Difference between revisions of "Groynes"

From Coastal Wiki
Jump to: navigation, search
 
(100 intermediate revisions by 10 users not shown)
Line 1: Line 1:
 +
 +
This article describes the features, possible effects and different types of groynes that extend from the shore into the sea. [[Groyne]]s are examples of [[hard coastal protection structures]] which aim to [[coastal protection|protect]] the shoreline from [[coastal erosion]]. A more detailed treatment of the effects of groynes is given in [[Groynes as shore protection]].
 +
 
==Introduction==
 
==Introduction==
A groyne is an active structure extending from shore into sea, most often perpendicularly or slightly obliquely to the shoreline. Adequate supply of sediment and existence of satisfactorily intensive longshore sediment transport are the sine qua non conditions of groynes efficiency.
+
A groyne is an active structure extending from the shore into the sea, most often perpendicular or slightly oblique to the shoreline. The main function of a groyne is catching and trapping part of the sediment moving in a longshore direction in the surf zone. Adequate supply of sediment and existence of medium-strong longshore sediment transport are major conditions of groyne efficiency.  
Catching and trapping of a part of sediment moving in a surf zone (mainly in a longshore direction), as well as reduction of the sediment amount transported seawards, are the principle functions of the groyne.
+
However, when storm waves approach the shore more or less perpendicularly, the protective role of the groynes decreases and part of the beach can be washed away (see [[Natural causes of coastal erosion]]).
As revealed by experiments, during weak and moderate wave conditions, the groynes partly dissipate energy of water motion and lead to sand accumulation in the vicinity of a shore, thus causing its accretion. Under storm waves, mainly approaching the shore perpendicularly, the role of the groynes decreases and a beach is partly washed out.
+
 
 +
Although groynes are widely used, it is a usually not a good solution when applied as sole shore protection measure, because of important lee side erosion.
 +
 
 +
==Effects of groynes on the shoreline==
 +
The groyne design (planform, length, height, [[cross-shore profile]], inclination) influences shore morphology; the impact also depends on sea water level, wave climate and sediment supply in the surf zone.
 +
[[Image:File1.jpg|350px|thumbnail|right|Figure 1: Scheme of interaction of groynes, waves, currents and shore]]
 +
 
 +
Groynes are applied in cases of prevailing shore-oblique wave incidence and associated longshore sand transport (littoral drift). The effect of groynes consists essentially of redistributing sand along the shore. Sand is accumulated at the updrift side of the groyne at the expense of the downdrift side where the shoreline retreats. Protection of the shore by use of a single groyne is therefore most often inefficient.
 +
 
 +
Shore protection schemes using groynes are generally designed as a group comprising from a few to tens of individual structures (see [[Groynes as shore protection]]). A scheme of interacting groynes is shown in Figure 1. Whereas a single groyne produces coastal erosion on the lee side of the structure, erosion in the case of a group of groynes is shifted to the lee side of the whole system. Erosion is also observed in the direct vicinity of the structures.
 +
 
 +
Water accumulation between the groynes induces compensating flows along the structures, so-called boundary rips (see [[Rip currents]]). These flows cause local erosion of the seabed and sand loss to deep water<ref>Nordstrom, K.F. 2014. Living with shore protection structures: A review. Estuarine, Coastal and Shelf Science 150: 11-23</ref>. Strong rip flow along the updrift groyne flank has been observed even under relatively small wave significant heights (< 1 m). The groyne length relative to surf zone width strongly controls the offshore extent of boundary rips, with a significant increase in surf zone exits above a relative groyne length (length/surf width) of 1.25. <ref name=S16>Scott, T., Austin, M., Masselink, G. and Russell, P. 2016. Dynamics of rip currents associated with groynes — field measurements, modelling and implications for beach safety. Coastal Engineering 107: 53–69</ref><ref>Castelle, B., Scott, T., Brander, R.W. and McCarroll, R.J. 2016. Rip current types, circulation and hazard. Earth Science Reviews 163: 1–21</ref>
 +
 
 +
During severe storms the groynes are 'short' compared to the surf zone width, with erosion occurring around them. Under mild wave conditions groynes become 'long' (comparable to the surf zone width), thus favouring updrift sand accumulation and local widening of the beach. Loss of contact between a groyne and the shore should be avoided. In such a case, longshore flows are generated between the shoreline and the groyne root. These flows cause washing out of the beach.
 +
 
