 1% of the blade) drastically changes the behavior (which totally does).

Nexy’s gluing method uses a recipe that other companies do not have.
And its effect is very dramatic.
Because of that, we have obtained a patent for this technology.