 +
==Features of groynes==
 +
[[Image:File2.jpg|350px|thumb|right|Figure 2 Types and shapes of groynes]]
 +
Appropriate choice of shapes, dimensions and location of groynes is crucial for the effectiveness of shore protection. Groyne length is usually related to the mean width of the surf zone and to the longshore spacing in the groyne field. The active length of the groyne increases with increasing wave incidence angle. Groynes are most effective if they do not trap the whole longshore sediment flux. Numerous investigations and observations suggest that the seaward extension of groynes should not exceed 40-50% of the storm surf zone width. The effectiveness of groynes also depends on their permeability. Groynes which are either structurally permeable or submerged (permanently or during high water levels) allow more sediment to pass alongshore, in comparison to impermeable or high groynes<ref>Pilarczyk K. & R.B. Zeidler.(1996): Offshore Breakwaters and Shore Evolution Control. "Balkema", the Netherlands pp560.</ref>.
 +
 
 +
The height of groynes influences the amount of longshore sediment transport trapped by the groynes. The same groyne can act either as emerged or submerged structure (Figure 2a), depending on water level changes due to tides and storm surges. Generally, groynes are designed to stick out about 0.5-1.0 m above mean sea level (MSL). Groynes that are too high cause wave reflection, resulting in local scouring. Considering the shape in plan view, the groynes can be straight, bent or curved, as well as L-shaped, T-shaped or Y-shaped. The most popular shapes and types of groynes are schematically shown in Figure 2.
 +
 
 +
==Types of groynes==
 +
In structural terms, one can distinguish between wooden groynes, sheet-pile groynes, concrete groynes, rubble-mound groynes made of concrete blocks or stones and groynes built of sand-filled geobags.
 +
 
 +
===Wooden groynes===
 +
[[Image:File3.jpg|350px|thumb|right|Figure 3. Example of two-row pile groyne at Hel Peninsula (the Baltic Sea)]]
 +
Wooden groynes are most often one- or two-row palisade structures. The influence of the T-shape wooden pile groyne on the shore (local erosion on the lee side and accretion on the updrift side) is illustrated in Figure 3. One-row wooden groynes are in general partly permeable structures; permeability reduces lee-side erosion and prevents undesirable [[nearshore]] water circulations. Wooden palisade groynes are cheap but their lifetime is rather short.
 +
 
 +
===Steel groynes===
 +
Steel groynes most often consist of vertical sheet piles, single or double, with various profiles, located perpendicularly to the shoreline. They are impermeable structures. Experiments have shown that groynes made of single sheet pile walls are not durable, due to corrosion of the material and abrasion by moving sand. Besides, ice loading is very harmful, causing instability and failure of the steel sheet pilings. Mixed massive structures, consisting of steel and concrete, are far more stable and durable.
 +
 
 +
===Groynes of concrete elements===
 +
[[Image:File4.jpg|350px|thumb|right|Figure 4 Concrete groyne, Ukraine (the Black Sea)]]
 +
Groynes built of reinforced concrete blocks belong to the most stable and long-lasting coastal structures. Because of their considerable weight, the elements composing such a groyne require the existence of suitable soil conditions and appropriate foundation. An example of a groyne consisting of reinforced concrete elements is shown in Figure 4.
 +
 
 +
===Rubble-mound groynes and groynes built of sand-filled geobags===
 +
Rubble-mound groynes are widely applied coastal protection structures. They are built either as loose mounds of stones or as mounds of various armour units, e.g. tetrapods. These groynes are often mixed structures, strengthened inside by a sheet piling. They are massive, durable and impermeable. The rubble-mound groynes are advantageous compared to steel, concrete and wooden groynes, as they better dissipate energy of waves and currents.
 +
 
 +
Groynes built of stacked sand- or ground-filled bags should be considered as a short-term protection measure. Some additional protection measures are necessary, especially at the groyne head. A special filter cloth should be used under the bags to reduce settlement in soft bottoms. This type of groynes requires large bags (heavier than 50 kg), even though large bags are more difficult to handle and require filling on the spot.
 +
 
 +
Examples of cross-sections of rubble-mound and sand-filled bag groynes are shown in Figure 2.
 +
 
 +
==Related articles==
 +
*[[Groynes as shore protection]]
 +
*[[Deteriorated groynes]]
 +
*[[Hard coastal protection structures]]
 +
*[[Human causes of coastal erosion]]
 +
*[[Natural causes of coastal erosion]]
 +
*[[Dealing with coastal erosion]]
 +
*[[Accretion and erosion for different coastal types]]
 +
*[[Port breakwaters and coastal erosion]]
 +
*[[Shoreline management]]
 +
*[[Stability of rubble mound breakwaters and shore revetments]]
 +
*[[Sand-filled geosystems in coastal engineering]]
 +
 
 +
 
 +
 
 +
==References==
 +
<references/>
 +
 
 +
 
 +
{{author
 +
|AuthorID=12956
 +
|AuthorFullName= Zbigniew Pruszak
 +
|AuthorName=Pruszak ZBIGNIEW }}
 +
 
 +
 
  
 +
{{Review
 +
|name=Job Dronkers
 +
|AuthorID=120
 +
}}
  
==Wooden groynes==
 
===subsection===
 
text here
 
===another subsection===
 
====subsubsection====
 
more text
 
  
==second chapter==
+
[[Category:Coastal protection]]
 +
[[Category:Hard structures]]

Latest revision as of 17:03, 31 October 2024

This article describes the features, possible effects and different types of groynes that extend from the shore into the sea. Groynes are examples of hard coastal protection structures which aim to protect the shoreline from coastal erosion. A more detailed treatment of the effects of groynes is given in Groynes as shore protection.

Introduction

A groyne is an active structure extending from the shore into the sea, most often perpendicular or slightly oblique to the shoreline. The main function of a groyne is catching and trapping part of the sediment moving in a longshore direction in the surf zone. Adequate supply of sediment and existence of medium-strong longshore sediment transport are major conditions of groyne efficiency. However, when storm waves approach the shore more or less perpendicularly, the protective role of the groynes decreases and part of the beach can be washed away (see Natural causes of coastal erosion).

Although groynes are widely used, it is a usually not a good solution when applied as sole shore protection measure, because of important lee side erosion.

Effects of groynes on the shoreline

The groyne design (planform, length, height, cross-shore profile, inclination) influences shore morphology; the impact also depends on sea water level, wave climate and sediment supply in the surf zone.

Figure 1: Scheme of interaction of groynes, waves, currents and shore

Groynes are applied in cases of prevailing shore-oblique wave incidence and associated longshore sand transport (littoral drift). The effect of groynes consists essentially of redistributing sand along the shore. Sand is accumulated at the updrift side of the groyne at the expense of the downdrift side where the shoreline retreats. Protection of the shore by use of a single groyne is therefore most often inefficient.

Shore protection schemes using groynes are generally designed as a group comprising from a few to tens of individual structures (see Groynes as shore protection). A scheme of interacting groynes is shown in Figure 1. Whereas a single groyne produces coastal erosion on the lee side of the structure, erosion in the case of a group of groynes is shifted to the lee side of the whole system. Erosion is also observed in the direct vicinity of the structures.

Water accumulation between the groynes induces compensating flows along the structures, so-called boundary rips (see Rip currents). These flows cause local erosion of the seabed and sand loss to deep water[1]. Strong rip flow along the updrift groyne flank has been observed even under relatively small wave significant heights (< 1 m). The groyne length relative to surf zone width strongly controls the offshore extent of boundary rips, with a significant increase in surf zone exits above a relative groyne length (length/surf width) of 1.25. [2][3]

During severe storms the groynes are 'short' compared to the surf zone width, with erosion occurring around them. Under mild wave conditions groynes become 'long' (comparable to the surf zone width), thus favouring updrift sand accumulation and local widening of the beach. Loss of contact between a groyne and the shore should be avoided. In such a case, longshore flows are generated between the shoreline and the groyne root. These flows cause washing out of the beach.

Features of groynes

Figure 2 Types and shapes of groynes

Appropriate choice of shapes, dimensions and location of groynes is crucial for the effectiveness of shore protection. Groyne length is usually related to the mean width of the surf zone and to the longshore spacing in the groyne field. The active length of the groyne increases with increasing wave incidence angle. Groynes are most effective if they do not trap the whole longshore sediment flux. Numerous investigations and observations suggest that the seaward extension of groynes should not exceed 40-50% of the storm surf zone width. The effectiveness of groynes also depends on their permeability. Groynes which are either structurally permeable or submerged (permanently or during high water levels) allow more sediment to pass alongshore, in comparison to impermeable or high groynes[4].

The height of groynes influences the amount of longshore sediment transport trapped by the groynes. The same groyne can act either as emerged or submerged structure (Figure 2a), depending on water level changes due to tides and storm surges. Generally, groynes are designed to stick out about 0.5-1.0 m above mean sea level (MSL). Groynes that are too high cause wave reflection, resulting in local scouring. Considering the shape in plan view, the groynes can be straight, bent or curved, as well as L-shaped, T-shaped or Y-shaped. The most popular shapes and types of groynes are schematically shown in Figure 2.

Types of groynes

In structural terms, one can distinguish between wooden groynes, sheet-pile groynes, concrete groynes, rubble-mound groynes made of concrete blocks or stones and groynes built of sand-filled geobags.

Wooden groynes

Figure 3. Example of two-row pile groyne at Hel Peninsula (the Baltic Sea)

Wooden groynes are most often one- or two-row palisade structures. The influence of the T-shape wooden pile groyne on the shore (local erosion on the lee side and accretion on the updrift side) is illustrated in Figure 3. One-row wooden groynes are in general partly permeable structures; permeability reduces lee-side erosion and prevents undesirable nearshore water circulations. Wooden palisade groynes are cheap but their lifetime is rather short.

Steel groynes

Steel groynes most often consist of vertical sheet piles, single or double, with various profiles, located perpendicularly to the shoreline. They are impermeable structures. Experiments have shown that groynes made of single sheet pile walls are not durable, due to corrosion of the material and abrasion by moving sand. Besides, ice loading is very harmful, causing instability and failure of the steel sheet pilings. Mixed massive structures, consisting of steel and concrete, are far more stable and durable.

Groynes of concrete elements

Figure 4 Concrete groyne, Ukraine (the Black Sea)

Groynes built of reinforced concrete blocks belong to the most stable and long-lasting coastal structures. Because of their considerable weight, the elements composing such a groyne require the existence of suitable soil conditions and appropriate foundation. An example of a groyne consisting of reinforced concrete elements is shown in Figure 4.

Rubble-mound groynes and groynes built of sand-filled geobags

Rubble-mound groynes are widely applied coastal protection structures. They are built either as loose mounds of stones or as mounds of various armour units, e.g. tetrapods. These groynes are often mixed structures, strengthened inside by a sheet piling. They are massive, durable and impermeable. The rubble-mound groynes are advantageous compared to steel, concrete and wooden groynes, as they better dissipate energy of waves and currents.

Groynes built of stacked sand- or ground-filled bags should be considered as a short-term protection measure. Some additional protection measures are necessary, especially at the groyne head. A special filter cloth should be used under the bags to reduce settlement in soft bottoms. This type of groynes requires large bags (heavier than 50 kg), even though large bags are more difficult to handle and require filling on the spot.

Examples of cross-sections of rubble-mound and sand-filled bag groynes are shown in Figure 2.

Related articles


References

  1. Nordstrom, K.F. 2014. Living with shore protection structures: A review. Estuarine, Coastal and Shelf Science 150: 11-23
  2. Scott, T., Austin, M., Masselink, G. and Russell, P. 2016. Dynamics of rip currents associated with groynes — field measurements, modelling and implications for beach safety. Coastal Engineering 107: 53–69
  3. Castelle, B., Scott, T., Brander, R.W. and McCarroll, R.J. 2016. Rip current types, circulation and hazard. Earth Science Reviews 163: 1–21
  4. Pilarczyk K. & R.B. Zeidler.(1996): Offshore Breakwaters and Shore Evolution Control. "Balkema", the Netherlands pp560.


The main author of this article is Zbigniew Pruszak
Please note that others may also have edited the contents of this article.

Citation: Zbigniew Pruszak (2024): Groynes. Available from http://www.coastalwiki.org/wiki/Groynes [accessed on 22-11-2024]